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The following points highlight the three main processes for biosynthesis of urea. The processes are: 1. Transamination 2. Oxidative Deamination 3. Ammonia Formation and Transport.
Process # 1. Transamination:
a. Transamination involves inter-conversion of a pair of α-amino acids and a pair of α- keto acids and is catalysed by transaminases or aminotransferases.
b. Pyridoxal phosphate (B6 PO4) is the coenzyme essential for the transaminase activity.
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c. Alanine-pyruvate transaminase (alanine transaminase) and glutamate-α-ketoglutarate transaminase (glutamate transaminase) present in most mammalian tissues, catalyze the transfer of amino groups from most amino acids to form alanine (from pyruvate) or glutamate (from α-ketoglutarate) shown in Fig. 20.2.
d. Transamination is a reversible process. This reversibility allows transaminases to function in amino acid catabolism and biosynthesis.
e. Each transaminase is specific for the specified pair of amino acid and keto acid as one pair of substrates.
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f. Most amino acids are substrates for transamination except lysine, threonine, proline and hydroxyproline. Not only δ- amino acid, δ-amino group of ornithine undergo transamination.
Process # 2. Oxidative Deamination:
a. Oxidative conversion of many amino acids to their corresponding α-keto acids occurs in mammalian liver and kidney tissues.
b. Both L- and D-amino acid oxidase activities occur in mammalian liver and kidney tissue and are also widely distributed in other animals and micro-organisms.
c. The amino acid oxidases are auto-oxidizable flavoproteins i.e. the reduced FMN or FAD is re-oxidized directly by molecular oxygen forming H2O2 without the help of cytochromes or other electron carriers shown in Fig. 20.3. The toxic product (H2O2) is then split to O2 and H2O by catalase which occurs widely in tissues, especially liver. If catalase is absent, the α- keto acid is decarboxylated by H2O2 forming a carboxylic acid with one carbon atom less.
In the amino acid oxidase reactions shown in Fig. 20.3, the amino acid is first dehydrogenated by the flavoprotein of the oxidase forming an α-imino acid which spontaneously decomposes to the corresponding α-keto acids by the addition of water.
d. Mammalian L-amino acid oxidase, an FMN-flavoprotein, is restricted to kidney and liver tissue and its activity is quite slow. Mammalian D-amino acid oxidase, an FAD-flavoprotein, occurs in the liver and kidney tissue of most mammals.
Significant Remarks:
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i. If the enzyme catalase is absent genetically, α-keto acid produced by oxidative deamination is decarboxylated by H2O2 forming a carboxylic acid with one carbon atom less.
ii. The activity of mammalian L-amino acid oxidase is restricted to liver and kidney only and the activity of this enzyme is quite slow in these tissues.
iii. The enzyme L-amino acid oxidase has no effect on glycine.
iv. This enzyme does not have a major role in the catabolism of mammalian amino acid and formation of ammonia.
Process # 3. Ammonia Formation and Transport:
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a. The amino groups of most amino acids are ultimately transferred to α-ketoglutarate by transamination. Release of this nitrogen as ammonia is catalyzed by L-glutamate dehydrogenase which is widely distributed in mammalian tissues. Certain hormones also influence glutamate dehydrogenase activity.
b. Glutamate dehydrogenase uses NAD+ or NADP+ as cosubstrate. The reaction is reversible.
c. Intestinal bacteria produce ammonia from dietary protein as well as from the urea present in fluids secreted into the gastrointestinal tract. This ammonia is absorbed from the intestine into the portal venous blood. Under normal conditions, the liver promptly removes the ammonia from the portal blood. Minute quantities of ammonia are toxic to the central nervous system.
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The symptoms of ammonia intoxication include slurring of speech, blurring of vision, a peculiar flapping tremor and in severe cases coma and death. These symptoms occur when brain ammonia levels are increased. Ammonia is produced in the kidney from intracellular amino acid, glutamine, catalyzed by renal glutaminase.
Ammonia production by the kidney is highly increased in metabolic acidosis and depressed in alkalosis.
d. Ammonia is excreted as ammonium salts during metabolic acidosis but the majority is excreted as urea. Ammonia is present only in traces in blood (10-20 µg/100 ml) because it is rapidly removed from the circulation by the liver and converted to glutamine or urea.
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e. Formation of glutamine is catalyzed by glutamine synthetase, a mitochondrial enzyme present in renal tissues in highest concentration, synthesis of glutamine is accompanied by the hydrolysis of ATP to ADP and Pi. The reaction is irreversible. Asparaginase and glutaminase are employed as antitumor agents because certain tumors require glutamine and asparagine.
f. In brain, the major mechanism for removal of ammonia is glutamine formation and in the liver, the most important pathway is urea formation. Brain tissue can form urea but this does not play a significant role in ammonia removal.