A SUITABLE BIOASSAY IS NEEDED TO MODEL LATHYRISM IN MONO-GASTRIC ANIMALS
Dirk Enneking
School of Food and Agriculture, University of Adelaide, Waite Agricultural Research Institute, Waite Rd. Glen
Osmond , 5064 South Australia (Australia).
•Introduction•Nutritional neuropathies•Malnutrition•The need for an animal bioassay to model neurolathyrism•Legume defence depletes sulfur amino acids
Global Production1-1,5 Mio ha0.7 - 1 Mio t of grain+/- forage
Also in
ChileCanadaChinaAustralia
Food & FeedNo problem withtoxicity
Mitchell, R. D. (1971). Ass Pacific Coast Geogr Yearbook 33: 29-46
% poor
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57 62 66 62 63 51
Neurolathyrism is intricately linked to famine (due to drought or conflict), poverty and malnutrition.
Ortiz de Landazuri (1944)
“in the presence of a protein poor diet (2000 kilo calories/day), 70 g/day of Lathyrus sativus do not produce lathyrism.
Up to 300 g of L. sativus can be consumed/day in the presence of protecting factors derived from better quality food (meat, cheese, milk) without provoking lathyrism.
A higher dose of L. sativus leads to lathyrism even in the presence of protecting factors.”
Nutritional neuropathies
Hong-Kong POW camp, 756 cases of peripheral neuropathy (Smith, 1946)
B-complex vitamins helped to alleviate symptoms
Smith, D. (1946). Nutritional neuropathies in the civilian internment camp, Hong Kong, January 1942—August 1945. Brain 69:209–22
Spillane, J. D. and Scott, G. (1945). Obscure neuropathy in the Middle East. Report on 112 cases in prisoners-of-war. The Lancet (6366)261-264
Malnutrition is also an important factor associated with other neuropathies, Konzo, optic neuropathy etc.
“ It demonstrates the sensibility of certain structures of the nervous system to various
agressions when there exists a basic level of undernutrition”
(Moya et al. Rev. Hyg. San. Hig. Publ. 1967)
Chronic undernutrition
Wasting: Mobilisation of nutrient reserves
Stunting: lower height for age due to prolonged wasting
Marasmus: severe malnutrition, no reserves left
grasspea eaters generally appear well nourished
-are easily missed by conventional nutritional surveys
? Specific form of biochemical wasting
Which nutrients are in short supply when a monotonous diets of grasspea or incompletely processed cassava is consumed for extended periods of time?
Which animal bioassay allows us to model neurolathyrism and Konzo?
Lathyrism in animals
Neurolathyrism in animals
Lathyrism in the horse
hindleg paralysis and and hoaring. Death occurs due to asphyxiation.
Large animals such as the horse are more frequently affected than small animals (Maleval, 1927)
Neurolathyrism in animals.
Numerous studies feeding grasspea to a variety of animals have produced mixed results (Fumarola and Zanelli, 1914)*.
Geiger et al. (1933) suggested that the differences in susceptibility of
individual animals is related to the quality of the base diet used in these experiments.
=>a poor quality base diet is likely to succeed better than an optimally balanced one to produce neurodegenerative symptoms
*Fumarola, G. and Zanelli, C. F. (1914). Anatomische experimentelle Forschungen ueber den Lathyrismus. Archiv Fuer Psychiatrie Und Nervenkrankheiten 54 (2)489-536
B group vitamins are all co-enzymes. They comprise:B1 thiamine, aneurineB2 riboflavinB3 niacin, nicotinic acidB6 pyridoxineB12 cobalmin, cyanocobalminBiotin, folic acid, pantothenic acidB group vitamins and vitamin C are water soluble and not stored in sufficient quantities in organisms
Insufficiences
Vitamins A,D,E, and K are all fat soluble and stored easilyLess likelyhood of insufficiencies.
Deficiencies in B vitamins
B1: polyneuritis, beriberi
B6: not well understood; convulsions, peripheral neuropathy, secondary pellagra
B6 Sources: whole grains, potatoes, green vegetables, maize, liver, red meat
B12 Important for all cells, particularly the nervous system.
Deficiencies lead to subacute degeneration of the spinal chord.
It is not found in significant amounts in plant foods but can be sourced from animal products (eggs, dairy, meat, liver, kidney, heart)
The B complex in general is involved in red blood cell formation, the normal functioning of the gastrointestinal tract and the metabolism of protein.
Sources: dark-green vegetables, legumes, whole grain, yeast, heart and pancreas.
Trace elementsCopperZincIron
López Aydillo, N. R. and Toledano Jiménez Castellanos, A. (1968) Trab. Inst. Cajal. Invest. Biol 60157-190
L. Sativus| missing
•Normal laboratory diet– this is the test diet (P. B.).
•oat mixed with milk (or milk soup. •Mixed diet: this diet is composed of 2g blue vetch L. sativus flour• plus 5g milk soup per rat per day. (milk soup contains approx. 1.33g bread and 3.67g milk).
•totally adjusted diet •(100% L. sativus + fed as pellets: olive oil, minerals, vits, casein and amino acids)•Partially adjusted diet
•Adjusted diet, lacking of olive oil.•Adjusted diet, lacking of mineral salts.•Adjusted diet, lacking of vitamins.•Adjusted diet, lacking of proteins•Adjusted diet, lacking of amino acids.
