Presence and Regulation of α-Ketoglutarate Dehydrogenase Complex in a Glutamate-Producing Bacterium,Brevibacterium flavum

The presence of α-ketoglutarate (α-KG) dehydrogenase complex in the glutamate-producing bacteria was demonstrated for the first time with Brevibacterium flavum. The partially purified enzyme, which was specific to KG and NAD⁺ with the usual requirements for other co-factors, was labile and stabilized by glycerol, Mg²⁺, and thiamine pyrophosphate. The enzyme showed an optimum pH of 7.6 and K_ms of 80, 86, and 61 μm for KG, NAD⁺, and CoA, respectively, cis-Aconitate, succinyl-CoA, NADPH, NADH, pyruvate, and oxalacetate strongly inhibited the activity, while it was activated by acetyl-CoA, but not by AMP. Various inorganic and organic salts also inhibited the activity. When cells were cultured in glucose and acetate media, the specific activity of the cell extracts increased markedly and reached to a maximum at the late-logarithmic phase. Then, it decreased to the basal level. The addition of glutamate stimulated the synthesis of the enzyme.     

Short-Term Regulation of the α-Ketoglutarate Dehydrogenase Complex by Energy-Linked and Some Other Effectors

The question of regulation of α-ketoglutarate dehydrogenase complex (KGDHC) has been considered in the biochemical literature very rarely. Moreover, such information is not usually accurate, especially in biochemical textbooks. From the mini-review of research works published during the last 25 years, the following basic view is clear: a) animal KGDHC is very sensitive to ADP, P_i, and Ca²⁺; b) these positive effectors increase manifold the affinity of KGDHC to α-ketoglutarate; c) KGDHC is inhibited by ATP, NADH, and succinyl-CoA; d) the ATP effect is realized in several ways, probably mainly via opposition versus ADP activation; e) NADH, besides inhibiting dihydrolipoamide dehydrogenase component competitively versus NAD⁺, decreases the affinity of α-ketoglutarate dehydrogenase to substrate and inactivates it; f) thioredoxin protects KGDHC from self-inactivation during catalysis; g) bacterial and plant KGDHC is activated by AMP instead of ADP. These main effects form the basis of short-term regulation of KGDHC.__________Translated from Biokhimiya, Vol. 70, No. 7, 2005, pp. 880–884.Original Russian Text Copyright © 2005 by Strumilo.     

Inhibition of the α-Ketoglutarate Dehydrogenase Complex from Bakers’ Yeast by Acetaldehyde and Glyoxylate

Gallic acid, methyl gallate, dehydrodigallic acid, three tannic constituents named MP–2, MP–3, MP–4 and a related substance MP–10 were isolated from chestnut galls by solvent fractionation and column chromatography. Hydrolysis with tannase revealed the components of these tannic substances as follows, MP–2: d-glucose, gallic acid and compound I (3,4, 5-trihydroxybenzyl alcohol); MP–3 and MP–4: d-glucose, compound I and compound II (dehydrodigallic acid); MP–10: d-glucose and compound I.     

Absence of 5-Hydroxy-4-Ketohexanoate and the α-Ketoglutarate Dehydrogenase Complex in Mutants of Saccharomyces oviformis Incapable of Growing on Ethanol

The roles of the enzyme which forms 5-hydroxy-4-ketohexanoate (HKH) and of related enzymes in the metabolism of ethanol were studied in Saccharomyces oviformis WH92 and its mutants, which grew poorly or not at all on ethanol. The strains, which did not grow on ethanol, did not form HKH from α-ketoglutarate and acetaldehyde enzymatically and were also devoid of the α-ketoglutarate dehydrogenase complex. Acetaldehyde inhibited the activity of α-ketoglutarate dehydrogenase. These mutants did not grow on acetate since they had no acetyl-CoA synthetase activity. The relationship of the formation of HKH with the metabolism of ethanol is discussed.     

