Evidence for the regulation of pyridoxal 5′-phosphate formation in liver by pyridoxamine (pyridoxine) 5′-phosphate oxidase

Pyridoxamine (pyridoxine) 5′-phosphate oxidase (EC 1.4.3.5) purified from rabbit liver is competitively inhibited by the reaction product, pyridoxal 5′-phosphate. The K_i, 3 μM, is considerably lower than the K_m for either natural substrate (18 and 24 μM for pyridoxamine 5′-phosphate and 25 and 16 μM for pyridoxine 5′-phosphate in 0.2 M potassium phosphate at pH 8 and 7, respectively). The K_i determined using a 10% rabbit liver homogenate is the same as that for the pure enzyme; hence, product inhibition $\text{in}\text{vivo}$ is probably not diminished significantly by other cellular components. Similar determinations for a 10% rat liver homogenate also show strong inhibition by pyridoxal 5′-phosphate. Since the reported liver content of free or loosely bound pyridoxal 5′-phosphate is greater than K_i, the oxidase in liver is probably associated with pyridoxal 5′-phosphate. These results also suggest that product inhibition of pyridoxamine-P oxidase may regulate the $\text{in}\text{vivo}$ rate of pyridoxal 5′-phosphate formation.     

Substrate-cofactor interactions for glycogen phosphorylase b: a binding study in the crystal with heptenitol and heptulose 2-phosphate

The structural relationships between substrate and pyridoxal phosphate in glycogen phosphorylase b (EC 2.4.1.1) have been studied by X-ray diffraction experiments at 3-A resolution. Recent work [Klein, H. W., Im, M. J., & Helmreich, E. J. M. (1984) in Chemical and Biological Aspects of Vitamin B6 Catalysis (Evangelopoulos, A. E., Ed.) pp 147-160, Liss, New York] has shown that phosphorylase in the presence of inorganic phosphate catalyzes the conversion of heptenitol to heptulose 2-phosphate. The latter compound is a dead-end product and a most potent inhibitor (Ki = 14 microM). The X-ray diffraction studies show that heptenitol binds at the catalytic site of phosphorylase in a position essentially identical with that observed for the glucopyranose moiety of glucose 1-phosphate. Incubation of a phosphorylase b crystal for 50 h in a solution containing the substrates heptenitol and inorganic phosphate and the activators AMP and maltohetaose resulted in the formation of a phosphorylated product bound at the active site. The structure of this product, as analyzed by a difference Fourier synthesis at 3 A, is consistent with that of heptulose 2-phosphate. Analysis of the surrounding soak solution by thin-layer chromatography showed that heptulose 2-phosphate was produced under these conditions. Heptulose 2-phosphate binds with its glucopyranose moiety in the same position as that for glucose 1-phosphate, but there is a marked difference in phosphate positions. The presence of the methyl group in the beta-configuration in heptulose 2-phosphate forces a change in the torsion angle O5-C1-O1-P from 117 degrees as observe in glucose 1-phosphate to -136 degrees in heptulose 2-phosphate. The "down" position of the phosphate (with respect to the crystallographic z axis) results in a change in the distance between the 5'-phosphorus atom of the pyridoxal phosphate and the phosphorus atom of the substrate from 6.8 (with glucose 1-phosphate) to 4.5 A (with heptulose 2-phosphate). The closest distance between the phosphate oxygen of the cofactor and a phosphate oxygen of heptulose 2-phosphate is 2.7 A, and it is assumed that there must be a hydrogen bond between them. These observations are consistent with the NMR experiments reported in the preceding paper in which sharing of a proton between heptulose 2-phosphate and pyridoxal 5'-phosphate is observed [Klein, H.W., Im, M. J., Palm, D., & Helmreich, E. J. M. (1984) Biochemistry (preceding paper in this issue)].(ABSTRACT TRUNCATED AT 400 WORDS)     

Factors affecting hepatic glycolysis and some changes that occur during development

