The enzymic reduction of glyoxylate and hydroxypyruvate in leaves of higher plants

Glyoxylate and hydroxypyruvate are metabolites involved in the pathway of carbon in photorespiration. The chief glyoxylate-reducing enzyme in leaves is now known to be a cytosolic glyoxylate reductase that uses NADPH as the preferred cofactor but can also use NADH. Glyoxylate reductase has been isolated from spinach leaves, purified to homogeneity, and characterized kinetically and structurally. Chloroplasts contain lower levels of glyoxylate reductase activity supported by both NADPH and NADH, but it is not yet known whether a single chloroplastic enzyme catalyzes glyoxylate reduction with both cofactors. The major hydroxypyruvate reductase activity of leaves has long been known to be a highly active enzyme located in peroxisomes; it uses NADH as the preferred cofactor. To a lesser extent, NADPH can also be used by the peroxisomal enzyme. A second hydroxypyruvate reductase enzyme is located in the cytosol; it preferentially uses NADPH but can also use NADH as cofactor. In a barley mutant deficient in peroxisomal hydroxypyruvate reductase, the NADPH-preferring cytosolic form of the enzyme permits sufficient rates of hydroxypyruvate reduction to support continued substrate flow through the terminal stages of the photosynthetic carbon oxidation (glycolate/glycerate) pathway. The properties and metabolic significance of the cytosolic and organelle-localized glyoxylate and hydroxypyruvate reductase enzymes are discussed.     

Structural and catalytic properties of L-alanine dehydrogenase from Bacillus cereus

Alanine dehydrogenase from Bacillus cereus, a non-allosteric enzyme composed of six identical subunits, was purified to homogeneity by chromatography on blue-Sepharose and Sepharose 6B-CL. Like other pyridine-linked dehydrogenases, alanine dehydrogenase is inhibited by Cibacron blue, competitively with respect to NADH and noncompetitively with respect to pyruvate. The enzyme was inactivated by 0.1 M glycine/HCl (pH 2) and reactivated by 0.1 M phosphate (pH 8) supplemented with NAD+ or NADH. The reactivation was characterized by sigmoidal kinetics indicating a complex mechanism involving rate-limiting folding and association steps. Cibacron blue interfered with renaturation, presumably by competition with NADH. Chromatography on Sepharose 6B-CL of the partially renatured alanine dehydrogenase led to the separation of several intermediates, but only the hexamer was characterized by enzymatic activity. By immobilization on Sepharose 4B, alanine dehydrogenase from B. cereus retained 66% of the specific activity of the soluble enzyme. After denaturation of immobilized alanine dehydrogenase with 7 M urea, 37% of the initial protein was still bound to Sepharose, indicating that on the average the hexamer was attached to the matrix via, at most, two subunits. The ability of the denatured, immobilized subunits to pick up subunits from solution shows their capacity to fold back to the native conformation after urea treatment. The formation of "hybrids" between subunits of enzyme from B. cereus and Bacillus subtilis demonstrates the close resemblance of the tertiary and quaternary structures of alanine dehydrogenases from these species.     

Substrate specificity and activities of glyoxylate and hydroxyypyruvate reductases from leaf extracts: differentiation by ammonium sulfate fractionation and by immunoprecipitation

Leaf extracts from seven monocotyledonous and dicotyledonous species contained considerable levels of NADPH-dependent glyoxylate- and hydroxypyruvate reductase activities. These activities ranged from 0.02 to 0.22 μmol (mg protein)⁻¹ min⁻¹. For all plants tested, the glyoxylate reductase (GR) activity, assayed with either NADPH or NADH, was sensitive to inhibition by acetohydroxamate, a glycine analogue. Hydroxypyruvate reductase (HPR) activities were unaffected by acetohydroxamate. Differential precipitation of soluble leaf proteins of spinach, pea and barley by ammonium sulfate (0–45% and 45–60% saturation) indicated the presence of at least three distinct reductases, which differed in their specificities for glyoxylate, hydroxypyruvate and NAD(P)H. For all species, the NADH-dependent HPR-activity was almost completely precipitated by low ammonium sulfate concentration (45%), while precipitation of the NADPH-GR, NADH-GR and, to some extent, NADPH-HPR activities required 60% ammonium sulfate. The NADPH-dependent GR and HPR activities had high affinity for glyoxylate and hydroxypyruvate, respectively, as indicated by low apparent K_m values of 40–120 μ M . The occurrence of at least three distinct reductases utilizing hydroxypyruvate and/or glyoxylate as substrate was supported by antibody-precipitation studies using antibodies prepared against NADH(NADPH)-HPR, the well-known peroxisomal enzyme that also shows non-specific GR activity. These data are discussed with respect to recent reports on the purification and characterization of NADPH(NADH)-GR, and NADPH (NADH)-HPR, two cytosolic reductases, and the role is assessed for these enzymes in reducing hydroxypyruvate and glyoxylate that may be leaked from peroxisomes.     

