The role of glutamine transaminase K (GTK) in sulfur and alpha-keto acid metabolism in the brain, and in the possible bioactivation of neurotoxicants

Glutamine transaminase K (GTK), which is a freely reversible glutamine (methionine) aromatic amino acid aminotransferase, is present in most mammalian tissues, including brain. Quantitatively, the most important amine donor in vivo is glutamine. The product of glutamine transamination (i.e., alpha-ketoglutaramate; alphaKGM) is rapidly removed by cyclization and/or conversion to alpha-ketoglutarate. Transamination is therefore "pulled" in the direction of glutamine utilization. Major biological roles of GTK are to maintain low levels of phenylpyruvate and to close the methionine salvage pathway. GTK also catalyzes the transamination of cystathionine, lanthionine, and thialysine to the corresponding alpha-keto acids, which cyclize to ketimines. The cyclic ketimines and several metabolites derived therefrom are found in brain. It is not clear whether these compounds have a biological function or are metabolic dead-ends. However, high-affinity binding of lanthionine ketimine (LK) to brain membranes has been reported. Mammalian tissues possess several enzymes capable of catalyzing transamination of kynurenine in vitro. Two of these kynurenine aminotransferases (KATs), namely KAT I and KAT II, are present in brain and have been extensively studied. KAT I and KAT II are identical to GTK and alpha-aminoadipate aminotransferase, respectively. GTK/KAT I is largely cytosolic in kidney, but mostly mitochondrial in brain. The same gene codes for both forms, but alternative splicing dictates whether a 32-amino acid mitochondrial-targeting sequence is present in the expressed protein. The activity of KAT I is altered by a missense mutation (E61G) in the spontaneously hypertensive rat. The symptoms may be due in part to alteration of kynurenine transamination. However, owing to strong competition from other amino acid substrates, the turnover of kynurenine to kynurenate by GTK/KAT I in nervous tissue must be slow unless kynurenine and GTK are sequestered in a compartment distinct from the major amino acid pools. The possibility is discussed that the spontaneous hypertension in rats carrying the GTK/KAT I mutation may be due in part to disruption of glutamine transamination. GTK is one of several pyridoxal 5'-phosphate (PLP)-containing enzymes that can catalyze non-physiological beta-elimination reactions with cysteine S-conjugates containing a good leaving group attached at the sulfur. These elimination reactions may contribute to the bioactivation of certain electrophiles, resulting in toxicity to kidney, liver, brain, and possibly other organs. On the other hand, the beta-lyase reaction catalyzed by GTK may be useful in the conversion of some cysteine S-conjugate prodrugs to active components in vivo. The roles of GTK in (a) brain nitrogen, sulfur, and aromatic amino acid/kynurenine metabolism, (b) brain alpha-keto acid metabolism, (c) bioactivation of certain electrophiles in brain, (d) prodrug targeting, and (e) maintenance of normal blood pressure deserve further study.     

Kynurenine Aminotransferase III and Glutamine Transaminase L Are Identical Enzymes that have Cysteine S-Conjugate β-Lyase Activity and Can Transaminate l-Selenomethionine

Three of the four kynurenine aminotransferases (KAT I, II, and IV) that synthesize kynurenic acid, a neuromodulator, are identical to glutamine transaminase K (GTK), α-aminoadipate aminotransferase, and mitochondrial aspartate aminotransferase, respectively. GTK/KAT I and aspartate aminotransferase/KAT IV possess cysteine S-conjugate β-lyase activity. The gene for the former enzyme, GTK/KAT I, is listed in mammalian genome data banks as CCBL1 (cysteine conjugate beta-lyase 1). Also listed, despite the fact that no β-lyase activity has been assigned to the encoded protein in the genome data bank, is a CCBL2 (synonym KAT III). We show that human KAT III/CCBL2 possesses cysteine S-conjugate β-lyase activity, as does mouse KAT II. Thus, depending on the nature of the substrate, all four KATs possess cysteine S-conjugate β-lyase activity. These present studies show that KAT III and glutamine transaminase L are identical enzymes. This report also shows that KAT I, II, and III differ in their ability to transaminate methyl-l-selenocysteine (MSC) and l-selenomethionine (SM) to β-methylselenopyruvate (MSP) and α-ketomethylselenobutyrate, respectively. Previous studies have identified these seleno-α-keto acids as potent histone deacetylase inhibitors. Methylselenol (CH₃SeH), also purported to have chemopreventive properties, is the γ-elimination product of SM and the β-elimination product of MSC catalyzed by cystathionine γ-lyase (γ-cystathionase). KAT I, II, and III, in part, can catalyze β-elimination reactions with MSC generating CH₃SeH. Thus, the anticancer efficacy of MSC and SM will depend, in part, on the endogenous expression of various KAT enzymes and cystathionine γ-lyase present in target tissue coupled with the ability of cells to synthesize in situ either CH₃SeH and/or seleno-keto acid metabolites.     