1. Glycolysis by the supernatant fraction of homogenates of liver from guinea pigs and rats at various stages of development (foetal, newborn and adult) has been examined in a suitably fortified medium by measurement of inorganic phosphate uptake and production of lactate and glycerol 1-phosphate. 2. Starting with glucose as substrate, two rate-determining steps in glycolysis occur at the stages of glucose phosphorylation and the phosphofructokinase reaction in liver tissue from animals of all ages. Effects of the post-natal development of glucokinase are recorded. 3. The appearance of microsomal glucose 6-phosphatase activity around birth has an effect on glycolysis owing to competition for glucose 6-phosphate. 4. A stimulating effect of the nuclear fraction, especially from foetal liver, on glycolysis by the supernatant fraction is interpreted as being due to stimulation by adenosine-triphosphatase activity at the 3-phosphoglycerate-kinase stage.     

Proposals for the catalytic mechanism of glycogen phosphorylase b prompted by crystallographic studies on glucose 1-phosphate binding

The crystal structure of glycogen phosphorylase b in the presence of the weak activator 2 mm-inosine 5′-phosphate has been solved at 3 Å resolution. The binding interactions of the substrate, glucose 1-phosphate, at the catalytic site are described. The nearby presence (6 Å) of the essential co-factor, pyridoxal phosphate, is consistent with biochemical studies but an analysis of the way in which this group might act in catalysis leads to results that are inconsistent with solution studies. Moreover it is difficult to accommodate a glycogen substrate with its terminal glucose in the position defined by glucose 1-phosphate. Model-building studies show that an alternative binding mode for glucose 1-phosphate is possible and that this alternative mode allows a glycogen substrate to be fitted with ease. The alternative binding site leads directly to proposals for the mechanism in which the phosphate group of pyridoxal phosphate acts as a nucleophile and the imidazole of histidine 376 functions as a general acid. It is suggested that these are the essential features of the catalytic mechanism and that, in the absence of the second substrate, glycogen, and in the absence of AMP, the enzyme binds glucose 1-phosphate in a non-productive mode. Conversion of the enzyme to the active conformation through association with AMP may result in conformational changes that direct the binding to the productive mode.     

A simplified protein precipitation and filtration procedure for determining serum vitamin B6 by high-performance liquid chromatography

Protein precipitation followed by centrifuge filtration was tested as a simplified sample preparation procedure for quantifying pyridoxal 5′-phosphate (PLP) and 4-pyridoxic acid (4PA) in serum by high-performance liquid chromatography. Serum samples (n = 160) were prepared by both centrifuge filtration and an established technique using traditional supernatant extraction with manual filtration. Bland-Altman bias analysis (95% confidence levels [CLs]) of the results showed a −1.3 (−2.2, −0.5)% difference in PLP values and a −6.2 (−7.3, −5.2)% difference in 4PA values using the simplified sample preparation. These deviations were found to be well within allowable biases on the basis of biologic variation.     

Inhibition of 7,8-diaminopelargonic acid aminotransferase from Mycobacterium tuberculosis by chiral and achiral anologs of its substrate: Biological implications

7,8-Diaminopelargonic acid aminotransferase (DAPA AT), a potential drug target in Mycobacterium tuberculosis, transforms 8-amino-7-oxononanoic acid (KAPA) into DAPA. We have designed an analytical method to measure the enantiomeric excess of KAPA, based on the derivatization of its amine function, by ortho-phtalaldehyde and N-acetyl-l-cysteine, followed by high pressure liquid chromatography separation. Using this methodology and enantiopure samples of KAPA it appeared that racemization of KAPA occurs rapidly (half-lives from 1 to 8 h) not only in 4 M HCl but more importantly in the usual pH range, from 7 to 9. Furthermore, we showed that racemic KAPA, and not enantiopure KAPA, was used in all previous studies. The only valid enantioselective synthesis of KAPA is that reported by Lucet et al. (1996) Tetrahedron: Asymmetry 7, 985–988. KAPA is produced as a pure (S)-enantiomer by KAPA synthase and by microbial production and DAPA AT only uses (S)-KAPA as substrate. However, (R)-KAPA is an inhibitor of this enzyme. It binds to the pyridoxal 5′-phosphate form (K_i1 = 5.9 ± 0.2 μM) and to the pyridoxamine 5′-phosphate form (K_i2 = 1.7 ± 0.2 μM) of M. tuberculosis DAPA AT. Molecular modeling showed that (R)-KAPA forms specific hydrogen bonds with T309 and the phosphate group of the cofactor of DAPA AT. Desmethyl-KAPA (8-amino-7-oxooctanoic acid), an achiral analog of KAPA, is also a potent inhibitor of M. tuberculosis DAPA AT. This molecule binds to the enzyme in a similar way than (R)-KAPA with the following constants: K_i1 = 4.2 ± 0.2 μM, and K_i2 = 0.9 ± 0.2 μM. These findings pave the way to the design of new antimycobacterial drugs.     