3α-Hydroxysteroid Dehydrogenase in Animal and Human Tissues

This review analyzes data on the biological role of 3-hydroxysteroid dehydrogenase (3-HSD) in animal and human tissues and describes its main characteristics, mechanism of action, and regulation of activity. Based on published data, a scheme for the actions of androgen, progestin, and glucocorticoids involving the participation of 3-HSD is proposed. According to this scheme, in the mechanism of steroid action 3-HSD not only regulates the concentration of the main effector androgen, 5-dihydrotestosterone, in target cells, but also switches androgen, progestin, and glucocorticosteroid genomic activity to non-genomic activity.     

Studies on Aspartic β-Semialdehyde Dehydrogenase in Pea Seedlings

Highly purified aspartic β-semialdehyde dehydrogenase was prepared from pea seedlings. The optimum pH and Km values for the substrates were determined, and the substrate and coenzyme specificities of this enzyme were examined.

Effects of various compounds on aspartic β-semialdehyde dehydrogenase prepared from pea seedlings were examined. From the behaviours toward thioglycolate and PCMB, this enzyme was concluded to be a -SH enzyme. The inhibitory effects of aldehydes and amino acids were also studied.     

Molecular Framework of Steroid/Retinoid Discrimination in 17β-Hydroxysteroid Dehydrogenase Type 1 and Photoreceptor-associated Retinol Dehydrogenase

Steroids and retinoids are signaling molecules that control a variety of physiological processes. 17β-Hydroxysteroid dehydrogenase type 1 (17β-HSD1) catalyzes the reduction of estrone to estradiol, supplying biologically active estrogen-regulating sex-specific differentiation. Photoreceptor-associated retinol dehydrogenase (prRDH) is evolutionarily closely related to 17β-HSD1 but reduces all-trans retinal to all-trans retinol, contributing to rhodopsin regeneration in the visual cycle. Sequence alignment revealed a new enzyme-specific conserved amino acid close to the active site: methionine (position 144 in human enzyme) in prRDH and glycine (position 145) in 17β-HSD1. We investigated the role of this residue in substrate discrimination in human and zebrafish enzymes. Both recombinant enzymes were expressed in HEK 293 cells followed by normalization of expression by semiquantitative Western blots. Changing of the prRDH-specific methionine to glycine resulted in a gain of function: the mutants now catalyzed the reduction of estrone and all-trans retinal. Human and zebrafish wild-type 17β-HSD1s efficiently catalyzed the reduction of all-trans retinal to its alcohol. Exchange of glycine for methionine increased the catalytic activity of 17β-HSD1 toward all-trans retinal in zebrafish but not in the human enzyme, in which the opposite effect was observed. Molecular modeling showed that the zebrafish 17β-HSD1 substrate-binding pocket is similar to that of prRDH and methionine insertion benefits all-trans retinal reduction. In contrast, in human 17β-HSD1, the insertion of the bulky methionine causes a disruption of substrate-binding site. We demonstrate for the first time the role of a single amino acid in the evolution of these functionally diverse enzymes and suggest new physiological functions for 17β-HSD1 in retinoid metabolism. This has implications for the validation of inhibitors of 17β-HSD1 developed for cancer treatment.     

α-Ketoglutarate abrogates the nuclear localization of HIF-1α in aluminum-exposed hepatocytes

Aluminum (Al), a known environmental pollutant, has been linked to numerous pathologies such as Alzheimer's disease and anaemia. In this study, we show that α-ketoglutarate (KG) mitigates the Al-mediated nuclear accumulation of hypoxia inducible factor-1α (HIF-1α) in cultured human hepatocytes (HepG2). The nuclear localization of HIF-1α appeared to be triggered by the Al-induced perturbation of prolyl hydroxylase 2 (PHD2). This enzyme was markedly diminished in the Al-challenged hepatocytes. The fate of PHD2 and HIF-1α was intricately linked to the mitochondrial dysfunction observed during Al stress. BN-PAGE, immunoblot, and HPLC revealed that the loss of α-ketoglutarate dehydrogenase (KGDH) and succinate dehydrogenase (SDH) activities were coupled to the accumulation of succinate. However, the treatment of the Al-stressed cells with KG recovered the activity and expression of KGDH, SDH, and PHD2 with a concomitant decrease in the levels of HIF-1α in the nucleus. Taken together, these data indicate that the homeostasis of KG plays a pivotal role in aerobic and anaerobic respiration.     

