The metabolism of 1-phospho-5-methylthioribose

In partially fractionated rat liver homogenate, 1-phospho-5-methylthioribose is oxidatively converted to 2-keto, 4-methylthiobutyric acid, 2-hydroxy, 4-methylthiobutyric acid and formate. The amount of formate formed is equal to the amount of 2-keto, 4-methylthiobutyric acid plus 2-hydroxy, 4-methylthiobutyric acid formed. The data suggest that the keto acid is the precursor of the hydroxy acid. No readily dissociable cofactors are involved in the reaction. A mechanism is proposed for the conversion of 1-phospho-4-methylthiobutyric acid to formate and 2-keto, 4-methylthiobutyric acid.     

Effect of anions on the photocycle of halorhodopsin. Substitution of chloride with formate anion

Halorhodopsin from Natronomonas pharaonis is a light-driven chloride pump which transports a chloride anion across the plasma membrane following light absorption by a retinal chromophore which initiates a photocycle. It was shown that the chloride anion bound in the vicinity of retinal PSB can be replaced by several inorganic anions, including azide which converts the chloride pump into a proton pump and induces formation of an M-like intermediate detected in the bR photocycle but not in native halorhodopsin. Here we have studied the possibility of replacing the chloride anion with organic anions and have followed the photocycle under several conditions. It is revealed that the chloride can be replaced with a formate anion but not with larger organic anions such as acetate. Flash photolysis experiments detected in the formate pigment an M-like intermediate characterized by a lifetime much longer than that of the O intermediate. The lifetime of the M-like intermediate depends on the pH, and its decay is significantly accelerated at low pH. The decay rate exhibited a titration-like curve, suggesting that the protonation of a protein residue controls the rate of M decay. Similar behavior was detected in N. pharaonis pigments in which the chloride anion was replaced with NO(2)(-) and OCN(-) anions. It is suggested that the formation of the M-like intermediate indicates branching pathways from the L intermediate or basic heterogeneity in the original pigment.     

Formate dehydrogenase of Clostridium pasteurianum

Formate dehydrogenase was purified to electrophoretic homogeneity from N2-fixing cells of Clostridium pasteurianum W5. The purified enzyme has a minimal Mr of 117,000 with two nonidentical subunits with molecular weights of 76,000 and 34,000, respectively. It contains 2 mol of molybdenum, 24 mol of nonheme iron, and 28 mol of acid-labile sulfide per mol of enzyme; no other metal ions were detected. Analysis of its iron-sulfur centers by ligand exchange techniques showed that 20 iron atoms of formate dehydrogenase can be extruded as Fe4S4 centers. Fluorescence analysis of its isolated molybdenum centers suggests it is a molybdopterin. The clostridial formate dehydrogenase has a pH optimum between 8.3 and 8.5 and a temperature optimum of 52 degrees C. The Km for formate is 1.72 mM with a Vmax of 551 mumol of methyl viologen reduced per min per mg of protein. Sodium azide competes competitively with formate (K1 = 3.57 microM), whereas the inactivation by cyanide follows pseudo-first-order kinetics with K = 5 X 10(2) M-1 s-1.     

Periplasmic methacrylate reductase activity in Wolinella succinogenes

The cell homogenate and the soluble cell fraction of Wolinella succinogenes grown with formate and fumarate catalyzed the oxidation of benzyl viologen radical by methacrylate [apparent Km=0.23 mM, Vmax=1.0 U (mg cell protein) -1] or acrylate [apparent Km=0.50 mM, Vmax=0.77 U (mg cell protein) -1]. Crotonate did not serve as an oxidant. A mutant of W. succinogenes lacking the fccABC operon was unable to catalyze methacrylate or acrylate reduction. In contrast, the inactivation of fccC alone had no effect on these activities. Methacrylate reduction by benzyl viologen radical was not catalyzed by fumarate reductase isolated from the membrane of W. succinogenes. Cells grown with formate and fumarate did not catalyze methacrylate reduction by formate, and W. succinogenes did not grow with formate and methacrylate as catabolic substrates. The results suggest that the reduction of methacrylate or acrylate by benzyl viologen radical is most likely catalyzed either by the periplasmic flavoprotein FccA or by a complex consisting of FccA and the predicted c-type cytochrome FccB. The metabolic function of the fccABC operon remains unknown.     

