Kinetic and homology model analysis of diaminopimelate decarboxylase from Cyanothece sp. ATCC 51142: unveiling a key enzyme in lysine biosynthesis.

Homocitrate synthase (HCS) catalyzes the first and committed step in lysine biosynthesis in many fungi and certain Archaea and is a potential target for antifungal drugs. Here we report the crystal structure of the HCS apoenzyme from Schizosaccharomyces pombe and two distinct structures of the enzyme in complex with the substrate 2-oxoglutarate (2-OG). The structures reveal that HCS forms an intertwined homodimer stabilized by domain-swapping between the N- and C-terminal domains of each monomer. The N-terminal catalytic domain is composed of a TIM barrel fold in which 2-OG binds via hydrogen bonds and coordination to the active site divalent metal ion, whereas the C-terminal domain is composed of mixed alpha/beta topology. In the structures of the HCS apoenzyme and one of the 2-OG binary complexes, a lid motif from the C-terminal domain occludes the entrance to the active site of the neighboring monomer, whereas in the second 2-OG complex the lid is disordered, suggesting that it regulates substrate access to the active site through its apparent flexibility. Mutations of the active site residues involved in 2-OG binding or implicated in acid-base catalysis impair or abolish activity in vitro and in vivo. Together, these results yield new insights into the structure and catalytic mechanism of HCSs and furnish a platform for developing HCS-selective inhibitors.

The crystal structure of the P-protein of the glycine cleavage system from Thermus thermophilus HB8 has been determined. This is the first reported crystal structure of a P-protein, and it reveals that P-proteins do not involve the alpha(2)-type active dimer universally observed in the evolutionarily related pyridoxal 5'-phosphate (PLP)-dependent enzymes. Instead, novel alphabeta-type dimers associate to form an alpha(2)beta(2) tetramer, where the alpha- and beta-subunits are structurally similar and appear to have arisen by gene duplication and subsequent divergence with a loss of one active site. The binding of PLP to the apoenzyme induces large open-closed conformational changes, with residues moving up to 13.5 A. The structure of the complex formed by the holoenzyme bound to an inhibitor, (aminooxy)acetate, suggests residues that may be responsible for substrate recognition. The molecular surface around the lipoamide-binding channel shows conservation of positively charged residues, which are possibly involved in complex formation with the H-protein. These results provide insights into the molecular basis of nonketotic hyperglycinemia.

Cystalysin is a C(beta)-S(gamma) lyase from the oral pathogen Treponema denticola catabolyzing L-cysteine to produce pyruvate, ammonia and H(2)S. With its ability to induce cell lysis, cystalysin represents a new class of pyridoxal 5'-phosphate (PLP)-dependent virulence factors. The crystal structure of cystalysin was solved at 1.9 A resolution and revealed a folding and quaternary arrangement similar to aminotransferases. Based on the active site architecture, a detailed catalytic mechanism is proposed for the catabolism of S-containing amino acid substrates yielding H(2)S and cysteine persulfide. Since no homologies were observed with known haemolysins the cytotoxicity of cystalysin is attributed to this chemical reaction. Analysis of the cystalysin-L-aminoethoxyvinylglycine (AVG) complex revealed a 'dead end' ketimine PLP derivative, resulting in a total loss of enzyme activity. Cystalysin represents an essential factor of adult periodontitis, therefore the structure of the cystalysin-AVG complex may provide the chemical basis for rational drug design.

Human liver peroxisomal alanine:glyoxylate aminotransferase (AGT) is a pyridoxal 5'-phosphate (PLP)-dependent enzyme that converts glyoxylate into glycine. AGT deficiency causes primary hyperoxaluria type 1 (PH1), a rare autosomal recessive disorder, due to a marked increase in hepatic oxalate production. Normal human AGT exists as two polymorphic variants: the major (AGT-Ma) and the minor (AGT-Mi) allele. AGT-Mi causes the PH1 disease only when combined with some mutations. In this study, the molecular basis of the synergism between AGT-Mi and F152I mutation has been investigated through a detailed biochemical characterization of AGT-Mi and the Phe(152) variants combined either with the major (F152I-Ma, F152A-Ma) or the minor allele (F152I-Mi). Although these species show spectral features, kinetic parameters, and PLP binding affinity similar to those of AGT-Ma, the Phe(152) variants exhibit the following differences with respect to AGT-Ma and AGT-Mi: (i) pyridoxamine 5'-phosphate (PMP) is released during the overall transamination leading to the conversion into apoenzymes, and (ii) the PMP binding affinity is at least 200-1400-fold lower. Thus, Phe(152) is not an essential residue for transaminase activity, but plays a role in selectively stabilizing the AGT-PMP complex, by a proper orientation of Trp(108), as suggested by bioinformatic analysis. These data, together with the finding that apoF152I-Mi is the only species that at physiological temperature undergoes a time-dependent inactivation and concomitant aggregation, shed light on the molecular defects resulting from the association of the F152I mutation with AGT-Mi, and allow to speculate on the responsiveness to pyridoxine therapy of PH1 patients carrying this mutation.

