3.1 – GLOBIN GENES: STRUCTURE AND FUNCTION
1. Importance of globin genes encode for proteins which make up haemoglobin – essential physiologically prevalent monogenic disorders commonly affect globin genes their evolution are paradigms for other vertebrate genes
2. Structure of Haemoglobin & types of globin chainsHaemoglobin
65.4kDa protein that constitutes 90% of RBC proteino CA is next biggest protein constituent
made of 2a-like and 2b-like globin chains, which are roughly 50% similar each globin chain is associated with a porphyrin ring, with a haem group and Fe atom in its
centreo The porphyrin ring binds to histidine residues on the E7 and F8 domains of globino oxygen lies between the E7 histidine and iron atom
oxygen binding subtly changes the conformation of haemoglobin from a tight protein (T) to a relaxed one (R)
o binding one O2 makes binding another easier. the same for losing one O2
Types of Globin & types of Haemoglobin
A-like b-like Hb name descriptionalpha2 beta2 HbA Adult; 97%alpha2 delta2 HbA2 Adult; 1-3%alpha2 gamma2 HbF Fetal; also <1% of total adult Hbzeta2 gamm2 Hb Portland Embryoniczeta2 epsilon2 Hb Gower1alpha2 epsilon2 HbGower2
3. Globin gene & temporal relationship to haemoglobin subtypes The alpha-like cluster lies on chromosome 16
o there are two alpha genes downstream of the embryonic zeta gene The beta-like cluster lies on chromosome 11
o there are 2 gamma genes and one each of epsilon, delta and beta transcription of the genes changes temporally in relation to their distance from the 5’ end
o except for delta, which lies 5’ to beta but is probably transcribed later in life embryonic transcription occurs in the yolk sac fetal transcription occurs in the liver and spleen; adult transcription occurs in the BM all genes are highly conserved – 3 exons and 2 introns
4. brief evolution of globin genes universal monogenic globin gene underwent
duplication and mutation both alpha and beta on the same chromosome
o this occurs in meiosis due to unequal recominbation
transposition led to separation of the genes alpha and beta then gave rise to other variants
and pseudogenes (relics)
5. molecular pathology in thalassaemiasbeta-thalassaemia nonsense mutations
o this is where a coding AA is replaced by a stop codon following mutation frameshift mutations
o this is where 2 adjacent bases are deleted = shift in reading frame defective mRNA splicing
o splice junction mutations = failure of splicing = translation of introns (particularly problematic if introns contain stop codons; subsequent exons will not be transcribed)
o cryptic mutations = mutation within an intron that causes splicing machinery to use a different splice-acceptor-site
eg GA at 110 on intron 1; mediterrarean variant associated with severe disease
promoter region/ polyA mutationso promoter mutations associated with decreased mRNA production; mild disease
deletions
alpha-thalassaemia deletions are a more prominent feature because one defective allele following point mutation
can usually be compensated for by the other 3 (see alpha thal lecture)
6. regulation of the beta globin locusChallenges to regulatory mechanisms the gene must be tissue (erythroid) specific and therefore so must regulatory mechanisms you need to make the right absolute and relative (to alpha) amounts of beta globin you need to make sure to can regulate all types of globin and accommodate for switching
Regulation Locus control region; has 7 hypersensitive sites to DNAases and influences all b-like genes
o confers position and copy number dependence, as well as erythroid specificity because they have binding sites for erythroid specific TFs (see below)
individual genes have their own promoter/enhancer regionso promoters work in cis and are always 5’ to the one gene they controlo enhancers work at a distance and can be 5’ or 3’ to the gene they control
transcription factors o erythroid TFs include GATA1, EKLF, NFE2, SSPo ubiquitous TFs (in all cells) include YY1, SP1, AP1, USFo TF binding sites (LCR, promoter/enhancer regions) are highly conserved. example
sequences are CACCC, CCAAT, TATA. chromatin structure & histone modifications
o (open) euchromatin is transcribed more readily. methylation inhibits transcriptiono histone acetylation promotes transcription
7. methods to study globin genes & globin gene regulation study the effects of prevalent mutations of DNA amongst disease sufferers analyse natural mutations in humans
o eg the gamma promoter region was found to be mutated in hereditary persistence of HbF disease
transgenic technology applied to miceo standard transgenics
putting segments of human DNA into mice and seeing is they make the human protein
o knockout studies GATA1 deficient mice demonstrate erythroid maturation block at the
proerythroblast stage EKLF deficient mice die in utero and demonstrate globin chain imabalance
o Highly conserved regions MUST be important for gene regulation; some key regulatory regions for alpha genes are highly conserved regions within introns of other genes
The thinking is that conserved regions are the binding sites for TFs Modelling
o competitive model of gene switching fetal and adult globin genes compete for the interaction of the LCR. The
transcriptional environment favors particular interactions and obviously the environment changes following birth.
FKLF and SSP important for HbF (delta); EKLF for HbA (beta)o autonomous silencing model
opposite of competition; suggests that genes get progressively silenced Sequences necessary for silencing of e and g genes have been mapped to their 5’
proximal regions (eg CACCC box in g gene)
3.2 – HAEMOGLOBIN STRUCTURE AND FUNCTION
1. synthesis of Haem 1st stage happens in mitochondria, second in cytosol and third in mitochondria again. iron needed for first step; stimulates ALA synthase haem takes part in auto-negative feedback by inhibiting its own synthesis (ferrochelatase
inhibition) and iron uptake
Ala placed in urine cup produces heme
2. Functions of Haemoglobin
O2 Transporto 2,3DPG favours
O2 release (and is often upregulated in anaemia to do this)
o the O2 disso curve is due to cooperativity
o 2,3DPG, temperature, acidity and HbS all shift the curve right CO2 Transport
o although most CO2 is transported dissolved in the plasma, about 15% binds to the n-terminus of a-globin in deoxyhaemoglobin; forming a carbamate ion COO-
Buffering Nitric oxide scavenging/ transport (3 functions)
o a) converts NO to nitrate inside RBCs; free Hb in the plasma also does this oxyHb + NO + O2 + 2H+ metHb + nitrate + H2O hence excess IV haemolysis = free Hb = less NO = vasoconstriction
o b)converts nitrite to nitrate oxyHb + nitrite +O2+2H+ metHb + Nitrate + H2O
o c) when there is a lack of oxygen (in tissues), deoxyHb regenerates NO from nitrite
3. mutations in globin genes May not have any effect (synonymous/same-sense mutation) may encode a different AA with no functional abnormality may encode a different AA with a resulting functional abnormality (see below) change a coding sequence to a stop codon and give a shorter transcript change a stop codon to a coding one and give a larger transcript
o (either change in size can affect stability)
4. functional abnormalities resulting from globin gene mutationPolymerisation of Hb at low O2 pressure and decreased O2 affinity ( HbS ) mutations affect ab2 bonds or favour formation of deoxyHb
Reduced Hb solubility (HbC ) HbC heterozygosity is prevalent in western Africa (malaria protection) heterozygosity is harmless; blood film often shows boat, target cells and IRCs
homozygosity leads to crystillation of HbC, cellular dehydration and rigidity and intravascular haemolysis
o = anaemia, hyperbilirubinaemia, gallstones
increased O2 affinity (Hb Luton, Hb Kempsey) a1b2 bond mutations = defective cooperativity (hindered movement/rotation) curve shifts left = reduced O2 delivery to tissues = EPO response & polycythaemia when HCT exceed 0.5, increased blood viscosity is another problem carboxyHb (high in smokers) also interrupts cooperativity and shifts curve left.
Hb instability (Hb Koln) mutations in histidine or a1b1 bonds leads to haem falling out of porphyrin in favour of water. if
damage is extensive enough, the tetramer may dissociate the precipitation/ loss of haem is stimulated by infection/ oxidant drugs haem-less Hb precipitates as Heinz bodies and increases cell rigidity = haemolysis Hb Koln may demonstrate blister cells, where a portion of the cell appears empty heat instability test may diagnose other mutations generally affect crucial sites eg a1b2 interface, c terminal of beta chain,
mutations in 2-3dpg binding site
Tendency for Hb to oxidise (Hb M ; Hyde Park) In HbM - mutations replace histidine with tyrosine so that iron is stable as Fe3+ = inability to
transport O2 = anaemia absorption spectra are similar to that of methaemoglobin
production of a Hb that interacts adversely with HbS C, Oarab, Dpunjub HbCHbS is not as severe as SCA because HbC has a normal O2 affinity so blood Hb is
higher/normalo SC poikilocytes are curved cells (S polymerisation) with rectiangular protrusions (C
crystals)
Production of a (thalassaemic) Hb at a reduced rate which can thus interact with thalassaemias deletion of a LCR gene deletion (delta.beta thalassaemia) gene fusion (Lepore) promoter sequence/ initiation codon mutation change in gene length RNA processing (splicing/ capping/ tailing) mutations - HbE
5. Examples of variant haemoblogins with more than one abnormality Polyumerisation and low O2 affinity (HbS) unstable with tendency to oxidise/ change in affinity methaemoglobinaemia with change in affinity
3.3 – SICKLE CELL DISEASE
1. Genetic basis of SCDcodon 6 = change from GAG to GTG = swapping glutamic acid for valine (uncharged)
2. Mechanisms in reversible sicklingRole of valine fits into a hydrophobic pocket of neighbouring deoxyHbS triggers polymerisation of deoxyHbS and formation of 7 twisted double fibres of HbS
o HbA and Heterotetramers (alpha2, beta, betaS) have a reduced ability to form polymers because normal beta chains can’t engage with the hydrophobic pocket
Polymerisation deform the cell into a sickle shape. Polymerisation is triggered byo hypoxiao infection (low pH, increased temperature, increased OSM)
Sickling is initially reversible (‘boat cell’), but ultimately becomes irreversibleo we know it is a reversible process because veins have more sickled cells than arterieso sickling manifests in organs where there is a long time for cells to travel from the arterial
bed to the venous bed. this allows time for sickling. the spleen is an exampleo secondary events (see below) makes cells irreversibly sickled
3. Mechanisms in irreversible sicklingMain mechanisms – increased adhesion, increased rigidity and change in cell shape
Further roles of HbS metHbS is formed via oxidation. it breaks down into hemichromes and releases haem and Fe3+ Haem and Fe3+ oxidise membrane lipids, cytoskeleton and other HbS molecules oxidised HbS precipitates as Heinz bodies which bind to ankyrin band 3 on inner CSM
o this is seen and removed by the spleen; extravascular haemolysis
Cytoskeletal damage Oxidation = loss of ability to tether to CSM = loss of CSM vesicles decreased CSM:cell content ratio means that cell becomes more rigid
CSM damage/loss Polymers of HbS can pierce the membrane/ produce a spicule which is then lost oxidation of lipids = rearrangement of inner and outer CSM lipids and loss of lipids
o relocation of PPDserine to outer CSM = increased adhesion to endothelium & macrophages (this happens before
changes in cell shape and rigidity) phagocytosis by macrophages complement activation = intravascular haemolysis prothrombotic effect
increased IgG binding = intravascular haemolysis
Cellular dehydration (high MCHC) Oxidative damage to CSM = activation of ion transport channels = loss of K + Cl = loss of water Mg usually inhibits KCl cotransport; SCD patients usually have low Mg Polymerisation increases CSM permeability = Ca influx & activation of Gardos channels
Roles of other cells
Endothelial dysfunction = prothrombotic, increased adhesion, and production of pro inflammatory cytokines
o pro inflammatory cytokines also activate Gardos channels Macrophages bind to Ig and complement on RBCs, particularly those with altered CSMs, and
phagocytose them Neutrophils are activated, particularly during infection, and this increases their adhesive
propertieso adhesion of neutrophils to endothelium helps to trap RBCs in venules = increased transit
time = promoted sickling
Role of NO IV haemolysis = free Hb in circulation = breakdown of NO = vasoconstriction and more platelet
activationo haptoblobin and haemopexin, two mechanisms by which Free Hb is removed from the
blood, are both reduced in SCDo IV haemolysis = release of arginase = breakdown of arginine = less NO synthesis
activated neutrophils (infection) also inhibit eNOS = decreased synthesis Low NO correlates with high LDH (infarcts)
4. Pathogenesis of Vaso-occlusion in SCD VCAM1 is upregulated by the dysfunctional endothelium. it binds to reticulocytes via VLA4 reversibly sickled cells also bind to dysfunctional endothelium and exposed ECM
o young sickle cells bind to integrins via LW antigen. LW antigen is upregulated by adrenaline so stress/adrenaline = adhesion and may lead to sickling
The majority of adhesion is believed to occur in post-capillary venuleso RBCs elongate in capillary bed (surface area) and there is slow blood flow in the venuleo adhesion leads to retrograde capillary obstruction = ischaemia/infarction
Vaso-occlusive disease starts after 6 months of life – HbF protects upto this pointo Painful crises (limbs/chest/abdomen) occur in 40% of patients?o hand foot syndrome (dactylitis) in the first two years of life leads to growth delayo adolescent sequelae include delayed puberty and priapism
5. Pathogenesis of stroke in SCD Years 1-10 ischaemic stroke due to microinfarcts (17% are not apparent clinically) haemorrhagic stroke
o endothelial dysfunction = intimal (fibroblasts/SMC) hyperplasia = narrowed carotids etc = aneurysms = haemorrhage
o narrowed carotids give turbulent blood flow; Doppler monitoring and transfusions can help prevent stroke (adams 1998)
6. Pathogenesis of ACS in SCD Years 3 microthrombi in pulmonary vessels = lung infarcts vasoconstriction due to less NO due to free Hb is another important mechanism rib infarcts = less deep breathing (pain) = hypoxia = sickling importantly, ACS hypoxia sickling ACS
o other things that make ACS worse include infection and BM emboli clinical features include fever, CP, cough, SOB, wheeze, cyanosis and LOC due to hypoxia
7. Splenic dysfunction in SCD
Haemolysis Splenomegaly recurrent sequestration crises due to infarcts atrophy and fibrosis of spleen hyposplenism (Howel Jolly bodies) recurrent infections occur due to immune dysfunction, particularly malaria, pneumococcus and meningococcus
splenomegaly usually disappears after 5 years. persistent splenomegaly may indicate thalassaemia or higher HbF
8. Pathogenesis of Pulmonary HTN in SCD recurrent Episodes of ACS can lead to this because it causes thrombosis, vasoconstriction and
thickening of vascular walls/fibrosiso Low NO (free Hb) also contributes to thrombosis and vasoconstriction
can lead to right heart failure and death
9. pathogenesis of priapism in SCD priapism is an unwanted, painful, persistent erection (acute emergency) Poor venous drainage from corpus spongiosum is the cause
o decreased NO synthesis (arginase release from RBCs) = vasoconstrictiono free Hb = NO scavengingo Increased reticulocyte adhesion = slow flow = sickling
10. pathogenesis of bone disease in SCD Bone infarcts lead to a spectrum of disease
o osteomyeleitis (particularly staphylococcus and salmonella)o infarct = osteonecrosis chronic osteoarthritiso infarct = BM emboli, particularly to lungs
11. renal dysfunction in SCD Increased OSM + hypoxia infarcts haematuria, papillary necrosis, loss of concentrating
abilityo hence pay particular attention for dehydration in SCD
sickle glomerulopathy CRF & Nephrotic syndrome CRF recurrent infections
12. retinal dysfunction in SCDvascular obstruction vitreous haemorrhage. HbSHbC is particularly associated because HbC has a normal O2 affinity so you have higher Hb = viscosity
13. Why does SCD cause anaemia? red cell life is reduced 10 fold due to intra- and extravascular haemolysis EPO response means that erythropoiesis is increases 3-6fold = increase in plasma volume
o expansion of BM increases need for folic acid. folic acid deficiency can contribute to anaemia in Africa
HbS has a lower affinity for O2 in the first place – this impairs the EPO response parvovirus B19 infection arrests haematopoiesis and can lead to symptomatic aplastic crises
14. why does SCD cause thrombosis? endothelial activation, adhesion and increased TF activity Platelet activation due to less NO CSM changes (externalisation of PPDserine) is prothrombotic reduction of Protein C and protein S increased prevalence of APS antibodies15. Why does SCD cause infection?