A purified cysteine conjugate beta-lyase from rat kidney cytosol. Requirement for an alpha-keto acid or an amino acid oxidase for activity and identity with soluble glutamine transaminase K

Cysteine conjugate beta-lyase has been purified from rat kidney cytosol. The enzyme is a 100,000-dalton dimer of two 55,000-dalton subunits and has an absorption maximum at 432 nm. The enzyme has phenylalanine alpha-keto-gamma-methiolbutyrate transaminase activity and appears to be identical to rat kidney cytosolic glutamine transaminase K. Metabolism of S-1,2-dichlorovinyl-L-cysteine (DCVC) by the purified enzyme was dependent on the presence of either alpha-keto-gamma-methiolbutyrate or a protein factor which is present in the cytosolic fraction of rat kidney cortex. The protein factor was identified as a flavin containing L-amino acid oxidase which oxidized DCVC to S-(1,2-dichlorovinyl)-3-mercapto-2-oxopropionic acid. S-(1,2-Dichlorovinyl)-3-mercapto-2-oxopropionic acid has not been previously reported as a metabolite of DCVC. The data also show that rat kidney cytosolic glutamine transaminase K catalyzes both a beta-elimination and a transamination reaction with DCVC when alpha-keto-gamma-methiolbutyrate is present and that amino acid oxidase and alpha-keto-gamma-methiolbutyrate stimulate the enzyme activity by providing amino acceptors. When incubations were done with DCVC as substrate in the presence of excess alpha-keto-gamma-methiolbutyrate, the beta-lyase catalyzed beta-elimination and transamination in a ratio of 1:1.3, respectively. Under conditions where most of the alpha-keto-gamma-methiolbutyrate was consumed, the beta-elimination predominated indicating that the S-1,2-dichlorovinyl-3-mercapto-2-oxopropionic acid pool was consumed by transamination after the alpha-keto-gamma-methiolbutyrate had been depleted. The data are discussed with regard to the importance of these pathways as regulators or participants in the toxicity of S-cysteine conjugates.     

Transamination of l-cystathionine and related compounds by bovine brain glutamine transaminase

Glutamine transaminase (EC 2.6.1.15) has been purified 113 fold from bovine brain. The product is free of aspariate amino transferase (EC 2.6.1.1.) and other common transaminases. The enzyme shows a wide specificity similar to that reported from the same transaminase purified from bovine kidney and liver as regards both the amino donor and the amino acceptor. Of interest is the transamination and cyclization of l-cystathionine, l-lanthionine, l-cystine and S-aminoethylcysteine. The latter result indicates that the deamination and the cyclization of the sulfur containing diamino acids described for bovine liver and kidney enzyme is feasible also in the brain and suggests the possible endogenous origin of cyclothionine and thiomorpholine dicarboxylate recently detected in bovine brain.     

Biochemical and Structural Properties of Mouse Kynurenine Aminotransferase III

Kynurenine aminotransferase III (KAT III) has been considered to be involved in the production of mammalian brain kynurenic acid (KYNA), which plays an important role in protecting neurons from overstimulation by excitatory neurotransmitters. The enzyme was identified based on its high sequence identity with mammalian KAT I, but its activity toward kynurenine and its structural characteristics have not been established. In this study, the biochemical and structural properties of mouse KAT III (mKAT III) were determined. Specifically, mKAT III cDNA was amplified from a mouse brain cDNA library, and its recombinant protein was expressed in an insect cell protein expression system. We established that mKAT III is able to efficiently catalyze the transamination of kynurenine to KYNA and has optimum activity at relatively basic conditions of around pH 9.0 and at relatively high temperatures of 50 to 60°C. In addition, mKAT III is active toward a number of other amino acids. Its activity toward kynurenine is significantly decreased in the presence of methionine, histidine, glutamine, leucine, cysteine, and 3-hydroxykynurenine. Through macromolecular crystallography, we determined the mKAT III crystal structure and its structures in complex with kynurenine and glutamine. Structural analysis revealed the overall architecture of mKAT III and its cofactor binding site and active center residues. This is the first report concerning the biochemical characteristics and crystal structures of KAT III enzymes and provides a basis toward understanding the overall physiological role of mammalian KAT III in vivo and insight into regulating the levels of endogenous KYNA through modulation of the enzyme in the mouse brain.     

