Untangling the glutamate dehydrogenase allosteric nightmare

Glutamate dehydrogenase (GDH) is found in all living organisms, but only animal GDH is regulated by a large repertoire of metabolites. More than 50 years of research to better understand the mechanism and role of this allosteric network has been frustrated by its sheer complexity. However, recent studies have begun to tease out how and why this complex behavior evolved. Much of GDH regulation probably occurs by controlling a complex ballet of motion necessary for catalytic turnover and has evolved concomitantly with a long antenna-like feature of the structure of the enzyme. Ciliates, the 'missing link' in GDH evolution, might have created the antenna to accommodate changing organelle functions and was refined in humans to, at least in part, link amino acid catabolism with insulin secretion.     

The structure and allosteric regulation of glutamate dehydrogenase

Glutamate dehydrogenase (GDH) has been extensively studied for more than 50 years. Of particular interest is the fact that, while considered by most to be a ‘housekeeping’ enzyme, the animal form of GDH is heavily regulated by a wide array of allosteric effectors and exhibits extensive inter-subunit communication. While the chemical mechanism for GDH has remained unchanged through epochs of evolution, it was not clear how or why animals needed to evolve such a finely tuned form of this enzyme. As reviewed here, recent studies have begun to elucidate these issues. Allosteric regulation first appears in the Ciliates and may have arisen to accommodate evolutionary changes in organelle function. The occurrence of allosteric regulation appears to be coincident with the formation of an ‘antenna’ like feature rising off the tops of the subunits that may be necessary to facilitate regulation. In animals, this regulation further evolved as GDH became integrated into a number of other regulatory pathways. In particular, mutations in GDH that abrogate GTP inhibition result in dangerously high serum levels of insulin and ammonium. Therefore, allosteric regulation of GDH plays an important role in insulin homeostasis. Finally, several compounds have been identified that block GDH-mediated insulin secretion that may be to not only find use in treating these insulin disorders but to kill tumors that require glutamine metabolism for cellular energy.     

Overexpression of constitutively activated glutamate dehydrogenase induces insulin secretion through enhanced glutamate oxidation

Glutamate dehydrogenase (GDH) catalyzes reversible oxidative deamination of l-glutamate to alpha-ketoglutarate. Enzyme activity is regulated by several allosteric effectors. Recognition of a new form of hyperinsulinemic hypoglycemia, hyperinsulinism/hyperammonemia (HI/HA) syndrome, which is caused by gain-of-function mutations in GDH, highlighted the importance of GDH in glucose homeostasis. GDH266C is a constitutively activated mutant enzyme we identified in a patient with HI/HA syndrome. By overexpressing GDH266C in MIN6 mouse insulinoma cells, we previously demonstrated unregulated elevation of GDH activity to render the cells responsive to glutamine in insulin secretion. Interestingly, at low glucose concentrations, basal insulin secretion was exaggerated in such cells. Herein, to clarify the role of GDH in the regulation of insulin secretion, we studied cellular glutamate metabolism using MIN6 cells overexpressing GDH266C (MIN6-GDH266C). Glutamine-stimulated insulin secretion was associated with increased glutamine oxidation and decreased intracellular glutamate content. Similarly, at 5 mmol/l glucose without glutamine, glutamine oxidation also increased, and glutamate content decreased with exaggerated insulin secretion. Glucose oxidation was not altered. Insulin secretion profiles from GDH266C-overexpressing isolated rat pancreatic islets were similar to those from MIN6-GDH266C, suggesting observation in MIN6 cells to be relevant in native beta-cells. These results demonstrate that, upon activation, GDH oxidizes glutamate to alpha-ketoglutarate, thereby stimulating insulin secretion by providing the TCA cycle with a substrate. No evidence was obtained supporting the hypothesis that activated GDH produced glutamate, a recently proposed second messenger of insulin secretion, by the reverse reaction, to stimulate insulin secretion.     