Hyposplenism, osteomyelities, cholecystitis, leg ulcers and renal infarcts
16. interactions of HbS with other variant haemoglobinsalpha-thalassaemia trait Higher HbA2 percentage = lower HbS concentration = less sickling and haemolysis, O2 affinity
increased, higher Hbo less sickling may preserve flow small vessels; stroke is less frequent and splenic function
is better preserved higher Hb = increased viscosity so vaso-occlusive sequelae in large vessels are more frequent
than in SCDo particularly painful crises, avascular necrosis and osteonecrosis
HbC very similar genetic mutation to HbS; mutation from GAG AAG in 6th codon of beta globin
swap from glutamic acid to lysine HbC binds to K+Cl- cotransporter and aggravates cellular dehydration = ICCs
o contracted cell = increased HbS conc = sickling HbC has greater O2 affinity = higher Hb conc = small vessel thrombotic risk (retinopathy
increases 10x) less sickling = delay in splenic atrophy/fibrosis = more common splenic crises HbOarab also does this and may also activate Gardos channels
More severe than SCD HbSHbSantillesSimilar to SCD HbS/B0thal, S/C.harlem, S/OarabMilder than SCD S/C, S/Dpunjab, S/B+thal, S/leporeConsiderably milder than SCD S/B++thal, S/DBthal, S/E, S/persistence of HbF
3.4 – VARIANT HAEMOGLOBINS (remember to look at HPLC stuff from intro)
1. introduction to variant haemoglobins most mutations that lead to formation of variant Hb are single AA replacements
o others include fusion Hbs, deletions, changes in size mutations may affect one/more of structure, function, production rate and stability only a few variants are clinically significant and lead to:
o sickling – AS/SS/SC/SDpunjab/SOarab/SBthalo thalassaemias –
beta – Lepore (fusion), HbE (mRNA processing mutations) alpha – Constant spring (short chain), quong Sze (unstable)
o unstable haemoglobinso altered O2 affinityo M haemoglobins
2. detection of variant haemoglobins Clinical presentation
o anaemia, erythrocytosis, cyanosis, haemolyisis Pre-op/antenatal/neonatal haemoglobinopathy screening
o FBC indices – Hb, RBC, MCV. MCH, MCHC, RDW morphology - microcytic anaemia, hypochromia, anisocytosis
target/irregularly contracted cells in HbC basophilic stippling may point out unstable Hbs Heinz bodies/ pappenheimer bodies
o sickle solubility positive result when HbS>20%
o Hb separation studies (electrophoresis, HPLC) HPLC now the gold standard in countries that can afford it
o antibody detection for haemolytic anaemias
3. beta globin variants apart from HbS HbE
o change from 26th AA from glutamic acid lysine; leads to reduced mRNA production o The mutation is located near to the junction between exon1 and intron1 and it unmasks
a cryptic splice site, which is not normally used. this site competes with the normal splice site. Some mRNAs are correctly processed however, a large amount of mRNA is wrongly processed and reaches an early stop codon.
o trait is prevalent in N. India and SE asiao homozygosity and carrier status have a mild microcytic anaemiao need to rule out compound heterozygosity with B0thal – which resembles b.thal o travels with C on alkaline electrophoresis and A on acid electrophoresiso lies in the A2 band on HPLC; suspect if A2 rises to 25-30%
HbCo change from 6th AA from glutamic acid lysineo trait is prevalent in west Africao heterozygotes are largely asymptomatic; homozygotes have a mild haemolytic
(hyperchromic, high MCHC) anaemia, splenomegaly; look for target cells and ICCs HbD
o change from 121st AA from glutamic acid glutamineo carrier status common in Punjab/ los angeles
o target cells abundant HbO
o change from 121st AA from glutamic acid to lysineo prevalent in north Africa and middle east (arab)o compound heterozygosity with HbS is similar to SCA
Hb Leporeo fusion of delta(1-87) and beta (116-146) following erroneous recombination in meiosiso particularly prevalent in middle and eastern Europeo homozygosity is similar to B-thal major
HbHo loss of three alpha genes leads to 4 beta chains composing the Hb tetramero can be asymptomatic or can result in severe anaemia dependent on transfusionso teardrop cells in blood film may be suggestive; look for precipitating granules after new
methylene blue staining as wello fast moving on electrophoresiso low HbA2
HbKolno change from 98th AA from valine methionine makes the molecule unstableo instability = reduced life span = haemolytic anaemia appearing from 6months onwards
as beta globin synthesis starts o Film = Heinz bodies, hypochromic RBCs on film, methaemoglobinaemiao indices = mild anaemia and reticulocytosis out of proportion with that anaemiao falls in HbA window on HPLC
4. Other globin variants Delta globin variants
Variant HbA2 (change from 16th AA from glycine arginine) and Hb Lepore (see above gamma globin variants
HbBartso loss of 4 alpha genes means where 4 gamma globins make up the Hb tetramero fast moving on electrophoresiso can result in hydrops fetalis without transfusions In utero
HbPooleo change from 130th AA trom trp glycine makes the molecule unstableo presents with haemolytic anaemia in childhood that diasappears as gamm globin
synthesis ceases by end of first year of life alpha chain variants
o HbG change from 68th AA from asparagine lysine most commonly found in black Americans (Philadelphia) split HbA2 reading on HPLC
High Performance Liquid chromatography Percentage of Hb in sample is demonstrated on a graph based on their retention time Furthest left is Injection artifact (and bilirubin if it is a haemolytic anaemia sample) then, in order, is HbF, A, A2 & S
o each Hb will have, in order, glycosylated (or acetylated for HbF) and post-translation modified product peaks prior to it; these peaks always exist and may be hidden in others
3.5 – BETA THALASSAEMIAS
1. introduction to thalassaemia thalassaemia = reduced rate of synthesis of one more globin chains, and thus haemoglobin. usually produces a microcytic anaemia any globin gene can be affected, and more than one can be affected at the same time alpha and beta thalassaemia are the clinically important thalassaemias alpha globin is a component of most haemoglobins except some embryonic forms, so alpha
thalassaemia, unlike beta, is symptomatic from fetal life onwards (beta from 1 year onwards) in beta thalassaemia:
o HbA is not formed/ formed at a reduced rate (no/less beta globin)o HbA2 rises upto 10% as compensation and HbF may also do this (neither have b globin)o High HbA2 is useful in the diagnosis of beta-thal
no diagnostic use in neonates; delta globin synthesis starts at 30weeks
2. genetic syndromes arising beta thalassaemia Reduced rate of synthesis = B+
o a very mildly reduced rate = B++ absent synthesis = B0
BB NormalB+B heterozygosity/ traitB0BB+B+ homozygosity these may not be true homozygotes because each allele
may still have a different mutation – compound heteroB0B0B+B0 compound heterozygoisty
3. Mutations in beta thalassaemia MAINLY POINT MUTATIONS affecting:
o promoter regiono mRNA processing: splice site (+cryptic splice mutations), CAP/PolyA siteo size of transcript (coding AA for stop codon and vice versa); can lead to instability
Deletions in entire gene or LCR regiono mutations that result in a variant thalassaemic Hb:
o eg HbE or HbLepore (delta-beta fusion), epsilon-gamma-delta-beta Hb; (similar to b-thal trait but difficult to diagnose because delta mutation means that A2 will not be raised)
4. clinical syndromes arising in beta thalassaemia Beta thalassaemia major – transfusion is essential
o usually associated with homozygous/compound heterozygous genotypes beta thalassaemia intermedia – heterogenous presentation where survival is possible without
transfusiono extramedullary haemopoiesis, leg ulcers, gallstones, hypercoagulability and pulm HTN
can all be present. o Bad anaemia may stimulate Fe absorption = iron overloado heterogenous basis of geneotype
Homozygosity but protection from a major: mutated genes were both mutated mildly coexisting alpha thal normalizes the a:b ratio coinheritance of hereditary persistence of HbF
Heterozygosity but worsening of a minor the mutated allele is severely mutated (dominant mutation) coexisting alpha chain excess worsens the ratio
beta thalassaemia minor – asymptomatico usually associated with heterozygous/trait statuso heterozygosity = unbalanced chain synthesis = increased a:b ratioo diagnosis is based on indices, film, increased HbA2 in the absence of symptoms
Indices = almost normal Hb, low MCV, low MCH, high RBC (EPO response) Film = hypochromia, microcytes, some pikilocytes
o symptoms may arise in infection/pregnancy- but the main concern with these patients is giving birth to a beta-thal major child (25%); screening
5. clinical features of beta thalassaemia major Major pathology is severe imbalance in globin chains
o reduced beta chain directly leads to anaemia because of decreased Hb synthesiso increased alpha chains precipitate = damage to erythroid precursors = ineffective EPO
response = marrow hyperplasiao damage to eryhtroid precursors contributes to haemolysis = anaemiao marrow/ eryhtroid hyperplasia = bone deformities eg osteoporosis
‘hair on end’ appearance of skull on XR Since BM cannot effectively respond to anaemia, extramedullary erythropoiesis is triggered
o splenomegaly pooling of RBCs hypersplenismo hepatomegaly
general appearance = abdominal enlargement, respiratory distress (ribs drawn in), wasted limbs, thick skull/jaw
Diagnosis/Investigation Indices - microcytic anaemia Film
o pappenheimer bodies = iron granules in RBCso a-chain precipitates in RBCso some nucleated red cells as evidence of erythroid hyperplasiao erythroblasts may appear devoid of Hb +/- vacuoles, lobulated nuclei, basophilic
stippling HPLC – absence of HbA, high HBA2 (and HbF sometimes)
Management Conservative – PREVENTING THE MAJOR CHILD BEING BORN
o ante- & prenatal sreening, with the option of termination o model 1980 lancet said abortions are now down from 70% to 30% as a result of couples
just not taking the risk Medical - principle of treatment is monthly transfusion from infancy the major risk is iron overload – particularly affectin heart, liver and endocrine glands
o Cardiac Fe overload accounts for 75% of beta-thal deaths in Sardinia (galanello 2003)o iron chelation therapy (SC infusion 5-6days/week) with desferrioxamine helpso compliance (social problem) determines survival (thalassaemia international federation)
hydroxycarbamide helps to stimulate HbF synthesis application of treatment is poor in N.Africa, middle east and SE asia
o transfusions are a sparse resourceo screening/ chelating treatment is expensive and it is prevalent in poor countries
o cultural problems – muslims are less compliant? those who don’t accept abortion. those who will have the child anyway (poor people, workers on a farm etc)
3.6 – INTERACTIONS OF BETA THALASSAEMIA
1. Compound heterozygous states that are clinically significanto When the other allele codes for a globin which is dangerous in high concs
o S, C, unstable alleleso this is because you end up being totally unable to produce HbA
o when the other allele codes for a variant ‘thalassaemic’ haemoglobino E, Lepore
o When two different carriers reproduce, there is a 25% chance each of the offspring being normal, either heterozygote or a compound heterozygote
2. Compund heterozygooisty with HbSo is a type of SCD
o but much rarer than SCA and HbSHbCo HbS/Hbthal+ is milder than HbS/Hb0 because you make more HbA; disrupts polymer formationo both forms are milder anaemias than SCA because of higher levels of HbA2 and HbF
Increased HbA2 = increased viscosity and less sickling osteonecrosis increased by 30% compared to SCD
3. Compund heterozygooisty with HbCo Not a clinical problemo blood film might show features of thalassaemia alongside HbC crystals and target cells
4. Compund heterozygooisty with HbEo HbE only contributes 25% to the compound instead of 50%, hence this usually presents with
thalassaemic properties (microcytic anaemia and thalassaemic indices)o often comparable to a thalassaemia minor or intermedia, but severity is not easily predictableo since HbE is a thalassaemic Hb the net result is:
o very low globin chain and hence Hb synthesis = anaemiao high alpha:beta ratio = precipitates = ineffective erythropoiesis
o compound heterozygopoisty accounts for a lot of beta-thalassaemia in SE asia
3.7 - EPIDEMIOLOGY OF RED BLOOD CELL DISORDERS/ MALARIA
1. To understand the hypothesis of gene selection in terms of survival advantage as applied to malaria
Immigrant populations in the US have a high frequency of haemoglobinopathies and thalassaemias. Reasons for this could be:
o Spontaneous mutation in this group, giving rise to the disease syndromeso The disease syndromes conferred a survival advantage (malaria)
Haldane 1949 observed that The corpuscules of anaemic heterozygotes (for thalassaemia) are smaller than normal, and more resistant to hypotonic solutions; possibly conferring resistance to malaria
Impact of malaria:o Incidence 350-500million; 41% of world population lives in endemic areaso Mortality upto 25-30%; 1.5mill deaths/year mostly in children
Red cell disorders that are protective against malaria include:o Blood group antigen - Duffy/ Glycophorin variantso Red cell membrane - Ellyptocytosis/ ovalocytosiso Hb disorders - Haemoglobinopathies/ variants/ Thalassaemias o Enzyme disorders - G-6-PD
deficiency Since the traits that are protective are
so heterogeneous, there are probably multiple mechanisms in protection, and polymorphisms may even be evolving
The protective effects have been demonstrated by
o Monozygotic twin studieso Family studieso Observing ethnic differences of disease prevalence within the same environment
Eg sub-sharan Africa (HbS) have resistance to plasmodium vivax Eg Nepalese people with a-thal have lower malaria rates than those without Eg Fulani tribe west Africa (protective antibodies) have low malaria rates
o Genetic approach using case control/ epidemiological studies
2. To understand how malaria is likely to have altered the prevalence of red blood cell disorders
HbS HbS prevalent in Africa and parts of south eastern Europe Sickling disorders have high childhood mortality (infection), reduced life expectancy on average
and increased hospital demands/drain on resources SC trait affects about 29% of Nigerians by age 5, there is almost no SCA at this age
o SCA is usually lethal in childhood. ; it has higher rates of parasitaemia than HbAo Normal HbA has higher frequency and density of parasitaemia that SC trait
SC trait gives 92% reduction in relative risk of severe malaria in one case control studyo 10 fold increased protection against severe malaria but not mild malariao Protection increases with age suggesting enhanced immunity
In vitro studies suggest SC trait and SCA both give:o Impaired parasite growth
Sickling, dehydration and haemolysis of parasitised cells Polymerised HbS either poor substrate/ damages parasite function by ‘impaling’ Slow growth rate in low oxygen tension
o Increased removal by Reticuloendothelial cells Sickling gives enhanced immune recognition
o Impaired rosetting (blood group O also does this)
HbC HbC prevalent in west Africa Carriers and homozygotes are both protected. Possible mechanisms are:
o Reduced cytoadherenceo Abnormal expression of surface protein PfEMP1o Clustering of band 3
HbE HbE prevalent in N.India and SE.Asia Mechanisms of protection may include resistance to parasite invasion and enhanced clearance
Alpha-thalassaemia 80% of the tharu Nepalese have alpha-thal and have lower malaria rates
o Alpha-thal distribution amongst these people altitude (malaria) and latitude dependanto Genetic linkage analyses showed that this is not due to founder effecto Early exposure to vivax may boost immunity to falciparum leading to reduced morbidity o May also be protective against other infections
The mechanism of protection is unknown but may include:o Reduced parasite growtho Increased antibody bindingo Enhanced splenic clearance
Duffy antigen (Fy)variants thought to be receptor for P. vivax; most black Africans lack duffy antigen Blacks from West Africa as well as US rarely have P.vivax malaria
o Resistance to P. knowlsei has been deomstrated in vitro It is thought that other CSM variants (glycophorin) only partially reduce parasitic invasion
3. To understand the basic mechanisms of how red cell and other genetic polymorphisms can protect against the severe effects of malaria
A balanced polymorphism is deleterious in the homozygous state but protective in the heterozygous state
o i.e over time (and the time period required depends on the degree on protection), the compensation of the heterozygous state for the deleterious effect that would otherwise be conferred by the homozygous state, becomes fixed/universal
Some non-RBC polymorphisms that maybe interact with malaria:o HLA - B53 and DRB*1302 = lower risk o TNF secretion promotion - polymorphism of promoter 308 = higher risk o ICAM1, iNOS promoter and Haptoglobin polymoprhisms also implicated
Impact of genetic red cell disorders:o becoming a global problem with major implications on healthcare resourceso Treatment is usually expensive and not available in poor countrieso There is need for increased datao We need to target resources, education, pre natal diagnosis
3.8 - ALPHA THALASSAEMIA
1. Introduction to alpha thalassaemia Alpha thalassaemia is a reduced Hb synthesis due to a reduced rate (a+) or absent (a0) alpha
globin synthesis Of the two alpha genes, alpha 2 usually directs a higher proportion of alpha chain synthesis and
thus its deletion/mutation is more commonly implicated in thalassaemia The majority of genetic insults resulting in thalassaemia are deletions. Non-deletional mutations
include:o Point mutations etc; denoted by (aTa/aa)o Mutations that give rise to a variant thalassaemic haemoglobin eg Hb constant spring
(aCSa/aa) or Hb Quong Sze (aQS/aa) Unclear which is more severe out of deletion or non deletional
2. Genetic syndromes arising in alpha thalassaemia Heterozygous states
o Loss of one out of four alpha genes = a+ hetero (commonest form is -a4.2/aa) Unequal recombination in meiosis giving fusion of two alpha genes on one
chromosome = a+ hetero (-a3.7/aa)o Loss of both alpha genes on one chromosome = a0 hetero (--/aa)
common variants in SE Asia and mediterranen, it is otherwise prevalent in Chinese, South-East Asians, Greeks, Turks, Cypriots, Sardinians
Homozygous stateso Loss of one alpha gene on each chromosome = a+ homo (commonest is -a4.2/-a4.2)
One fusion gene each on the pair of chromosomes = a+ homo (-a3.7/-a3.7)o Loss of all four alpha genes = a0 homozygoisty (--/--)
Compound heterozgosiity arises from deletions of 3 alpha genes = a+ and a0o this is called HbH disease
Genotype
Name Phenotype Clinical significance
Genetic significance
– α/ αα A+ hetero α thalassaemia trait None None– α /– α A+ homo None None– – / αα A0 hetero None Major– α / – – Compound hetero HbH disease Moderate Major– – / – – A0 homo HbBarts hydrops fetalis Major Rather irrelevant