Purification and characterization of hydroxypyruvate reductase from the facultative methylotroph Methylobacterium extorquens AM1.

Hydroxypyruvate reductase was purified to homogeneity from the facultative methylotroph Methylobacterium extorquens AM1. It has a molecular mass of about 71 kDa, and it consists of two identical subunits with a molecular mass of about 37 kDa. This enzyme uses both NADH (Km = 0.04 mM) and NADPH (Km = 0.06 mM) as cofactors, uses hydroxypyruvate (Km = 0.1 mM) and glyoxylate (Km = 1.5 mM) as the only substrates for the forward reaction, and carries out the reverse reaction with glycerate (Km = 2.6 mM) only. It was not possible to detect the conversion of glycolate to glyoxylate, a proposed role for this enzyme. Kinetics and inhibitory studies of the enzyme from M. extorquens AM1 suggest that hydroxypyruvate reductase is not a site for regulation of the serine cycle at the level of enzyme activity.     

Purification and characterization of a novel NADPH(NADH)-dependent glyoxylate reductase from spinach leaves. Comparison of immunological properties of leaf glyoxylate reductase and hydroxypyruvate reductase.

A novel reductase displaying high specificity for glyoxylate and NADPH was purified 3343-fold from spinach leaves. The enzyme was found to be an oligomer of about 125 kDa, composed of four equal subunits of 33 kDa each. A Km for glyoxylate was about 14-fold lower with NADPH than with NADH (0.085 and 1.10 mM respectively), but the maximal activity, 210 mumol/min per mg of protein, was similar with either cofactor. Km values for NADPH and NADH were 3 and 150 microM respectively. Optimal rates with either NADPH or NADH were found in the pH range 6.5-7.4. The enzyme also showed some reactivity towards hydroxypyruvate with rates less than 2% of those observed for glyoxylate. Results of immunological studies, using antibodies prepared against either glyoxylate reductase or spinach peroxisomal hydroxypyruvate reductase, suggested substantial differences in molecular structure of the two proteins. The high rates of NADPH(NADH)-glyoxylate reductase in crude leaf extracts of spinach, wheat and soya bean (30-45 mumol/h per mg of chlorophyll) and its strong affinity for glyoxylate suggest that the enzyme may be an important side component of photorespiration in vivo. In leaves of nitrogen-fixing legumes, this reductase may also be involved in ureide breakdown, utilizing the glyoxylate produced during allantoate metabolism.     

Purification and characterization of hydroxypyruvate reductase from a serine-producing methylotroph, Hyphomicrobium methylovorum GM2

Hydroxypyruvate reductase of a serine-producing methylotroph, Hyphomicrobium methylovorum GM2, was purified to complete homogeneity, crystallized and characterized, the first time for an enzyme from a methylotroph. The enzyme was found to be a dimer composed of identical subunits (38 kDa), the molecular mass of the enzyme being about 70 kDa. The enzyme was stable against heating at 25 degrees C for 10 min at pH values between 5 and 9. Optimal activity was observed at pH 6.8 and around 45 degrees C. The enzyme catalyzed the reduction of hydroxypyruvate with the oxidation of only NADH. Other than hydroxypyruvate, only glyoxylate served as a substrate. The Km values were found to be 0.175 mM for hydroxypyruvate and 10.8 mM for glyoxylate. Taking advantage of the high substrate specificity of this enzyme, a means of enzymatic determination of hydroxypyruvate was established.     

