Biotransformation of D-methionine into L-methionine in the cascade of four enzymes

D-Methionine was converted to L-methionine in a reaction system where four enzymes were used. D-amino acid oxidase (D-AAO) from Arthrobacter protophormiae was used for the complete conversion of D-methionine to 2-oxo-4-methylthiobutyric acid. Catalase was added to prevent 2-oxo-4-methylthiobutyric acid decarboxylation. In the second reaction step, L-phenylalanine dehydrogenase (L-PheDH) from Rhodococcus sp. was used to convert 2- oxo-4-methylthiobutyric acid to L-methionine, and formate dehydrogenase (FDH) from Candida boidinii was added for NADH regeneration. Enzyme kinetics of all enzymes was analyzed in detail. Mathematical models for separate reactions steps, as well as for the complete system were developed and validated in the batch reactor experiments. Complete conversion of D-methionine to L-methionine was achieved. Considering that both enzymes act on different substrates, such a system could be easily employed for the synthesis of other amino acids from D-isomer, as well as from the racemate of a certain amino acid (DL-amino acid).     

Metabolism of 5-methylthioribose to methionine

During ethylene biosynthesis, the H₃CS- group of S-adenosylmethionine is released as 5′-methylthioadenosine, which is recycled to methionine via 5-methylthioribose (MTR). In mungbean hypocotyls and cell-free extracts of avocado, [¹⁴C]MTR was converted into labeled methionine via 2-keto-4-methylthiobutyric acid (KMB) and 2-hydroxy-4-methylthiobutyric acid (HMB), as intermediates. Incubation of [ribose-U-¹⁴C]MTR with avocado extract resulted in the production of [¹⁴C]formate, indicating the conversion of MTR to KMB involves a loss of formate, presumably from C-1 of MTR. Tracer studies showed that KMB was converted readily in vivo and in vitro to methionine, while HMB was converted much more slowly. The conversion of KMB to methionine by dialyzed avocado extract requires an amino donor. Among several potential donors examined, l-glutamine was the most efficient. Anaerobiosis inhibited only partially the oxidation of MTR to formate, KMB/HMB, and methionine by avocado extract. The role of O₂ in the conversion of MTR to methionine is discussed.     

Ketomethylthiobutyric acid formation from methylthioadenosine: A diffusion assay

Typical enzyme kinetics were observed when 5′-methylthioadenosine was used as substrate with extracts of malignant murine cells in a diffusion assay. The volatile product was measured after diffusion into a solution of the sulfhydryl reagent, 5,5′-dithiobis(2-nitrobenzoic acid), which it reduced to a yellow chromophore. Cysteine was required in the system. The volatile product was identified as H₂S derived from the cysteine. The yield of H₂S was similar to the amount of 2-keto-4-methylthiobutyric acid (KMTB) formed from methylthioadenosine when the KMTB was measured simultaneously in an ether extraction assay. KMTB could replace methylthioadenosine as a substrate capable of causing the formation of the diffusible product from cysteine. It is concluded that the following sequence of reactions takes place in the diffusion assay system: (1) 5′-methylthioadenosine + P_i → adenine + 5-methylthioribose-1-P, (2) 5-methylthioribose-1-P → KMTB, (3) KMTB + cysteine → methionine + 3-mercaptopyruvate, (4) 3-mercaptopyruvate + excess R-SH → pyruvate + H₂S, (5) H₂S + 5,5′-dithiobis(2-nitrobenzoic acid) → 5-mercapto-2-nitrobenzoic acid. Thus, the diffusion assay measures the amount of KMTB formed. The key enzyme, cysteine aminotransferase, EC 2.6.1.3, was partially purified from malignant cells and from liver and several of its characteristics are described. The diffusion assay using this enzyme is useful in measuring de novo synthesis of α-keto acids and it is applicable to crude enzyme preparations. The sensitivity is about 5 nmol of keto acid and the accurate range is 5 to 100 nmol.     

Design, synthesis and cytotoxic evaluation of keto-C-glycoside fatty acid conjugates.

Keto C-glycoside-fatty acid conjugates were synthesized from 6-hydroxy 2- and 4-keto unsaturated D-C-glycosides. These compounds were tested for cytotoxic activity against LFCl₂A cells (Rat hepatocarcinoma cells). The introduction of a lipid chain to 2-keto C-glycosides induced a drop in the cyctotoxic activity of these compounds. On the other hand 4-keto unsaturated C-glycoside-fatty acid conjugates possessed IC₅₀ values of 0.7–0.001 μM with 21 being the most potent.     