In Vivo Validation of In Silico Predicted Metabolic Engineering Strategies in Yeast: Disruption of α-Ketoglutarate Dehydrogenase and Expression of ATP-Citrate Lyase for Terpenoid Production

Background

Engineering of the central carbon metabolism of Saccharomyces cerevisiae to redirect metabolic flux towards cytosolic acetyl-CoA has become a central topic in yeast biotechnology. A cell factory with increased flux into acetyl-CoA can be used for heterologous production of terpenoids for pharmaceuticals, biofuels, fragrances, or other acetyl-CoA derived compounds. In a previous study, we identified promising metabolic engineering targets in S. cerevisiae using an in silico stoichiometric metabolic network analysis. Here, we validate selected in silico strategies in vivo.

Results

Patchoulol was produced by yeast via a heterologous patchoulol synthase of Pogostemon cablin. To increase the metabolic flux from acetyl-CoA towards patchoulol, a truncated HMG-CoA reductase was overexpressed and farnesyl diphosphate synthase was fused with patchoulol synthase. The highest increase in production could be achieved by modifying the carbon source; sesquiterpenoid titer increased from glucose to ethanol by a factor of 8.4. Two strategies predicted in silico were chosen for validation in this work. Disruption of α-ketoglutarate dehydrogenase gene (KGD1) was predicted to redirect the metabolic flux via the pyruvate dehydrogenase bypass towards acetyl-CoA. The metabolic flux was redirected as predicted, however, the effect was dependent on cultivation conditions and the flux was interrupted at the level of acetate. High amounts of acetate were produced. As an alternative pathway to synthesize cytosolic acetyl-CoA, ATP-citrate lyase was expressed as a polycistronic construct, however, in vivo performance of the enzyme needs to be optimized to increase terpenoid production.

Conclusions

Stoichiometric metabolic network analysis can be used successfully as a metabolic prediction tool. However, this study highlights that kinetics, regulation and cultivation conditions may interfere, resulting in poor in vivo performance. Main sites of regulation need to be released and improved enzymes are essential to meet the required activities for an increased product formation in vivo.     

Uptake of α-Ketoglutarate by Citrate Transporter CitP Drives Transamination in Lactococcus lactis

Transamination is the first step in the conversion of amino acids into aroma compounds by lactic acid bacteria (LAB) used in food fermentations. The process is limited by the availability of α-ketoglutarate, which is the best α-keto donor for transaminases in LAB. Here, uptake of α-ketoglutarate by the citrate transporter CitP is reported. Cells of Lactococcus lactis IL1403 expressing CitP showed significant levels of transamination activity in the presence of α-ketoglutarate and one of the amino acids Ile, Leu, Val, Phe, or Met, while the same cells lacking CitP showed transamination activity only after permeabilization of the cell membrane. Moreover, the transamination activity of the cells followed the levels of CitP in a controlled expression system. The involvement of CitP in the uptake of the α-keto donor was further demonstrated by the increased consumption rate in the presence of l-lactate, which drives CitP in the fast exchange mode of transport. Transamination is the only active pathway for the conversion of α-ketoglutarate in IL1403; a stoichiometric conversion to glutamate and the corresponding α-keto acid from the amino acids was observed. The transamination activity by both the cells and the cytoplasmic fraction showed a remarkably flat pH profile over the range from pH 5 to pH 8, especially with the branched-chain amino acids. Further metabolism of the produced α-keto acids into α-hydroxy acids and other flavor compounds required the coupling of transamination to glycolysis. The results suggest a much broader role of the citrate transporter CitP in LAB than citrate uptake in the citrate fermentation pathway alone.     