A novel FAD-protein that allows effective reduction of methyl viologen by NADH (NADH-methyl viologen reductase) from photosynthetic bacterium, Rhodospirillum rubrum: purification and characterization

It was found that the cytoplasm of light-grown cells of Rhodospirillum rubrum could catalyze the reduction of methyl viologen (MV) (Em, 7 = -0.44 V) by NADH and NADPH. In the present study, the enzyme capable of catalyzing MV reduction by NADH (NADH-MV reductase) was purified 1,500-fold from an extract of cells with a yield of 4.4%. The purification procedure comprised (NH4)2SO4 fractionation, and chromatographies on Sepharose CL-6B, DEAE-Sepharose CL-6B, phenyl-Sepharose CL-4B, Blue-Cellulofine, and TSK-Gel G3000SW. Two NADPH-MV reductases were separated during the purification. The NADH-MV reductase obtained was nearly homogeneous, as judged on polyacrylamide gel electrophoresis both in the presence and absence of sodium dodecyl sulfate. The enzyme has a molecular weight of 220,000 and an isoelectric point of 4.8; it is composed of four subunits with a molecular weight of 57,000, and is bound with about 1 mol FAD/mol subunit. The activity is optimum at pH 8. The Km values for NADH and MV are 115 microM and 1.3 mM, respectively, with a molecular activity of 13,000 min-1. The activity was stimulated 2.4-fold in the presence of 20-100 mM ammonium ions. The enzyme also catalyzed the reduction of benzyl viologen, methylene blue and 2,6-dichlorophenol-indophenol (Em, 7 = -0.36, +0.011, and +0.217 V, respectively) at comparable rates. The ratios of the activity with NADH to that with NADPH were 80, 133, 41, and 5.5 with MV, benzyl viologen, methylene blue and 2,6-dichlorophenolindophenol, respectively. The enzyme was significantly stable in the presence of both 5mM 2-mercaptoethanol and 20% (w/v) glycerol. The activity was not appreciably influenced by the presence of 2 M urea, although the reagent caused dissociation to the subunits.     

Purification, characterization and identification of aromatic 2-oxo acid reductase.

Aromatic 2-oxo acid reductase was purified to homogeneity from the cytosol of dog heart. The purified enzyme utilized various 2-oxo acids as substrates in the following order of activity: oxaloacetate > 3,5-diiodo-4-hydroxyphenylpyruvate > indolepyruvate > phenylpyruvate. Little or no activity was detected with glyoxylate, pyruvate, hydroxypyruvate, 2-oxoglutarate and 2-oxoadipate. NADH was active as coenzyme but not NADPH. The enzyme has an isoelectric point of 5.4 and is probably composed of two identical subunits with a molecular weight of approx. 40000. Evidence was presented that aromatic 2-oxo acid reductase is identical with one of the cytosol malate dehydrogenase isoenzymes. The enzyme was also found in the brain, kidney and liver of dog.     

A novel hyperthermophilic archaeal glyoxylate reductase from Thermococcus litoralis. Characterization, gene cloning, nucleotide sequence and expression in Escherichia coli.

A novel NADH-dependent glyoxylate reductase has been found in a hyperthermophilic archaeon Thermococcus litoralis DSM 5473. This is the first evidence for glyoxylate metabolism and its corresponding enzyme in hyperthermophilic archaea. NADH-dependent glyoxylate reductase was purified approximately 560-fold from a crude extract of the hyperthermophile by five successive column chromatographies and preparative PAGE. The molecular mass of the purified enzyme was estimated to be 76 kDa, and the enzyme consisted of a homodimer with a subunit molecular mass of approximately 37 kDa. The optimum pH and temperature for enzyme activity were approximately 6.5 and 90 degrees C, respectively. The enzyme was extremely thermostable; the activity was stable up to 90 degrees C. The glyoxylate reductase catalyzed the reduction of glyoxylate and hydroxypyruvate, and the relative activity for hydroxypyruvate was approximately one-quarter that of glyoxylate in the presence of NADH as an electron donor. NADPH exhibited rather low activity as an electron donor compared with NADH. The Km values for glyoxylate, hydroxypyruvate, and NADH were determined to be 0.73, 1.3 and 0.067 mM, respectively. The gene encoding the enzyme was cloned and expressed in Escherichia coli. The nucleotide sequence of the glyoxylate reductase gene was determined and found to encode a peptide of 331 amino acids with a calculated relative molecular mass of 36,807. The amino-acid sequence of the T. litoralis enzyme showed high similarity with those of probable dehydrogenases in Pyrococcus horikoshii and P. abyssi. The purification of the enzyme from recombinant E. coli was much simpler compared with that from T. litoralis; only two steps of heat treatment and dye-affinity chromatography were needed.     