Substrate-dependent effect of 1–34 human parathyroid hormone fragment,dibutyryl cAMP and cAMP on gluconeogenesis in rabbit renal tubules

In the presence of 0.5 mM extracellular Ca²⁺ concentration both 1–34 human parathyroid hormone fragment (0.5 μg/ml) as well as 0.1 mM dibutyryl cAMP stimulated gluconeogenesis from lactate in renal tubules isolated from fed rabbits. However, these two compounds did not affect glucose synthesis from pyruvate as substrate. When 2.5 mM Ca²⁺ was present the stimulatory effect of the hormone fragment on gluconeogenesis from lactate was not detected but dibutyryl cAMP increased markedly the rate of glucose formation from lactate, dihydroxyacetone and glutamate, and inhibited this process from pyruvate and malate. Moreover, dibutyryl cAMP was ineffective in the presence of either 2-oxoglutarate or fructose as substrate. Similar changes in glucose formation were caused by 0.1 mM cAMP. As concluded from the ‘crossover’ plot the stimulatory effect of dibutyryl cAMP on glucose formation from lactate may result from an acceleration of pyruvate carboxylation due to an increase of intramitochondrial acetyl-CoA, while an inhibition by this compound of gluconeogenesis from pyruvate is likely due to an elevation of mitochondrial NADH/NAD⁺ ratio, resulting in a decrease of generation of oxaloacetate, the substrate of phosphoenolpyruvate carboxykinase. Dibutyryl cAMP decreased the conversion of fracture 1,6-bisphosphate to fructose 6-phosphate in the presence of both substrates which may be secondary to an inhibition of fructose 1,6-bisphosphatase.     

Effects of Metformin and Vanadium on Leptin Secretion from Cultured Rat Adipocytes

Objective: We have reported that glucose utilization regulates leptin expression and secretion from isolated rat adipocytes. In this study, we employed two antidiabetic agents that act to increase glucose uptake by peripheral tissues, metformin and vanadium, as pharmacological tools to examine the effects of altering glucose utilization on leptin secretion in primary cultures of rat adipocytes. Research Methods and Procedures: Isolated adipocytes (100 μL of packed cells per well) were anchored in a defined matrix of basement membrane components (Matrigel) with media containing 5.5 mM glucose and incubated for 96 hours with metformin or vanadium. Leptin secretion, glucose utilization, and lactate production were assessed. Results: Metformin (0.5 and 1.0 mM) increased glucose uptake in the presence of 0.16 nM insulin by 37 ± 10% (p < 0.005) and 62 ± 8% (p < 0.0001) over insulin alone, respectively. Metformin from 0.5 to 5.0 mM increased lactate production by 105 ± 43% (p < 0.025) to 202 ± 52% (p < 0.0025) and at 1.0 and 5.0 mM increased the proportional rate of glucose conversion to lactate by 78 ± 18% (p < 0.005) and 166 ± 41% (p < 0.0025), respectively. At concentrations less than 0.5 mM, metformin did not affect leptin secretion, but at 0.5 mM, the only concentration that significantly increased glucose utilization without increasing glucose conversion to lactate, leptin secretion was modestly stimulated (by 20 ± 9%; p < 0.05). Concentrations from 1.0 to 25 mM inhibited leptin secretion by 25 ± 8% (p < 0.005) to 89 ± 4% (p < 0.0001). Across metformin doses, leptin secretion was inversely related to the percentage of glucose taken up and released as lactate (r = ?0.74; p < 0.0001). Vanadium (5 to 20 μM) increased glucose uptake from 20 ± 7% (p < 0.01) to 34 ± 13% (p < 0.02) and increased lactate production at 5 μM by 17 ± 8% (p < 0.025) and 10 μM by 61 ± 20% (p < 0.02) but did not alter the conversion of glucose to lactate. Vanadium (5 to 50 μM) inhibited leptin secretion by 33 ± 6% (p < 0.0025) to 61 ± 8% (p < 0.0001). Discussion: Both metformin and vanadium increase glucose uptake and inhibit leptin secretion from cultured adipocytes. The inhibition of leptin secretion by metformin is related to an increase in the metabolism of glucose to lactate. The inhibition by vanadium most likely involves direct effects on cellular phosphatases. We hypothesize that the effect of glucose utilization to stimulate leptin production involves the metabolism of glucose to a fate other than anaerobic lactate production, possibly oxidation or lipogenesis.     