Structural basis for leucine-induced allosteric activation of glutamate dehydrogenase

Glutamate dehydrogenase (GDH) catalyzes reversible conversion between glutamate and 2-oxoglutarate using NAD(P)(H) as a coenzyme. Although mammalian GDH is regulated by GTP through the antenna domain, little is known about the mechanism of allosteric activation by leucine. An extremely thermophilic bacterium, Thermus thermophilus, possesses GDH with a unique subunit configuration composed of two different subunits, GdhA (regulatory subunit) and GdhB (catalytic subunit). T. thermophilus GDH is unique in that the enzyme is subject to allosteric activation by leucine. To elucidate the structural basis for leucine-induced allosteric activation of GDH, we determined the crystal structures of the GdhB-Glu and GdhA-GdhB-Leu complexes at 2.1 and 2.6 Å resolution, respectively. The GdhB-Glu complex is a hexamer that binds 12 glutamate molecules: six molecules are bound at the substrate-binding sites, and the remaining six are bound at subunit interfaces, each composed of three subunits. The GdhA-GdhB-Leu complex is crystallized as a heterohexamer composed of four GdhA subunits and two GdhB subunits. In this complex, six leucine molecules are bound at subunit interfaces identified as glutamate-binding sites in the GdhB-Glu complex. Consistent with the structure, replacement of the amino acid residues of T. thermophilus GDH responsible for leucine binding made T. thermophilus GDH insensitive to leucine. Equivalent amino acid replacement caused a similar loss of sensitivity to leucine in human GDH2, suggesting that human GDH2 also uses the same allosteric site for regulation by leucine.     

From pancreatic islets to central nervous system, the importance of glutamate dehydrogenase for the control of energy homeostasis

Glutamate dehydrogenase (GDH) is a mitochondrial enzyme linking the Krebs cycle to the multifunctional amino acid glutamate. Thereby, GDH plays a pivotal role between carbohydrate and protein metabolisms, controlling production and consumption of the messenger molecule glutamate in neuroendocrine cells. GDH activity is under the control of several regulators, conferring to this enzyme energy-sensor property. Indeed, GDH directly depends on the provision of the co-factor NADH/NAD⁺, rendering the enzyme sensitive to the redox status of the cell. Moreover, GDH is allosterically regulated by GTP and ADP. GDH is also regulated by ADP-ribosylation, mediated by a member of the energy-sensor family sirtuins, namely SIRT4. In the brain, GDH ensures the cycling of the neurotransmitter glutamate between neurons and astrocytes. GDH also controls ammonia metabolism and detoxification, mainly in the liver and kidney. In pancreatic β-cells, the importance of GDH as a key enzyme in the regulation of insulin secretion is now well established. Inhibition of GDH activity decreases insulin release, while activating mutations are associated with a hyperinsulinism syndrome. Although GDH enzyme catalyzes the same reaction in every tissue, its function regarding metabolic homeostasis varies greatly according to specific organs. In this review, we will discuss specificities of GDH regulation in neuroendocrine cells, in particular pancreatic islets and central nervous system.     

Two genetic forms of hyperinsulinemic hypoglycemia caused by dysregulation of glutamate dehydrogenase

Glutamate dehydrogenase (GDH) has recently been shown to be involved in two genetic disorders of hyperinsulinemic hypoglycemia in children. These include the hyperinsulinism/hyperammonemia syndrome caused by dominant activating mutations of GLUD1 which interfere with inhibitory regulation by GTP and hyperinsulinism due to recessive deficiency of short-chain 3-hydroxy-acyl-CoA dehydrogenase (SCHAD, encoded by HADH1). The clinical manifestations of the abnormalities in pancreatic ß-cell insulin regulation include fasting hypoglycemia, as well as protein-sensitive hypoglycemia. The latter is due to abnormally increased sensitivity of affected children to stimulation of insulin secretion by the amino acid, leucine. In patients with GDH activating mutations, mild hyperammonemia occurs in both the basal and protein-fed state, possibly due to increased renal ammoniagenesis. Some patients with GDH activating mutations appear to be at unusual risk of developmental delay and generalized epilepsy, perhaps reflecting consequences of increased GDH activity in the brain. Studies of these two disorders have been carried out in mouse models to define the mechanisms of insulin dysregulation. In SCHAD deficiency, the activation of GDH is due to loss of a direct inhibitory protein-protein interaction between SCHAD and GDH. These two novel human disorders demonstrate the important role of GDH in insulin regulation and illustrate unexpectedly important reasons for the unusually complex allosteric regulation of GDH.     