Reduced nicotinamide adenine dinucleotide-nitrate reductase of Chlorella vulgaris. Purification, prosthetic groups, and molecular properties.

NADH:nitrate reductase (EC 1.6.6.1) from Chlorella vulgaris has been purified 640-fold with an over-all yield of 26% by a combination of protamine sulfate fractionation, ammonium sulfate fractionation, gel chromatography, density gradient centrifugation, and DEAE-chromatography. The purified enzyme is stable for more than 2 months when stored at minus 20 degrees in phosphate buffer (pH 6.9) containing 40% (v/v) glycerol. After the initial steps of the purification, a constant ratio of NADH:nitrate reductase activity to NADH:cytochrome c reductase and reduced methyl viologen:nitrate reductase activities was observed. One band of protein was detected after polyacrylamide gel electrophoresis of the purified enzyme. This band also gave a positive stain for heme, NADH dehydrogenase, and reduced methyl viologen:nitrate reductase. One band, corresponding to a molecular weight of 100, 000, was detected after sodium dodecyl sulfate polyacrylamide gel electrophoresis. The enzyme contains FAD, heme, and molybdenum in a 1:1:0.8 ratio. One "cyanide binding site" per molybdenum was found. No non-heme-iron or labile sulfide was detected. From a dry weight determination of the purified enzyme, a minimal molecular weight of 152, 000 per molecule of heme or FAD was calculated. An s20, w of 9.7 S for nitrate reductase was found by the use of sucrose density gradient centrifugation and a Stokes radius of 89 A was estimated by gel filtration techniques. From these values, and the assumption that the partial specific volume is 0.725 cc/g, a molecular weight of 356, 000 was estimated for the native enzyme. These data suggest that the native enzyme contains a minimum of 2 molecules each of FAD, heme, and molybdenum and is composed of at least three subunits.     

L-Lactate dehydrogenase from leaves of higher plants. Kinetics and regulation of the enzyme from lettuce (Lactuca sativa L).

1. L-Lactate dehydrogenase from lettuce (Lactuca sativa) leaves was purified to electrophoretic homogeneity by affinity chromatography. 2. In addition to its NAD(H)-dependent activity with L-lactate and pyruvate, the enzyme also catalyses the reduction of hydroxypyruvate and glyoxylate. The latter activities are not due to a contamination of the enzyme preparations with hydroxypyruvate reductase. 3. The enzyme shows allosteric properties that are markedly by the pH. 4. ATP is a potent inhibitor of the enzyme. The kinetic data suggest that the inhibition by ATP is competitive with respect to NADH at pH 7.0 and 6.2. The existence of regulatory binding sites for ATP and NADH is discussed. 5. Bivalent metal cations and fructose 6-phosphate relieve the ATP inhibition of the enzyme. 6. A function of leaf L-lactate dehydrogenase is proposed as a component of the systems regulating the cellular pH and/or controlling the concentration of reducing equivalents in the cytoplasm of leaf cells.     

Effect of the lyotropic series of anions on denaturation and renaturation of 20 beta-hydroxysteroid dehydrogenase

The effect of the lyotropic series of anions on the stability and renaturation of tetrameric 20 beta-hydroxysteroid dehydrogenase (17,20 beta,21-trihydroxysteroid:NAD+ oxidoreductase, EC 1.1.1.53) was investigated. The variations in enzymatic activity were correlated with the changes in protein fluorescence, circular dichroism, reactivity of histidine residues and molecular weight. High concentrations of salting-out anions (phosphate, citrate, sulphate) were found to stabilize the enzyme markedly and increase the renaturation yield of the urea-denatured enzyme. Phosphate, for instance, induced the highest stabilization at about 1.2 M and the maximum reactivation (66%) at 0.5 M. At low anion concentration (0.01 M), the reactivation was only 7%. The renaturation property of salting-out anions seems to be due to their stabilizing effect on the end-product, i.e., the assembled tetramer. Salting-in anions (perchlorate, thiocyanate, iodide) inactivated the enzyme. At moderate anion concentrations (no greater than 0.25 M) the activation, which occurred slowly, without tetramer dissociation and with minor modifications of enzyme conformation, was fully reversed by concentrated phosphate or by saturating concentrations of NADH. In contrast, the inactivation induced by high anion concentrations (1-2 M) was rapid, irreversible and linked to considerable modifications of enzyme conformation.     