3. clinical syndromes arising in alpha thalassaemiaAlpha-thal trait related to all heterozygous genetic states and the two a+ homozygous states harmless loss of two genes may resemble beta-thal trait; the only significance is genetic/ screening for a0
hetero to prevent conception of a child with Hb Barts DNA analysis (because all HbA, A2 and F are reduced) is necessary to diagnose a0 hetero
o indices show low Hb (can be normal in A+ homo), MCV, MCH<25
HbH disease high beta:alpha chain ratio
o excess beta chains form tetramers, known as HbH
o HbH is ineffective at O2 transport (hyperbolic disso curve)o HbH damages RBCs = haemolytic anaemia = splenomegaly
moderately severe hypochromic microcytic anaemia HbH has a ‘less worse’ anaemia than beta-thal major because the haemopoietic response to
haemolysis is better and sustained, whereas it is ineffective in beta-thal because of the toxicity of a chain excess
Diagnosis is made byo Indices - low Hb, MCV, MCH, MCHCo Film - golf ball cells and increased reticulocyte counto Electrophoresiso Microscopy of special HbH preparation
Hb Barts & Hydrops fetalis Loss of all alpha genes means that the only Hbs that can be made are those reliant on zeta chain
= Gower 1 and Portland 1; only embryonic survival is conferredo Compensation leads to production of the abnormal haemoglobins Portland 2 (z2d2) and
Barts (g4) If both zeta genes are also lost then all you can make is Barts and e4
o This is seen in (--FIL/--) and (--THAI/--)o HbBarts and e4 are both non-functional, so in this case the embryo dies
Unless transfusion is started in utero, this condition is incompatible with lifeo abortion is usually the route takeno failure to diagnose can lead to maternal death too due to HTN - need to pick up parents
who both have a0 hetero
3.9 - MALARIA - read around pathology
DefinitionA febrile illness caused by infection of red blood cells by one of four protozoal plasmodium parasites
EpidemiologyIncidence - 515million cases/year
On the up becauseo More people are travelling to tropical countrieso Global warming favours mosquitoso There is increased drug resistanceo It is prevalent in poor countries, who are poorly equipped to deal with it, and HIV
may also play a role
Geography - ‘Malarial belt’ - S.America, Sub.Saharan Africa (70%), SE Asia, equatorial guinea
AetiologyCausative organisms Plasmodium Falciparum
o Has no life cycle outside RBCs, is becoming resistant to chloroquines and can be fatalo Higher rate of multiplication = high parasitaemia & high sequestration
Sequestration confers evasion of splenic clearance Another virulence factor is antigenic variation = evading host immune response
o Infects all steps of RBC lineage Plasmodium Vivax
o Has a hypnozoite stage in hepatocytes, has low resistance and is rarely fatalo Preferentially invades reticulocytes
Plasmodium Ovaleo Also has a hypozoite stage in hepatocytes
Plasmodium Malariaeo Low grade persistent parasitaemia
Acquisition of infection/ routes of transmission Natural - Female anopheles mosquito bite/ transplacental transmisiion
o Leads to high transmission at young ages with development of immunity as adults Artificial - contamination of infected blood (transfusion, IVDU)
o Leads to less solid establishment of immunity
Life cycle of Plasmodium On a mosquito bite, parasitic sporozoites are injected
into blood and replicate into immature schizonts within hepatocytes, which eventually burst
Schizonts mature into trophozoites within RBCso Trophozoites give rise to more schizonts = RBC
rupture and cycle repeatso Trophozoites produce gametocytes which are
taken up by mosquitos Gametocytes mature into sporozoites within oocytes,
which eventually burst and cycle repeats
PathogenesisCytoadherence - sequestration of parasites in deep vasculature = blood flow obstruction Rosetting is when a normal RBC adheres to an infected RBC. CD36, GAGs, complement receptor
1, Ig, fibrinogen and albumin all assist resetting Parasites prefer low oxygen so they tend to persist in post-capillary venules (low flow) Sequestration involves mainly infected cells but also some non-infected cells Excessive sequestration may be associated with organ dysfunction Plasmodium falciparum may bind to several cellular receptors (eg CD36, thrombospondin,
VCAM/ICAM, selectin, GAGs) simulatenously, with pfEMP1 : o Several extracellular Duffy binding-like domains (DBL 1-5) o one to two cysteine rich interdomain regions (CIDRs) between the DBLso Transmembrane region (TM)o Submembrane/Cytoplasmic
domain (Acidic terminal sequence anchored to HRP)
RBC CSM changes Insertion of transport channels Modification of membrane antigens Electron dense protruberances in the
erythrocyte membrane called Knobs increased deformability of non-infected
RBC correlates with diseases severityo anaerobic glycolysis = acidosiso Insertion of parasite antigens
on non-infected RBC Increased uptake of Ig Changes in lipid compostion
Cytokines - over/unbalanced production directly causes organ damage Cytokines are produced by macrophages and T cells
o Production increased in both falciparum and vivax malaria = severe disease Triggers for macrophages/ T cells to release cytokines
o Soluble/exo-antigens secreted into serum. (sharp increase of TNF production)o GPI anchor - Glycosylphosphatidylinositols: anchor proteins/ polysaccharides CSMo Pigment/ Products of red cell destruction
Pro-inflammatory = TNFa, IL1, 6, 8o Harmful effects of TNFa = haemophagocytosis, hypoglycaemia, tissue damage, BM
suppression, adhesion molecule productiono Although some beneficial effects = phagocytosis of infected cells, pyrogenic
Anti-inflammatory = IL4,5,10, TGFbo Dyserythropoiesis in chronic anaemia & Megaloblastic changes possibly due to low IL10,
12, high IFNg and macrophage dysfunction IFNg is also released by shizont recognition by T cells and leads to increased phagocytosis =
persistent anaemia
Mechanisms behind Anaemia Two main patterns recognised:
o Acute: due to one attack in non-immune adults and young children
o ‘Chronic’: repeated attacks may result in with intermittent fever Clinical features:
o May be obscured by the other more dramatic complications of severe malariao May be subtle and patient may be asymptomatic in chronic malariao Correlates poorly with parasitaemia and reticulocyte count
Three phases proposed, these often overlapo Phase 1: destruction of parasitised RBC - due to parasite burst and macrophageso Phase 2: destruction of non-parasitised RBC
Non-immune mechanisms = increased deformability of noninfected RBC, reticuloendothelial hyperplasia, rarely HMS (see below), DIC
Immune mechanisms = IgG, c3 dependento Phase 3: reduced red cell production
Acute malaria: Cytokine mediated suppression of erythropoiesis Reduced erythroblast iron incorporation Minor degree of dyserythropoiesis
Chronic malaria - Mainly due to dyserythropoiesis BM erythroid hyperplasia suggests ineffective erythropoiesis
o Increased proportion of RBCs in G2; megalobastic changes
Clinical FeaturesSymptoms/Signs/Examination Highly variable - depends on age, genetic factors, transmission and infective organism Acute malaria is a febrile illness in non-/semi-immune individuals. Watch out for severe malaria:
o Severe anaemia: Hb <5.0g/dl o Cerebral malaria may give unrousable coma or seizureso Respiratory complications including ARDS and severe acidosiso Hyperparasitaemia or hyperthermia and hypoglycaemiao Renal failure
Chronic malaria is typically a severe anaemia in children with Hyper reactive malarial splenomegaly (HMS) and Nephrotic syndrome if infected with P. malariae
Asymptomatic malaria may occur with P. malariae
Diagnosis/investigations Clinical suspicion - fever pattern, rigors, splenomegaly Blood count/film
o Neutrophilia in acute malaria, monocytosis, perhaps CD4 lymphopeniao Thrombocytopenia of little clinical significance
Microscopy is gold standard. Parasite species and quantitation Immunological detection of parasite antigen (Parasight™) HRP of malaria parasite Fluorescence: QBC test, DNA probes & Serology
ManagementConservative
Fluid replacement, correction of metabolic complications (hypoglycaemia and acidosis) Ventilation, renal support if required Transfusion and exchange transfusion
Medical Most antimalrial drugs are active in erythrocytic phase: (schizonticidal)
o Some (primaquine) also act against tissue schizonts, hypnozoites and gametocytes Chloroquines can be used to treat Vivax, ovale and malariae
o Some vivax may be resistant to chloroquineo Add Primaquine after clearance of parasitaemia (2days) to treat hepatic phase of P.
ovale and P. vivax (watch out for G6PD def) IV quinine for severe falciparum infections or those unable to keep down oral medication.
o Quinine For 7 days then tetracycline or Fansidar™o Parasite clearance may take >3dayso Gametocytes may persist (does not mean treatment failure)o Artemesinin and artemether derivatives also effective but still unlicensed in UK
PrognosisSevere malaria has upto 20% mortality rate
3.10 - NORMAL HAEMOPOIESIS
1. Recap of developmental haemopoiesis First signs are seen in yolk sac at 3 weeks
o This is Primitive haemopoiesis - there are no definitive HSCs; differentiation is believed to stem from sub-specialised subendothelial haemoangioblastic cord cells
Definitive haemopoiesis begins in the AGM at 5 weekso The evidence of HSC presence at the AGM came from repopulating ability of AGM cells
(de brujn 2000)o Lack of microenvironment in AGM means it cant support HScs past 7 weekso The fetal liver is not mature at 5 weeks o AGM would occlude if it sustained haemopoiesis
Hence the transition from AGM to liver is very important for life Definitive haemopoiesis continues in the fetal liver between 7-8 weeks The BM starts to make cells from 12 weeks, but the liver and spleen are the main players in
utero
2. Role of transcription factors in haemopoiesis The following transcription factors are important for initiation of haemopoiesis in the yolk sac:
o LMO2, SCL/Tal1, GATA1o They appear to cooperate; mutation in one can affect another
AML1/Runx1 is an important TF for definitive haemopoiesis, but it has no role in primitive haemopoiesis
Mutations in haematopoietic transcription factors are implicated in leukaemiaso LMO2 mutations are implicated in T-ALLo GATA1 mutations may cause M7 AML, but only in the context of Down’s syndrome
(Wechsler 2002)o Translocations in runx1 associated with AMl (8/21) and ALL (12/21) may appear in utero
3. Cells and development of different lioneages Properties of HSCs:
o Undergo self renewalo Multilineage differentiation abilityo Can sustain lifelong haemopiesis if transfuse into another
Progenitor cells have less self-renewal capacity and are committed to a select number of lineages:
o Lymphoid progenitor T, B, NK and possibly some GM cellso Myeloid everything else
In order to give full differentiation of one lineage, other lineages need to be silencedo Downs syndrome demonstrates intrinsic silencing of the lymphoid lineage = myeloid
overload Pathways following the common myeloid progenitor
o MEP Eryhtroid is the default pathway - beginning at 3 weeks and stimulated by EPO MK starts at 5 weeks, with normal platelet counts reached by 16 weeks; TPO
o GM Stimulated by GM-CSF, G-CSF and M-CSF
4. Diseases caused by stem cell abnormalities Bone Marrow failure (inc. Diamond Blackfan anaemia) Leukaemia
MDS MPD
5. Clinical uses involving stem cells SCT for:
o Bone marrow failureo Inherited RBC disorders - de la fuente demonstrated 10year disease free survival was
94.5% for children with haemoglobinopathy treated with AlloSCTo Haematological malignancies
Repair of tissue damage (dubious evidence) Gene therapy for immunodeficieneies, inherited red cell disorders - this uses AutoSCT [see
diagram]o Possibly watch out for incidence of insertional mutagenesis? French trial that gave
HMGA2 activation following lentiviral transmission aiming to cure beta-thal-major had to be stopped for 2 years
3.11 - HAEMOGLOBINOPATHIES PRESENTING IN NEONATES
1. Haemoglobins present in utero/foetuses/neonates 2-4weeks (yolk sac erythroblasts)
o Gower 1 (z2e2)o Gower 2 (A2E2)
4weeks (yolk sac erythroblasts/AGM/liver)o Portland (z2g2)o HbF (a2g2)
6-8weeks (liver/ spleen(3-7months)/BM)o Adult (a2b2)
2. Red cell indices in neonates Hb - 12-14 MCV - 105-120 (watch out for offsetting of a microcytosis by reticulocytes; RDW) MCH - 31-39 Platelets >150 Nucleated RBCs as a proportion of WBCs should be <20/100
3. Neonatal alpha globin disorders: A-thalassaemia and hydrops fetalis Alpha thalassaemias result from gene deletions. The size of the deletion impacts on phenotype
o Large deletions involve the zeta gene (thai variant) hydrops fetaluso Smaller deletions spare the zeta gene (SEA/MED) child can be born (prematurely)
without any alpha globin, because Portland (and gower1) will keep them alive Delayed blood transfusion in utero, for babies where zeta is preserved =
death/neruodisability Hydrops fetalis - mechanisms of anaemia
o Reduced Hb synthesiso Ineffective extramedullary haemopoiesiso Hb Barts (g4) is an unstable moleculeo Hb Barts precipitates = RBC damage = haemolysis & ineffective haemopoiesiso Hb Barts has high O2 affinity so less is left for Portland
Clinical features of Hb Barts/ Hydrops fetaliso Severe haemolytic anaemia with hepatosplenomegalyo Cardiac failure, oedema, pulmonary hypoplasiao Genital and limb abnornmalitieso Mother may present with polyhydramnios (due to fetal anaemia) and life-threatening
hypertension Look for target cells, increased eryhthroblasts, polychromasia (reticulocytes) and denatured Hb+
inclusions (on cresyl blue film)
4. Beta globin disorders in neonates Beta globin disorders present between 4-6months after birth, due to protection from HbF
o Thal major presents with anaemia and failure to thrive as opposed to adult symptomso SCD rarely presents with clinical features, there is no anaemia and blood film is normal
except for HbS/HbC where they may be target cells Only HbF on HPLC could = btea thal major No HbA on HPLC could = SCA (but not ture for pre-term babies who wouldn’t have HbA anyway)
5. Gamma globin disorders in neonates Rare. They cause unexplained neonatal (<1mnth) hemolysis in the first few weeks of life that
resolves as HbF dies down and HbA takes over HbPoole is a common gamma globin variant that leads to this Diagnose with HPLC/mass spectrometery
3.12 - MOLECULAR TECHNIQUES IN HAEMOGLOBINOPATHY
1. Methods in Haemoglobinpathy DiagnosisObtaining DNA Red cells are anucleate DNA can be taken from patient’s WBCs Prenatal screening uses DNA obtained from amniocytes (amniocentesis) or chorionic villi
o Samples can be taken transabdmonally or transvaginally
Analysis of DNA sample Southern blotting - not used anymore; laborious and requires radioactive substances (Sanger) Sequencing (comparing DNA sequence to a normal/wild-type DNA sequence) PCR
o Sample + TAQp+primers+buffer+free nucelotideso Denature at 95, extend at 72, anneal at 58; repeat
GAP (primers flank mutation sites) ARMS (primers at mutation sites; 1 normal & 1 mutant) RFLP (restriction endonucleases)
ASO detection system Denaturing gradient gel electrophoresis (DGGE)
2. Methods used in diagnosis of alpha thalassaemia Most common method is multiplex GAP PCR The principle is that we know alpha-thal major/ a0 hetero is down to large deletions of specified
lengtho Hence you design primers that flank the two breakpoints of the deletiono In addition you design a primer that flanks the other side of one breakpointo If the deletion occurs, the two flankers are brought into proximity (300-1000bp) and
produce a product which is different in size to the normal, undeleted allele Hence this can detect presence of a deletion
o Knowing the breakpoints/sizes of the common deletions (SEA,MED, -20.5, FIL) allows us to specifically locate the primers, and compare the products to those obtained from known alpha-thal sufferers
Hence this can detect the sub-type of the deletion
3. Methods used in diagnosis of beta thalssaemia Most common method is (Sanger) sequencing on beta globin gene
o The principle is that we know beta-thal major is down to mutations, so we can sequence the DNA and compare it to a normal DNA sequence to look for a difference
PCR can also be usedo RFLP - design restriction endonucleases that target the normal sequence at the known
mutation sites For beta globin it is commonly AA 6 (S,C), 121 (D,O), 26 (E) If the mutation is present, the sequence is not cleaved by the enzyme Lack of fragmentation is evidence for a lack of mutation >1 enzyme can be used to cover all the mutation sites in one test
o ARMS - design2 primers against a mutation size, with one targeting the normal sequence and one targeting a mutant sequence
A control is always carried out to compare strength of signal
2 strong signals = heterozygoisyt
1 strong signal from either = homozygosity
ASO detection system also used HPLC can also be used - the problem is this
only tells you there is a mismatch/mutation, but not which one it is
4. Methods used in diagnosis of other red cell disorders
Direct/Sanger sequencing can be applied to diagnose G6PD & PK deficiencies & diamond blackfan anaemia
o The most common mutant allele in DBA is RPS19
5. Principles in next generation sequencing 2 key steps are:
o Target enrichment - where you hybridise and capture Ribosomal Protein Gene DNA including exons, introns, & regulatory regions
o Cluster generation - where the DNA is bridged on a flow cell and primers are added, giving a high output sequencing method
Advantageso Much more useful than traditional methods when it comes to the diagnosis of disorders
that are down to >1 mutationo Quicko High output - you can look at 80 genes at onceo Does not require the need to know existent mutations/targeting; hence can find new
mutations that would have been missed by old methodso It is expensive, but works out cost-effective because of the time it saves youo Can probably be applied to alpha & beta thalassaemia and other red cell disorders
3.13 - OVERVIEW OF RED CELL ENZYME DISORDERS
1. Overview of red cell function Transport of O2 and CO2 (and other functions achieved by Hb) Deformability, achieved via loss in intracellular contents, is key to SA/V ratio
o No mitochondria = no oxidative phosphorylation = dependence on glycolysis Key Metabolic pathways
o Anaerobic glycolysis = ATPo Pentose Phosphate pathway & glutathione cycle (reducing power) = resistance to
oxidant damage (this is key because RBCs are particularly prone)o Pathways to remove/degrade toxic nucleotides
Enzyme abnormalities result from mutations that give rise to:o A normally functioning but unstable/ prematurely deactivated proteino An abnormally functioning protein
2. General effects of red cell enzyme disorders Tend to result in a chnoric, non-spherocytic haemolytic anaemia
o Extravascular haemolysis = splenomegaly Cycle; splenomegaly = pooling = worsening of anaemia