Structural studies on ADP activation of mammalian glutamate dehydrogenase and the evolution of regulation

Glutamate dehydrogenase (GDH) is found in all organisms and catalyzes the reversible oxidative deamination of L-glutamate to 2-oxoglutarate. Unlike GDH from bacteria, mammalian GDH exhibits negative cooperativity with respect to coenzyme, activation by ADP, and inhibition by GTP. Presented here are the structures of apo bovine GDH, bovine GDH complexed with ADP, and the R463A mutant form of human GDH (huGDH) that is insensitive to ADP activation. In the absence of active site ligands, the catalytic cleft is in the open conformation, and the hexamers form long polymers in the crystal cell with more interactions than found in the abortive complex crystals. This is consistent with the fact that ADP promotes aggregation in solution. ADP is shown to bind to the second, inhibitory, NADH site yet causes activation. The beta-phosphates of the bound ADP interact with R459 (R463 in huGDH) on the pivot helix. The structure of the ADP-resistant, R463A mutant of human GDH is identical to native GDH with the exception of the truncated side chain on the pivot helix. Together, these results strongly suggest that ADP activates by facilitating the opening of the catalytic cleft. From alignment of GDH from various sources, it is likely that the antenna evolved in the protista prior to the formation of purine regulatory sites. This suggests that there was some selective advantage of the antenna itself and that animals evolved new functions for GDH through the addition of allosteric regulation.     

Glutamate dehydrogenase in brain mitochondria: do lipid modifications and transient metabolon formation influence enzyme activity?

Metabolism of glutamate, the primary excitatory neurotransmitter in brain, is complex and of paramount importance to overall brain function. Thus, understanding the regulation of enzymes involved in formation and disposal of glutamate and related metabolites is crucial to understanding glutamate metabolism. Glutamate dehydrogenase (GDH) is a pivotal enzyme that links amino acid metabolism and TCA cycle activity in brain and other tissues. The allosteric regulation of GDH has been extensively studied and characterized. Less is known about the influence of lipid modifications on GDH activity, and the participation of GDH in transient heteroenzyme complexes (metabolons) that can greatly influence metabolism by altering kinetic parameters and lead to channeling of metabolites. This review summarizes evidence for palmitoylation and acylation of GDH, information on protein binding, and information regarding the participation of GDH in transient heteroenzyme complexes. Recent studies suggest that a number of other proteins can bind to GDH altering activity and overall metabolism. It is likely that these modifications and interactions contribute additional levels of regulation of GDH activity and glutamate metabolism.     

Green tea polyphenols modulate insulin secretion by inhibiting glutamate dehydrogenase

Insulin secretion by pancreatic beta-cells is stimulated by glucose, amino acids, and other metabolic fuels. Glutamate dehydrogenase (GDH) has been shown to play a regulatory role in this process. The importance of GDH was underscored by features of hyperinsulinemia/hyperammonemia syndrome, where a dominant mutation causes the loss of inhibition by GTP and ATP. Here we report the effects of green tea polyphenols on GDH and insulin secretion. Of the four compounds tested, epigallocatechin gallate (EGCG) and epicatechin gallate were found to inhibit GDH with nanomolar ED(50) values and were therefore found to be as potent as the physiologically important inhibitor GTP. Furthermore, we have demonstrated that EGCG inhibits BCH-stimulated insulin secretion, a process that is mediated by GDH, under conditions where GDH is no longer inhibited by high energy metabolites. EGCG does not affect glucose-stimulated insulin secretion under high energy conditions where GDH is probably fully inhibited. We have further shown that these compounds act in an allosteric manner independent of their antioxidant activity and that the beta-cell stimulatory effects are directly correlated with glutamine oxidation. These results demonstrate that EGCG, much like the activator of GDH (BCH), can facilitate dissecting the complex regulation of insulin secretion by pharmacologically modulating the effects of GDH.     