Tissue-Specific Increases in 11β-Hydroxysteroid Dehydrogenase Type 1 in Normal Weight Postmenopausal Women

With age and menopause there is a shift in adipose distribution from gluteo-femoral to abdominal depots in women. Associated with this redistribution of fat are increased risks of type 2 diabetes and cardiovascular disease. Glucocorticoids influence body composition, and 11β-hydroxysteroid dehydrogenase type 1 (11βHSD1) which converts inert cortisone to active cortisol is a putative key mediator of metabolic complications in obesity. Increased 11βHSD1 in adipose tissue may contribute to postmenopausal central obesity. We hypothesized that tissue-specific 11βHSD1 gene expression and activity are up-regulated in the older, postmenopausal women compared to young, premenopausal women. Twenty-three pre- and 23 postmenopausal, healthy, normal weight women were recruited. The participants underwent a urine collection, a subcutaneous adipose tissue biopsy and the hepatic 11βHSD1 activity was estimated by the serum cortisol response after an oral dose of cortisone. Urinary (5α-tetrahydrocortisol+5β-tetrahydrocortisol)/tetrahydrocortisone ratios were higher in postmenopausal women versus premenopausal women in luteal phase (P<0.05), indicating an increased whole-body 11βHSD1 activity. Postmenopausal women had higher 11βHSD1 gene expression in subcutaneous fat (P<0.05). Hepatic first pass conversion of oral cortisone to cortisol was also increased in postmenopausal women versus premenopausal women in follicular phase of the menstrual cycle (P<0.01, at 30 min post cortisone ingestion), suggesting higher hepatic 11βHSD1 activity. In conclusion, our results indicate that postmenopausal normal weight women have increased 11βHSD1 activity in adipose tissue and liver. This may contribute to metabolic dysfunctions with menopause and ageing in women.     

Hidden Alleles at the α-Glycerophosphate Dehydrogenase Locus in Colias Butterflies

By varying polyacrylamide gel pore size, the alpha-glycerophosphate dehydrogenase locus of Colias butterflies is shown to contain at least five alkeles, rather than the two which had been reported previously. Two of the alleles have the same apparent net charge, and presumably are detected electrophoretically because of the conformational differences. Additional variation occurs in the isoelectric points of the proteins. It is suggested that electrophoresis employing a single gel of intermediated pore size will fail to discriminate between many alleles, and that the concept of electrophoretic alleles as differing simply in charge may not always be appropriate.     

Subcellular Localization and Properties of L-Galactono-γ-lactone Dehydrogenase in Spinach Leaves

L-Galactono-γ-lactone dehydrogenase, which catalyzes the final step of the biosynthesis of L-ascorbate, is bound to spinach mitochondrial membrane, as confirmed by linear sucrose density gradient centrifugation. The solubilized enzyme was very labile, but stabilized in the presence of L-galactono-γ-lactone under anaerobic conditions. The enzyme reduced cytochrome c and phenazine methosulfate in the presence of L-galactono-γ-lactone, but not when L-gulono-γ-lactone was used as an electron donor. The K_ms of the enzyme for L-galactono-γ-lactone and cytochrome c were 192 μM and 180 μM, respectively.     

Circadian Variations in the Activities of 6‐Phosphogluconate Dehydrogenase and Glucose‐6‐Phosphate Dehydrogenase in the Liver of Conrol and Streptozotocin‐Induced Diabetic Rats

The aim of this study was to examine: the 24 h variation of 6‐phosphogluconate dehydrogenase and glucose‐6‐phosphate dehydrogenase activities, key enzymes for the maintenance of intracellular NADPH concentration, in rat liver in control and streptozotocin‐induced diabetic animals. Adult male rats were fed ad libitum and synchronized on a 12:12 h light‐dark cycle (lights on 08:00 h). One group of animals was treated with streptozotocin (STZ, 55 mg/kg, intraperitoneal) to induce experimental diabetes. Eight weeks after STZ injection, the animals were sacrificed at six different times of day—1, 5, 9, 13, 17 and 21 Hours After Lights On (HALO)—and livers were obtained. Enzyme activities were determined spectrophotometrically in triplicate in liver homogenates and expressed as units per mg protein. 6‐phosphogluconate dehydrogenase activity was measured by substituting 6‐phosphogluconate as substrate. Glucose‐6‐phosphate dehydrogenase activity was determined by monitoring NADPH production. Treatment, circadian time, and interaction between treatment and circadian time factors were tested by either one or two way analysis of variance (ANOVA). Two‐way ANOVA revealed that 6‐phosphogluconate dehydrogenase activity significantly depended on both the treatment and time of sacrifice. 6‐phosphogluconate dehydrogenase activity was higher in control than diabetic animals; whereas, glucose‐6‐phosphate dehydrogenase activity did not vary over the 24 h in animals made diabetic by STZ treatment. Circadian variation in the activity of 6‐phosphogluconate dehydrogenase was also detected in both the control and STZ treatment groups (one‐way ANOVA). Time‐dependent variation in glucose‐6‐phosphate dehydrogenase activity during the 24 h was detected in control but not in diabetic rats. No significant interaction was detected between STZ‐treatment and time of sacrifice for both hepatic enzyme activities. These results suggest that the activities of NADPH‐generating enzymes exhibit 24 h variation, which is not influenced by diabetes.     