Conversion of 5-S-ethyl-5-thio-D-ribose to ethionine in Klebsiella pneumoniae. Basis for the selective toxicity of 5-S-ethyl-5-thio-D-ribose

5-S-Ethyl-5-thio-D-ribose (ethylthioribose) exhibits antiprotozoal activity against Plasmodium falciparum, Giardia lamblia, and Ochromonas malhamensis, but is nontoxic to cultured human and murine bone marrow cells (Riscoe, M. K., Ferro, A. J., and Fitchen, J. H. (1988) Antimicrob. Agents Chemother. 32, 1904-1906). We propose the following mechanism to account for the observed selective toxicity of ethylthioribose. 1) The cytocidal action of ethylthioribose against protozoa is a result of its conversion to ethionine, a well-known cytotoxic agent. 2) This transformation occurs through the pathway which normally converts 5-S-methyl-5-thio-D-ribose (methylthioribose) to methionine. 3) Conversion of ethylthioribose to ethionine cannot occur in mammalian cells since these cells cannot phosphorylate methylthioribose (ethylthioribose), a first step in the pathway to methionine (ethionine). To test this hypothesis, [5-3H]ethylthioribose has been synthesized and its metabolism by cell-free extracts of Klebsiella pneumoniae and rat liver was examined. The pathway by which methylthioribose is converted to methionine in K. pneumoniae is well characterized. When supplemented with ATP and L-glutamine, the bacterial extract efficiently converted [5-3H]ethylthioribose to [3H]ethionine. By contrast, ethionine was not produced upon incubation of [5-3H]ethylthioribose, ATP, and L-glutamine with rat liver homogenate. The mammalian cell extract lacks a kinase activity capable of converting ethylthioribose to 1-phospho-5-S-ethyl-5-thio-alpha-D-ribofuranoside, an obligate intermediate in the biosynthesis of ethionine from ethylthioribose in K. pneumoniae. These results support our hypothesis and provide a basis for understanding the apparently selective toxicity of ethylthioribose.     

Oxalate:formate exchange. The basis for energy coupling in Oxalobacter

In the Gram-negative anaerobe, Oxalobacter formigenes, the generation of metabolic energy depends on the transport and decarboxylation of oxalate. We have now used assays of reconstitution to study the movements of oxalate and to characterize the exchange of oxalate with formate, its immediate metabolic derivative. Membranes of O. formigenes were solubilized with octyl-beta-D-glucopyranoside in the presence of 20% glycerol and Escherichia coli phospholipid, and detergent extracts were reconstituted by detergent dilution. [14C]Oxalate was taken up by proteoliposomes loaded with unlabeled oxalate, but not by similarly loaded liposomes or by proteoliposomes containing sulfate in place of oxalate. Oxalate transport did not depend on the presence of sodium or potassium, nor was it affected by valinomycin (1 microM), nigericin (1 microM), or a proton conductor, carbonylcyanide-p-trifluoromethoxyphenylhydrazone (5 microM) when potassium was at equal concentration on either side of the membrane. Such data suggest the presence of an overall neutral oxalate self-exchange, independent of common cations or anions. Kinetic analysis of the reaction in proteoliposomes gave a Michaelis constant (Kt) for oxalate transport of 0.24 mM and a maximal velocity (Vmax) of 99 mumol/min/mg of protein. A direct exchange of oxalate and formate was indicated by the observations that formate inhibited oxalate transport and that delayed addition of formate released [14C]oxalate accumulated during oxalate exchange. Moreover, [14C]formate was taken up by oxalate-loaded proteoliposomes (but not liposomes), and this heterologous reaction could be blocked by external oxalate. Further studies, using formate-loaded proteoliposomes, suggested that the heterologous exchange was electrogenic. Thus, for assays in which N-methylglucamine served as both internal and external cation, formate-loaded particles took up oxalate at a rate of 2.4 mumol/min/mg of protein. When external or internal N-methylglucamine was replaced by potassium in the presence of valinomycin, there was, respectively, a 7-fold stimulation or an 8-fold inhibition of oxalate accumulation, demonstrating that net negative charge moved in parallel with oxalate during the heterologous exchange. The work summarized here suggests the presence of an unusually rapid and electrogenic oxalate2-:formate1- antiport in membranes of O. formigenes. Since a proton is consumed during the intracellular decarboxylation that converts oxalate into formate plus CO2, antiport of oxalate and formate would play a central role in a biochemical cycle consisting of (a) oxalate influx, (b) oxalate decarboxylation, and (c) formate efflux.(ABSTRACT TRUNCATED AT 400 WORDS)     