High throughput screening reveals several new classes of glutamate dehydrogenase inhibitors

Glutamate dehydrogenase (GDH) has been shown to play a regulatory role in insulin secretion by pancreatic beta-cells. The most compelling evidence of this comes from features of the hyperinsulism/hyperammonemia (HI/HA) syndrome where a dominant mutation causes the loss of inhibition by GTP, and from studies that link leucine (and its analogue BCH) activation of GDH to stimulation of insulin secretion. This suggests that GDH may represent a new and novel drug target to control a variety of insulin disorders. Recently we demonstrated that a subset of green tea polyphenols are potent inhibitors of glutamate dehydrogenase in vitro and can efficaciously block BCH stimulation of insulin secretion. In these current studies, we extend our search for GDH inhibitors using high throughput methods to pan through more than 27,000 compounds. A number of known and new inhibitors were identified with IC50s in the low micromolar range. These new inhibitors were found to act via apparently different mechanisms with some inhibiting the reaction in a positively cooperative manner, the inhibition by only some of the compounds was reversed by ADP, and one compound was found to stabilize the enzyme against thermal denaturation. Therefore, these new compounds not only are new leads in the treatment of hyperactive GDH but also are useful in dissecting the complex allosteric nature of the enzyme.     

The structure of bovine glutamate dehydrogenase provides insights into the mechanism of allostery.

BACKGROUND: Bovine glutamate dehydrogenase (boGDH) is a homohexameric, mitochondrial enzyme that reversibly catalyzes the oxidative deamination of L-glutamate to 2-oxoglutarate using either NADP(H) or NAD(H) with comparable efficacy. GDH represents a key enzymatic link between catabolic and biosynthetic pathways, and is therefore ubiquitous in both higher and lower organisms. Only mammalian GDH exhibits strong negative cooperativity with respect to the coenzyme, however, and is regulated by a large number of allosteric effectors. RESULTS: The atomic structure of boGDH in complex with NADH, glutamate, and the allosteric inhibitor GTP has been determined to 2.8 A resolution. The major difference between the bacterial and bovine GDH structures is the presence of an additional 'antenna' in boGDH that protrudes from each trimer, twisting counterclockwise along the threefold axis. NADH and glutamate are clearly observed in the active site, but the contacts differ slightly from those observed in Clostridium symbiosum GDH. A second, inhibitory NADH molecule lies buried in the core of the hexamer. Finally, two GTP molecules bind near the hinge region connecting the NAD(+)- and glutamate-binding domains. CONCLUSIONS: We propose that the antenna serves as an intersubunit communication conduit during negative cooperativity and allosteric regulation. GTP and NADH inhibit GDH by keeping the catalytic cleft in a closed conformation. In contrast, ADP probably binds to the back of the NAD(+)-binding domain and activates the enzyme by keeping the catalytic cleft open. Extensive contacts between antennae within the crystal lattice may represent hexamer interactions in solution and, perhaps, with other enzymes within the mitochondrial matrix.     

Epigallocatechin-3-gallate (EGCG) activates AMPK through the inhibition of glutamate dehydrogenase in muscle and pancreatic ß-cells: A potential beneficial effect in the pre-diabetic state?

Glucose homeostasis is determined by insulin secretion from the ß-cells in pancreatic islets and by glucose uptake in skeletal muscle and other insulin target tissues. While glutamate dehydrogenase (GDH) senses mitochondrial energy supply and regulates insulin secretion, its role in the muscle has not been elucidated. Here we investigated the possible interplay between GDH and the cytosolic energy sensing enzyme 5′-AMP kinase (AMPK), in both isolated islets and myotubes from mice and humans. The green tea polyphenol epigallocatechin-3-gallate (EGCG) was used to inhibit GDH. Insulin secretion was reduced by EGCG upon glucose stimulation and blocked in response to glutamine combined with the allosteric GDH activator BCH (2-aminobicyclo-[2,2,1] heptane-2-carboxylic acid). Insulin secretion was similarly decreased in islets of mice with ß-cell-targeted deletion of GDH (ßGlud1^−/−). EGCG did not further reduce insulin secretion in the mutant islets, validating its specificity. In human islets, EGCG attenuated both basal and nutrient-stimulated insulin secretion. Glutamine/BCH-induced lowering of AMPK phosphorylation did not operate in ßGlud1^−/− islets and was similarly prevented by EGCG in control islets, while high glucose systematically inactivated AMPK. In mouse C2C12 myotubes, like in islets, the inhibition of AMPK following GDH activation with glutamine/BCH was reversed by EGCG. Stimulation of GDH in primary human myotubes caused lowering of insulin-induced 2-deoxy-glucose uptake, partially counteracted by EGCG. Thus, mitochondrial energy provision through anaplerotic input via GDH influences the activity of the cytosolic energy sensor AMPK. EGCG may be useful in obesity by resensitizing insulin-resistant muscle while blunting hypersecretion of insulin in hypermetabolic states.     