Purification and characterization of an enantioselective carbonyl reductase from Candida viswanathii MTCC 5158

A highly enantioselective carbonyl reductase produced by a new yeast strain Candida viswanathii MTCC 5158, which was isolated using an acetophenone enriched medium, has been purified and characterized. The enzyme has been purified to near homogeneity using ammonium sulfate precipitation, ion exchange and gel filtration chromatography. The molecular properties of the carbonyl reductase suggested the native enzyme to be tetrameric, with an apparent molecular weight of 120 kDa, the monomer being about 29 kDa. Acetyl aryl ketones were found to be the preferred substrates for the enzyme and the best reaction was the enantioselective reduction of acetophenone. The enzyme yielded (S)-alcohol in preference to (R)-alcohol and utilized NADH, but not NADPH as the cofactor. The purified enzyme exhibited maximum enzyme activity at pH 7.0 and 60 °C. The enzyme retained about 80% of its activity after 7 h incubation at 25 °C in sodium phosphate buffer (50 mM, pH 7.0). The addition of reducing agents like dithiothreitol and β-mercaptoethanol enhanced the enzyme activity while organic solvents, detergents and chaotropic agents had deleterious effect on enzyme activity. Metal chelating agents like hydroxyquinoline and o-phenanthroline have significant effect on enzyme activity suggesting that the carbonyl reductase required the presence of a tightly bound metal ion for activity or stability. The maximum reaction rate (V_max) and apparent Michaelis–Menten constant (K_m) for acetophenone and NADH were 59.21 μmol/(min mg) protein and 0.153 mM and 82.64 μmol/(min mg) protein and 0.157 mM at a concentration range of 0.2–2 mM acetophenone (NADH fixed at 0.5 mM) and 0.1–0.5 mM NADH (acetophenone fixed at 2 mM), respectively.     

An analysis of the reassembly of denatured creatine kinase from monkey brain

Creatine kinase isolated from monkey brain was characterized with respect to denaturation/inactivation and renaturation/reactivation/reassociation in order to determine the mechanism of reassembly. Enzyme unfolded in 8 M urea exhibits several characteristics of denatured protein: complete loss of enzymatic activity, decrease in intrinsic fluorescence with a red shift in the emission maximum and loss of circular dichroism at 220 nm. The renatured protein reassembles to its apparently native condition as judged by these criteria, but small differences of uncertain origin persist. Dependence of activity and fluorescence on denaturant concentration indicate that inactivation is more sensitive to urea than is unfolding; spectral changes at the intermediate urea concentrations suggest formation of aggregated protein. Upon dilution, enzyme previously exposed to 8 M urea for 40 min regains 70-80% native activity, independent of protein concentration over the range of 0.56-160 nM. Reactivation kinetics, measured using the assay mixture with and without trypsin, are independent of protein concentration, and are adequately described by a single rate constant, 3.2 X 10(-3) s-1 and 4.2 X 10(-3) s-1, respectively. Reactivation is completed 20-30 min after initiation of renaturation. Fluorescence changes during refolding are at least biphasic, exhibiting a rapid increase, then a slow decrease completed at approximately 15-20 min after initiating refolding. Reassociation is measured by competitive hybridization between dimerizing B subunits and M subunits to form MB heterodimer. The time dependent decay in heterodimer formation during competitive dimerization shows that reassociation is completed between 60 and 90 min after initiation of reassembly. These results indicate that the brain isozyme of creatine kinase, like the muscle form, is composed of subunits which do not require association for expression of catalytic activity. Furthermore, a comparison of spectral data and susceptibility to trypsin inactivation between the muscle and brain isozymes supports previous suggestions that in the native state, the brain isozyme is a conformationally looser, more open protein.     

Cloning, mutagenesis, and physiological effect of a hydroxypyruvate reductase gene from Methylobacterium extorquens AM1.