o Severity varies; aplastic crises may occur and splenectomy may be requiredo Pigment gall stones can be common (high BR)
Methaemoglobinaemia and polycythaemia as rarer phenotypes Red cells are particularly prone, and hence some unbiquitous deficiencies only affect them
because:o Mutant variants are less stable in RBCso RBCs can’t make more because they are anucleate o RBCs cant compensate via other pathways because they have no mitochondria
Non-erythroid abnormalities (neurological deficit and myopathies are common) can occur with deficiencies of ubiquitous enzyme without different isoforms in different lineages
Glycolytic enzymes may have other effects???o Transcriptional/ GF regulation, stimulation of motility, apoptosis control
3. Pyruvate Kinase deficiency Definition - Congenital Deficiency of PK; A tetramer with 4 isoenzymes/isoforms; PKR is the one
in RBCs; commonest glycolytic pathway deficiency Epidemiology - 1/20k in whites Pathogenesis - AR disease associated with 180 mutations; 80% of which are missense
o Possible mechanism of anaemia is ATp deficiency and anti-apoptotic effects of PK giving decreased erythroblast maturation
Clinical Featureso Extravascular haemolysis of varying severity in childhood; spleen usually enlargedo Gallstones are commono Physiological response to chronic anaemia may lead to excess iron
Investigtionso Film - normochromic anaemia, reticulocytosis, spur cells (as a mark of cellular
dehydration) Spur cells can be an artefact of RBCs spending too much time in EDTA Reticulocyte count can increase 10 fold after splenectomy
o Molecular methods are key to definitive diagnosis Management
o Conservative - folate and iron chelation
o Medical - blood transfusion in early childhoodo Surgical - splenectomy for those who become transfusion dependent
Gene therapy/ HSC transplant has been effective in murine models
4. Abnormalities of other glycolytic enzymes are RARE (<100cases worldwide) GP isomerase
o 3rd commenst after PK and G6PDo Hetergenous presentation from mild haemolytic anaemia to death in uteroo No isoenzymes = myopathies, granulocyte dysfunction, neurological deficit
Hexokinaseo Homozygoisty is lethal; carrier status is mild, also affects platelets
Phosphofructokinaseo Minimal haemolysis and mild erythrocytosiso Has multiple isoenzymes but ‘M subunit deficiency’ can cause myopathy and glycogen
storage problems Triose phosphate isomerase
o Severe disorder leading to death in utero or early childhood due to progressive crippling neuromuscular disease or infection
o Commonest mutation is Glu104Asp Phosphoglycerate kinase - X linked disorder associated with neurological deficit and myopathy Others - aldolase, enolase, LDH
5. The Pentose phosphate and glutathione cycles & related enzyme deficiencies DEFENCE AGAINST OXIDATIVE STRESS Pentose phosphate pathway generates NADPH
o Pyrimidine 5 nucelotidase catalyses the detoxification of Ump + CMP uridine + cytosine
o Deficiency = nucleotide accumulation which inhibits the pentose phosphate shunt Haemolytic anaemia, unehlped by splenectomy, with basophilic stippling
Glutathione cycle uses glutathione to detoxify substanceso Glutathione deficiency results in chronic haemolytic anaemia, can present transiently in
neonates Defects of this system =
o Increased susceptibility to oxidative stress (drugs, infections, braod beans) Hb denatures and precipitates as Heinz bodies; CSM oxidisied too
o This is an Intravascular haemolysis Acute haemolysis is due to irreversible damage to Hb; CSM rigidity ?Chronic haemolysis = high plasma oxidised Hb
If filtered by kidneys = methaemoglobinaemia If unfiltered by kidneys = blockage = renal failure
6. Some enzyme defieincies are rare causes of Polycythaemia Bisphosphoglycerate mutase is involved in late eryhtroid differentation’ it regulates 2,3P2G level
and thus O2 affinity; defiency alters affinity = polycythaemia Cytochrome b5 reductase converst metHb Hb; carriers of the deficiency get
methaemoglobinaemia and homozygotes may get polycythaemia
3.14 - INDICATIONS AND CONTRAINDICATIONS OF TRANSFUSION IN RED CELL DISORDERS
1. Indications for transfusion Episodic management of:
o SCA, including HbsB+thalo Bad phenotype HbHo bad phenotype beta thal intermedia
Lifetime management of:o HbSB0thalo Hb constant springo A0 thal including In utero transfusions of a0thal where gamma globin is preservedo beta thal major
generally not required for enzyme and membrane disorders
2. Principles of transfusion Get right blood to right Px; identify before and after, and correct labelling of products with
signatureo Don’t pre label before transfusingo Insufficient clinical information will result in sample not being processedo SHOT/SAVER are two error reporting schemes; error reporting has improved
Transfusion is generally warranted when benefits outweigh the risks (see below)
3. Transfusion in beta thal majorObjectives
Improve O2 carrying capacity Suppress ineffective haemopoiesis Maintain RBCs in circulation (not in spleen) Maintain Hb between 9 and 10.5
Iron overload & chelation 200-250mg of Fe is in each unit of transfused blood
o Cannot be excretedo Utilised poorly in patients with ineffective erythropoiesis
Accumulates in macrophages, overwhelms them and build in parenchyma = heart, liver and endocrine damage
Chelation is usually by slow SC deferoixamine 20-60mg/kg/day over 8-24hrs Some oral iron chelators (desferiox, deferipone) are available but they have side effects (GI
disturbance, neutropenia, agranulocytosis) With transfusions and compliant chelating therapy, most will live to 40-50
4. Transfusion in SCATypes of transfusion in SCA Episodic (simple transfusion) relief of crises Lifelong regimes (similar to beta thal major) aimed at maintining Hb Exchange transfusion - isovolaemic exchange
Management of Clinical syndromes in SCA Aplastic crises - are usually, but not always, transient (parvovirus B19) and resolve without
transfusion Splenic sequestration
o This is a sudden pooling of RBCs in spleen because sickled cells get trapped in sinusoids
o Hb falls to less than 6 or drops by >3 compared to baselineo Simple transfusions should be at half the expected dose to prevent viscosity, because
after transfusion the spleen unloads RBCs (auto-transfusion)o Hepatic sequestration is managed in the same way
Acute Stroke - STOP II trail said simple/exchange transfusion every 3-4 weeks in children with turbulent flow confirmed by Doppler, prevents first stroke; aim for HbAS/Hct <30%
Acute chest syndrome - simple transfusion required within 48 hours of progressive pO2 decline; exchange transfusion for rapid deterioration
Intermittent simple or exhancge transfusuions are useful for those with acute multi-organ system failure (due to infection), or patients with an isolated infection who become asymptomatically anaemic
Perioperative - GA promotes IV sickling; transfusion has been shown to increase complications after surgery; but not recommended for those with Hb>7
Pulmonary HTN, Priapiasm and leg ulcers are all controversial indications of transfusiono Partial exchange transfusion in priapism can give ASPEN (Associated with SCD Priapism
Exchange transfusion with Neurological complication); possibly due to ischaemia after acute Hct rise, and release of vasoactive compounds in detumesence
o PDGF may be better for leg ulcers
5. Transfusion in other surgeries Eye surgery - Excessive damage to microvasculature Pregnancy - reserved for hypoxaemia, progressive persistent asymptomatic anaemia, acute
chest syndrome, plenic sequestration, pre-eclampsia
6. Problems with transfusiona. Recurrent venous access becomes difficult - may require cut down procedure/ central
vein accessb. Transmission of infectious agents – HIV,HCV,HBV Bacteria CJD etc.c. Haemolytic transfusion reaction
i. Delayed reactions occur 7-10days after transfusion, with features of haemolysis and a positive coombs test
d. Immunological reactions i. In the UK most patients are black and most donors are white; poor-phenotypic
compatabiltye. Transfusion associated lung injury (TRALI)f. Transfusion associated Graft v Host disease (TA-GvHD) (Rare)g. Post transfusion Purpura (PTP)h. Anaphylaxis/ Allergic /Febrile reactionsi. Hyperhaemolysis syndrome
i. Sevre haemolysis, reticulocytopenia, hyperbilirubinaemia, haemoglobinuria after transfusion
ii. Both patient and donor cells are haemolysediii. Coombs test usually negative
3.15 - CHALLENGES OF BLOOD TRANSFUSION IN AFRICA
1. General challenges High transfusion demand - maternal and child mortality is high Lack of resources:
o Unsafe blood pool (HIV) and distribution Donors can often be lost to follow up/repeat donation
o Lack of pooled resources; lack of ICTo Poor quality testing, standards and regulation
Outdated equipment is a source of error Social aspects - most healthcare in Africa is private so most people can’t afford it
o Hence NGOs are trying to replace hospital based services with centralised specialist ones A major challenge is developing a sustainable system
2. Sources of mortality Maternal
o Pregnancy-related haemorrhage accounts for 34% maternal deaths (within 2 hours)o This is complicated by high starting rates of anaemia amongst motherso In Africa blood can’t be given in 2 hours, antenatal screening (ABO) is unreliable and
there is no records service, which would allow transfusion without X-match in an acute situation in other countires
o 48% of deaths could be avoided by: Improving initial management of critical patients, and postpartum monitoring Improving availability of blood transfusions
Childo 20% mortality rate below the age of 5; mostly due to malaria and lack of transfusion
support
3. How a transfusion service usually works Recruit donors test and process their samples give samples to blood banks
Sources of blood donors - evidence from ghana, guinea and Cameroon says volunteer are the best sources - lower Hep and HIV rates of tansmission
o Voluntary Students are a major source of donors in africa Watch out for seroconversion in repeat donors
o Family ?high risk infection
o Commercial (paid to donate) Often poor people looking to make quick money - high risk of infection and give
blood more often than is safe Solution - get rid of commercial donors and get more voluntaires. Get family members on the
register so they can donate to people who aren’t their relatives
Problems with recruiting donors in Africa Loss of donors/ poor donor pool (see above)
o 20% of recruits are probably positive for a blood borne infection in Africa; a further 0.1% of repeat donors will acquire one
o Donors can also be lost through death, lack of interest, migration Financial - Expectation of reward = decreased altruistic values = high chance of deviant
behaviour
Blood donation is free but there is a fee charged to patient from hospitals. Social - Fear of getting an adverse HIV sero-status report/ others knowing this Bureaucracy Lack of education
Testing & processing Rapid testing is used in Africa, which is better than nothing but there is poor quality control, has
a high fals positive rate, and there is the social problem of telling people they are diseased within minutes of them coming in to donate blood
It can test foro HIV - EIA, p24o HBV - HBsAgo HCV - EIA, Subtyping NATo Syphilis - TPHAo Also malaria and other parasites, HTLV
4. Poor technology and economy are other reasons making transfusion difficult in Africa IT is needed for
o reliable database about donorso traceability about who has donated what to whomo automated control of blood testing and processingo communication between transfusion centres
Money is needed foro Donor recruitment, campaigning etc.o Good quality equipment for Blood testing and processingo Staff costso It is probably more economical to centralise services in Africa rhater than put these
services in every hospital There are more bodies of regulation and laws in MEDCs than Africa, outlines roles and
responsibilities of blood establishments and blood bankso UK - MHRA; USA - CBER
5. Case study about Nigeria Has 6 geo-political zones, each with a regional specialist screening centre Most transfusions used to come from family and commercial donors HIv prevalence is not as high as other African countries Maternal and child mortality rates are high, as are malaria and sickle cel incidences The Abuja project 2004 did the following:
o (club 25) encourages high school leavers to pledge to a healthy lifestyle and donate blood
o Provided training RE knowledge, quality control, donor recruitment, safetyo Introduced standards in the laboratory
Lagos is a state in neigeria that does better off because it has laws restricting transfusion to licensed centres, and a paper-based records service
3.16 - AIHA & CHD
1. Classification of acquired haemolytic anaemia Immune
o Warm (IgG)o Cold (igM) CHD & PNH
Non-immuneo Infectiouso Haemophagocytic syndromeo MAHA/fragmentation syndromeso Drug induced
2. Antibodies in haemolytic anaemia & Coombs Test Auto antibodies - produced against self RBCs Alloantibodies
o Self antibodies acting against foreign cells in transfusiono ‘autoantibodies’ that are secondarily acquired due to drug-inductiono Placental transfer of HPLa1a? antibodies in HDN
Evidence for haemolysiso Increased RBC breakdown
Urine haemoglobin urobilinogen, serum bilirubin and LDH all increase Haptoglobins are all used up
o Increased RBC production - reticulocytes, Erythroid hyperplasiao Morphological features
SPHEROCYTES AIHA is the commonest cause of spherocytosis (small dense cells) AI damage CSM removal spherocyte; ultimately dies prematurely
Polychromasia (reticulocytes) Direct antiglobulin/ coombs test - looking for and Ab already bound to RBCs
o Uses antihuman complement or antihuman globulin and adds to red cell concentrate and centrifuges the mixture
o Clumping is a positive result (the added antibody bridges those that are bound to RBCs) Indirect antiglobulin test - looking for presence of a Ab in a Px who has previously been
sensitised (screening)o Uses recipient serum, which is removed after mixing donor RBCs, and then adds the
antihuman complement/globulin as with coombs
3. Warm AIHA Definition - Autoimmune AIHA involving IgG against RBCs = Intravascular haemolytic anaemia Epidemiology - 1/75k per year; accounts for 60-70% AIHA Aetiology - 50% are idiopathic and the reminader occur in context of underlying disease eg CLL Pathogenesis - IgG binds to RBCs (targeted antigens include Rh) Clinical features - variable but often severe haemolytic anaemia, can be rapid which is an
emergency (often in the elderly) or an indolent disease course Investigations - features of shortened RBC survival (see above), reticulocytes, spherocytes, and
thrombocytopenia may also be present (evans syndrome)o Coombs test may show presence of IgG, C3d, or botho Elution studies also show presense of IgG
Management - corticosteroids are the mainstay; 60-100mg on alternate days for three weeks achieves remission in 25-30% of patients
o Splenectomy may also require maintenance low dose prednisolone
o Rituximab (bussone 2009) achieved remisiion in 18/27; only 2 failedo IVIg and plasmapheresis are other optionso Don’t transfuse unless theres life threatening anaemia
4. CHD Definition - Autoimmune AIHA involving IgM against RBCs = Intravascular haemolytic anaemia
mediated by complement at cold temepratures. Can be acute or chronic. Epidemiology - accounts for 1./4 of AIHA Aetiology
o Acute CHD can be idiopathic or secondary to Mycoplasma infection or prolymphocytic leukaemia
Pathogenesis - IgM binds complement to RBCs at 4degs; the antibody dissociates on warming but complement remains and causes RBC lysis via MAC and phagocytes
o Peripheries (get cold quickest) are worst affectedo There are 3 types of CHD:
Primary/Idiopathic Clonal Ab Anti. ISecondary to lymphoporliferative disease (PLL) Clonal Ab Anti ISecondary to infection (mycoplasma) Polyclonal Ab IgM, anti I or anti I (EBV)
Clinical features - indolent chronic anaemia, exacerbated in winter; acute crises can give haemoglobinuria
o Raynaud’s may also be present Investigations
o Film - clumping of RBCso Serology - IgM, complement coating of RBCs, high titre cold agglutinins and anti I
antibodies (except EBV where it is anti i) Mangement - AVOID THE COLD; be wary in cold operations e.g. cardiac bypass
o Chemo/rituximab may be useful for PLL patients
5. PNH Similar to CHD but mediated by IgG which means dissociation can occur at higher temperatures
so haemolysis may occur at something like 20degrees (biphasic haemolysin) Usually secondary to infection (syphilis, VZV) and hence episodic and transient but severe cases
may need transfusion Anti P antibodies Diagnose with Donath-lanstiener test where you take 2 samples; keep one at 0 and one at 37,
warm the 0 one up to 37 and then centrifuge both; the 0 one will haemolyse because the change in temperature activates complement mediated lysis
Manage by treating underlying cause
6. Other acquired haemolytic anaemias Mixed Type AIHA - both IgG and IgM; may respond to steroids IgM Warm AIHA - rare, poor prognosis Drug induced - 4 mechanisms
A Drug binds to RBC and attracts IgG PenicillinB Drug binds to Ig in serum and the complex binds to RBC Methyl/levodopaC Drug-Ig-RBC form and immune complex QuinineD Plasma protein? Cephalosporins
3.17 - THE SPLEEN
1. Structure of the spleen Derived from Mesenchymal stem cell Major component of reticulo-endothelial system Can regenerate if part of it is removed Considered enlarged (USS/ CT/MRI) if >14cm by lognest axis Vasculature - Supplied by splenic artery (coeliac axis) and drained by splenic vein (portal vein)
o Hence portal HTN backflow splenomegaly Histology- made of white pulp (lymphoid follicles) and red pulp composed of splenic cords
(monocytes/macrophages)
2. Functions of the spleen White pulp - antibody production & a reservoir of lymphocytes Red pulp
o Filtration and phagocytosis of abnormal RBCs o Removal of RBC inclusions eg howell-jolly bodies, precipitateso Pitting, malaria?o Reservoir of red cells and plateletso Synthesis of complement and F8o Capable of haemopoiesis in BM failure
3. Causes of splenomegaly** = massive splenomegaly = extension below umbilicus
Infectiouso Visceral Leishmaniasis**o Malaria (HMS**)o Bacteria (Brucella, TB) & Viruses (EBV)
Haematologicalo Hbopathies - Thalassaemia major** (and bad intermedia), Early SCA and HbSCo MPDs - CML**, Myelofibrosis**, PV**o Lymphomas - SLVL
Storage Diseases (Gauchers**) Collagen disorders Congestive (varices, portal HTN) Inflammatory - felty’s syndrome (RA)
Splenomeg pooling hypersplenismo Peripheral cytopenia and anaemia (high proportion of circulating volume in spleen)
4. Splenectomy Indications
o TRAUMAo ITP, hereditary spherocytosis, lymphoma, MPD, Thalassaemia
Complicationso Perioperative bleedingo Infections
Encapsulated bacteria; pneumococcus, meningococcus, haemophilus 5 fold increase in sepsis, highest in children Give immunisations (pneumovax2) and prophylactic antibiotics
o Thrombocytosis after 7-12days and hence embolism