NADP-glutamate dehydrogenase isoenzymes of Saccharomyces cerevisiae. Purification, kinetic properties, and physiological roles

In the yeast Saccharomyces cerevisiae, two NADP(+)-dependent glutamate dehydrogenases (NADP-GDHs) encoded by GDH1 and GDH3 catalyze the synthesis of glutamate from ammonium and alpha-ketoglutarate. The GDH2-encoded NAD(+)-dependent glutamate dehydrogenase degrades glutamate producing ammonium and alpha-ketoglutarate. Until very recently, it was considered that only one biosynthetic NADP-GDH was present in S. cerevisiae. This fact hindered understanding the physiological role of each isoenzyme and the mechanisms involved in alpha-ketoglutarate channeling for glutamate biosynthesis. In this study, we purified and characterized the GDH1- and GDH3-encoded NADP-GDHs; they showed different allosteric properties and rates of alpha-ketoglutarate utilization. Analysis of the relative levels of these proteins revealed that the expression of GDH1 and GDH3 is differentially regulated and depends on the nature of the carbon source. Moreover, the physiological study of mutants lacking or overexpressing GDH1 or GDH3 suggested that these genes play nonredundant physiological roles. Our results indicate that the coordinated regulation of GDH1-, GDH3-, and GDH2-encoded enzymes results in glutamate biosynthesis and balanced utilization of alpha-ketoglutarate under fermentative and respiratory conditions. The possible relevance of the duplicated NADP-GDH pathway in the adaptation to facultative metabolism is discussed.     

Making biochemistry count: life among the amino acid dehydrogenases

The guiding principle of the IAS Medal Lecture and of the research it covered was that searching mathematical analysis, depending on good measurements, must underpin sound biochemical conclusions. This was illustrated through various experiences with the amino acid dehydrogenases. Topics covered in the present article include: (i) the place of kinetic measurement in assessing the metabolic role of GDH (glutamate dehydrogenase); (ii) the discovery of complex regulatory behaviour in mammalian GDH, involving negative co-operativity in coenzyme binding; (iii) an X-ray structure solution for a bacterial GDH providing insight into catalysis; (iv) almost total positive co-operativity in glutamate binding to clostridial GDH; (v) unexpected outcomes with mutations at the catalytic aspartate site in GDH; (vi) reactive cysteine as a counting tool in the construction of hybrid oligomers to probe the basis of allosteric interaction; (vii) tryptophan-to-phenylalanine mutations in analysis of allosteric conformational change; (viii) site-directed mutagenesis to alter substrate specificity in GDH and PheDH (phenylalanine dehydrogenase); and (ix) varying strengths of binding of the 'wrong' enantiomer in engineered mutant enzymes and implications for resolution of racemates.     

Nerve tissue-specific (GLUD2) and housekeeping (GLUD1) human glutamate dehydrogenases are regulated by distinct allosteric mechanisms: implications for biologic function