The gene encoding the serine cycle hydroxypyruvate reductase of Methylobacterium extorquens AM1 was isolated by using a synthetic oligonucleotide with a sequence based on a known N-terminal amino acid sequence. The cloned gene was inactivated by insertion of a kanamycin resistance gene, and recombination of this insertion derivative with the wild-type gene produced a serine cycle hydroxypyruvate reductase null mutant. This mutant had lost its ability to grow on C-1 compounds but retained the ability to grow on C-2 compounds, showing that the hydroxypyruvate reductase operating in the serine cycle is not involved in the conversion of acetyl coenzyme A to glycine as previously proposed. A second hydroxypyruvate-reducing enzyme with a low level of activity was found in M. extorquens AM1; this enzyme was able to interconvert glyoxylate and glycollate. The gene encoding hydroxypyruvate reductase was shown to be located about 3 kb upstream of two other serine cycles genes encoding phosphoenolpyruvate carboxylase and malyl coenzyme A lyase.     

Conversion of serine to glycerate in intact spinach leaf peroxisomes: role of malate dehydrogenase

In photorespiration, leaf peroxisomes convert serine to glycerate via serine-glyoxylate aminotransferase and NADH-hydroxypyruvate reductase. We isolated intact spinach leaf peroxisomes in 0.25 M sucrose, and characterized their enzymatic conversion of serine to glycerate using physiological concentrations of substrates and coenzymes. In the presence of glycolate (glyoxylate), and NADH and NAD alone or together in physiological proportions, the rate of serine-to-glycerate conversion was enhanced and sustained by the addition of malate. The rate was similar at 1 and 5 mM serine, but was two to three times higher in 50 mM than 5 mM malate. In the presence of NAD and malate, there was 1:1 stoichiometric formation of glycerate and oxaloacetate. Addition of 1 or 5 mM glutamate resulted in a negligible enhancement of the conversion of hydroxypyruvate to glycerate. Intact peroxisomes produced glycerate from either serine or hydroxypyruvate at a rate two times higher than osmotically lysed peroxisomes. These results suggest that under physiological conditions, the peroxisomal malate dehydrogenase operates independent of aspartate-alpha-ketoglutarate aminotransferase in supplying NADH for hydroxypyruvate reduction. This supply of NADH is the rate-limiting step in the conversion of serine to glycerate. The compartmentation of hydroxypyruvate reductase and malate dehydrogenase in the peroxisomes confers a higher efficiency in the supply of NADH for hydroxypyruvate reduction under a normal, high NAD/NADH ratio in the cytosol.     

Isolation and Characterization of a Soluble NADPH-Dependent Fe(III) Reductase from Geobacter sulfurreducens

NADPH is an intermediate in the oxidation of organic compounds coupled to Fe(III) reduction in Geobacter species, but Fe(III) reduction with NADPH as the electron donor has not been studied in these organisms. Crude extracts of Geobacter sulfurreducens catalyzed the NADPH-dependent reduction of Fe(III)-nitrilotriacetic acid (NTA). The responsible enzyme, which was recovered in the soluble protein fraction, was purified to apparent homogeneity in a four-step procedure. Its specific activity for Fe(III) reduction was 65 micromol. min(-1). mg(-1). The soluble Fe(III) reductase was specific for NADPH and did not utilize NADH as an electron donor. Although the enzyme reduced several forms of Fe(III), Fe(III)-NTA was the preferred electron acceptor. The protein possessed methyl viologen:NADP(+) oxidoreductase activity and catalyzed the reduction of NADP(+) with reduced methyl viologen as electron donor at a rate of 385 U/mg. The enzyme consisted of two subunits with molecular masses of 87 and 78 kDa and had a native molecular mass of 320 kDa, as determined by gel filtration. The purified enzyme contained 28.9 mol of Fe, 17.4 mol of acid-labile sulfur, and 0.7 mol of flavin adenine dinucleotide per mol of protein. The genes encoding the two subunits were identified in the complete sequence of the G. sulfurreducens genome from the N-terminal amino acid sequences derived from the subunits of the purified protein. The sequences of the two subunits had about 30% amino acid identity to the respective subunits of the formate dehydrogenase from Moorella thermoacetica, but the soluble Fe(III) reductase did not possess formate dehydrogenase activity. This soluble Fe(III) reductase differs significantly from previously characterized dissimilatory and assimilatory Fe(III) reductases in its molecular composition and cofactor content.     