Ontogenesis of Oxidative Reaction of 17β-hydroxysteroid Dehydrogenase and 11β-hydroxysteroid Dehydrogenase in Rat Leydig Cells, a Histochemical Study

The enzyme 17β-hydroxysteroid dehydrogenase is required for the synthesis and 11β-hydroxysteroid dehydrogenase for the regulation of androgens in rat Leydig cells. This histochemical study describes ontogenetic changes in distribution and intensity of these enzymes in Leydig cells from postnatal day (pnd) 1–90. Using NAD or NADP as the cofactor, 17β-hydroxysteroid dehydrogenase (substrate: 5-androstene-3β, 17β-diol) peaks were observed on pnd 16 for fetal Leydig cells and on pnd 19 and 37 for adult Leydig cells. Between pnd 13 and 25 the fetal cells showed a higher intensity for the 17β-enzyme than the adult cells; more fetal Leydig cells were stained with NADP, whereas more adult cells were positive with NAD on pnd 13 and 16. A nearly identical distribution of 11β-hydroxysteroid dehydrogenase (substrate: corticosterone) was observed with NAD or NADP as the cofactor; the reaction was present from pnd 31 onwards, first in a few adult Leydig cells and later in almost all these cells homogeneously. The ontogenetic curves of the two enzymes show an inverse relationship. To conclude: (1) Generally, a stronger reaction for 17β-hydroxysteroid dehydrogenase is shown with NAD as cofactor than with NADP; using NADP, fetal Leydig cells show a stronger staining than adult Leydig cells. (2) The data possibly support the notion of a new isoform of 11β -hydroxysteroid dehydrogenase in addition to types 1 and 2.     

Distribution of ω-Amino Acid: Pyruvate Transaminase and Aminobutyrate: α-Ketoglutarate Transaminase in Microorganisms

The distribution of ω-amino acid transaminases in microorganisms was investigated, ω-Amino acid: pyruvate transaminase (ω-APT) was found in bacteria and yeasts, but not in actinomycetes and fungi. On the contrary, aminobutyrate: α-ketoglutarate transaminase (GABA-T) was shown in most of the microorganisms from bacteria to fungi. β-Alanine is a preferred amino donor for the co-APT reaction. Although bacterial and yeast GABA-T are inactive for β-alanine, fungal and actinomycete enzymes react with this compound and γ-aminobutyrate. In comparing these results with those of plant and mammalian enzymes, two different pathways of co-amino acid metabolism are suggested for bacteria, yeast and plants, i.e. one for β-alanine and the other for γ-aminobutyrate, catalyzed by ω-APT and GABA-T, respectively. In actinomycetes, fungi, and mammals GABA-T may be involved in the metabolism of both ω-amino acids. In addition, evolutionary changes of ω-amino acid transaminases are discussed.     

The Krebs Cycle Enzyme α-Ketoglutarate Decarboxylase Is an Essential Glycosomal Protein in Bloodstream African Trypanosomes

α-Ketoglutarate decarboxylase (α-KDE1) is a Krebs cycle enzyme found in the mitochondrion of the procyclic form (PF) of Trypanosoma brucei. The bloodstream form (BF) of T. brucei lacks a functional Krebs cycle and relies exclusively on glycolysis for ATP production. Despite the lack of a functional Krebs cycle, α-KDE1 was expressed in BF T. brucei and RNA interference knockdown of α-KDE1 mRNA resulted in rapid growth arrest and killing. Cell death was preceded by progressive swelling of the flagellar pocket as a consequence of recruitment of both flagellar and plasma membranes into the pocket. BF T. brucei expressing an epitope-tagged copy of α-KDE1 showed localization to glycosomes and not the mitochondrion. We used a cell line transfected with a reporter construct containing the N-terminal sequence of α-KDE1 fused to green fluorescent protein to examine the requirements for glycosome targeting. We found that the N-terminal 18 amino acids of α-KDE1 contain overlapping mitochondrion- and peroxisome-targeting sequences and are sufficient to direct localization to the glycosome in BF T. brucei. These results suggest that α-KDE1 has a novel moonlighting function outside the mitochondrion in BF T. brucei.     