o Recurrence of initial disease (ITP) may suggest splenosis/accessory spleen (present in 15% of population); splenosis is seeding of splenic tissue onto peritoneum following rupture
5. Causes of hyposplenismLong term Splenomegaly, without splenectomy, usually turns into atrophy
SCA (infarcts = fibrosis = atrophy) Long term effect of Myelofibrosis, ET, SLE, RA Coeliac, dermatitis herpetiformis Congenital absence of spleen
6. Features of hyposplenism/ splenectomy
Haematologicalo lymphocytosis & monocytosis & reticulocytosis o Thrombocytosis, leucocytosis may also occur transiently
Morphologicalo Persistence of things that the spleen usually removes:
Howell jolly bodies (nuclear) Heinz bodies (Hb) Pappenheimer bodies (siderotic) Target cells, acanthocytes, irregularly contracted cells, nucleated RBCs,
spherocytes
3.18 - TRANSPLATION IN NON-MALIGNANT DISORDERS (possibly read around this)
1. Principles of HSCT Primary objective is to achieve myeloablation and hence eradicate disease Secondary objectives are to avoid graft failure and Graft versus Host Disease This is possible by
a. HLA matchingi. memo - intracellular peptides are presented by class 1 & extracellular by class 2
b. Myeloablationc. Immunosuppression
Stem cells can be obtained from PB, BM, Unbilical cord or via Haploidentical transplant The obtained sample can be subsequently depleted of red cells, plasma or t cells
2. Infections after HSCT Infections occur because:
o Tissue damage from conditioning regimens: mouth and gut = mucositis skin
o Hickman line, Neutropenia (early), Immunosuppression (late) Common infections include:
o Bacterial: G-ve gut flora, Skin Staphylococcus ,Throat Streptococcus o Viral - CMV, HSV, adenoviruso Fungal - candida, aspergillus
3. Graft Failure (Host versus graft disease) Primary failure does not achieve a neutrophil count (0.5e9) within 28days Secondary failure occurs after evidence of engraftment (you achieve the count and it drops off)
o Neutropenia almost always accompanied by thrombocytopenia and anaemiao Exclude the following: infections (parvovirus), drugs, GvHD, hypersplenism
4. Graft versus host disease GvHD is an immune response accentuated/ stimulated by injury from the conditioning regimen
o Skin: pruritic micropapillary rash on palms, soles, or face; may become generalizedo Gut: nausea, vomiting, abdominal pain, diarrhoea, bloody stoolso Liver: jaundiceo Lung: SOB and hypoxaemia
GvHD and its treatment immunosuppression fatal infection Management options in GvHD:
o Conservative - dietetic intervention with formula feeding/ TPNo Corticosteroids - topical/ systemico Immunosuppression: e.g. tacrolimus, mycophenolate mofetil, sirolimuso Monoclonal antibodies: e.g. dacluzimab, infliximab
5. Side effects of treatment Hepatic veno-occlusive disease
o In the context of HSCT, caused by total body irradiation, busulfan, cyclophosphamideo Pathology is that damaged sinusoidal endothelium sloughs = circulation blocko Clinical features include painful hepatomegaly, rapid weight gain, jaundice, peripheral
oedema and ascites, and possibly renal & respiratory failure if severe enougho Manage with defibrotide and fluids
Increased risk of solid tumours
Long term FX - infertility, pubertal failure, chronic GvHD, organ toxicity, secondary malignancyo Eggleston 2007 suggested both height and weight were impairedo Walters 2010 showed males demonstrate hypogonadotrophic hypogonadism (normal
hormone levels) whereas females show primary ovarian failure (increased hormone levels); lukasa showed males demonstrate azoo/oligospermia
o CNS problems - stroke/ silent infarcts (cognitive problems) Other Limitations:
o Lack of donors - the eurocord study 2003 Only 18% SCD patients have a matched donor who is not affected Ethical considerations, psychological cost to the parents and financial cost
o Lengthy hospital stay (2 months; followed by 4 month outpatient management)o Transplant related mortality (leukaemia module said this was upto 50%)
Solution is to reduce the intensity of conditioning without compromising unwanted immune responses occuring
6. Roles of HSCT in non-malignant haematological conditionsAcquired Aplastic anaemia Usually reserved for patients <40 with a matched sibling
o Otherwise ATG + CsA is common Young 2010 showed matched donors have greater survival than non-identical; especially early
on Stepensky and Rosenborg did work on Fludarabine as the conditioning regimen, this is now
recommended ifo Plt <40, Hb <9, neutrophils <1o Persistent cytogenetic abnormalitieso MDS/AML co-presence
DC - alemtuzumab, cyclophosphamide, fludarabine and TBI with 200cGy is the conditioning
Diamond-Blackfan 40% of patients become dependent on transfusions; the majority of the remainder who are not
dependent on transfusions are dependent on steroids Several studies have shown the HSCT improves survival (75-80% 5 year survival) Matched donor is recommended for transfusion dependednt patients Unmatched donors can be used in severe circumstances eg development of aplasia/ AML/ iron
overload
Thalassaemia The preparatory regimen includes administration of busulfan, fludarabine and
cyclophosphamide, which can eradicate the thalassemia clone, enhance immunosuppression, and facilitate sustained allogeneic engraftment
Survival is influenced by the Pesaro risk classification:o Class 1 (1 risk factor) has 94% survival; 87% thal-free survivalo Class 2 (1/2 risk factors) has 84% survival; 81% thal-free survivalo Class 3 (3 risk factors) has 80% survival; 56% thal-free survivalo Risk factors are hepatomegaly, irregular chelation and portal fibrosis
HSCT associates with functional liver improvement and lower hepatic Fe conc (Mariotti 1996)
SCD - Blacks do better than whites in SCA; and females do better than makles (platt 1994)
3.19 - MOLECULAR BASIS OF ALPHA THALASSAEMIA
1. Physiological abnormalities in thalssaemia On a molecular level. The body can’t detect, or rather it doesn’t downregulate what you have
left (as this would worsen an already poor O2 carrying capacity), when one globin chain is thalassemic
o This is why chain imbalance results from thalssaemiao This is why high HbF protects from bet-thal major in HPHF and in the neonatal period -
gamm globin ‘mops’ up free, cytotoxic alpha chain
2. Transcriptional environments of globin gene clusters Alpha locus is in a GC rich area = easily unwindable
o Beta globin is in a GC poor area Alpha locus is in a CGP island rich area = less methylation
o Beta globin is in a CGP island poor area Alpha genes are surrounded by a lot of ubiquitous/housekeeping genes = more open chromatin
as it needs to be readily transcribedo Beta genes are surrounded by fewer, tissue specific genes = closed chromatino Hence, major control of alpha genes is keeping genes off at the wrong times, whereas
for beta genes it is turning genes on at the right times
3. Transcription factors in eryhtroid development In cis factors are factors produced by one chromosome that affect other genes on the same
chromosome In trans factors affect genes on chromosomes different to the ones from which they originate Globin gene expression increases as erythroid cells mature Important early TFs = nuclear/ ribosomal proteins, other TFs, eg PU1
o HSCs have GATA2 and SCL targeted against HS40o CMP has GATA1 and SCL tagrted against HS40 and local promoter regionso important) at the centre = transcription
Late TFs = haem/ globin e.g GATA1o Proerythroblasts have NFE2 poising the cell so it is ready to make globino The thinking is that in RBCs, the polymerase complex causes DNA to loop so that all the
regulatory regions come into physical proximity with the alpha genes at the centre (a2 more than a1)
o Late factors may inhibit early ones to further promote differentiation (GATA1 inhibits PU1)
Transcription factors bind to euchromatous regions; highly conserved regions are euchromatous
4. Epigenetic control of alpha globin transcription Heterochromatin has methylation of histones at H3K27 / K9 Euchromatin has acetylated histones and methylation of J3K4 Chromatin remodelling factors use ATP to ‘remove’ histones completely, leaving free DNA for TF
bindingo CRFs preferentially bind at key regulatory sites
CHIP; chromatin immunoprecipitation; is a useful study for examining epigeneticso You mix DNA with formaldehde and blast it with sound waves so chromatin fragmentso Then you treat some of it with anitbodies against histones, CRF, Tfs etco You label bound and unbound chromatin with a colour each, and areas where the
colours match are important and colour poor regions are not importanto Lining the colours up with the DNA sequence tells you which gene it is
5. Alpha thalassaemia mutations without alpha globin deletion There are some deletions that do not involve either alpha gene but seem to overlap in a region
5’ of the a2 locus - this is probably a key regulatory element There is one syndrome where deletion of one gene (A+ hetero) presents like HbH
o Not sure if the rest of this is completely true but it’s something along these lineso Here, the deletion of a1 and its stop codon leads to extended activity of a reverse mRNA
3’ of the a1 locus, which is not stopped by normal antisense mRNA (because the a1 is missing)
o This leads to increased susceptibility from DNA methyltransferaseo So you have deletion of one gene and methylation/downregulation of others
There is a mutation that allows binding of GATA1 at the wrong site = polymerase complex centres DNA looping at the wrong site = dysfunctional mRNA produced even though both alpha genes are normal
ATR-X syndromeo Presents with mild anaemia, retardation and only affects boyso ATR-X gene is on the x chromosome (in-trans factor). The inherited mutation is believed
to untangle DNA to make looping and transcription easier and therefore more likely to occur at wrong sites
o The idea is that the polymerase complex moves along DNA like a zip, so any site that is ‘primed’, rightly or wrongly, will get transcribed
ATMDS syndromeo Acquired ATRX mutationo Unlike ATRX syndrome, it presents like HbH, it can occur in women and is not associated
with mental retardationo It is believed that the differences between ATRX and ATMDS’s presentation, despite
having the same mutant gene, is due to the influence of genetic changes associated with MDS
3.20 - AN ANTENATAL SERVICE FOR DIAGNOSING HAEMOGLOBINOPATHY
Shit lecture; very simplistic; essay is definitely a better source of information; all that is here is the main points from what he said
NHS SCT was set up in 2001 (universal screening had been in place in ‘high prevalence’ areas since the 1980s)
High rpevalnce is defined as a positive test result 1.5k/10k pregnancies sct.screening.nhs.uk cpd.screening.nhs.uk/timeline otherwise everything and more is in the essay
3.21 - HAEMOGLOBINPATHY DIAGNOSIS PRACTICAL ( important, read bain’s book and do online sheets)
FILM Heinz bodies indicate G6PD or an unstable Hb
o E.g. Hb Hammersmith Acanthocytes are spindly cells that are associated with hypospleism
INDICES MCH <25 is common with a0 thal MCH <27 is common for beta thal majore
ALKALINE GEL ELECTROPHORESIS
+VEC
Origin
SA/E/D/G/A2F-VE
Correct wording is ‘there is a band with the same mobility of…. [CSFA] Barts and H are ‘fast moving bands’ You can separate between D and G (D being a beta variant and G being an alpha variant)
because G will show 3 bands Small irregular (shit looking) bands around the origin may suggest denatured Hb - unstable
variant Hb Lepore moves with S
ACID GEL ELECTROPHORESIS
Most acid traces give a prominent F band anyway - don’t automatically think persistence of HbF/ beta thal etc
HPLC Percentage of Hb in sample is demonstrated on a graph based on their retention
time Furthest left is Injection artifact then, in order, is HbF, A, A2 & S
o each Hb will have, in order, glycosylated (or acetylated for HbF) and degradation product peaks prior to it; these peaks always exist and may be hidden in others
If a variant window takes up 50% of total haemoglobin, it is probably a beta globin varianto Alpha chain variants take up 25% (4 genes)
High HbA2 and HbF in beta thal trait/major (match with clinical picture and electrophoretic bands)
For HbE - look for an A2 percentage which is high and roughly a third of the total haemoglobin; this is because the splicing mutation in HbE only makes the correct product 1/3 of a time
For Hb Dpunjab - look for a steep window to the right of A2o A wide based window is seen with Hb Kempsey - a variant with a high O2 affinity
You need a O2 disso curve to diagnose high affinity haemoglobins Small irregular (shit looking) windows may suggest denatured Hb - unstable variant HbH shows an equal double peak to the left of HbF wheras Hb Barts is a steeper peak; looks
more like hyperbilirubinaemia HbS is to the right of A2 Hb Lepore can be present if the A2 window is increased to 10-15%
o Homozygoisty presents like beta-thal intermedia A delta variant called HbA2’ gives a peak that looks like S and a mildly increased A2. Add the
two peaks for the true A2 value; and suspect heterogeneity with a beta-thal if the A2 total is high
Origin band CA A2/C/E S/D/G F A (Portland, barts) H
3.22 - PSYCHOLOGICAL DIMENSIONS IN SCD & THALASSAEMIA
1. Initial Challenges faced by affected child Cognitive
o Understanding the cause, prognosis, and complications of the diseaseo Need for parents to revise their expectations/visions of their childs lifeo Recurrent strokes can directly impair cognitive function, attention, executive function
Emotionalo Coming to terms with the illnesso Dealing with fears/ anxieities about illnesso Uptake of faith? Hoping and praying
Behavioural/social
o Degree of dependence of affected individual on otherso Impaired social life due to treatment burden, hospital visits etc
Loss of schooling and academic involvement of the child (CF cognitive challenges)
o Social problems faced in concern with poor pubertal growth; body image; confidenceo Disease may limit some aspects of ‘normal’ activityo Effect of disease on relationships with family members, family income etco Affected family may become isolated
2. Issues arising in adolescence Limitations of disease burden Strain on relationships Attitudes formed against health professionals Compliance to treatment
The AT&T study group 2000 said important issues are giving knowledge to the patient so they can become self-dependent. Confidence and self-efficacy increases with age and when they are confident enough, parents can relinquish care/ responsibility
3. Challenges in intervention Shifting the emphasis from hospital-based to community/ independent care Establishing home support Maintain their quality of life
4. Psychosocial Interventions that can be used Psychoeduaction - establighes groupwork, encourages coping and improves education Problem-solving CBT - encourages coping, provides emotional support
and encourages self-help Neuro-education- computer programs that provide
neuro-psycological assessments Expert patient programme - DH initiative that teaches
patients about self-management in a chronic illness We need to incorporate psychosocial interventions
into clinical management protocols
3.23 - PNH
1. Synthesis & importance of GPI GPI is a highly conserved protein bound to the outer half of the CSM Synthesis of GPI:
o PIG-A adds glucosamine to IP3 on the surface of the ERo Flippase internalises the complex and mannose domains are added in the ER lumeno Phospho-ethanolamine residues are also added in ER
GP anchors a number of proteins, including CD59 and other complement regulators, enzymes, adhesion molecules and co-receptors
o Proteins are usually attached to phosphor-ethanolamine residues CD59 usually competes with c9 for binding sites in the C5b-7 complex; hence it prevents MAC
assembly and thus complement-mediated lysis
2. Molecular basis of PNH SOMATIC MUTATION in PIG-A gene on X-chromosome
o Only one mutation is needed to cause disease; women can get ito Mutations have been mapped to multiple points across the 6 exons of the PIG-A gene
The mutation tends to occurs solely in HSCso = loss of GPI synthesis = loss of GPi anchored proteins from CSM of all HSc derivativeso ‘amplified effect of one mutation’
70% of mutations are inactivating which means there is complete GPI loss; worse phenotypeo 30% of mutations are missense = partial GPI loss; better phenotypeo You can have one type of mutation in one HSC; and another in another; giving two sub-
clones CD59, CD24 and FLAER (GPI binding protein) are useful diagnostic markers The idea is that there is a fluid dynamic between the proportion of normal/mutated HSCs; and
that when the balance is tipped too far; symptoms occur
3. Clinical features of PNH Intravascular haemolysis = anaemia + haemoglobinuria
o It can lead to acute renal failureo Bone marrow failure, iron deficiency and folate deficiency can all further contribute to
anaemia IV haemolysis = free Hb in blood = effects of depleted NO
o Coaguloation related - Vasoconstiriction, thrombosis, platelet activationo SMC related - oesophageal spasms, erectile dysfunction
Venous (and arterial) thromboembolismo Due to platelet activation from low CD59 levels, low uPAR, low NO and microparticle
release following lysis o Not all patients are affected and it seems to be more common in the west than easto Hence PNH is probably contributory but not sufficient to cause thrombosiso Can cause budd chiari and strokeo Diagnosi with MRA/ US+doppler
Bone marrow failure and cytopenias (see below)
4. Treatment of PNH Conservative - treat anaemia with iron/folate supplements
MEDICAL - ECULIZUMABo Monoclonal antibody against c5 that inhibits MAC formation without affecting upstream
complement pathwayso Given IV fortnightly and costs £250k/pt/yearo Data from TRIUMPH trual suggests that it:
Lowers LDH (a marker of RBC lysis) Lowers transfusion dependence; 49% of patients did not require a single
transfusion Reduces frequency of thromboembolic events; especially in patients where
>50% of granulocytes carry the mutation Improves quality of life & survival
Other Treatments needed include vaccination against meningococcus/pneumococcus/haemophilus due to increased risk of infection. Prophylactic antibiotics may also be given
5. Mechanism of bone marrow failure in PNH & the role of AlloSCT There is porbably a co-exisiting, unrelated, autoimmune disease where auto-reactive T-cells
target the normal HSCs and that the PIG-A mutation confers some sort of survival advantage Aims of AlloSCT are therefore to remove the abnormal HSCs and T cells and replace them with
normal ones Parker 2005 said the 10year overall survival is 56% It is generally reserved for young aptients with moderate/severe bone marrow failure as they
are at an increased risk of developing MDS/AMLo Incidence is <5% and the mutated cells may or may not have the mutation, hence it is
believed that the clones are not the reason for the development but rather the effect of the abnormal bone marrow enrivonment on other, normal cells.