Enzymatic assimilation of cyanide via pterin-dependent oxygenolytic cleavage to ammonia and formate in Pseudomonas fluorescens NCIMB 11764

Utilization of cyanide as a nitrogen source by Pseudomonas fluorescens NCIMB 11764 occurs via oxidative conversion to carbon dioxide and ammonia, with the latter compound satisfying the nitrogen requirement. Substrate attack is initiated by cyanide oxygenase (CNO), which has been shown previously to have properties of a pterin-dependent hydroxylase. CNO was purified 71-fold and catalyzed the quantitative conversion of cyanide supplied at micromolar concentrations (10 to 50 micro M) to formate and ammonia. The specific activity of the partially purified enzyme was approximately 500 mU/mg of protein. The pterin requirement for activity could be satisfied by supplying either the fully (tetrahydro) or partially (dihydro) reduced forms of various pterin compounds at catalytic concentrations (0.5 micro M). These compounds included, for example, biopterin, monapterin, and neopterin, all of which were also identified in cell extracts. Substrate conversion was accompanied by the consumption of 1 and 2 molar equivalents of molecular oxygen and NADH, respectively. When coupled with formate dehydrogenase, the complete enzymatic system for cyanide oxidation to carbon dioxide and ammonia was reconstituted and displayed an overall reaction stoichiometry of 1:1:1 for cyanide, O(2), and NADH consumed. Cyanide was also attacked by CNO at a higher concentration (1 mM), but in this case formamide accumulated as the major reaction product (formamide/formate ratio, 0.6:0.3) and was not further degraded. A complex reaction mechanism involving the production of isocyanate as a potential CNO monooxygenation product is proposed. Subsequent reduction of isocyanate to formamide, whose hydrolysis occurs as a CNO-bound intermediate, is further envisioned. To our knowledge, this is the first report of enzymatic conversion of cyanide to formate and ammonia by a pterin-dependent oxygenative mechanism.     

Biosynthesis of vitamin B2.

GTP cyclohydrolase II catalyzes the hydrolytic release of formate and pyrophosphate from GTP producing 2,5-diamino-6-ribosylamino-4(3H)-pyrimidinone 5'-phosphate, the first committed intermediate in the biosynthesis of riboflavin. The enzyme was shown to contain one zinc ion per subunit. Replacement of cysteine residue 54, 65 or 67 with serine resulted in proteins devoid of bound zinc and unable to release formate from the imidazole ring of GTP or from the intermediate analog, 2-amino-5-formylamino-6-ribosylamino-4(3H)-pyrimidinone 5'-triphosphate. However, the mutant proteins retained the capacity to release pyrophosphate from GTP and from the formamide-type intermediate analog. The data suggest that the enzyme catalyzes an ordered reaction in which the hydrolytic release of pyrophosphate precedes the hydrolytic attack of the imidazole ring. Ring opening and formate release are both dependent on a zinc ion acting as a Lewis acid, which activates the two water molecules involved in the sequential hydrolysis of two carbon-nitrogen bonds.     

Real-time monitoring of the oxalate decarboxylase reaction and probing hydron exchange in the product, formate, using fourier transform infrared spectroscopy

