Urea cycle and amino acid metabolism
Biochemistry for NursingSummer semester, 2015
Dr. Mamoun Ahram
Protein digestion
• In mouth: The breakdown of protein (large pieces of food are converted into smaller, more digestible portions).
• In stomach: – Proteins are denatured by the acidic
environment– Proteins are hydrolyzed by pepsin (its zyomgen
= pepsinogen)• In small intestine:
– Pepsin is inactivated by the neutral pH– Proteins and peptides are hydrolyzed by other
proteases (trypsin, chymotrypsin, and carboxypeptidase) into free amino acids.
• Amino acids are absorbed and released into bloodstream.
Protein hydrolysis
• The end result of protein digestion is hydrolysis of all peptide bonds to produce a collection of amino acids.
AMINO ACID METABOLISM
Fates of nitrogen and carbons of amino acids• Our bodies do not store nitrogen-containing compounds and
ammonia is toxic to cells. Therefore, the amino nitrogen from dietary protein and amino acids has just two possible fates:– either be incorporated into urea and excreted– Be used in the synthesis of new nitrogen-containing
compounds• The carbon atoms of amino acids are converted to
compounds that can enter the citric acid cycle, gluconeogenesis, fatty acid synthesis, or acetyl CoA.
Examples of compounds derived from amino acid carbons
• Intermediates of citric acid cycle.– About 10 20% of our energy is normally produced in
from amino acids. • Triacylglycerols (via lipogenesis)• Glycogen (via gluconeogenesis and glycogen
synthesis). • Ketone bodies.
Examples of nitrogen-containing compounds• Nitric oxide (NO, a chemical messenger)• Hormones• Neurotransmitters• Nicotinamide (NADH and NADPH)• Heme (in red blood cells)• Purine and pyrimidine bases (for nucleic acids)
The first step in amino acid catabolism is removal of the amino group.
Transamination reaction
• Transamination reactions interconvert amino acid amino groups and carbonyl groups.
• They are reversible and go easily in either direction, depending on the concentrations of the reactants.
• In this way, amino acid concentrations are regulated by keeping synthesis and breakdown in balance.
Alanine transaminase
• Alanine aminotransferase (ALT) is abundant in the liver.• Above-normal ALT concentration in the blood is an indication
of liver damage due to leakage into the bloodstream.
Production of ammoniaglutamate dehydrogenase
• The glutamate from transamination is as an amino group carrier.
• Most of the glutamate is recycled to regenerate –ketoglutarate.
• This process, known as oxidative deamination.• The ammonium ion formed in this reaction enters into the urea
cycle where it is eliminated in the urine as urea.
Features of the urea cycle
• This cycle is active in the liver.• The liver cleans the blood.• It removes with this cycle ammonia (NH4 +) from the
body in the form of urea.• Urea gets excreted through the kidneys in the urine.• The cycle occurs in the mitochondria and cytoplasm.
The cycleStart
The first reaction
• Carbamoyl phosphate is formed in the mitochondria of the cell from CO2 (in the form of bicarbonate), NH4
+ and ATP.
Building up reactive intermediates
• A carbamoyl group of carbamoyl phosphate ( ) is transferred to the ornithine forming citrulline.
• Exergonic reaction
High-energy bond
Building up reactive intermediates
• Citrulline and aspartate are condensed together into argininosuccinate.– Energy is provided by splitting ATP into AMP and
pyrophosphate.
More energy is produced
X2
Cleavage
• Argininosuccinate is split into arginine and fumarate.
Hydrolysis
• Arginine is hydrolyzed into urea and ornithine.• Ornithine can then enter the cycle again.
Net result
Remember: fumarate
Oxaloacetate
Transamination reaction
Atomic sources of urea
Hyperammonemia
• A complete block of any step in the urea cycle is fatal.
• Inherited disorders result in hyperammonemia which can lead to mental retardation.
• Extensive ammonia accumulation leads to vomiting in infancy, lethargy, irregular muscle coordination (ataxia), and mental retardation, extensive liver damage, and death.
• Treatment:– Dialysis– Low protein diet (long-term)
Gout
• A small amount of our waste nitrogen is excreted in urine and feces as urate rather than urea.
• Because the urate salt is highly insoluble, any excess of the urate anion causes precipitation of sodium urate in joints.
• The pain of gout results from a cascade of inflammatory responses to these crystals in the affected tissue.
Metabolism
• Uric acid is an end product of the breakdown of purine nucleosides, and loss of its proton (H+) gives ureate ion.
Causes of gout
• Metabolic (accelerated breakdown of ATP, ADP, or AMP)– Alcohol abuse generates acetaldehyde that must be metabolized
in the kidney by a pathway that requires ATP and produces excess AMP.
– Inherited fructose intolerance and glycogen storage diseasesaccelerate uric acid production.
– Circulation of poorly oxygenated blood • With low oxygen, ATP is not efficiently regenerated from ADP in
mitochondria, excess ADP is disposed.• Renal
– Conditions that diminish excretion of uric acid include kidney disease, dehydration, hypertension, lead poisoning, and competition for excretion from anions produced by ketoacidosis.
Treatment
• Allopurinol inhibits the enzyme which produces uric acid.– Since hypoxanthine and
xanthine are more soluble than sodium urate, they are more easily eliminated.
• Rasburicase catalyzes enzymatic oxidation of poorly soluble uric acid into amore soluble metabolite allantoin.– It is still under investigation for
treating gout.
Essential and nonessential amino acids
Nonessential EssentialAlanine HistidineArginine IsoleucineAsparagine LeucineAspartate LysineCysteine MethionineGlutamate PhenylalanineGlutamine ThreonineGlycine TryptophanProline ValineSerineTyrosine
• Human beings cannot make 9 amino acids. These are known as essential amino acids
• The other 11 amino acids are termed nonessential amino acids
The importance of essential amino acids and effects of deficiencies• Histidine: A deficiency can cause joint pain (linked to rheumatoid
arthritis)• Lysine: formation of collagen for bones and cartilage.• Methionine: a primary source of sulfur when cysteine intake is
limited.• Phenylalanine: a source of tyrosine.• Tryptophan: the metabolic starting material for serotonin; it is a
natural relaxant that can relieve insomnia. Its deficiency leads to serotonin deficiency syndrome.
• Arginine: the majority of arginine is synthesized in the urea cycle where it is cleaved to form urea and ornithine; a certain amount must be taken daily, especially for men of reproduction age, since 80% of the amino acid composition of male seminal fluid is made of arginine.
Foods with complete amino acids
Foods with incomplete amino acids
Complementary sources of amino acids
Fate of amino acids
White boxes: ketogenic amino acids
Green boxes: glucogenic amino acids
Both ketogenic and glucogenic amino acids are able to enter fatty acid biosynthesis via acetyl-SCoA
Biosynthesis of nonessential amino acids Glutamate
• The amino group of glutamate is the precursor of all nonessential amino acids
• Glutamate is made from -ketoglutarate by reductive deamination
Other precursors of amino acids
Glutamine and asparagine
• Glutamine is made from glutamate
• Asparagine is made from glutamine
Phenylketonuria
• Tyrosine is made from phenylalanine.
• Inability to drive this reaction causes accumulation of phenylalanine, a condition known as phenylketonuria.
Metabolites
Symptoms and treatment of phenylketonuria
• Mental retardation
• Treatment: diet with low phenylalanine (low-protein grain)
• Individuals with PKU must avoid foods sweetened with aspartame (Nutrasweet, for example), which is a derivative of phenylalanine.
Test for phenylketonuria
Alkaptonuria
Symptoms