Interaction of pyridoxal phosphate with the amino groups at the active site of 5- aminolevulinic acid dehydratase in maize

Pyridoxal 5′-phosphate strongly and reversibly inhibited maize leaf 5-amino levulinic acid dehydratase. The inhibition was linearly competitive with respect to the substrate 5-aminolevulinic acid at pH values between 7 to 9.0. Pyridoxal was also effective as an inhibitor of the enzyme but pyridoxamine phosphate was not inhibitory. The results suggest that pyridoxal 5′-phosphate may be interacting with the enzyme either close to or at the 5-aminolevulinic acid binding site. This conclusion was further corroborated by the detection of a Schiff base between the enzyme and the substrate, 5-aminolevulinic acid and by reduction of pyridoxal phosphate and substrate complexes with sodium borohydride     

Syntheses,properties, and use of fluorescent N-(5′-phospho-4′-pyridoxyl)amines in assay of pyridoxamine (pyridoxine) 5′-phosphate oxidase

A sensitive and simple fluorometric assay has been developed for detection of pyridoxamine (pyridoxine) 5′-phosphate oxidase. This technique utilizes fluorescent N-(5′-phospho-4′-pyridoxyl)amines as substrates that, upon incubation with the oxidase, release the free fluorescent amine. The substrates were prepared by condensation of pyridoxal 5′-phosphate with fluorescent amines and subsequent hydrogenation of the Schiff bases. Since N-(1-naphthyl)ethylenediamine is 15 times less fluorescent in the intramolecularly quenched substrate than the product amine, the direct increase of fluorescence, as well as selective extraction of more fluorescent product, can be utilized for assay. The apparent K_m value for this substrate is 8 μm, which is slightly less than that of pyridoxamine 5′-phosphate; V is larger than the natural substrate value. The greater sensitivity gained by this fluorimetric method allows detection of the oxidase in smaller quantities than can be determined by the conventional colorimetric assay.     

Pyridoxal 5′-phosphate binds to a lysine residue in the adenosine 3′-phosphate 5′-phosphosulfate recognition site of glycolipid sulfotransferase from human renal cancer cells

In the course of characterization of glycolipid sulfotransferase from human renal cancer cells, the manner of inhibition of sulfotransferase activity with pyridoxal 5-phosphate was investigated. Incubation of a partially purified sulfotransferase preparation with pyridoxal 5-phosphate followed by reduction with NaBH₄ resulted in an irreversible inactivation of the enzyme. When adenosine 3-phosphate 5-phosphosulfate was co-incubated with pyridoxal 5-phosphate, the enzyme was protected against this inactivation. Furthermore, pyridoxal 5-phosphate was found to behave as a competitive inhibitor with respect to adenosine 3-phosphate 5-phosphosulfate with aK _i value of 287 µm. These results suggest that pyridoxal 5-phosphate modified a lysine residue in the adenosine 3-phosphate 5-phosphosulfate-recognizing site of the sulfotransferase.     