Glutamine transaminase K and cysteine S-conjugate beta-lyase activity stains.

An activity stain to detect glutamine transaminase K subjected to nondenaturing polyacrylamide gel electrophoresis (ND-PAGE) was developed. The gel is incubated with a reaction mixture containing L-phenyl-alanine, alpha-keto-gamma-methiolbutyrate (alpha KMB), glutamate dehydrogenase, phenazine methosulfate (PMS) and nitroblue tetrazolium (NBT). Glutamine transaminase K catalyzes a transamination reaction between phenylalanine and alpha KMB. The resultant methionine is a substrate of glutamate dehydrogenase. The NADH formed in the oxidative deamination of methionine reacts with PMS and NBT to form a blue band on the surface of the gel coincident with glutamine transaminase K activity. Cysteine S-conjugate beta-lyase activity is detected in the gel by incubating the gel with a reaction mixture containing alpha KMB (to ensure maintenance of the enzyme in the pyridoxal 5'-phosphate form), S-(1,2-dichlorovinyl)-L-cysteine (DCVC), PMS, and NBT. The products of the lyase reaction interact with PMS and NBT to form a blue dye coincident with the lyase activity. In addition, a new assay procedure for measuring cysteine S-conjugate beta-lyase activity was devised. This procedure couples pyruvate formation from DCVC to the alanine dehydrogenase reaction. Preparations of purified rat kidney glutamine transaminase K yield a single protein band on ND-PAGE (apparent Mr approximately 95,000). This band coincides with both the cysteine S-conjugate beta-lyase and glutamine transaminase K activities. Activity staining showed that homogenates of rat kidney, liver, skeletal muscle, and heart possess a glutamine transaminase K/cysteine S-conjugate beta-lyase activity with an Rf value on ND-PAGE identical to that of purified rat kidney glutamine transaminase K.(ABSTRACT TRUNCATED AT 250 WORDS)     

Highly purified glutamine transaminase from rat brain. Physical and kinetic properties.

Glutamine transaminase from rat brain was purified to a high degree. The isolated enzyme appeared to be homogeneous by electrophoresis on polyacrylamide gel. The molecular weight was found to be approximately 98 000; the enzyme is probably composed of two subunits. The absorbance maximum at 410 nm and the inhibition by carbonyl reagents are strong indications for the presence of pyridoxal phosphate. The enzyme showed maximal activity at pH 9.0 to 9.2. Of the amino acids tested, none could replace glutamine in the transamination reaction. Glyoxylate and phenylpyruvate was found to be the best amino acceptors. The Km values for glutamine and glyoxylate were 0.6 and 1.5 mM, respectively.     

The transamination of L-cystathionine, L-cystine and related compounds by a bovine kidney transaminase

An enzyme which actively transaminates L-cystathionine, L-cystine, L-lanthionine and S-aminoethyl-L-cysteine has been purified from bovine kidney. The transaminase appears to be pure up to 90% and probably consists of two subunits of similar molecular mass of about 47 kDa. The enzymatic products arising from the transamination of L-cystathionine and related compounds spontaneously cyclize into ketiminic structures, which are the immediate precursors of unusual imino acids recovered in biological materials. The specificity towards other amino acid and oxo acid acceptors is similar to the specificity exhibited by rat kidney glutamine transaminase. This suggests that the sulfur amino acid transaminations that have been described could be performed by the bovine kidney glutamine transaminase.     