The metabolism of 5'-methylthioadenosine and 5-methylthioribose 1-phosphate in Saccharomyces cerevisiae

Cordycepin sensitive mutants of Saccharomyces cerevisiae, which are permeable to 5'-deoxy-5'-methylthioadenosine (MTA), were used to study the fate of the methylthioribose carbons of this purine nucleoside. Evidence is presented for the recycling of the methylthio group and part of the ribose portion of MTA in a biosynthetic pathway which leads to the synthesis of methionine. The main pathway involves the phosphorylytic cleavage of MTA by MTA phosphorylase yielding 5-methylthioribose 1-phosphate and adenine as products. Loss of the phosphate group of 5-methylthioribose 1-phosphate, concurrent with the rearrangement of the ribose carbons, leads to the synthesis of 2-keto-4-methylthiobutyric acid. In the final step of the sequence, 2-keto-4-methylthiobutyric acid is converted to methionine via transamination. Several compounds not directly associated with the biosynthesis of methionine were also isolated. These compounds, which may arise through the degradation of intermediates in the pathway, were: 5'-methylthioinosine, a deaminated catabolite of MTA; 5-methylthioribose, a result of the phosphorylysis of 5-methylthioribose 1-phosphate, and 3-methylthiopropionaldehyde, 3-methylthiopropionic acid and 2-hydroxy-4-methylthiobutyric acid, all arising from the catabolism of 2-keto-4-methylthiobutyric acid.     

Uptake of alpha-ketoisocaproic acid in lymphoblast line WI-L2.

The uptake of α-ketoisocaproate by the cultured human lymphoblast line WI-L2 appears to be mediated by a transport system which has an apparent Km of 125 μM. The rate of uptake of α-ketoisocaproate decreases with increasing pH values, i.e., pH 6 > 7 > 8 and is stimulated by sodium at all pH values. Closely related branched chain α-ketoacids, α-keto-β-methylvaleric and α-ketoisovaleric exhibited the greatest inhibition of α-ketoisocaproate transport. Straight chain α-keto acids inhibited α-ketoisocaproic acid uptake to a lesser degree as did the α-hydroxy analogs of the branched chain α-keto acids. Inhibitors of the general anion transport system of erythrocytes, 1-anilino-8-napthalene sulfonic acid and 4-acetamido-4-isothiocyanostilbene-2-1′-disulfonic acid did not affect α-ketoisocaproate transport. A reduced sulfhydryl group is critical for α-ketoisocaproate acid uptake; transport is partially or completely inhibited by sulfhydryl reagents such as dithio-bis-nitrobenzoate, iodoacetamide, and p-chloromercuribenzoate. Inhibition by the sulfhydryl reagents is reversed with β-mercaptoethanol or partially with dithiothreitol.     

Aureobasidium pullulans metabolism of prostaglandins of the A-type.

Aureobasidium pullulans, originally introduced as an inadvertent contaminant in solutions used for evaluating the stability of prostaglandins, proved to lead to the rapid disappearance of the cyclopentenone unit of PGA2 (as monitored by circular dichroic spectroscopy). The cyclopentenone unit is converted, in various metabolites, to a 9-keto, 9 alpha or 9 beta-hydroxy group lacking the ring unsaturation. The major EtoAc-soluble 9-hydroxy metabolite (Compound-I) was shown to be 9 alpha, 15 alpha-dihydroxy-2, 3, 4, 5-tetranor-13-trans-prostenoic acid. Similar tetranor 9-hydroxy metabolites with one additional degree of unsaturation, and with a 9 beta-hydroxy group, also occur but these have not been fully characterized. Only two of the wide range of 9-keto metabolites are fully characterized by mass spectral (MS) data: 9, 15-oxo-2, 3, 4, 5-tetranorprostanoic acid and 9, 15-oxo-2, 3, 4, 5-tetranor-13-trans-prostenoic acid. The water soluble metabolites have not been characterized further. The fully characterized metabolites together with MS data from mixtures of minor metabolites indicate that A. pullulans can perform the following transformation: beta-oxidation, dehydrogenation at C-15, reduction of the enone carbon-carbon double bonds (both delta 10,11 and delta 13,14), reduction of the 9-ketone, and possibly migration of the cyclopentyl double bond (delta 10, 11 leads to delta 11, 12). A. pullulans metabolizes 15-epimeric PGA2 equally readily with the production of similar products. PGA1 affords less 9-keto metabolites with compound I constituting 33% of the product by HPLC analysis. A. pullulans displays some enantioselectivity, PGA2 and 15-epi-PGA2 are each metabolized more rapidly than their enantiomers. Other prostaglandins appear to be less readily metabolized.     