Facile “stop codon” method reveals elevated neuronal toxicity by discrete S87p-α-synuclein oligomers

Herein, a new method for preparing phosphorylated proteins at specific sites has been applied to α-synuclein (α-Syn). Three different α-Syn species phosphorylated at Serine 87 (S87p-α-Syn), Serine 129 (S129p-α-Syn) and Serine 87/129 (S87p,129p-α-Syn) were prepared through the ‘stop codon’ method and verified by LC/MS/MS and immunoblotting. Each type of phosphorylated α-Syn was tested for oligomerization trends and cellular toxicity with dopamine (DA), Cu²⁺ ions and pyridoxal 5′-phosphate. Aggregation trends induced by DA or DA/Cu²⁺ were similar between phosphorylated and non-phosphorylated α-Syn in SDS–PAGE. However, except for the monomer, phosphorylated oligomers showed higher toxicity than the non-phosphorylated α-Syn (Np-α-Syn) oligomers via WST-1 assays when tested on SH-SY5Y human neuroblastoma cells. In particular, S87p-α-Syn and S87p,129p-α-Syn oligomers induced by DA/Cu²⁺, showed higher toxicity than did S129p-α-Syn. When α-Syn was treated with pyridoxal 5′-phosphate in the presence of DA or Cu²⁺ to determine aggregation effects, high inhibition effects were shown in both non-phosphorylated and phosphorylated versions. α-Syn co-incubated with DA or DA/Cu²⁺ showed less cellular toxicity upon pyridoxal 5′-phosphate treatment, especially in the case of DA-induced Np-α-syn. This study supports that phosphorylated oligomers of α-Syn at residue 87 can contribute to neuronal toxicity and the pyridoxal 5′-phosphate can be used as an inhibitor for α-Syn aggregation.     

Kinetic studies on microsomal glucose dehydrogenase in rat liver.

Glucose dehydrogenase from rat liver microsomes was found to react not only with glucose as a substrate but also with glucose 6-phosphate, 2-deoxyglucose 6-phosphate and galactose 6-phosphate. The relative maximum activity of this enzyme was 29% for glucose 6-phosphate, 99% for 2-deoxyglucose 6-phosphate, and 25% for galactose 6-phosphate, compared with 100% for glucose with NADP. The enzyme could utilize either NAD or NADP as a coenzyme. Using polyacrylamide gradient gel electrophoresis, we were able to detect several enzymatically active bands by incubation of the gels in a tetrazolium assay mixture. Each band had different Km values for the substrates (3.0 x 10(-5)M glucose 6-phosphate with NADP to 2.4M glucose with NAD) and for coenzymes (1.3 x 10(-6)M NAD with galactose 6-phosphate to 5.9 x 10(-5)M NAD with glucose). Though glucose 6-phosphate and galactose 6-phosphate reacted with glucose dehydrogenase, they inhibited the reaction of this enzyme only when either glucose or 2-deoxyglucose 6-phosphate was used as a substrate. The Ki values for glucose 6-phosphate with glucose as substrate were 4.0 x 10(-6)M with NAD, and 8.4 x 10(-6)M with NADP; for galactose 6-phosphate they were 6.7 x10(-6)M with NAD and 6.0 x 10(-6)M with NADP. The Ki values for glucose 6-phosphate with 2-deoxyglucose 6-phosphate as substrate were 6.3 x 10(-6)M with NAD and 8.9 x 10(-6)M with NADP; and for galactose 6-phosphate, 8.0 x 10(-6)M with NAD and 3.5 x 10(-6)M with NADP. Both NADH and NADPH inhibited glucose dehydrogenase when the corresponding oxidized coenzymes were used (Ki values: 8.0 x 10(-5)M by NADH and 9.1 x 10(-5)M by NADPH), while only NADPH inhibited cytoplasmic glucose 6-phosphate dehydrogenase (Ki: 2.4 x 10(-5)M). The results indicate that glucose dehydrogenase cannot directly oxidize glucose in vivo, but it might play a similar role to glucose 6-phosphate dehydrogenase. The differences in the kinetics of glucose dehydrogenase and glucose 6-phosphate dehydrogenase show that glucose 6-phosphate and galactose 6-phosphate could be metabolized in quite different ways in the microsomes and cytoplasm of rat liver.     