Human glutamate dehydrogenase (GDH), an enzyme central to the metabolism of glutamate, is known to exist in housekeeping and nerve tissue-specific isoforms encoded by the GLUD1 and GLUD2 genes, respectively. As there is evidence that GDH function in vivo is regulated, and that regulatory mutations of human GDH are associated with metabolic abnormalities, we sought here to characterize further the functional properties of the two human isoenzymes. Each was obtained in recombinant form by expressing the corresponding cDNAs in Sf9 cells and studied with respect to its regulation by endogenous allosteric effectors, such as purine nucleotides and branched chain amino acids. Results showed that L-leucine, at 1.0 mM:, enhanced the activity of the nerve tissue-specific (GLUD2-derived) enzyme by approximately 1,600% and that of the GLUD1-derived GDH by approximately 75%. Concentrations of L-leucine similar to those present in human tissues ( approximately 0.1 mM:) had little effect on either isoenzyme. However, the presence of ADP (10-50 microM:) sensitized the two isoenzymes to L-leucine, permitting substantial enzyme activation at physiologically relevant concentrations of this amino acid. Nonactivated GLUD1 GDH was markedly inhibited by GTP (IC(50) = 0.20 microM:), whereas nonactivated GLUD2 GDH was totally insensitive to this compound (IC(50) > 5,000 microM:). In contrast, GLUD2 GDH activated by ADP and/or L-leucine was amenable to this inhibition, although at substantially higher GTP concentrations than the GLUD1 enzyme. ADP and L-leucine, acting synergistically, modified the cooperativity curves of the two isoenzymes. Kinetic studies revealed significant differences in the K:(m) values obtained for alpha-ketoglutarate and glutamate for the GLUD1- and the GLUD2-derived GDH, with the allosteric activators differentially altering these values. Hence, the activity of the two human GDH is regulated by distinct allosteric mechanisms, and these findings may have implications for the biologic functions of these isoenzymes.     

Ligand-induced changes in the conformational stability and flexibility of glutamate dehydrogenase and their role in catalysis and regulation

Bovine glutamate dehydrogenase (GDH) is allosterically regulated and requires substrate‐induced subunit interactions for maximum catalytic activity. Steady‐state and presteady‐state kinetics indicate that the rate‐limiting step depends on the nature of the substrate and are likely associated with conformational fluctuations necessary for optimal hydride transfer. Deuterated glutamate shows a steady‐state isotope effect but no effect on the presteady‐state burst rate, demonstrating that conformational effects are rate limiting for hydride transfer while product release is overall rate limiting for glutamate. Guanidine hydrochloride unfolding, heat inactivation, and differential scanning calorimetry demonstrate the effects of alternative substrates, glutamate and norvaline, on conformational stability. Glutamate has little effect on overall stability, whereas norvaline markedly stabilizes the protein. Limited proteolysis demonstrates that glutamate had a variety of effects on local flexibility, whereas norvaline significantly decreased conformational fluctuations that allow protease cleavage. Dynamic light scattering suggests that norvaline stabilizes all interfaces in the hexamer, whereas glutamate had little effect on trimer–trimer interactions. The substrate glutamate exhibits negative cooperativity and complex allosteric regulation but has only minor effects on global GDH stability, while promoting certain local conformational fluctuations. In contrast, the substrate norvaline does not show negative cooperativity or allow allosteric regulation. Instead, norvaline significantly stabilizes the enzyme and markedly slows or prevents local conformational fluctuations that are likely to be important for cooperative effects and to determine the overall rate of hydride transfer. This suggests that homotropic allosteric regulation by the enzymatic substrate involves changes in both global stability and local flexibility of the protein.     

Nerve Tissue-Specific Human Glutamate Dehydrogenase that Is Thermolabile and Highly Regulated by ADP