3.24 - HAEMOPHAGOCYTIC LYMPHOHISTIOCYTOSIS (HLH)
1. Normal Cytotoxic T cell response to viral infection It starts with the following 2 interactions between CTL and APC:
o Receptor - HLA1-TCRo Coreceptor - B7-CD28
In response to activation, T cells make perforino Perforin and granzyme vesicles travel along actin so they get to the right target cello Perforin makes a pore and granzyme activates caspases to mediate lysis of infected cells
The activated t cell also:o Activate NK cells, which always make perforin even when they are quiescento Activate macrophages, which then make cytokines to stimulate other T cells
Regulation of T cell proliferation may be via perforin-mediated lysis of other T cells
2. Molecular basis of HLH Most mutations involve perforin loss (anywhere over 3 exons) No perforin =
o Inability to lyse target cellso Uncontrolled proliferation of T cells, NK cells and macrophageso CYTOKINE STORM; Extensive production of cytokines eg TL1, Il6, TNFao Ineffective self perpetuant inflammation and histiocytosis
3. Clinical features of HLH Infiltration of organs by Tcell/macrophages = hepatosplenomegaly, LNadenopathy, CNS
involvement Haemophagocytosis by macrophages = anaemia, bone marrow failure can also occur Cytokine storm due to t cells and macrophages = coagulopathy, liver dysfunction, fever
4. Causes of HLHInherited (rare) Acquired (more common)Familial HLH Infectious - Viral, leishmaniaAs part of another syndrome e/ge Griscelli 2, chediak higashi, X-linked lymphoproliferative
Neoplastic - EBV-lymphoma
AI disease - SLEIatrogenic
Mechanisms in acquired HLh are poorly understood but viral products may inhibit exocytosis and thus release of perforin. It has a 50% mortality if untreated
5. Mutations seen in inherited HLH Familial HLH
o 40% of mutations invovle the perforin gene, commonly seen in Africa (FHLH2)o Mutations in munc prevent release of a normal perforin protein from T cells, this is seen
in FHLH3 (30%) and FHLH5 (10%)o 74% of Turkish patients have an STX mutation; FHLH5
Griscelli 2 - o rab27 mutation means melanin can’t be delivered from melanocytes to keratinocytes =
dyspigmentation (silver hair and hyperpigmentation in sun exposed areas)o Rab27 is also involved in perforin’s ability to cause pores = HLH
X-linked lymphoproliferative syndromeo Only affects males (1/million)o 50-70% of mutations involve SAP; an adapter protein in immune signalling cascades/o Other features of this syndrome are persistent EBV infections, lymphoma and increased
risk of AI diseases
6. Diagnosis of HLH Molecular diagnosis
o Functional assays A low cytotoxic ability of NK cells
o Flow cytometry CD107a as a surrogate marker for exocytosis
o Genetic analysis Test for mutations in PRF1, STX11, Munc; and look for ones that are common in
certain ethnic groups 5 out of the following 8 criteria, if there is no molecular diagnosis
o Fever, splenomegaly, cytopeniaso High triglycerides and/or low fibrinogeno Morphological evidence of haemophgaocytosis in BM/ LNs/ spleeno No evidence of other cancero Low or absent NK cell activityo Ferritin 500mg/lo Soluble Cd25 2400U/ml
7. Management of HLH Treat the underlying cause in acquired HLH
o Amphoterecin for leishmaniao Steroids and cyclosporine for AI diseases
Supportive antibiotics for either inherited/acquired if there is an infection Chemo/immunotherapy for ingerited/ acquired disease to return to normal cell environment
o Chemo - Eteoposide + steroids+ intrethercal methotrexate + ciclosporino Immuno - ATG + ciclosporin (dying out because AlloSCT is better)o Monoclonal antibodies against TNFa and CD25
AlloSCT for inherited HLH onlyo Matched donor has much better survival than unmatched/unrelated
HLH-94 treatment protocol for inherited HLH:o Start with deaily steroids, chemo, intrathecal meth, for about 8 weekso Change to fortnightly steroids and add ciclosporin o 80% will survive until a donor becomes available
3.25 - BETA-
THALASSAEMIA INTERMEDIA
1. Definition of beta thal intermedia Heteregenous condition resulting from decreased/absent globin synthesis that may be
compatible with life without the need for regular transfusiono The phenotype is not always predictable based on genotypeo Not all patients who are transfusion dependent to begin with need it for their whole life
The reason for the heterogeneity is that the disease phenotype largely depends on the amount of globin chain imbalance
o More imbalance = more ineffective erythropoiesis = symptoms You can differentiate it from Fe def anaemia on the basis of raised HbA2
NB thal cells may appear larger on blood film, but it is microcytic. The large cells are a spreading artefact that arises because cells are devoid of Hb
2. Genotypes arising in beta thal intermedia75% of patients have 2 thalassaemic genes (homozygote) Most of these will have anaemia which is fatal without transfusion However, there are some genetic traits that prevent/ameliorate emergence of the beta-thal
major phenotype, by normalising the globin chain imbalance:o The mutations inherited are mild B+ one (eg IVS6 T-C)o Compound heterozygosityo Co inheritance of alpha thalassaemiao Coinheritance of determinants that increase HbF (HPHF, delta-beta thal, Hb Lepore)
25% of patients have 1 thalassaemic gene (heterozygote) There are some genetic traits that worsen the trait/carrier phenotype, by worsening the globin
chain imbalance:o Coinheritance of triplicated alpha gene (meiosis); usually mild diseaseo Inheritance of ‘dominant beta thalssaemia’ rare mutation that codes for a
hyperunstable Hbo Coinheritance of HbE; this is probably the commonest form of thalassaemia intermedia
worldwide (S.E asia)
Other genetic modifiers include Alpha-Hb-stabilising protein (AHSP), which normalises the imbalance
3. Clinical features of beta thal intermedia & of standard treatment of beta thal intermedia
Natural disease course As a result of standard treatmentAnaemia HaemochromatosisJaundice Psychosocial problemsGallstone Inconvenience; regular hospital visitsBone deformities Recurrent venous accessSplenomegaly Transfuision related infectionPulmonary Hypertension
Transfusion related antibody formation (worse for intermida px than for major because they receive intermittent transfusion ata time when immune system is more mature)Leg ulcers
Splenomegaly + extramedullary haematopoiesiso Extramedullar haematopoiesis often effects paravertebral areas; pain in legs/ pain on
sitting may be the first signso Treatment options are local radio, hypertransfusion and hydroxyurea
Pulmonary HTN - can occur in upto 60% of patients that are not regularly transfused as a result of free Hb and NO depletion
Hemochromatosiso As a physiological response to chronic anaemia + ineffective erythropoiesis as well as
due to regular transfusionso It is difficult to assess Fe loading, T2* MRI is now used to image heart and livero Non-transferrin-bound-iron only drops for the duration of chelation; so short of 24/7
infusions, a patient will always develop iron overload Psychosocial - different for different people
o Regular hospital visits = loss of education, activity, integration
o Bony changes and jaundice = self consciousnesso Anxietyo Sexual maturation/function problemso 81% said they would have chosen rpe natal diagnosis and abortion in hindsight
4. Other treatment methods in beta thal intermedia The OPTIMALCARE study 2010 said people who are regularly transfused and chelated have a
lowed incidence of complications than those with no treatmento But you must make the decision based on patient preferences because there is no clear
life expectancy difference with either avenue Oral Chelators
o Deferriprone (TDS) is good for decreasing cardiomyopathy but has SFX of agranulocytosis, arthritis and GI intolerance
o Deferasirox (OD) also have SFX of GI intolerance as well as renal and liver troubleo Evidence is not sure whther these are better than normal infusions
Splenectomy - can riase Hb by 2g/dl and is indicated foro Hypersplenic patients; painfuk/bulky spleeno Where transfusion/chelation is not available/doableo Watch out for risk of thrombosis and sepsis after splenectomy
Hydroxyurea may increase HbF levels but clinically, it is inconsistent Mini allografts are basically partial BM transplants Gene therapy may be an option for the future
3.26 - RED CELL MEMBRANE, STRUCTURE, FUNCTION & INHERITED DEFECTS
1. Basic structure of the RBC CSM It is a lipid bilayer in relationship with:
o Skeletal proteins that maintain a skeleton underneath the inner layer (see below)o Trans membrane proteins studded within the membraneo (cholesterol)
By weight, there are equal proportions of cholesterol and phospholipids in the CSM In terms of phospholipids, the outer membrane contains mainly PPDcholine and
PPDsphingomyelin
o In the inner membrane contains IP3, PPDethanolamine and PPDserineo When PPDserine is present on the outer layer; macrophages phagocytose the RBCs
Maintenance of the phospholipid composition (‘dysequilibrium’) is achieved by flippase, floppase and scramblase enzymes
Some important RBC membrane proteins are:o Blood group antigens (ABO, Rh)o Transport proteins
Band 3 and RhAG are important for O2/CO2 transport AQP1 (water), Glut1 (glucose), Kidd (urea), ATPases and cotransporters are
amongst the otherso Adhesive proteins e.g. ICAM4, Luo Signalling receptors
2. Basic functions of RBC CSM Mechanical functions
o It is strong and resistant to damageo It is relatively elastic and deformable - this allows RBCs to change shape in responses to
fluid stress eg. travel through small apertures eg capillaries and splenic cordso It can elongate upto 250% of its original dimensions
BUT surface area is not modifiable and is kept constant; small changes in SA lead to cell lysis
‘functional’ functionso Antigen presentation (blood group)o Transport of molecules to and from the cello Mainteneance of phospholipid ‘dysequilibirum’ and thus evasion of macrophage
phagocytosis and inappropriate adhesion
3. The importance of macromolecular protein complexes for the RBC Primarily important for maintenance of structure/function relationships by allowing ‘cross talk’
between CSM proteins and intracellular skeletal proteins Ankyrin is the ‘anchor’ in the ankyrin complex; Band 3 and RhAG are connect the CSM to ankyrin
vertically Protein 41R is the anchor of its omplex; Duffy antigen, Glut 1 & glycophorin connect the CSM to
protein 41R vertically Anchoring proteins bind to intracellular, horizontal, skeletal proteins e.g.
o Alpha and beta spectrin These are lone filamentous triple helices of repeats of 106AAs (20 repeats in
alpha and 16 repeats in beta)o Actino Adducing, dermatin, tropomyosin, tropomodulin
Interactions between skeletal proteins are important in maintaining structural responses to extracellular stresses etc.
4. Structure-function relationships in the CSM RBC Geometry& maintenance of biconcave shape
o The shape arises because of physical adhesion between skeletal and CSM prtoeins which prevent vesiculisation.