Ethylene formation by cell-free extracts of Escherichia coli

The pathway leading to the formation of ethylene as a secondary metabolite from methionine by Escherichia coli strain B SPAO has been investigated. Methionine was converted to 2-oxo-4-methylthiobutyric acid (KMBA) by a soluble transaminase enzyme. 2-Hydroxy-4-methylthiobutyric acid (HMBA) was also a product, but is probably not an intermediate in the ethylene-forming pathway. KMBA was converted to ethylene, methanethiol and probably carbon dioxide by a soluble enzyme system requiring the presence of NAD(P)H, Fe³⁺ chelated to EDTA, and oxygen. In the absence of added NAD(P)H, ethylene formation by cell-free extracts from KMBA was stimulated by glucose. The transaminase enzyme may allow the amino group to be salvaged from methionine as a source of nitrogen for growth. As in the plant system, ethylene produced by E. coli was derived from the C-3 and C-4 atoms of methionine, but the pathway of formation was different. It seems possible that ethylene production by bacteria might generally occur via the route seen in E. coli.Abbreviations EDTA ethylenediaminetetraacetic acid - HMBA 2-hydroxy-4-methylthiobutyric acid (methionine hydroxy analogue) - HSS high speed supernatant - KMBA 2-oxo-4-methylthiobutyric acid - PCS phase combining system     

Effect of estradiol on the metabolism of testosterone by rat prostate

Prostatic tissue from normal, estradiol-treated, and castrated rats was incubated with testosterone, and the metabolites formed were studied. Pretreatment with estradiol-17β did not affect the total amount of testosterone metabolized per unit weight of tissue. In contrast, the total amount of testosterone metabolized was significantly reduced following castration. The formation of dihydrotestosterone (17β-hydroxy-5α-androstan-3-one; DHT) was not affected by treatment with estradiol, but was significantly reduced by previous castration. Estradiol treatment enhanced the formation of 17-keto metabolites of testosterone by the prostate, giving lower 17-hydroxy to 17-keto ratios than incubations with prostates from control or castrated rats. These results are consistent with the theory that the mechanisms leading to the involution of prostate after estradiol treatment and after castration are different.     

Methylthioadenosine metabolism in malignant murine cells

An ether-extractable product formed from 5′-methylthioadenosine by extracts of malignant murine lymphocytic cells is shown to be 2-keto-4-methylthiobutyric acid. When 5′-methylthio [U-¹⁴C]adenosine was used as substrate, the product was labelled, confirming earlier reports that carbons of the keto acid are derived from carbons of the ribose. When hydroxylamine was added to the reaction mixture, the ketomethylthiobutyric acid was trapped as the oxime. When glutamine was added, the main product was methionine.     

Synthesis of eicosa-2-trans-8,11,14-all cis-tetraenoic acid-3-14C and DL-3-hydroxy eicosa-8,11,14-all cis-trienoic acid-3-14C

A general procedure for the synthesis of 2-trans polyenoic fatty acids and of dl-3-hydroxypolyenoic acids is described. The 2-trans acids are prepared by LiAlH(4) reduction of a suitable polyenoic fatty acid ester to the alcohol, formation of the tosylate, oxidation to the aldehyde, and Doebner condensation of the latter with malonic acid. The 3-hydroxy acids are obtained by reaction of the acyl chloride of a suitable polyenoic acid with the sodium enolate of methyl acetoacetate and sodium methoxide to give the 3-keto ester, the keto group of which is reduced with sodium borohydride to the alcohol. These procedures were applied to the synthesis of eicosa-2-trans-8, 11, 14-all cis-tetraenoic acid-3-(14)C and DL-3-hydroxy eicosa-8, 11, 14-trienoic acid-3-(14)C.     