Oxalate decarboxylase converts oxalate to formate and carbon dioxide and uses dioxygen as a cofactor despite the reaction involving no net redox change. We have successfully used Fourier transform infrared spectroscopy to monitor in real time both substrate consumption and product formation for the first time. The assignment of the peaks was confirmed using [(13)C]oxalate as the substrate. The K(m) for oxalate determined using this assay was 3.8-fold lower than that estimated from a stopped assay. The infrared assay was also capable of distinguishing between oxalate decarboxylase and oxalate oxidase activity by the lack of formate being produced by the latter. In D(2)O, the product with oxalate decarboxylase was C-deuterio formate rather than formate, showing that the source of the hydron was solvent as expected. Large solvent deuterium kinetic isotope effects were observed on V(max) (7.1 +/- 0.3), K(m) for oxalate (3.9 +/- 0.9), and k(cat)/K(m) (1.8 +/- 0.4) indicative of a proton transfer event during a rate-limiting step. Semiempirical quantum mechanical calculations on the stability of formate-derived species gave an indication of the stability and nature of a likely enzyme-bound formyl radical catalytic intermediate. The capability of the enzyme to bind formate under conditions in which the enzyme is known to be active was determined by electron paramagnetic resonance. However, no enzyme-catalyzed exchange of the C-hydron of formate was observed using the infrared assay, suggesting that a formyl radical intermediate is not accessible in the reverse reaction. This restricts the formation of potentially harmful radical intermediates to the forward reaction.     

5-Dehydro-3-deoxy-D-arabino-heptulosonic acid 7-phosphate. An intermediate in the 3-dehydroquinate synthase reaction.

3-Dehydroquinate synthase was purified to homogeneity from Escherichia coli. It was found to be a single polypeptide chain of Mr = approximately 57,000. Reaction mixtures of pure enzyme and the substrate, 3-deoxy-D-arabino-heptulosonic acid 7-phosphate, were incubated for short times and treated with NaB3H4. The resulting 3-deoxyheptonic acid 7-phosphate was degraded with sodium periodate, and formic acid representing C-5 of the substrate was isolated. The presence of 3H in the formate corresponding to 15% of the enzyme was interpreted as indicating a 5-dehydro derivative of the substrate as an intermediate of the reaction. Quinic acid, resulting from reduction of 3-dehydroquinate with NaB3H4, was also isolated and degraded with periodate. The formate from C-4 of the quinate was unlabeled, indicating that 3,4-bisdehydroquinate is not an intermediate.     

Formation of the formate-nitrate electron transport pathway from inactive components in Escherichia coli.

When Escherichia coli was grown on medium containing 10 mM tungstate the formation of active formate dehydrogenase, nitrate reductase, and the complete formate-nitrate electron transport pathway was inhibited. Incubation of the tungstate-grown cells with 1 mM molybdate in the presence of chloramphenicol led to the rapid activation of both formate dehydrogenase and nitrate reductase, and, after a considerable lag, the complete electron transport pathway. Protein bands which corresponded to formate dehydrogenase and nitrate reductase were identified on polyacrylamide gels containing Triton X-100 after the activities were released from the membrane fraction and partially purified Cytochrome b1 was associated with the protein band corresponding to formate dehydrogenase but was not found elsewhere on the gels. When a similar fraction was prepared from cells grown on 10 mM tungstate, an inactive band corresponding to formate dehydrogenase was not observed on polyacrylamide gels; rather, a new faster migrating band was present. Cytochrome b1 was not associated with this band nor was it found anywhere else on the gels. This new band disappeared when the tungstate-grown cells were incubated with molybdate in the presence of chloramphenicol. The formate dehydrogenase activity which was formed, as well as a corresponding protein band, appeared at the original position on the gels. Cytochrome b1 was again associated with this band. The protein band which corresponded to nitrate reductase also was severely depressed in the tungstate-grown cells and a new faster migrating band appeared on the polyacrylamide gels. Upon activation of the nitrate reductase by incubation of the cells with molybdate, the new band diminished and protein reappeared at the original position. Most of the nitrate reductase activity which was formed appeared at the original position of nitrate reductase on gels although some was present at the position of the inactive band formed by tungstate-grown cells. Apparently, inactive forms of both formate dehydrogenase and nitrate reductase accumulate during growth on tungstate which are electrophoretically distinct from the active enzymes. Activation by molybdate results in molecular changes which include the reassociation of cytochrome b1 with formate dehydrogenase and restoration of both enzymes to their original electrophoretic mobilities.     