López Aydillo, N. R. and Toledano Jiménez Castellanos, A. (1968) Trab. Inst. Cajal. Invest. Biol 60157-190
Totally Adjusted diet Per 100g L. sativus flour fed as pellets
% survival
Male Female
Control 100 100
Mixed L.s. (control + L. s.) 93.3 100Total Adj L.s. (100 %L.s. + olive oil, salt, vitamins, casein, aminoacids+ 40 80
Total Adj L.s. No olive oil 0 0
Total Adj L.s. No salt 20 0
Total Adj L.s. No vitamins 40 0
Total Adj L.s. No casein 0 40
Total Adj L.s. No aminoacids 40 80
López Aydillo, N. R. and Toledano Jiménez Castellanos, A. (1968) Trab. Inst. Cajal. Invest. Biol 60157-190
a) The results of laboratory diet were normalb) Anatomical hurts were more important and extensive proceeding from exclusive
diet flour and total and partial adjusted dietsc) They were extensive and steady subarachnoid, pial and subpial hemorrhages
(excepting in those with salt depletion); demyelinisation, specially at the Corpus callosum and the white matter of the small cerebellar lobes; both Bergmann's and Alzheimer's ameboid types of gliosis
d) Neuronal changes overweighed in Ammon's horn area (Fascia dentata and Stratum pyramidale)
e) The hemorrhagic condition as a whole was similar to that of human internal hemorrhagic pachymeningitis
f) Morphological changes had no resemblance with those of deficiency diseases, because they were limited to a Nissl's chronic disturbance pattern
g) Exclusive daily food of blue vetch peas flour (Lathyrus sativus) as well as added with another complementary food (mixed diet) results in an endemic lathyritic condition. It is in strong nutritional indigence of exceptional times that such exclusive diet of flour originates the classic epidemical lathyrism
h) At present, both the clinical observations and the biochemical findings (Adiga's, Murti's, Rao's and Bell's tests) as well as our histopathological data, all support the toxic etiology of human lathyritic disease.
Legume seeds are generally deficient in sulfur amino acids
Exceptions:Vigna (cowpea) & Acacia spp. glutamyl-S-methyl-cysteine sulphoxide
Vicia (V. narbonensis et al.) glutamyl-S-ethenyl-cysteine
Legume defence strategy:
Deplete reduced thiols
Sulfur hypothesis:
Concerted action of legume antinutritional factors leads to depletion of reduced thiols in their predators
Example: Vicia sativa
Beta-cyanoalanine inhibits conversion of methionine to cysteine (source of reduced thiols).
Gamma-glutamyl-betacyanoalanine ends up in
the brain as
analog of glutathione (glu-cys-gly)
Impairment of glutathione metabolism!
Vicine oxidises reduced thiols in red blood cells.
Lack of sufficient reduced thiols –> hemolysis (favism in individuals lacking glucose 6-P-dehydrogenase in their red blood cells)
= genetically susceptible individuals are affected!
Protease inhibitors [high S aa content]*bind with proteases in the digestive tract.
Increased biosynthesis of proteases by the pancreas leads to
pancreatic hypertrophy.
=> Depletion of sulfur amino acids + other aa
Other enzyme inhibitors (alpha amylase i., lipase i. etc.) are likely to have similar effects.
*TI in lima and navy beans 2.5% of total, 32-40% of total cystine (cys-cys) Lajolo & Genovese (2002) J. Sci.Fd.Chem. 50, 6592-6598
Vicia sativa continued:
Tannins also bind digestive enzymes
Cyanogenic glycosides vicianine and prunasine release cyanide Ressler & Tatake, (2001) J. Agric. Food Chem. 49, 5075-5080
Cyanide is detoxified by thiosulphate derived from sulfur amino acids
-> A concerted attack on reduced thiols
Chowdhury, D.; Tate, M. E.; McDonald, G. K., and Hughes, R. (2001). Towards reducing seed toxin levels in common vetch (Vicia sativa L.). Proceedings of the 10th Australian Agronomy Conference, in Hobart Australian Society of Agronomy.http://www.regional.org.au/au/asa/2001/5/c/chowdury.htm
Vetch %12.5 25
12.5% vetch + 12.5 % L. cicera
25% Lathyrus sativus
Their anti-nutritional factors deplete sulfur amino acids in predators
Many target glutathione (glu-cys-gly) dependent systems (reduced thiols)
Lathyrus sativus seeds contain:
Low levels of sulfur amino acids
Trypsin inhibitors [high SAA]
Tannins
Lectins
ODAP
Homoarginine
Phytate
ODAP
Competes with Cysteine for uptake
Causes oxidative stress
depletion of reduced thiols
Inhibition of reduced thiol replenishment
ODAP inhibits tyrosine amino transferase (SLN Rao)
-> L-DOPA and its metabolites accumulate,
These are O-methylated
This requires S-adenosylmethionine
=> Depletion of sulfur amino acids
Hypothesis:
A lack of reduced thiols predisposes to lathyrism
This is caused through depletion by antinutrients, low intake of SAA, oxidative stress and/or genetic defect (s) in thiol metabolism
Animal model of toxic nutritional neuropathy
Poor base diet ToxinOxidative stressors
Sulfur amino acid deficiency/ depletion by inhibitorsB complex vitamin deficienciesEnergy depletionLipids, Micronutrients+/- genetic knockout models
Conclusion
Neurolathyrism and Konzo are intricately linked to nutritional deficiencies.
To model these and other nutritional neuropathies, a malnutrition animal model is needed.
Legumes deplete sulfur amino acids (saa) in their predators, suggesting that adequate saa supplementation protects against neurolathyrism. Additional neuroprotective nutrients ie. olive oil may also play a role.
Genetic animal models may help to dissect the underlying mechanisms.
Eradicate lathyrism !
Reduce toxicity (ODAP) in cultivars and provide adapted non-toxic varieties to grasspea eaters
Manage nutritional stress
(famines, poverty) & excessive grasspea consumption
Identify undernourished grasspea eaters during times of hardship
Monitor grasspea production, consumption and prices
Educate about processing options (detoxification) + supplements