o Chemical interacting between skeletal proteins and others maintain integrity of CSMo Cation regulation by transport proteins maintains RBC volume
Cytoplasmic viscosityo Viscosity is proportional to MCH & cation concentration
o High viscosity (including globin precipitates in globin synthesis disorders) hampers the cellular ability to change shape, get through small capillaries and deliver oxygen to tissues
Membrane deformabilityo Spectrin filaments can fold/unfold rapidly; allowing the RBC to stretcho The deformability also prevents deformation-induced cell fragmentation, which would
otherwise be prevalent in cases of high blood flow shear stress, physical damage in narrow capillaries etc
5. When to suspect a CSM defect Clinical Picture - (extravascular) haemolytic anaemia, jaundice, reticulocytosis, splenomegaly,
gallstones Family history (most are autosomal dominant inheritance) No evidence of immune mediated haemolysis (negative coombs test) Specialised test
o EMA binding assay - spherocytes don’t pick up the EMA dyeo SDS PAGE electrophoresis - runnin CSM proteins eg spectrin on a gel
6. Clinical features of some hereditary RBc CSM defects Hereditary spherocytosis
o AD disease, common in Caucasians, were red cells are destroyed in splenic cordso Heterogeneous presentation ranging from asymptomatic disease to anaemia require
intrauterine transfusiono Thought to be due to loss of CSM SA due to mutations in proteins that are important
vertical adhesive proteins in macromolecular protein complexeso Spherocytes appear small, dense, spherical and lack central pallor
Hereditary elliptocytosiso AD disease; may confer protection from malariao Also heteregenous but far fewer (10%) are asymptomatico Thought to be due to loss of CSM SA due to mutations in proteins that are important
horizontal adhesive proteins in macromolecular protein complexeso SDS PAGE electro on spectrin may show proness for spectrin to form diemrs rather than
usual tetramers Hereditary stomatocytosis - AD disease where high cytoplasmic cation content gives
overhydrated cells that appear as stomatocytes (increased viscosity = loss of deformability) Hereditary Ovalocytosis
o Single mutation in band 3 cofners loss of deformability; common in SE Asianso Ovalocytes differ from spherocytes because they are paler and some appear as ellipses
3.27 - ACQUIRED BONE MARROW DYSFUNCTION
1. Definition of bone marrow dysfunctionUNDERPRODUCTION of precursors OR production of DYSPLASTIC precursors Underproduction - aplastic anaemia, pure red cell aplasia, anaemia of chronic disease
o Aplastic anaemia is hypoproliferation of all cell lineages. Acquired causes include drugs, infections and AI disease (see below)
Dysplasia -MDS & dyserythropoiesis
2. Mechanisms of acquired bone marrow dysfunction Ineffective haematopoiesis due to failure of normal HSC proliferation/differentitation:
o Direct infection of HSCso Auto-immune T cells conferring cytotoxicity or producing cytokine imbalanceso Abnormal bone marrow microenvironment
Evidence for the role of T cells/ AI disease in bone marrow dysfunction:o Idiopathic aplastic anaemia responds to immunosuppressiono Aplastic anaemia is associated with other AI cytopeniaso Oligo- and clonal populations of T cells are present in many patients with aplastic
anaemia, large granulocytic leukaemia and other AI cytopenias
3. Role of parvovirus This is a single stranded DNA virus which is non-enveloped It is usually spread via respiratory tract, but also via blood and placenta The protein NS1 binds to P antigen (globoside) on erythroid cells and activates caspases to cause
apoptosiso It may also cause G1 cell cycle arrest; with other proteins further arresting at G2
Disease course Viral blood load starts at 5 days and peaks and about 9; antibodies follow Transient reticulocytopenia occurs for the first 5 days and there may be a subclinical anaemia Polyarthopathy may follow clearance of virus Most infections are asymptomatic but parvovirus B19 is the commonest acquired cause of pure
red cell aplasia in those who have a underlying fast rate of erythropoiesis e.g.:o Patients with haemolytic anaemia, sickle cell anaemia, thalassaemia
Crises are self limiting but may be fatalo Diaghnosis is made by seeing only giant erythroblasts (no reticulocytes or other
precursors) in bone marrowo Recovery is followed by immunity
Immunosuppressed patients eg HIV lymphoproliferative disease, iatrogenic patients may suffer from chornic pure red cell aplasia as they cannot clear the virus; give IVIg
infected foetuses can die in utero
Diagnosis anaemia with reticulocytopenia leads to clinical syuspicion bone marrow appearance PCR/ viral DNA hybridisation ELISA for antibodies against parvovirus (IgM during disease; IgG after immunity is acquired)
4. Role of HIV This is a retrovirus It uses gp120 to bind to CD4 cells, usually requiring coreceptors
o CXCR4 in T cells and megakayrocyteso CCR5 in GM-CFU cells
Advent of HAART means that haematological effects of HIV are less frequent nowadays
How HIV affects the microenvironment• Effects can be mediated directly or by other microbes, which there are an increased incidence of
in HIB (MAI/MAC, PCP, TB), or by an invasive lymphoma• Disrupted architecture
• Disorganized architecture with increased fibrosis• Gelatinous degeneration or BM necrosis• Granulomata
• Multilineage dysplasia:• Erythroblasts: nuclear irregularity and fragmentation, megaloblasts if AZT used• Myeloid cells: GMMC, nuclear fragments, abnormal chromatin pattern, apoptosis• Megakaryocytes: clustering and dysplastic forms
• Increased in lymphoid cells• plasma cells especially perivascular• Increased lymphoid aggregates
Effects on lymphocytes CD4 lymphopenia that correlates with viral load B cell activation; polyclonal hypergammglobulinaemia
How HIV causes anaemia Dyserythropoiesis conferred by virus/ by increased susceptibility to others eg CMV, parvovirus Infiltration of BM when infections disseminate ege PCP, mycobacteria Increased risk of cancer eg NHL (DLBCL, Burkitts) and Kaposi sarcoma Malabsorption/ poor intake of B12, folate, iron Iatrogenic - AZT (megaloblastic), gancyclovir (dyserythropoiesis), chemo, antifolates Miscellaenous causes eg AIHA, TTP, DIC, Hypersplenism Treat it by treating underlying cause, dietrary supplements, EPO, transfusions
How HIV causes neutropenia Dysregulated microenvironement and iatrogenic are main causes Treat underlying disease and you ould give G-CSF
How HIV causes thrombocytopenia Direct megakaryocyte infection, cytokine imbalance, TTP and auto-immune (because viral
proteins and GP2b3a share epitopes) are the proposed mechnaisms The phenotype is indistinguishable from ITP; anti-retrovirals, IVIg, asteroids and splenectomy are
all treatment options
5. Other infections giving rise to dyserythropoiesis Malaria - can affect all three lines, commoner in chronic falciparum and vivax infections Leishmania and trypanosoma can also cause dyserythropoiesis
6. Mechanism of dyserythropoiesis in ACD Reduced production of erythrocytes:
o Reduced BFUe and CFUe caused by IFN a,b and g, TNF and IL-1o Induction of apoptosiso Reduced EPO receptors production (and thus EPO synthesis) by kidneys
Dysregulation of iron metabolismo Increased production of hepcidin by the liver (stimulated by LPS & IL6):
Inhibition of transferrin = less iron absorption from gut Reduced ferroportin = reduced release of iron from macrophages Stimulation of DMT1 = iron accumulates in macrophages
o Increased uptake of iron by macrophages: Increased production of ferritin, DMT1 Upregulation of transferrin receptor Increased erythrophagocytosis
The changes stated may not be observed in a patient who has a coexisiting iron deificnecy anaemia (where ferritin is low and thus may normalise)
3.28 - COMPLEMENT
1. Pathways in the complement system Classical pathway
o Immune complexes are recognised by c1 complexo C1 complex activates c3 via c3 convertase with c4 and c2
Lectin pathwayo Important for innate immunity; starts with recognition of TLRs eg MBL, ficolin, collectin
11o Activates c3 via c4 and c2
Alternative pathwayo Constitutively active; c3 auto activates itself with help of D & B proteases
Terminal pathwayo C3 activates c5 via c5 covertase complexo Attraction of c6-9 leads to formation of MAC; cell lysis si only directed at RBCs
2. Classical pathway C1q binds to Fc portions of IgG or IgM (but not IgG4)
o Other triggers include CRP and some pathogens Binding = activation of c1q into c1r and finally c1s (serine esterase) C1s cleaves c4 into c4a and b
o A fragments are released into circulation. They can recruit inflammatory cells and cleave other complement proteins
o B fragments bind to CSM; c4b is an important part of both c3 and c5 convertase complexes
C4b binds to c2 C1s cleaves c2 into c2a. c4b2a is known as the classical c3 convertase
3. Lectin pathway Binding of TLR activates proteases called MASPs which are analogous to c1 The rest of the pathway is the same as seen in the classical
4. Alternative pathway & terminal pathway This pathway is antibody independent and fundamental for amplification of complement
response C3 binds with water and undergoes spontaneous hydrolysis. It binds to D & B protiens
o D cleaves B into ba and Bb C3H20Bb is the alternative c3 covertase which rapidly cleaves c3 into c3b = auto activation C3b activates c5& initiates MAC assembly when it is bound on foreign surfaces e.g. bacteria/
cells that have poor complemetregualtory molecules e.g. RBCso Key point in MAC assembly is polymerisation of c9 which forms a cellular pore
Other functions of MAC - enzyme activation, cytokine/chemokine production, cell recovery, protein synthesis, proliferation
5. Regulation of complement Fluid/ in serum regulation
o Factor H & factor I are bought into contact with C3b by sialic acid. This forms ic3b which can no longer assemble the MAC
Bacteria lack sialic acid = proness to MAC mediated lysiso C1 inhibitor and c4bp inhibit the classical pathway
Membrane bound regulatorso CR1, DAF, MCP (c3) and CD59 (c5/MAC); all inhibit the terminal pathway
Intrinsic ‘instability’ of convertase complexes
Importance of regulation is in l imiting damage to host tissues and preventing depletion of complement
6. Functions of complement Defence against infection
o Opsonisation by c3 and c4
o Chemotaxis and leucocyte activation by c5a C5a is a powerful anaphylotoxin
o Lysis by MAC (particularly encapsulated ones like Neisseria) Interface/bridge between innate and adaptive immunity
o Antibody augmentation by C3 and C4o Enhancement of memory by C3 and c4o C3 receptors are found on B cells and APCs
Waste disposalo Clearance of immune complexes, apoptotic/ dead cells; mainly by classical pathway
7. Methods of measuring complement Antigenic assays for c3 or c4 Functional assays; CH50 tests via the classical pathway and AP50 tests via the alternative
pathwayo Failure of both implies a terminal pathway problem
8. Role of complement is haemoatological disease Complement deficiency usually associated with recurrent infection
o Classical pathway deficiency = SLEo C3 defieincy = pyogenic infections which improves with age because of mature
adapative immunityo Terminal pathway deficiency = recurrent Neisseria
Deficiencies of regulation Impaired fluid regulation = HUS = MAHA, renal failure, thrombocytopenia
o Typical HUS is associated with cercytotoxins produced by E.Colio Atypical HUS can be sporadic or familial and is associated with polymorphisms in one or
more of Factor H, I, MCP, or high activity of B/c3 or anti-H antibody production Impaired membrane regulation = PNH = haemolgobinuria at night/early morning because low
serum/urine pH increases RBC fragilityo Acquired PigA mutation = loss of Cd59 = no protection from MACo DAF deficiency increases c3 binding on RBCs but gives no cell lysis unless there is
concomitant CD59 deficiencyo Codeficiency of c9 may remove haemolysiso Anti c5 eculizumab is a good treatment
3.29 - GENE THERAPY IN HAEMTOLOGICAL DISORDERS
1. Requirements for gene therapy A disease where the current best treatment has failed and in which the therapeutic gene has
been sequenced/cloned Cells that you can target (see below) and vectors you can use (see below) A treatment strategy (ex-vivo or in vivo??; ex-vivo better for HSCs)
2. Transient gene expression in gene therapy; causes & solutions
Cause SolutionFailure to delvier to HSC Improve vector system or HSC prepUse of poorly integrating/replicating vector Use a integrating/replicating vectorImmunological reactions to vector Simplify vector, change regime, steroidsSilencing of integrated gene Use insulator sequences
3. Target cell requierments Types of target cell - HSC/ long lived non-differntiating cell/ induced stem cell
o You can induce a stem cell by reprogramming somatic cells by forcing expression of TFs like oct4, sox2, klf4 and c-myc. These are easier to grow/transfect
It is difficult to do gene therapy in HSCs because there is a loss of self replication as they mature and they are difficult to isolate and transduce
Solutions to problems with HSCs areo Mobilise stem cells, purify and cultureo Use vectors that efficiently deliver to non-dividing cells (lentivirus)o Engineer selective advantage to transduced cells
4. VectorsThe ideal vector:
Have low immunogenicity Have adequate capacity for therapeutic gene Support long-term and appropriate expression Efficiently deliver gene to correct cells Be safe (fully disabled/non-mutagenic)
Most vectors are viruses: Retrovirus
o Removal of parts of retroviral genome e.g. gag, pol, env = no viral replicationo But then you need to infect a packaging cell line to make the viral proteins needed for it
to transfect the target cell Lentiviruses are a sublass of retrovirus that infect non-dividng cells better Adenovirus - host may have preexisiting immunity
o DNA virus; E1, E2 and E4 domains & other coding sequences are removed o (You might need a ‘helper’ once you take out its guts)
AAV - doesn’t divide without associated infection of adenoviruso 4kb small single stranded DNA virus with terminal repeatso The repeats and some promoter regions are kept in the final product
Non viral vectors include cationic lipids, which form DNA-cationic lipid complexes when tranduced, and the gene gun which is only really used in plants
Virus size efficiency immunogenecity mutagenesis Transient?retro small Yes - but mostly dividing low yes No - provirus maintainedadeno large Good + non dividing yes No - episomal yesAAV small Good + non dividing low No - episomal yes
5. Gene therapy in SCID X linked disease associated with IL2 receptor mutation
o = absent Il2 signalling (usually necessary for TCR rearrangement and Tcell maturation)o Abnormal T cells = abnormal B cells
Used to be fatal within 1 year; you could live life in a bubble hoping HSCT would work French trial cured 17/20 patients but 4 developed T-ALL
o The high cure rate is believed to be because the gene therapy gave infected cells a selective advantage, as well as normal function
Association with ALL is because the onco-retrovirus tends to integrate near genes and its LTR region was believed to promote LMO2
6. Gene therapy in SCA/ ThalassaemiaChallenges
• No selective advantage for infected cells is anticipated.• High levels of b-globin expression required, erythroid specific. • Avoid oncogene inactivation.
Approach efficient delivery of vector to HSC (pseudotyped lentivirus) include selectable marker into vector e.g. MDR gene include b-globin control sequences (e.g. HSs and LCRs) minimal host gene activation (e.g. SIN vectors)
For diseases where no selective advantage is expected, need to: ensure high efficiency of stem cell transduction
create a selective advantage: introduce selectable marker with therapeutic gene condition patient to impair proliferation of competing cells
7. Gene therapy in haemophilia - self complementary, liver specific AAV8 (see mod 1)
8. Gene therapy in cancer• Reverse mutations by expressing tumour suppressor genes/ silencing oncogenes• Virus-directed enzyme/prodrug therapy (VDEPT); bystander effect.• Stimulation of immune response to tumor; express genes for e.g.cytokines, HLA• Improve Bone Marrow Transplants; use genes that prevent GvHD
9. Gene therapy for AIDS Use genes for RNAi, Ribozymes, Interfering proteins/RNA, Intracellular antibodies Sequestration
proteins (need to target multiple stages of life cycle)
10. Gene correction Safer than ‘gene replacement’ because theres less immunogenicity, less mutagenesis and no
need for a virus so no chance it will get out Principle is using Zinc finger nucleases to create a DSB in order to introduce a repair construct Repair contructs are homoglous to the normal sequence and use cells own machinery to repaur
DNA mutation3.30 - DISORDERS OF GLOBIN CHAIN SYNTHESIS
This was mainly a recap of stuff already covered; useful additional notes are as follows:
Hydrops fetalis Large deletions that involve the zeta gene can result in hydrops fetalis. Some of these include
Filipino, Thai and haawaiin variants. The SEA variant does not include zeta chain so in theory fetuses can be saved by intrauterine transfusions
The anaemia in hydrops fetalis is because of inadequate Hb synthesis ( and the fact that Hb barts is pants at o2 binding/delivery), AND ineffective erythropoeises due to Hb Barts precipitates
Anaemia and tissue hypoxia = o Cardiac failureo Abnormal organogenesiso Placental enlargement = pre-eclampsia and antepartum haemorrhage risks for mother
Linking phenotypes to Functionally abnormal hameoglobins Sickling can be due to a variant that polymerises and/or has reduced solubility (HbS/C) High RBC could be due to a high O2 afinity Hb (Hb luton) Haemolysis could be due to an unstable Hb (Hb koln) Cyanosis could be due to a Hb that tends to oxidise (Hb M [hyde park])
Compund heterozygotes that present like SCA: Compound heterozygoisty for HbS and one of HbC/ Dpunjab/ Oarab
Principle cellular changes in sickling = RIGID, ADHERENT, DEHYDRATED
Compounf heterozygotes that present like thal HbBthal/HbE or lepore; delta beta thalassamia Hbconstant spring Hbathal
Some other tests in diagnosis of globin chain disorders: Sickle solubility test - only identifies HbS and thus only tells you there is an SCD present; not the
subtype. A positive result is turbidit/ loss of solubility Heat stability/ isopropanolol precipitation tests give a positive result (turbidity) in the presence
of an unstable haemoglobin (tandem) mass spectrometry can be used to differentiate haemoglobin variants on the basis of
mass and charge
3.31 - HAEMOLYTIC ANAEMIAS
1. Classifications of haemolytic anaemia (PROBABLY WORTH DOING A BETTER ONE)Defined as anaemia due to shortened red cell survival
Extravascular IntravascularAuto/alloimmune MalariaHereditary spherocytosis G6PD def
Cold Autoimmune HAMismatched (ABO) blood transfusionDrugsMAHA, TTP, PNH
2. Inherited haemolytic anaemiaCan arise due to abnormalities in:
CSM - proteins/ permeability Metabolism/ enzymes Hb - thalassaemia, sickling, unstable Hb variants
Consequences/ clinical featuresConsequence Clinical featuresVarying degree on anaemia (depending on success of EPO response/compensation)
Pallor, SOBOE
Erythroid hyperplasia, reticulocytosis Bony painExtramedullary haematopoiesis hepatosplenomegalyHigh bilirubin Gallstones; jaundiceFree Hb in blood (if intravascular) Haemoglobinuria, NO depletion
Increased folate demand can lead to folate deficiency in less developed countries Susceptibility to aplastic events following parvovirus B19 (because of low survival; remember
retics would be low in this case) Chronic anaemia and reflex absorption can give Fe overload Coinheritance of Gilberts syndrome can worsen gallstone disease
o Gilberts = homozygoisty for 7TA repeats = decreased BR conjugation
Suspicion of inherited HA from history Young age/ congenital Episodic haemolysis may point more to something like G6PD Mode of inheritance/ family Hx Other systemic disorders (eg neuro/ myopathy trouble with enzyme deficiencies without
multiple isoforms)
Lab features of inherited HA Film - Anaemia, reticulocytosis, polychromasia Bloods - high BR, LDH & low (used up) haptoglobins in intravascular haemolysis Urine - haemoglobinuria (red)/ haemosiderinuria (brown) in intravascular haemolysis
3. Red cell membrane disordersRed cell cytoskeletal proteins are numbered in the order they separate on electrophoresis
Herditary spherocytosis Hereditary spherocytosis is the commonest inherited HA; usually autosomal dominant It gives osmotic chsnges to RBCs - osmotic fragility test can diagnose Associated with mutations of vertical (CSM-cytoskeletal bridges) proteins; ankyrin mutations are
the commenst cause of dominant HS; band 3 and spectrin mutations also seen Flow cytometry is now more frequently used in diagnosis
o Eosin-5-maleimide usually binds to band 3; and band 3 content is usually reduced in hereditary spherocytosis
Hereditary elliptocytosis No osmotic red cell changes Varying severity of disease Mutations in alpha spectrin mostly, alos b spectrin
South east Asian Ovalocytosis Macroovalocytosis where upto half of cells may have 1 or 2 slits Heteroxzygotes may be protected against malaria; homozygotes may die because the mutation
is due to deletion of band 3
4. RBC metabolic pathways G6PD is a x linked disease; may be protective against malaria
o Most mutations are missense Catalyses first step in pentose phosphate pathway = generation of NADPH = maintenance of GSH Manifests as neonatal jaundice (probably because of effect of deficiency on hepatocytes) and
intermittent episodes of haemolysis, triggered by oxidants ego Drugs - anti malarials (primaquine), antibiotics (sulphonamides)o Infections, broad beans, moth balls
PK deficiency is the commenst glycolytic deficiency It gives poorly deformable cells which loss K+, water, become dehydrated and are ultimately
haemolysed
Other metabolic pathways in RBC = 2,3 DPG shuttle, nucleotide metabolism pathwyays, GSH biosynthetic pathway (linked to pentose phosphate) and reduction of metHb by cytochrome b5 reductase
5. Investigating a haemolytic anaemia Features of haemolysis on film; heinz bodies Direct coombs (tells you if its immune or not) See ‘lab features of inherited HA’ for specific tests Thick and thin blood film for someone whose just been to a malaria endemic area; dipstick test is
an alternative
6. Principles of managing haemolytic anaemia Conservative - avoiding triggers in G6PD, monitoring complications, folate Medical - transfusions for severe anaemia, immunization against HepB Surgical - cholecystectomy for recurrent gallestones. Splenectomy is good for:
o Pk deficeicny, HS, severe HE and sometime in thalassaemiao Patients who are between 3-10, transfusion dependent, have poor growth and chronic
Hb<8 Watch for encapsulated bacteria sepsis; give prophylactic penicillin
3.32 - G6PD DEFICIENCY
1 Structure/ Function of G6PD 59kDA dimer Binds NADP to produce NADPH (and ultimately reduced
glutathione) Thus it provides protection against oxidant injury, which is
important in (deformable) red cells
o But, mature RBCs can make it and it’s half-life is only half that of red cell life span (old cells have less)
o For example, its activity is 5x greater in reticulocytes that it is in old RBCs
2. Physiological effects of G6PD def Oxidization of Hb = Heinz bodies which attach to inner part of CSM to cause contracted cells
o Is sufficient oxidation of Fe can lead to metHBaemia Oxidation of membrane proteins & lipids = cellular rigidity, dehydration Can manifest as either intra- and extravascular haemolysis
3. genetic basis of G6PD X-linked inheritance associated with mostly missense mutations
o Female (heterozygotes) are effected intermediatelyo Mutations in exons 10/11 have the most severe deficiency and hence phenotype
Sporadic mutations are rare but severe (class 1) and give a chronic haemolytic anaemia Polymorphisms are common and give intermittent episodes of haemolysis
o Highest prevalence in tropical Africa, middle east, SEA and the mediterranea; selection by malaria
o G6PD A- is a polymorphism that gives and unstable enzyme, mild intermittent haemolysis and occurs in Africans
o G6PD Med gives severe intermittent haemolysis and is the commonest abnormality in Caucasians
4. Clinical features of G6PD Can be asymptomatic/ intermittent haemolysis or chronic haemolysis; nonspehrocytic
o Severity of disease depends on premature birth, type of trigger, mutation involvedo Can be fatal (G6PD Med, Chronic disease in neonatal jaundice)
Intermittent episodes can be triggered by drugs, infection, acidosis, hypoxia, broad beans and lead to death of old red cells
o Occurs 2-3d after usage of drug and worsens over a week; some drugs are: Dapsone Methylene blue Nitrofurantoin Primaquine Quinolones Sulphonamides
o Infection is the commonest cause; watch for viruses in kids (URTi, GIT, Hep) and pneumococcus too
o Occurs within 1 day of broad beans (intravascular); can also occur in babies breast feeding off a mother who has eaten broad beans; Hb drop often severe and may require transfusion
Chronic (nonspherocytic) anaemia results from sporadic/class 1 mutations and is mostly extravascular and exacerbated by oxidant stress
Neonatal jaundice presents possibly because of effect of deficiency on early hepatocytes, or because neonatal RBCs have high ascorbic acid, low vit E and low catalase = prone to haemolysis
o Jaundice usually seen 2-3d with anaemia, reticulocytosis and may require exchange transfusion
o Suspect underlying class 1 mutation if the presentation is severe
5. Diagnosis of G6PD High BR tends to occur even when there are no episodes of haemolysis
o Could be unrelated to G6PD def in some caseso Could be because of impaired liver BR conjugation; coinheritance of gilberts??