Identification and characterization of the 2-phospho-L-lactate guanylyltransferase involved in coenzyme F420 biosynthesis

Coenzyme F 420 is a hydride carrier cofactor functioning in methanogenesis. One step in the biosynthesis of coenzyme F 420 involves the coupling of 2-phospho- l-lactate (LP) to 7,8-didemethyl-8-hydroxy-5-deazaflavin, the F 420 chromophore. This condensation requires an initial activation of 2-phospho- l-lactate through a pyrophosphate linkage to GMP. Bioinformatic analysis identified an uncharacterized archaeal protein in the Methanocaldococcus jannaschii genome, MJ0887, which could be involved in this transformation. The predicted MJ0887-derived protein has domain similarity with other known nucleotidyl transferases. The MJ0887 gene was cloned and overexpressed, and the purified protein was found to catalyze the formation of lactyl-2-diphospho-5'-guanosine from LP and GTP. Kinetic constants were determined for the MJ0887-derived protein with both LP and GTP substrates and are as follows: V max = 3 micromol min (-1) mg (-1), GTP K M (app) = 56 microM, and k cat/ K M (app) = 2 x 10 (4) M (-1) s (-1) and LP K M (app) = 36 microM, and k cat/ K M (app) = 4 x 10 (4) M (-1) s (-1). The MJ0887 gene product has been designated CofC to indicate its involvement in the third step of coenzyme F 420 biosynthesis.     

GTP cyclohydrolase II structure and mechanism

GTP cyclohydrolase II converts GTP to 2,5-diamino-6-beta-ribosyl-4(3H)-pyrimidinone 5'-phosphate, formate and pyrophosphate, the first step in riboflavin biosynthesis. The essential role of riboflavin in metabolism and the absence of GTP cyclohydrolase II in higher eukaryotes makes it a potential novel selective antimicrobial drug target. GTP cyclohydrolase II catalyzes a distinctive overall reaction from GTP cyclohydrolase I; the latter converts GTP to dihydroneopterin triphosphate, utilized in folate and tetrahydrobiopterin biosynthesis. The structure of GTP cyclohydrolase II determined at 1.54-A resolution reveals both a different protein fold to GTP cyclohydrolase I and distinctive molecular recognition determinants for GTP; although in both enzymes there is a bound catalytic zinc. The GTP cyclohydrolase II.GMPCPP complex structure shows Arg(128) interacting with the alpha-phosphonate, and thus in the case of GTP, Arg(128) is positioned to act as the nucleophile for pyrophosphate release and formation of the proposed covalent guanylyl-GTP cyclohydrolase II intermediate. Tyr(105) is identified as playing a key role in GTP ring opening; it is hydrogen-bonded to the zinc-activated water molecule, the latter being positioned for nucleophilic attack on the guanine C-8 atom. Although GTP cyclohydrolase I and GTP cyclohydrolase II both use a zinc ion for the GTP ring opening and formate release, different residues are utilized in each case to catalyze this reaction step.     

Evidence for two genetically distinct DNA primase activities specified by plasmids of the B and I incompatibility groups.

Soluble formate dehydrogenase from Methanobacterium formicicum was purified 71-fold with a yield of 35%. Purification was performed anaerobically in the presence of 10 mM sodium azide which stabilized the enzyme. The purified enzyme reduced, with formate, 50 mumol of methyl viologen per min per mg of protein and 8.2 mumol of coenzyme F420 per min per mg of protein. The apparent Km for 7,8-didemethyl-8-hydroxy-5-deazariboflavin, a hydrolytic derivative of coenzyme F420, was 10-fold greater (63 microM) than for coenzyme F420 (6 microM). The purified enzyme also reduced flavin mononucleotide (Km = 13 microM) and flavin adenine dinucleotide (Km = 25 microM) with formate, but did not reduce NAD+ or NADP+. The reduction of NADP+ with formate required formate dehydrogenase, coenzyme F420, and coenzyme F420:NADP+ oxidoreductase. The formate dehydrogenase had an optimal pH of 7.9 when assayed with the physiological electron acceptor coenzyme F420. The optimal reaction rate occurred at 55 degrees C. The molecular weight was 288,000 as determined by gel filtration. The purified formate dehydrogenase was strongly inhibited by cyanide (Ki = 6 microM), azide (Ki = 39 microM), alpha,alpha-dipyridyl, and 1,10-phenanthroline. Denaturation of the purified formate dehydrogenase with sodium dodecyl sulfate under aerobic conditions revealed a fluorescent compound. Maximal excitation occurred at 385 nm, with minor peaks at 277 and 302 nm. Maximal fluorescence emission occurred at 455 nm.     