Coenzyme specificity of mammalian liver D-glycerate dehydrogenase

D-Glycerate dehydrogenase (glyoxylate reductase) was partially purified from rat liver by anion- and cation-exchange chromatography. When assayed in the direction of D-glycerate or glycolate formation, the enzyme was inhibited by high (greater than or equal to 0.5 mM), unphysiological concentrations of hydroxypyruvate or glyoxylate much more potently in the presence of NADPH than in the presence of NADH. However, the dehydrogenase displayed a much greater affinity for NADPH (Km less than 1 microM) than for NADH (Km = 48-153 microM). Furthermore, NADP was over 1000-fold more potent than NAD in inhibiting the enzyme competitively with respect to NADH. NADP also inhibited the reaction competitively with respect to NADPH whereas NAD, at concentrations of up to 10 mM had no inhibitory effect. When measured by the formation of hydroxypyruvate from D-glycerate, the enzyme also displayed a much greater affinity for NADP than for NAD. These properties indicate that liver D-glycerate dehydrogenase functions physiologically as an NADPH-specific reductase. In agreement with this conclusion, the addition of hydroxypyruvate or glyoxylate to suspensions of rat hepatocytes stimulated the pentose-phosphate pathway. The coenzyme specificity of D-glycerate dehydrogenase is discussed in relation to the biochemical findings made in D-glyceric aciduria and in primary hyperoxaluria type II (L-glyceric aciduria).     

Subunit structure and hybrid formation of bovine pyruvate kinases

After denaturing either type M or L pyruvate kinase by guanidine hydrochloride, urea, or low pH, enzymatic activity and quaternary structure can be recovered by diluting the enzyme into buffer containing beta-mercaptoethanol. After denaturation of type M pyruvate kinase by guanidine hydrochloride, the yield and polarization of the intrinsic protein fluorescence, as well as most of the circular dichroism characteristic of the native enzyme, were regained very rapidly, while enzymatic activity was recovered much more slowly. Under the conditions used, about 50% of the original M and 30-50% of the original type L activity were typically recovered. Average half-times for recovery of enzymatic activity were 37 min for type M and 104 min for type L but depended somewhat on the renaturation buffer and on protein concentrations in the renaturation medium. If types M and L pyruvate kinases are renatured together, an approximately random recombination of the two subunits types results in a five-membered hybrid set. We have used this hybridizability to determine the kinetics of reformation of the native tetramer by denaturing each isozyme and beginning its renaturation separately at various times mixing the two isozymes and continuing their renaturation together. These studies indicate that reformation of stable tetramers occurs relatively slowly, qualitatively paralleling the regain of enzymatic activity, and that tetramer formation may be necessary for enzymatic activity. Using a similar technique to test for spontaneous dissociation of the native isozymes in buffer, we find that type L, but not type M, reversibly dissociates into dimers and monomers in buffer solutions. This dissociation is decreased by the presence of the substrate, phosphoenolpyruvate, by Mg2+ ions, or by the allosteric effector, fructose bisphosphate.     

The oxidation of d- and l-glycerate by rat liver

1. The interconversion of hydroxypyruvate and l-glycerate in the presence of NAD and rat-liver l-lactate dehydrogenase has been demonstrated. Michaelis constants for these substrates together with an equilibrium constant have been determined and compared with those for pyruvate and l-lactate. 2. The presence of d-glycerate dehydrogenase in rat liver has been confirmed and the enzyme has been purified 16–20-fold from the supernatant fraction of a homogenate, when it is free of l-lactate dehydrogenase, with a 23–29% recovery. The enzyme catalyses the interconversion of hydroxypyruvate and d-glycerate in the presence of either NAD or NADP with almost equal efficiency. d-Glycerate dehydrogenase also catalyses the reduction of glyoxylate, but is distinct from l-lactate dehydrogenase in that it fails to act on pyruvate, d-lactate or l-lactate. The enzyme is strongly dependent on free thiol groups, as shown by inhibition with p-chloromercuribenzoate, and in the presence of sodium chloride the reduction of hydroxypyruvate is activated. Michaelis constants for these substrates of d-glycerate dehydrogenase and an equilibrium constant for the NAD-catalysed reaction have been calculated. 3. An explanation for the lowered V_max. with d-glycerate as compared with dl-glycerate for the rabbit-kidney d-α-hydroxy acid dehydrogenase has been proposed.