Efficient production of 2-deoxyribose 5-phosphate from glucose and acetaldehyde by coupling of the alcoholic fermentation system of Baker's yeast and deoxyriboaldolase-expressing Escherichia coli

2-Deoxyribose 5-phosphate production through coupling of the alcoholic fermentation system of baker's yeast and deoxyriboaldolase-expressing Escherichia coli was investigated. In this process, baker's yeast generates fructose 1,6-diphosphate from glucose and inorganic phosphate, and then the E. coli convert the fructose 1,6-diphosphate into 2-deoxyribose 5-phosphate via D-glyceraldehyde 3-phosphate. Under the optimized conditions with toluene-treated yeast cells, 356 mM (121 g/l) fructose 1,6-diphosphate was produced from 1,111 mM glucose and 750 mM potassium phosphate buffer (pH 6.4) with a catalytic amount of AMP, and the reaction supernatant containing the fructose 1,6-diphosphate was used directly as substrate for 2-deoxyribose 5-phosphate production with the E. coli cells. With 178 mM enzymatically prepared fructose 1,6-diphosphate and 400 mM acetaldehyde as substrates, 246 mM (52.6 g/l) 2-deoxyribose 5-phosphate was produced. The molar yield of 2-deoxyribose 5-phosphate as to glucose through the total two step reaction was 22.1%. The 2-deoxyribose 5-phosphate produced was converted to 2-deoxyribose with a molar yield of 85% through endogenous or exogenous phosphatase activity.     

Inactivation of the Reconstituted Oxoglutarate Carrier from Bovine Heart Mitochondria by Pyridoxal 5′-Phosphate

The effect of pyridoxal 5-phosphate and some other lysine reagents on the purified,reconstituted mitochondrial oxoglutarate transport protein has been investigated. The inhibition ofoxoglutarate/oxoglutarate exchange by pyridoxal 5-phosphate can be reversed by passing theproteoliposomes through a Sephadex column but the reduction of the Schiff's base by sodiumborohydride yielded an irreversible inactivation of the oxoglutarate carrier protein. Pyridoxal5-phosphate, which caused a time- and concentration-dependent inactivation of oxoglutaratetransport with an IC₅₀ of 0.5 mM, competed with the substrate for binding to the oxoglutaratecarrier (K _i = 0.4 mM). Kinetic analysis of oxoglutarate transport inhibition by pyridoxal5-phosphate indicated that modification of a single amino acid residue/carrier molecule wassufficient for complete inhibition of oxoglutarate transport. After reduction with sodiumborohydride [³H]pyridoxal 5-phosphate bound covalently to the oxoglutarate carrier. Incubation ofthe proteoliposomes with oxoglutarate or L-malate protected the carrier against inactivationand no radioactivity was found associated with the carrier protein. In contrast, glutarate andsubstrates of other mitochondrial carrier proteins were unable to protect the carrier. Mersalyl,which is a known sulfhydryl reagent, also failed to protect the oxoglutarate carrier againstinhibition by pyridoxal 5-phosphate. These results indicate that pyridoxal 5-phosphateinteracts with the oxoglutarate carrier at a site(s) (i.e., a lysine residue(s) and/or the amino-terminalglycine residue) which is essential for substrate translocation and may be localized at or nearthe substrate-binding site.     

Commensalistic Interaction Between Lactobacillus acidophilus and Propionibacterium shermanii