Abstract: Glutamate dehydrogenase (GDH), an enzyme that is central to the metabolism of glutamate, is present at high levels in the mammalian brain. Studies on human leukocytes and rat brain suggested the presence of two GDH activities differing in thermal stability and allosteric regulation, but molecular biological investigations led to the cloning of two human GDH-specific genes encoding highly homologous polypeptides. The first gene, designated GLUD1, is expressed in all tissues (housekeeping GDH), whereas the second gene, designated GLUD2, is expressed specifically in neural and testicular tissues. In this study, we obtained both GDH isoenzymes in pure form by expressing a GLUD1 cDNA and a GLUD2 cDNA in Sf9 cells and studied their properties. The enzymes generated showed comparable catalytic properties when fully activated by 1 mM ADP. However, in the absence of ADP, the nerve tissue-specific GDH showed only 5% of its maximal activity, compared with ～40% showed by the housekeeping enzyme. Low physiological levels of ADP (0.05–0.25 mM) induced a concentration-dependent enhancement of enzyme activity that was proportionally greater for the nerve tissue GDH (by 550–1,300%) than of the housekeeping enzyme (by 120–150%). Magnesium chloride (1–2 mM) inhibited the nonactivated housekeeping GDH (by 45–64%); this inhibition was reversed almost completely by ADP. In contrast, Mg²⁺ did not affect the nonstimulated nerve tissue-specific GDH, although the cation prevented much of the allosteric activation of the enzyme at low ADP levels (0.05–0.25 mM). Heat-inactivation experiments revealed that the half-life of the housekeeping and nerve tissue-specific GDH was 3.5 and 0.5 h, respectively. Hence, the nerve tissue-specific GDH is relatively thermolabile and has evolved into a highly regulated enzyme. These allosteric properties may be of importance for regulating brain glutamate fluxes in vivo under changing energy demands.     

Branched-chain Amino Acid Metabolon: INTERACTION OF GLUTAMATE DEHYDROGENASE WITH THE MITOCHONDRIAL BRANCHED-CHAIN AMINOTRANSFERASE (BCATm)*

The catabolic pathway for branched-chain amino acids includes deamination followed by oxidative decarboxylation of the deaminated product branched-chain α-keto acids, catalyzed by the mitochondrial branched-chain aminotransferase (BCATm) and branched-chain α-keto acid dehydrogenase enzyme complex (BCKDC). We found that BCATm binds to the E1 decarboxylase of BCKDC, forming a metabolon that allows channeling of branched-chain α-keto acids from BCATm to E1. The protein complex also contains glutamate dehydrogenase (GDH1), 4-nitrophenylphosphatase domain and non-neuronal SNAP25-like protein homolog 1, pyruvate carboxylase, and BCKDC kinase. GDH1 binds to the pyridoxamine 5′-phosphate (PMP) form of BCATm (PMP-BCATm) but not to the pyridoxal 5′-phosphate-BCATm and other metabolon proteins. Leucine activates GDH1, and oxidative deamination of glutamate is increased further by addition of PMP-BCATm. Isoleucine and valine are not allosteric activators of GDH1, but in the presence of 5′-phosphate-BCATm, they convert BCATm to PMP-BCATm, stimulating GDH1 activity. Sensitivity to ADP activation of GDH1 was unaffected by PMP-BCATm; however, addition of a 3 or higher molar ratio of PMP-BCATm to GDH1 protected GDH1 from GTP inhibition by 50%. Kinetic results suggest that GDH1 facilitates regeneration of the form of BCATm that binds to E1 decarboxylase of the BCKDC, promotes metabolon formation, branched-chain amino acid oxidation, and cycling of nitrogen through glutamate.     

Single amino acid substitution (G456A) in the vicinity of the GTP binding domain of human housekeeping glutamate dehydrogenase markedly attenuates GTP inhibition and abolishes the cooperative behavior of the enzyme

Human glutamate dehydrogenase (GDH) exists in two isoforms encoded by the GLUD1 and GLUD2 genes, respectively. Although the two enzymes share in their mature form all but 15 of their 505 amino acids, they differ markedly in their allosteric regulation. To identify the structural basis for these allosteric characteristics, we performed site-directed mutagenesis on the human GLUD1 gene at sites that differ from the GLUD2 gene using a cloned GLUD1 cDNA. Results showed that substitution of Ala for Gly-456, but not substitution of His for Arg-470 or Ser for Asn-498, renders the enzyme markedly resistant to GTP inhibition (IC(50) = 2.80 microm) as compared with the wild type GLUD1-derived GDH (IC(50) = 0.19 microm). The G456A mutation abolished the cooperative behavior of the enzyme, as revealed by the GTP inhibitory curves. The catalytic and kinetic properties of the G456A mutant and its activation by ADP were comparable with those of the wild type GDH. Gly-456 lies in a very tightly packed region of the GDH molecule, and its replacement by Ala may lead to steric clashes with neighboring amino acids. These, in turn, may affect the conformational state of the protein that is essential for the allosteric regulation of the enzyme by GTP.