α-Ketoglutarate dehydrogenase: a mitochondrial redox sensor

α-Ketoglutarate dehydrogenase (KGDH), a key regulatory enzyme within the Krebs cycle, is sensitive to mitochondrial redox status. Treatment of mitochondria with H?O? results in reversible inhibition of KGDH due to glutathionylation of the cofactor, lipoic acid. Upon consumption of H?O?, glutathione is removed by glutaredoxin restoring KGDH activity. Glutathionylation appears to be enzymatically catalysed or require a unique microenvironment. This may represent an antioxidant response, diminishing the flow of electrons to the respiratory chain and protecting sulphydryl residues from oxidative damage. KGDH is, however, also susceptible to oxidative damage. 4-Hydroxy-2-nonenal (HNE), a lipid peroxidation product, reacts with lipoic acid resulting in enzyme inactivation. Evidence indicates that HNE modified lipoic acid is cleaved from KGDH, potentially the first step of a repair process. KGDH is therefore a likely redox sensor, reversibly altering metabolism to reduce oxidative damage and, under severe oxidative stress, acting as a sentinel of mitochondrial viability.     

Evidence for Hysteretic Substrate Channeling in the Proline Dehydrogenase and Δ1-Pyrroline-5-carboxylate Dehydrogenase Coupled Reaction of Proline Utilization A (PutA)

PutA (proline utilization A) is a large bifunctional flavoenzyme with proline dehydrogenase (PRODH) and Δ¹-pyrroline-5-carboxylate dehydrogenase (P5CDH) domains that catalyze the oxidation of l-proline to l-glutamate in two successive reactions. In the PRODH active site, proline undergoes a two-electron oxidation to Δ¹-pyrroline-5-carboxlylate, and the FAD cofactor is reduced. In the P5CDH active site, l-glutamate-γ-semialdehyde (the hydrolyzed form of Δ¹-pyrroline-5-carboxylate) undergoes a two-electron oxidation in which a hydride is transferred to NAD⁺-producing NADH and glutamate. Here we report the first kinetic model for the overall PRODH-P5CDH reaction of a PutA enzyme. Global analysis of steady-state and transient kinetic data for the PRODH, P5CDH, and coupled PRODH-P5CDH reactions was used to test various models describing the conversion of proline to glutamate by Escherichia coli PutA. The coupled PRODH-P5CDH activity of PutA is best described by a mechanism in which the intermediate is not released into the bulk medium, i.e., substrate channeling. Unexpectedly, single-turnover kinetic experiments of the coupled PRODH-P5CDH reaction revealed that the rate of NADH formation is 20-fold slower than the steady-state turnover number for the overall reaction, implying that catalytic cycling speeds up throughput. We show that the limiting rate constant observed for NADH formation in the first turnover increases by almost 40-fold after multiple turnovers, achieving half of the steady-state value after 15 turnovers. These results suggest that EcPutA achieves an activated channeling state during the approach to steady state and is thus a new example of a hysteretic enzyme. Potential underlying causes of activation of channeling are discussed.     

Artefacts in cell culture: α-Ketoglutarate can scavenge hydrogen peroxide generated by ascorbate and epigallocatechin gallate in cell culture media

Ascorbate and several phenolic compounds readily oxidise in cell culture media to generate hydrogen peroxide. However, addition of α-ketoglutarate, which is known to be released by several cell types, decreased the levels of H₂O₂, and the α-ketoglutarate was depleted and converted to succinate. These observations could account for previous reports of the protective effects of α-ketoglutarate in promoting the growth of cells in culture, and may contribute to explaining some of the variability in the literature in reported rates of H₂O₂ production from autoxidisable compounds in cell culture systems.