Substrate specificity of human glutamine transaminase K as an aminotransferase and as a cysteine S-conjugate beta-lyase

Rat kidney glutamine transaminase K (GTK) exhibits broad specificity both as an aminotransferase and as a cysteine S-conjugate β-lyase. The β-lyase reaction products are pyruvate, ammonium and a sulfhydryl-containing fragment. We show here that recombinant human GTK (rhGTK) also exhibits broad specificity both as an aminotransferase and as a cysteine S-conjugate β-lyase. S-(1,1,2,2-Tetrafluoroethyl)-l-cysteine is an excellent aminotransferase and β-lyase substrate of rhGTK. Moderate aminotransferase and β-lyase activities occur with the chemopreventive agent Se-methyl-l-selenocysteine. l-3-(2-Naphthyl)alanine, l-3-(1-naphthyl)alanine, 5-S-l-cysteinyldopamine and 5-S-l-cysteinyl-l-DOPA are measurable aminotransferase substrates, indicating that the active site can accommodate large aromatic amino acids. The α-keto acids generated by transamination/l-amino acid oxidase activity of the two catechol cysteine S-conjugates are unstable. A slow rhGTK-catalyzed β-elimination reaction, as measured by pyruvate formation, was demonstrated with 5-S-l-cysteinyldopamine, but not with 5-S-l-cysteinyl-l-DOPA. The importance of transamination, oxidation and β-elimination reactions involving 5-S-l-cysteinyldopamine, 5-S-l-cysteinyl-l-DOPA and Se-methyl-l-selenocysteine in human tissues and their biological relevance are discussed.     

Kynurenine pyruvate transaminase and its inhibitor in rat intestine

Kynurenine pyruvate transaminase was found to be present in rat small intestine, partially purified and characterized. The enzyme catalysed the conversion of L-kynurenine to kynurenic acid. Transamination rates of 3-hydroxy-DL-kynurenine and 5-hydroxy-DL-kynurenine by the enzyme were 1/2.9 and 1/2.6 that of L-kynurenine. The enzyme showed higher preference for pyruvate than 2-oxoglutarate as aminoacceptor. The pH optimum of the reaction was 8.0 to 8.5. Purification of the enzyme lowered markedly apparent Km for L-kynurenine but not for pyruvate. It was shown that the inhibitor of kynurenine pyruvate transaminase was present in the intestine, on the basis of the inhibition produced by heating a portion of each purification step enzyme preparation in 50% ethanol, centrifuging, concentrating it, and adding it to an incubate of the unheated preparation. The possible interrelationship of enzyme and inhibitor was discussed and comparisons with kynurenine transaminase in liver, kidney and brains were noted.     

The pathway of glutamine and glutamate oxidation in isolated mitochondria from mammalian cells

1. Pyruvate strongly inhibited aspartate production by mitochondria isolated from Ehrlich ascites-tumour cells, and rat kidney and liver respiring in the presence of glutamine or glutamate; the production of (14)CO(2) from l-[U-(14)C]glutamine was not inhibited though that from l-[U-(14)C]glutamate was inhibited by more than 50%. 2. Inhibition of aspartate production during glutamine oxidation by intact Ehrlich ascites-tumour cells in the presence of glucose was not accompanied by inhibition of CO(2) production. 3. The addition of amino-oxyacetate, which almost completely suppressed aspartate production, did not inhibit the respiration of the mitochondria in the presence of glutamine, though the respiration in the presence of glutamate was inhibited. 4. Glutamate stimulated the respiration of kidney mitochondria in the presence of glutamine, but the production of aspartate was the same as that in the presence of glutamate alone. 5. The results suggest that the oxidation of glutamate produced by the activity of mitochondrial glutaminase can proceed almost completely through the glutamate dehydrogenase pathway if the transamination pathway is inhibited. This indicates that the oxidation of glutamate is not limited by a high [NADPH]/[NADP(+)] ratio. 6. It is suggested that under physiological conditions the transamination pathway is a less favourable route for the oxidation of glutamate (produced by hydrolysis of glutamine) in Ehrlich ascites-tumour cells, and perhaps also kidney, than the glutamate dehydrogenase pathway, as the production of acetyl-CoA strongly inhibits the first mechanism. The predominance of the transamination pathway in the oxidation of glutamate by isolated mitochondria can be explained by a restricted permeability of the inner mitochondrial membrane to glutamate and by a more favourable location of glutamate-oxaloacetate transaminase compared with that of glutamate dehydrogenase.     

Subcellular distribution and properties of kynurenine pyruvate transaminase in rat kidney.