Inhibition of mammalian fatty acid synthetase activity by NADP involves decreased mobility of the 4'-phosphopantetheine prosthetic group

Mammalian fatty acid synthetase carrying a 3-keto, 3-hydroxy, or 2-enoyl acyl-enzyme intermediate on the 4'-phosphopantetheine thiol is reversibly inhibited by binding of NADP to the enoyl reductase domain. Acyl moieties which can normally leave the enzyme by thioester hydrolysis or by transfer to a CoA acceptor cannot readily be removed from the NADP-inhibited enzyme; in addition, 3-keto or 2-enoyl moieties attached to the enzyme 4'-phosphopantetheine cannot readily be reduced when NADP is replaced by NADPH, even though model substrates can be reduced immediately. Reactivation of the NADP-inhibited 3-ketoacyl-enzyme, by exposure to NADPH, is paralleled by reduction and dehydration of the 3-ketoacyl moiety to a saturated acyl moiety without accumulation of either the 3-hydroxy or 2-enoyl acyl-enzyme intermediates, indicating that once the 4'-phosphopantetheine engages the ketoacyl moiety in the ketoreductase domain, subsequent reactions occur very rapidly. The results are consistent with a hypothesis which proposes that NADP binding to the enoyl reductase domain of fatty acid synthetase carrying an acyl intermediate other than a saturated moiety induces a conformational change in the enzyme that results in decreased mobility of the 4'-phosphopantetheine prosthetic group. Normal mobility of the prosthetic group, essential for transfer of acyl-enzyme intermediates through the active sites of the various functional domains, is restored relatively slowly when NADP is replaced by NADPH. It remains to be determined whether this modulation by pyridine nucleotides observed in vitro plays a role in the regulation of fatty acid synthetase activity in vivo.     

metabolism of prostaglandins of the A-type

, originally introduced as an inadvertent contaminant in solutions used for evaluating the stability of prostaglandins, proved to lead to the rapid disappearance of the cyclopentenone unit of PGA₂ (as monitored by circular dichroic spectroscopy). The cyclopentenone unit is converted, in various metabolites, to a 9-keto, 9α or 9β-hydroxy group lacking the ring unsaturation. The major EtoAc-soluble 9-hydroxy metabolite (Compound-I) was shown to be 9α, 15α-dihydroxy-2,3,4,5-tetranor-13- -prostenoic acid. Similar tetranor 9-hydroxy metabolites with one additional degree of unsaturation, and with a 9β-hydroxy group, also occur but these have not been fully characterized. Only two of the wide range of 9-keto metabolites are fully characterized by mass spectral (MS) data: 9,15-oxo-2,3,4,5-tetranorprostanoic acid and 9,15-oxo-2,3,4,5-tetranor-13- -prostenoic acid. The water soluble metabolites have not been characterized further.The fully characterized metabolites together with MS data from mixtures of minor metabolites indicate that can perform the following transformations: β-oxidation, dehydrogenation at C-15, reduction of the enone carbon-carbon double bonds (both Δ^10,11 and Δ^13,14), reduction of the 9-ketone, and possibly migration of the cyclopentyl double bond (Δ^10,11 → Δ^11,12). metabolizes 15-epimeric PGA₂ equally readily with the production of similar products. PGA₁ affords less 9-keto metabolites with compound I constituting 33% of the product by HPLC analysis. displays some enantioselectivity, PGA₂ and 15-epi-PGA₂ are each metabolized more rapidly than their enantiomers. Other prostaglandins appear to be less readily metabolized.     

Production of aromatic d-amino acids from α-keto acids and ammonia by coupling of four enzyme reactions

A multi-enzyme system composed of glutamate racemase, thermostable d-amino acid aminotransferase, glutamate dehydrogenase and formate dehydrogenase was employed for the production of aromatic d-amino acids, d-phenylalanine and d-tyrosine, from the corresponding α-keto acids, phenylpyruvate and hydroxyphenylpyruvate, respectively. The optimal concentration of ammonium formate for the production of these d-amino acids was found in the range of 0.25–1.0 M. The optimal concentration of α-keto acid was determined to be 50 mM, above which the productivity greatly decreased. To keep the concentration of α-keto acid around this concentration, α-keto acid was intermittently fed into the multi-enzyme system during the production period. By running the multi-enzyme system for 35 h, 48 g l⁻¹ of d-phenylalanine and 60 g l⁻¹ of d-tyrosine were produced with 100% of optical purity from the equimolar amounts of phenylpyruvate and hydroxyphenylpyruvate, respectively. The production levels of both aromatic d-amino acids were demonstrated to be dependent on the stability of glutamate racemase.     