Propionibacterium shermanii and Lactobacillus acidophilus were grown in batch mixed culture in a 5-liter fermenter under controlled conditions of pH 5.8 and 35°C on a semisynthetic medium with glucose as an energy source. Cellular efficiencies and fermentation balances were developed for this pair and compared with P. shermanii grown in pure culture on glucose, lactate, and a mixture of these substrates and with L. acidophilus grown on glucose. P. shermanii had ATP yield coefficient values of 17 for each substrate alone but had an average value of 30 for substrate mixtures. Growth rates were similar for P. shermanii on glucose or lactate but higher cell yields were observed for glucose. P. shermanii used both lactate and glucose in mixed substrate until lactate was exhausted, and growth rates slowed thereafter. L. acidophilus had a similar ATP yield coefficient of 15 but produced lower cell yields than did P. shermanii on glucose. Mixed culture of both microorganisms on glucose resulted in much faster and nearly equal growth rates for both and no lactate accumulation in the medium. Acetic acid production rates per generation were lower in mixed culture, suggesting use by the growing culture. The cause of the synergistic effect was not determined but may be due to the rapid production and removal of lactate or CO₂ enhancement in mixed culture.     

Inhibition of Brain Glycolysis by Aluminum

Abstract: Aluminum inhibited both the cytosolic and mitochondrial hexokinase activities in rat brain. The IC₅₀ values were between 4 and 9 μ M . Aluminum was effective at mildly acidic (pH 6.8) or slightly alkaline (pH 7.2–7.5) pH, in the presence of a physiological level of magnesium (0.5 m M ). However, saturating (8 m M ) magnesium antagonized the effect of aluminum on both forms of hexokinase activity. Other enzymes examined were considerably less sensitive to inhibition by aluminum. The IC₅₀ of aluminum for phosphofructokinase was 1.8 m M and for lactate dehydrogenase 0.4 m M . At 10–600 μ M , aluminum actually stimulated pyruvate kinase. Aluminum also inhibited lactate production by rat brain extracts: this effect was much more marked with glucose as substrate than with glucose-6-phosphate. However, the IC₅₀ for inhibiting lactate production using glucose as substrate was 280 μ M , higher than that required to inhibit hexokinase. This concentration of aluminum is comparable to those reportedly found in the brains of patients who had died with dialysis dementia and in the brains of some of the patients who had died with Alzheimer disease. Inhibition of carbohydrate utilization may be one of the mechanisms by which aluminum can act as a neurotoxin.     

Destabilization of tyrosine aminotransferase by amino acids

Summary Several L-amino acids (tyrosine, glutamate, methionine, tryptophan, and phenylalanine) and penicillamine destabilized purified tyrosine aminotransferase by removing enzyme-bound pyridoxal 5-phosphate. The destabilization was measured as a progressive loss of enzyme activity in samples taken at intervals from a primary mixture that was incubated at 37°C. Each destabilizing amino acid either served as a substrate for this enzyme or was a product of transamination. In contrast, L-cysteine destabilized the enzyme only if liver homogenate was added, which generated polysulfide by desulfuration. Cysteine complexed free pyridoxal-5-phosphate but did not remove it from the enzyme. Other amino acids did not destabilize tyrosine aminotransferase at the concentrations tested.Abbreviations TyrAT tyrosine aminotransferase (E.C. 2.6.1.5) - PLP pyridoxal-5-phosphate     

Substrate Preference in a Strain of Megasphaera elsdenii, a Ruminal Bacterium, and Its Implications in Propionate Production and Growth Competition

The NIAH 1102 strain of Megasphaera elsdenii utilized lactate in preference to glucose when the two substrates were present. Even when lactate was supplied to cells fermenting glucose, the cells switched substrate utilization from glucose to lactate and did not utilize glucose until lactate decreased to a low concentration (1 to 2 mM). Since substrate utilization was shifted gradually without intermittence, typical diauxic growth was not seen. The cyclic AMP content did not rise markedly with the shift in substrate utilization, suggesting that this nucleotide is not involved in the regulation of the shift. It was unlikely that propionate was produced from glucose, which was explicable by the fact that lactate racemase activity dropped rapidly with the exhaustion of lactate and cells actively fermenting glucose did not possess this enzyme. A coculture experiment indicated that M. elsdenii NIAH 1102 is overcome by Streptococcus bovis JB1 in the competition for glucose, mainly because M. elsdenii NIAH 1102 is obliged to utilize lactate produced by S. bovis JB1; i.e., glucose utilization by M. elsdenii NIAH 1102 is suppressed by the coexistence of S. bovis JB1.