Kinetic behavior of the Arabidopsis thaliana leaf formate dehydrogenase is thermally sensitive

Two previous kinetic studies on the Arabidopsis thaliana leaf NAD-dependent formate dehydrogenase (EC 1.2.1.2) have demonstrated two very different sets of Km values for the formate and NAD+ substrates. We examined the kinetics of the enzyme partially purified from a leaf extract by gel-filtration desalting and chromatography on DEAE-cellulose, as well as by isolation of a mitochondria-enriched fraction obtained by differential centrifugation. Both of these methods produce a formate dehydrogenase enzyme with the higher Km values of approximately 10 mmol/L formate and 75 mumol/L NAD+. The kinetic properties of the Arabidopsis formate dehydrogenase expressed to high levels in transgenic tobacco plants were also those of the high Km form. The high Km form of the enzyme converted to a low Km form by heating for 5 minutes at 60 degrees C. An Arrhenius plot of the activity during the heating process was linear, indicating that the heating did not cause alterations in either the active site or the thermal dependence of the catalytic reaction. We conclude that the native form of the formate dehydrogenase probably resembles the form with the higher Km values. Heating seemingly converts this native enzyme to the molten globule state and cooling results in formation of a non-native structure with altered kinetic properties.     

28 kDa adenosine-binding proteins of brain and other tissues.

Membranes prepared from calf brain were solubilized and chromatographed on a column containing 5'-amino-5'-deoxyadenosine covalently linked to agarose through the 5'-amino group. When the column was eluted with adenosine, a pure protein emerged with subunit molecular mass of 28 kDa. The protein was extracted from the membranes with sodium cholate, but not with 100 microM-adenosine or 0.5 M-NaCl. A similar 28 kDa protein was isolated from the soluble fraction of calf brain. The yield of membrane-bound and soluble 28 kDa protein per gram of tissue was about the same. The 28 kDa protein was also found in membrane and soluble fractions of rabbit heart, rat liver and vascular smooth muscle from calf aorta. The yield per gram of tissue fell into the order brain greater than heart approximately vascular smooth muscle greater than liver for the 28 kDa protein from the membrane fraction, and brain approximately heart greater than vascular smooth muscle greater than liver for the 28 kDa protein from the soluble fraction. Polyclonal antibodies to pure 28 kDa protein from calf brain membranes cross-reacted with the 28 kDa protein from calf brain soluble fraction and with 28 kDa proteins isolated from other tissues. The 28 kDa protein from calf brain membranes was also eluted from the affinity column by AMP and 2',5'-dideoxyadenosine, but at a concentration higher than that at which adenosine eluted the protein, but N6-(R-phenylisopropyl)adenosine, 5'-N-ethylcarboxamidoadenosine, ADP, ATP, GTP, NAD+, cyclic AMP and inosine failed to elute the protein at concentrations up to 1 mM. The 28 kDa protein from the soluble fraction was not eluted by 3 mM-AMP or 1 mM-N6-(R-phenylisopropyl)adenosine,-5'-N-ethylcarboxamidoadenosine or -cyclic AMP. Unexpectedly, the soluble 28 kDa protein was eluted by AMP in the presence of sodium cholate. Soluble 28 kDa protein from calf brain had a KD for adenosine of 12 microM. Membrane 28 kDa protein from calf brain had a KD of 14 microM in the presence of 0.1% sodium cholate. Amino acid compositions of the 28 kDa proteins were similar, but not identical.     

Formate auxotroph of Methanobacterium thermoautotrophicum Marburg.

A formate-requiring auxotroph of Methanobacterium thermoautotrophicum Marburg was isolated after hydroxylamine mutagenesis and bacitracin selection. The requirement for formate is unique and specific; combined pools of other volatile fatty acids, amino acids, vitamins, and nitrogen bases did not substitute for formate. Compared with those of the wild type, cell extracts of the formate auxotroph were deficient in formate dehydrogenase activity, but cells of all of the strains examined catalyzed a formate-carbon dioxide exchange activity. All of the strains examined took up a small amount (200 to 260 mumol/liter) of formate (3 mM) added to medium. The results of the study of this novel auxotroph indicate a role for formate in biosynthetic reactions in this methanogen. Moreover, because methanogenesis from H2-CO2 is not impaired in the mutant, free formate is not an intermediate in the reduction of CO2 to CH4.     