Enantioselective synthesis of various D-amino acids by a multi-enzyme system

We have developed an effective method for the synthesis of various D-amino acids from the corresponding α-keto acids and ammonia by coupling four enzyme reactions catalyzed by D-amino acid aminotransferase, glutamate racemase, glutamate dehydrogenase, and formate dehydrogenase. In this system, D-glutamate is continuously regenerated from α-ketoglutarate, ammonia and NADH by the coupled reaction of glutamate dehydrogenase and glutamate racemase, and used as an amino donor for the enantioselective D-amino acid synthesis by the D-amino acid aminotransferase reaction. The unidirectional formate dehydrogenase reaction is also coupled to regenerate NADH consumed. Under the optimum conditions, D-enantiomers of valine, alanine, α-keto analogues with a molar yield higher than 80%.     

Biochemical Studies of Piricularia oryzae

It has been shown that Piricularia oryzae could grow in the presence of amino acid, even in the absence of a proper carbon source and that the first step of utilization was the formation of the corresponding α-keto acid by deamination in the medium. For further confirmation of this process, DL-valine was used as the amino acid to be tested in the current experiment. In each of the three cases, that is, DL-valine alone, DL-valine plus arsenite and DL-valine plus sucrose, the dimethlpyruvic acid formed was identified as its 2, 4-dinitrophenylhydrazone. Even in the presence of a sufficient amount of sucrose, some parts of DL-valine added were found to be utilized as a carbon source through the conversion to its α-keto analog.     

Studies of ethylene-forming system in rat liver extract

Evidence of enzymatic formation of ethylene from methionine by rat liver extracts is presented. The ethylene production is closely associated with growth of the animal. The conversion of l-methionine to ethylene is oxygen dependent. Substrate analogue studies show that the ethylene-forming system is structurally specific and requires in the center of the molecule α-CH₂-CH₂- with one end attached to an unencumbered sulfur atom from a thioether moiety and the other end attached to a carboxyl group. Sylfhydryl agents are found to be very effective inhibitors of the ethylene-forming system. The finding of α-keto-4-methylthiobutyric acid to be a more efficient precursor of ethylene production suggests the possibility that α-keto-4-methylthiobutyric acid may be an intermediate in the biosynthesis of ethylene from methionine in mammalian tissues.     

A highly enantioselective rhodium catalyst for the hydrogenation of aliphatic α-keto esters

The enantioselective hydrogenation of several α-keto acid derivatives with rhodium diphosphine catalysts has been investigated using a random screening approach. The neutral rhodium catalyst prepared in situ from bis(2,5-norbornadiene rhodium chloride) and NORPHOS has been found to be an excellent catalyst for preparing aliphatic α-hydroxy esters in high optical purities. The reaction parameters for the hydrogenation of ethyl 2-oxo-4-phenyl-butyrate, an intermediate for the ACE inhibitor Benazepril, were optimized and the best optical yields obtained were 96%.     

The effect of adrenalectomy on the aggregation of rat blood platelets and the endogenous formation of thromboxane B2 and 12-hydroxy-5,8,10,14-eicosatetraenoic acid

Rat platelets were isolated and labelled with [1-14C] arachidonic acid. After aggregation thromboxane B2, 12-hydroxy 5,8,10-heptadecatrienoic acid (HHT) and 12-hydroxy-eicosatetraenoic acid (12-HETE) were the main metabolites formed. A comparison was made between several properties of the platelets of adrenalectomized and sham operated rats. There was no difference in collagen-induced aggregation. The amount of 12-HETE and the sum of TxB2 and 12-HETE formed from endogenous arachidonic acid after aggregation was higher in the first group.     

Studies of ethylene-forming system in rat liver extract.

Evidence of enzymatic formation of ethylene from methionine by rat liver extracts is presented. The ethylene production is closely associated with growth of the animal. The conversion of L-methionine to ehtylene is oxygen dependent. Substrate analogue studies show that the ethylene-forming system is structurally specific and requires in the center of the molecule alpha-CH2-CH2- with one end attached to an unencumbered sulfur atom from a thioether moiety and the other end attached to a carboxyl group. Sylfhydryl agents are found to be very effective inhibitors of the ethylene-forming system. The finding of alpha-keto-4-methylthiobutyric acid to be a more efficient precursor of ethylene production suggests the possibility that alpha-keto-4-methylthiobutyric acid may be an intermediate in the biosynthesis of ethylene from methionine in mammalian tissues.