Kynurenine transaminase activity in rat kidney was found in both the mitochondrial and supernatant fractions. These fractions contained (a) kynurenine pyruvate transaminase, which showed a preference for pyruvate as amino acceptor, and had a pH optimum between 8.0 and 8.5, and (b) kynurenine 2-oxoglutarate transaminase, with a preference for 2-oxoglutarate and a pH optimum between 6.0 and 6.5. The apparent Km value of the former enzyme for L-kynurenine was much lower than that of the latter enzyme.     

Asparagine transaminase from rat liver.

Asparagine transaminase has been purified about 200-fold from rat liver. The enzyme has a broad specificity toward both amino acids and alpha-keto acids. Thus, amino acids substituted in the beta position such as asparagine, S-methylcysteine, phenylalanine, cysteine, serine, and aspartate are substrates. The enzyme is also active with alanine, methionine, homoserine, alpha-aminobutyrate, glutamine, and leucine. The enzyme has a high affinity for glyoxylate but the affinity falls off markedly through the series glyoxylate, pyruvate, alpha-ketoburyrate, alpha-Keto acids substituted in the beta or gamma position, such as alpha-ketosuccinamate, phenylpyruvate, p-hydroxyphenylpyruvate, alpha-keto-gamma-methiolburyrate, and alpha-keto-gamma-hydroxybutyrate, are substrates for the enzyme. Amino acids or alpha-keto acids possessing a branch point at the beta carbon are inactive. Kinetic analysis of the asparagine glyoxylate transamination reaction is consistent with a ping-pong mechanism.     

Transamination of L-cystathionine and related compounds by a bovine liver enzyme. Possible identification with glutamine transaminase

A transaminase which catalyses the monodeamination of L-cystathionine was purified 1100-fold with a yield of 15% from bovine liver. The monoketoderivative of cystathionine spontaneously produces the cyclic ketimine. Other sulfur-containing amino acids related to cystathionine such as cystine, lanthionine and aminoethylcysteine were also substrates for the enzyme. The relative molecular mass of the enzyme was determined to be 94 000 with a probable dimeric structure formed of identical subunits. The isoelectric point of the enzyme was at pH 5.0 and the maximal enzymatic activity was found at pH 9.0--9.2. Kinetic parameters for cystathionine and for the other sulfur amino acids as well as for some alpha-keto acids were also determined. Among the natural amino acids tested, glutamine, methionine and histidine were the best amino donors. The enzyme exhibited maximal activity toward phenylpyruvate and alpha-keto-gamma-methiolbutyrate as amino acceptors. The broad specificity of the enzyme leads us to infer that the cystathionine transaminase is very similar or identical to glutamine transaminase.     

Mitochondrial aspartate aminotransferase: a third kynurenate-producing enzyme in the mammalian brain

The tryptophan metabolite kynurenic acid (KYNA), which is produced enzymatically by the irreversible transamination of l-kynurenine, is an antagonist of alpha7 nicotinic and NMDA receptors and may thus modulate cholinergic and glutamatergic neurotransmission. Two kynurenine aminotransferases (KAT I and II) are currently considered the major biosynthetic enzymes of KYNA in the brain. In this study, we report the existence of a third enzyme displaying KAT activity in the mammalian brain. The novel KAT had a pH optimum of 8.0 and a low capacity to transaminate glutamine or alpha-aminoadipate (the classic substrates of KAT I and KAT II, respectively). The enzyme was inhibited by aspartate, glutamate, and quisqualate but was insensitive to blockade by glutamine or anti-KAT II antibodies. After purification to homogeneity, the protein was sequenced and the enzyme was identified as mitochondrial aspartate aminotransferase (mitAAT). Finally, the relative contributions of KAT I, KAT II, and mitAAT to total KAT activity were determined in mouse, rat, and human brain at physiological pH using anti-mitAAT antibodies. KAT II was most abundant in rat and human brain, while mitAAT played the major role in mouse brain. It remains to be seen if mitAAT participates in cerebral KYNA synthesis under physiological and/or pathological conditions in vivo.     