Cytidylate cyclase: the product isolated by the method of Cech and Ignarro is not cytidine 3',5'-monophosphate.

When mouse liver homogenates were incubated with [α-³²P]-CTP according to the method of Cech and Ignarro (4,5), a [³²P] product (100–120 pmoles/mg protein/minute) was isolated by chromatography on alumina column, in the same fraction as [³H]-cyclic CMP.¹ However this product did not behave as cyclic CMP in various chromatographic systems. Moreover the amount of this [³²P] product isolated was markedly reduced by removal of protein prior to chromatography on alumina. Chromatography of the enzymatic reaction product either before or after alumina purification on Dowex 1 — formate column indicated that 5′-CMP and CDP are the major products, with no formation of cyclic CMP. These results indicate that the [³²P] labeled material isolated by Cech and Ignarro is mainly if not entirely 5′-CMP and CDP.     

Carbon monoxide-dependent methyl coenzyme M methylreductase in acetotrophic Methosarcina spp

Cell extracts of acetate-grown Methanosarcina strain TM-1 and Methanosarcina acetivorans both contained CH3-S-CoM methylreductase activity. The methylreductase activity was supported by CO and H2 but not by formate as electron donors. The CO-dependent activity was equivalent to the H2-dependent activity in strain TM-1 and was fivefold higher than the H2-dependent activity of M. acetivorans. When strain TM-1 was cultured on methanol, the CO-dependent activity was reduced to 5% of the activity in acetate-grown cells. Methanobacterium formicicum grown on H2-CO2 contained no CO-dependent methylreductase activity. The CO-dependent methylreductase of strain TM-1 had a pH optimum of 5.5 and a temperature optimum of 60 degrees C. The activity was stimulated by the addition of MgCl2 and ATP. Both acetate-grown strain TM-1 and acetate-grown M. acetivorans contained CO dehydrogenase activities of 9.1 and 3.8 U/mg, respectively, when assayed with methyl viologen. The CO dehydrogenase of acetate-grown cells rapidly reduced FMN and FAD, but coenzyme F420 and NADP+ were poor electron acceptors. No formate dehydrogenase was detected in either organism when grown on acetate. The results suggest that a CO-dependent CH3-S-CoM methylreductase system is involved in the pathway of the conversion of acetate to methane and that free formate is not an intermediate in the pathway.     

Characterization of a defect in the pathway for converting 5'-deoxy-5'-methylthioadenosine to methionine in a subline of a cultured heterogeneous human colon carcinoma

5'-Deoxy-5'-methylthioadenosine (methylthioadenosine) is cleaved to adenine and 5-methylthioribose-1-phosphate (methylthioribose-1-P). Methylthioribose-1-P is converted to 2-keto-4-methylthiobutyrate ( ketomethylthiobutyrate ) which is transaminated to methionine. We report that one subline of a heterogeneous human colon carcinoma, DLD-1 Clone D, only forms methylthioribose-1-P from methylthioadenosine or 5'-deoxy-5'-methylthioinosine (methylthioinosine), a deaminated derivative of methylthioadenosine, whereas Clone A converts methylthioadenosine and methylthioinosine to methionine, as shown by growth studies in culture of Clone A and Clone D cells and radioactive studies utilizing [methyl-14C]methylthioadenosine or [methyl-14C]methylthioinosine in the presence of extracts of these cells lines. To characterize this defect, we utilized three protein fractions isolated from rat liver which together convert methylthioribose-1-P to ketomethylthiobutyrate . Addition of only Fraction A to Clone D sonicates restores its ability to convert methylthioadenosine to methionine. This fraction is responsible for converting methylthioribose-1-P to 5- methylthioribulose -1-phosphate; radioactive studies confirm this observation. Thus, Clone D is deficient in an enzyme contained in Fraction A; this represents a qualitative biochemical difference between the two clones derived from a single human tumor.