Apart from clinical suspicion and film; specific G6PD tests include:o Screening, based on NADPH detection (?depletion)o Quantitative assays
6. Management of G6PD Mostly conservative - screening (especially for neonatal jaundice), education/avoidance of
triggers, folate supplements for the chronic form of the disease Medical management needed for neonatal jaundice:
o treat hypoxia, sepsis, acidosis promptlyo phototherapyo exchange transfusion if necessary
Surgical options - splenectomy may be beneficial for chronic form of the disease because it is extravascular
3.33 - HYPER REACTIVE MALARIAL SPLENOMEGALY
1. Epideimology of HRMS Age - 20-40years old Sex - generally women more than men but it varies Geography - Tends to occur in endemic malarial areas
o 20% of people here have splenomegaly; massive in 4-5%o Sexual/ethnic prevalence varies by area
Less common in people who have sickle trait
2. Clinical features of HRMS Many are asymptomatic; those who are present with abdo swelling/ discomfort with B
symptoms Signs usually elicited are hepatosplenomegaly and signs of anaemia; fever and jaundice may
occur Lab features
o Film - hypersplenism signs (peripheral cytopenia), low number of malarial parasiteso Marrow - hypercellularo Bloods - usually cytopenia (pooling) but you can get a polyclonal lymphocytosis
sometimeso Immune - IgM, cryoglobulins, ANA, RF, thyroglobulins, immune complexes (IgM/G/C),
autoantibodies, lymphocytosis
3. Pathophysiology of HRMS Mechanisms of anaemia:
o splenic poolingo Reduced RBC survival/ Occasional episodes of increased haemolysis (commoner in
pregnancy; coombs negative; steroids may improve)o Increased plasma volumeo Increased erythropoiesis
Proposed mechanism is that malaria gives chronic stimulation of B cellso Leads to IgM production and immune complex deposition in Kuppfer cellso Helper T cells are stimulated but suppressor T cells are inhibited
4. Criteria for diagnosis Major criteria
o Massive splenomegaly (>10cm or below umbilicus) with no other cause (see below)o Immunity to malaria through prolonged exposureo Raised polyclonal IgM (not specific to malaria)o Improvement (40% reduction in spleen size) with malaria treatment
Minor criteriao Hypersplenism o Hepatic sinusoidal T- lymphocytosiso Normal lymphocyte response to pyhtohaemoagglutinnino PB/BM infiltiration with polyclonal lymphocyteso High antimalarial antibodiyo Family history
5. Other causes of massive splenomegaly in the tropics (differential diagnosis) Cirrhosis Portal HTN backflow of blood Infectious; kala azar & schisto Hb disorders - thalassaemia major , SS, SC Neoplastic/myeloproliferative - CML, myelofibrosis
6. Management of HRMS Medical - antimalrial therapy with daily proguanil or weekly chloroquine for atleast 12 weeks;
70% response rate Surgical - splenectomy
7. Prognosis of HRMS
50% 5 year mortality in some studies; death usually cuased by infection, anaemia or progression to lymphoma (see below)
8. HRMS as a pre-lymphomatous state Theory - High WCC is often demonstrated & lymphoma is the second commenst cause of death
in HRMS patients Features of european SLVL
o Epidemiology - Rare, occurs in the elderly >50, slightly males >females, western worldo Features - splenomegaly, possible BM involvement & circulating Villous Lymphocyteso Diagnosis - morphology (VLs) and immunophenotypes (IgM, 20, 22, 79a, FMC7+; 23, 25-)o Prognosis - good; 80% 5 year survival
African SLVL might be the same as HRMS because it presents in women who are younger and has consistent signs/ features
o It is possible that a genetic mutation makes the B cells independent og malarial antigen stimulation and this results in SLVL
3.34 – RED CELL APLASIA
1. Features of Red Cell Aplasia may occur as a part of aplastic anaemia or by itself (PRCA) anaemia and reticulocytopenia are hallmarks
o since red cells and platelets come from MEP; anaemia may be accompanied by thrombocytosis
maturation arrest is more common that complete absence of precursors
2. Features & Associations of Acquired Pure Red Cell Aplasia rare disease; usually presents in early/middle adulthood anaemia is usually normocytic most cases are idiopathic with erythropoietic inhibitors of unknown origin May occur secondary to:
o Immune diseases thymoma – 5-10% get PRCA but removal of thymus doesn’t cure PRCA AI Disease eg RA T LGL these cells are cytotoxic to RBCs
o Viruses PARVOVIRUS B19 Also Hep, HIV, EBV
o Pregnancy & HDNo Iatrogenic – e.g. antiepileptics, azathioprine, EPO
NB this is rare noe because we use synthetic EPO with less immunogenicity
3. pathophysiology of acquired Red Cell Aplasia Immune
o antibody mediated – serum inhibitors against red cellso cell mediated – as seen with T-LGL
BM failure - may result in absence of progenitors rather than maturation arrest
4. Management of PRCA Conservative – stop causative drugs (including EPO) Medical
o treat anaemia with transfusions and iron chelationo immunosuppression for immune mediated disease e.g. steroids, ATG, ciclosporin,
Rituximab, alemtuzumab and IVIG Surgical – Splenectomy not very effective, consider BMT for non-immune disease
5. Prognosis of PRCA most people recover deaths are rarely due to aplasia; more commonly due to underlying disease e.g. AI disease,
pancytopenia
6. Parvovirus B19 & PRCA This is a DNA virus viraemia lasts for a week and BM suppression occurs in this period Mostly asymptomatic, but can cause erythema in children and polyarthropathy in adults
o most adults have IgG seropositivyt indicating previous asymptoimatic infection and immunity
It binds to P-antigen principally of CFU-Es but P antigen is ona number of cells so it may have a wide presentation:
o Transient aplasia – sudden onset anaemia which may be life threatening in people with underlying haemolytic anaemia or conditions of eryhtropoietic stress
o PRCA – chronic anaemia that more commonly occurs in immunocompromised patients; diagnose with BM PCR and treat with IVIg
o Hydrops Fetalis occurs because P antigen is present on placenta; so virus infects foetus occurs in 2nd trimester and may be fatal and requiring of IU transfusions
o Congenital infection
occurs because P antigen is present on heart (myocarditis), liver (Liver disease) and megakaryocytes (thrombocytopenia)
7. Transient erythroblastopenia of childhood TEC vs DBA in PRCA
TEC DBAmay present later presents in infants <1yrNormal ADA High ADANormal HbF High HbFRecovers in 4-8 weeks does not recover
TEC presents as a transient anaemia and reticulocytopenia and reduced precursors in the BM possibly caused by a virus 50% need no treatment – pbserve and only transfuse if patients develop CVS compromise
3.35 – INHERITED BONE MARROW FAILURE SYNDROMES25% of paediatric and 10% of young adults with aplastic anaemia have underlying BM failure
1. Clinical Features of Fanconi Anaemia mean presentation is 7 years of age 30% have no abnormalities Those that are symptomatic present with BM failure and somatic abnormalities:
o Skeletal deformity – no radius or thumbo skin pigmentationo short stature
o horshoe kidney, ASD/VSD, hypospadias are less common Increased predisposition to cancer due to chromosome fragility
o AML, Head/neck SCCs are equally commono diagnose with chromosome fragility test using diepoxybutane or mitomycin C (principle
is introduce DSBs, spread metaphases and look for excessive breakage)
2. genetic basis of fanconi anaemia AR mutations of 1 of 13 FANC genes
o FANCA, FANCC and FANCG are the ones most commonly mutated FANCD1 is the same as BRCA2 = higher risk of breast/ovarian Ca, brain and Wilms tumour somatic mosaicism is when FA patients don’t display chromosomal fragility because the HSC has
undergone gene correction = these people present with no abnormalities but have the mutation
3. management of fanconi anaemia Conervative – avoid head/neck XR, annual BM monitoring, dentists to survey for Head/neck SCCs Medical –
o HPV vaccine may protect against head/neck SCCo androgens (eg oxymetholone) support haematopoiesis
Surgical – SCTo SCT doesn’t prevent future cancer; only resolves BM failure which is the main cause of
detaho also consider surgery to correct somatic abnormalities, if present
4. clinical features of DBA presents as a PRCA from infancy with somatic abnormalities:
o short stature present in 1/3o hand, cardiac and renal abnormalities also common
May progress to complete pancytopenia4 increased risk of developing cancer – particularly MDS, AML and osteogenic sarcomas
5. genetic basis of DBA Commonest mutations are in RPS19, RPL5, 11 = defective protein synthesis by ribosomes red cells are produced at the highest rate so this is why they are more vulnerable to protein
synthesis disorders
6. management of DBA conservative – no smoking, fibre diet, no growth hormone medical –
o transfusion for children less than 1 year old; 10% may enter spontaneous remission without transfusion
o steroids can restore BM function in children older than 1 year; those that don’t respons rewuire chronic transfusion + chelation
Surgical – SCT may resolve anaemia and reduce risk of developing myeloid neoplasm, may need additional surgery for somatic features
7. Dyskeratosis congenital Usually present in teenagers/ young adults with a typical triad:
o dystrophy in nailso dyspigmentation of skino oral leukoplakia
BM failure rate is 94% by 40years old, Pulmonary fibrosis is also common
1 of the triad + BM failure + molecular evidence of mutation = diagnosiso differential diagnosis ncludes Hoyeraal-hreiadarrson syndrome (brain) and revesz
syndrome (exudative retinopathy) Increased risk of cancer; solid tumours (head/neck carcinomas) more common than AML/MDS Mutations usually involve telomerase proteins – dyskerin (XL), TEKT (AD) and TERC (AR)
o shorter telomeres = apoptosis/failure of chromosome replication
8. scwachman-diamond syndrome AR disease presenting in childhood with:
o pancreatic exocrine insufficiency (may improve with age)o Failure to thriveo Short stature
most patients have neutropenia, mechanism for this is unclear increased risk of developing aplastic anaemia, MDS by teenage years; solid tumours less
common Diagnosis:
o pancreatic insufficiency – low serum trypsinogen, amylase, elastase in stools, fatty pancreas on USS/CT/MRI
o cytogenetics – 7-, del 7qo molecular – 95% of patients had SBDS mutation (null or hypomorphic) = dysfunctional
ribosomal 60s subunit Management
o conservative – fat soluble vitamins, enxyme supplements, annual BM monitoringo medical – GCSF for neutropeniao surgical – SCT (50% have hypocellular BM)
9. severe congenital neutropenia Heterogeneous prestnation at infancy spanning from neutropenia, recurrent pyogenic infections
to marrow maturation arrest in granulopoiesis Most cases are AD; a variant called Kostmann SCN is inherited AR
o AD – ELA2 mutationso AR – HAX133o XL – WAS mutationso Somatic/acquired mutations may involve GCSF receptor
Differntial diagnosis:o cyclic neutropenia (exclude because this rpeats every 21days; SCN doesn’t)o immune mediated diseaseo hypersplenismo MDSo BM examination may show maturation arrest at promyelocyte; APML
management – GCSF and SCT (some evidence that SCN is a pre-leukaemic disease)
10. amegakaryocytic thrombocytopenia presents with thrombocytopenia in infants which may progress to aplastic anaemia/ AML in
teens AR disease involving mutations in TPO receptor
o TPO can influence the HSC which is why you can progress to aplastic anaemiao null mutations are more severe than missense mutations
manage with androgens possibly, but mainly SCT
11. thrombocytopenia with absent radii congeintial BM failure, childhood haemorrhage with no radii, malformed phalanges but
presence of thumbs possibly increased risk of AML, but not aplastic anaemia; TPO receptor pathway or microdeletion
on choromosome 1 may be implicated platelet count usually recovers; may recover enough for orthopaedic surgery SCT rarely needed
3.36 - HAEMOGLOBIN E SYNDROMES
1. Properties to HbE Beta globin variant arising from glutamic acid lysine @ 26th AA Has a normal oxygen affinity but is slightly unstable Is produced at a reduced rate because 2/3 of the mutant transcript is nonsense and doesn’t
make any protein; 1/3 makes HbE
2. Detection of HbE Electrophoresis - runs with HbA2
Heat instability test +ve Indices/film (thlassaemic/reduced rate)
o Carrier - Microcytic indices MCV 75, MCH 27, Hb 12 with Hypochromic film +/- target cells; Hb E usually 1/3 of total haemoglobin produced
o Homozygote - MCV 65, MCH 20, Hb 11, more abnormal film, HbE 95% of total with increased alpha chain production ratio
3. Epidemiology of HbE Sri Lanka, North India, SE asia; may offer protection from malaria
o Most carriers in the UK are migrants from these areaso Compound heterozygotes in these areas may need transfusion; centres are well
established in Sri Lanka; not so much in India/ Pakistan/ thaliand/ SEA Mutation may have spontaneously risen atleast 4 times
4. HbE and alpha thalassaemia Coinheritance with alpha trait reduced HbE to 20-25% Coinheritance a0/a+ compound hetero = HbH
o The only globins made in this case are HbBarts and ~14% HbE Decreased chain imbalance = reduced severity of disease
5. HbE and beta thalassaemia Heterogenous presentation ranging from no symptoms to transfusion dependence
o difficult to explain purely in terms of globin-chain imbalance o possible roles of Hb instability, Age, Environmento Roles of other genetic factors eg. Xmnl & epigenetic (UGT1a) polymorphisms
Excess of alpha chains probably causes HbE to become unstableo RBCs cannot handle oxidative stress as well; may interact with malaria, broad beans
etco No evidence of heamolysis (but dapsone is said to cause it in 1 report)
This is commonest form of sever thalassaemia in the world; Features
o Dyseryhtropoietic film (not haemolytic)o Hb <10 [mean 7.6] , MCV 50-80, o No HbA is made; HbF may be raised and HbE is of the order 20-80% [mean 44%]
depending on exact mutation The high HbF is useful is distinguishing this from HbE homozygoisty %HbF correlates with total Hb made; hydroxyurea may be of use
6. HbE/beta thal in the UK Presents at 4years (later) with pallor and/or acute illness and incidental diagnosis Majority of patients are Asian (Bangladeshi) migrants living in London Commonest mutation gives a svere B+ (IVS1-5;g-c); most others give a B0 70% have a XmnI polymorphism 50% become transfusion dependent at 8 years for growth failure, anaemia, acute illness
therapyo 45% have splenectomies
7. Other HbE syndromes HbE/HbS - mild sickling disorder; increasingly common HbE/G6PD deficiency -no obvious phenotype HbE/HbLepore - thalassaemia intermedia, but rare
HbE/HbC - symptomless; occurs in Thailand
8. Future management of HbE syndromes Improved understanding of natural history
o Sri Lankan studies Noninvasive prenatal diagnosis Better prediction of phenotype from genotype Establish role of splenectomy, blood transfusion, hydroxyurea New therapeutic options
o Pomalidomide, lenalidomide Management of older patients Improved iron chelation