Purification and properties of hydroxypyruvate: l-Alanine transaminase from rabbit liver

A procedure is described for the extensive purification of hydroxypyruvate:l-alanine transaminase from rabbit liver. On the basis of gel filtration studies, the molecular weight of the enzyme is estimated to be about 41,000 daltons. A similar value was obtained when the enzyme was subjected to gel electrophoresis in the presence of sodium dodecyl sulfate indicating that the enzyme consists of a single polypeptide chain.The purified enzyme catalyzes the transamination of glyoxylate as well as hydroxypyruvate with l-alanine as the preferred amino donor for both substrates. The two enzymatic activities were not separated during purification nor by Chromatographic or electrophoretic procedures. Kinetic studies demonstrated that the two α-keto acids are competitive substrates. The above data are consistent with the fact that a single enzyme catalyzes the transamination of both glyoxylate and hydroxypyruvate. The effects of various inhibitors on enzymatic activity were investigated. The enzyme is inhibited by glyceraldehyde-3-phosphate and other aldehydes.The possible role of hydroxypyruvate:l-alanine transaminase in gluconeogenesis is discussed.     

Cloning and Characterization of a Soluble Kynurenine Aminotransferase from Rat Brain: Identity with Kidney Cysteine Conjugate β-Lyase

Abstract: In this study, we describe the cloning and characterization of a soluble form of kynurenine aminotransferase (KAT, EC 2.6.1.7) present in rat brain. Soluble KAT was purified from rat kidney and the amino acid sequences of four tryptic peptides determined. These peptides were found to belong to the amino acid sequence reported for rat kidney soluble cysteine conjugate β-lyase, indicating that rat kidney KAT and β-lyase represent the same molecular entity. Oligonucleotide probes derived from the β-lyase cDNA were then used as primers for PCR of reverse-transcribed rat brain poly(A)⁺ RNA. After subcloning of the resulting PCR fragment and sequencing of the isolated rat brain clone, its oligonucleotide sequence was found to be identical to that reported for the β-lyase cDNA. Further evidence that the isolated rat brain clone encoded for KAT was obtained by transfecting HEK-293 cells with a construct containing the coding sequence for the enzyme. The transfected cells exhibited KAT activity and, in the presence of 2 m M pyruvate and 2-oxoglutarate, the K _m values for l -kynurenine were 1.2 m M and 86.3 µ M , respectively. Northern blot analysis of rat kidney, liver, and brain RNA revealed a single species of KAT/β-lyase mRNA of ∼2.1 kb.     

Separation of L-phenylalanine: pyruvate transaminase and L-phenylalanine: alpha-ketoglutarate transaminase by sephadex-electrophoresis.

By means of a Sephadex-electrophoresis column, L-phenylalanine: pyruvate transaminase (PPT) was separated from L-phenylalanine: α-ketoglutarate transaminase (PKT) from rat liver. These enzymes differed in heat lability $\text{in vitro}$ and in their inducibility by glucagon $\text{in vivo}$. PPT was heat-stable and was induced by chronic glucagon injection. On the other hand, PKT was heat-labile and was not induced by glucagon under the experimental conditions used. These studies provide evidence that distinct enzymes catalyze the transamination of phenylalanine with pyruvate or with α-ketoglutarate as the amino acceptor.     

Analysis of kynurenine transaminase activity in Drosophila by high performance liquid chromatography

A sensitive assay for kynurenine transaminase activity (E.C. 2.6.1.7) based on rapid separation of the reaction product by high performance liquid chromatography (HPLC) has been developed. Drosophila sordidula extracts have been assayed by this new method and this is the first time that kynurenine transaminase activity has been demonstrated in Drosophila. The method of assay developed can be extended to any other organism. Kynurenine and 3-hydroxykynurenine were both used as substrates, and they were transaminated to kynurenic acid and xanthruenic acid, respectively. HPLC is used to separate and quantitate these reaction products from all other components in the reaction mixture.In crude extracts from Drosophila, the reaction requires pyridoxal 5′-phosphate and an amino acid acceptor. The enzyme activity showed a maximum at 47°C and pH 8.0 with kynurenine and pyruvic acid as substrates. Transaminase activity was present in both head and body, nevertheless the specific activity was higher in the former. In bodies, pyruvic acid was the best amino acceptor whereas in heads it was α-oxoglutaric acid. The variation of kynurenine transaminase during development of D. sordidula showed, in the larval and pupal stages, activity levels practically constant and much lower than those found in the adult. This seems to suggest a preferential role of this enzyme in the metabolism of intermediates in the biosynthesis of ommochromes.