Acetylornithine aminotransferase (AcOAT) is one of the key enzymes involved in arginine metabolism and catalyzes the conversion of N-acetylglutamate semialdehyde to N-acetylornithine (AcOrn) in the presence of L-glutamate. It belongs to the Type I subgroup II family of pyridoxal 5'-phosphate (PLP) dependent enzymes. E. coli biosynthetic AcOAT (eAcOAT) also catalyzes the conversion of N-succinyl-L-2-amino-6-oxopimelate to N-succinyl-L,L-diaminopimelate, one of the steps in lysine biosynthesis. In view of the critical role of AcOAT in lysine and arginine biosynthesis, structural studies were initiated on the enzyme from S. typhimurium (sAcOAT). The K(m) and k(cat)/K(m) values determined with the purified sAcOAT suggested that the enzyme had much higher affinity for AcOrn than for ornithine (Orn) and was more efficient than eAcOAT. sAcOAT was inhibited by gabaculine (Gcn) with an inhibition constant (K(i)) of 7 microM and a second-order rate constant (k(2)) of 0.16 mM(-1) s(-1). sAcOAT, crystallized in the unliganded form and in the presence of Gcn or L-glutamate, diffracted to a maximum resolution of 1.90 A and contained a dimer in the asymmetric unit. The structure of unliganded sAcOAT showed significant electron density for PLP in only one of the subunits (subunit A). The asymmetry in PLP binding could be attributed to the ordering of the loop L(alphak-) (betam) in only one subunit (subunit B; the loop from subunit B comes close to the phosphate group of PLP in subunit A). Structural and spectral studies of sAcOAT with Gcn suggested that the enzyme might have a low affinity for PLP-Gcn complex. Comparison of sAcOAT with T. thermophilus AcOAT and human ornithine aminotransferase suggested that the higher specificity of sAcOAT towards AcOrn may not be due to specific changes in the active site residues but could result from minor conformational changes in some of them. This is the first structural report of AcOAT from a mesophilic organism and could serve as a basis for drug design as the enzyme is important for bacterial cell wall biosynthesis.

The final step in lysine biosynthesis in bacteria, the conversion of meso-diaminopimelate to L-lysine, is catalyzed by the only known D-amino-acid decarboxylase, diaminopimelate decarboxylase (DDC). The Escherichia coli DDC has been cloned, overexpressed in E. coli with a carboxy-terminal polyhistidine purification tag and crystallized from lithium sulfate. The protein is intensely yellow, owing to the pyridoxal-5'-phosphate cofactor, and is enzymatically active. Large well ordered crystals, belonging to space group P6(1)22 with unit-cell parameters a = b = 98.6, c = 177 A, make high-resolution X-ray diffraction studies possible to characterize the residues important in stereospecific decarboxylation and reprotonation during catalytic turnover.

The rate of porphyrin biosynthesis in mammals is controlled by the activity of the pyridoxal 5'-phosphate-dependent enzyme 5-aminolevulinate synthase (EC 2.3.1.37). Based on the postulate that turnover in this enzyme is controlled by conformational dynamics associated with a highly conserved active site loop, we constructed a variant library by targeting imperfectly conserved noncatalytic loop residues and examined the effects on product and porphyrin production. Functional loop variants of the enzyme were isolated via genetic complementation in Escherichia coli strain HU227. Colony porphyrin fluorescence varied widely when bacterial cells harboring the loop variants were grown on inductive media; this facilitated identification of clones encoding unusually active enzyme variants. Nine loop variants leading to high in vivo porphyrin production were purified and characterized kinetically. Steady state catalytic efficiencies for the two substrates were increased by up to 100-fold. Presteady state single turnover reaction data indicated that the second step of quinonoid intermediate decay, previously assigned as reaction rate-limiting, was specifically accelerated such that in three of the variants this step was no longer kinetically significant. Overall, our data support the postulate that the active site loop controls the rate of product and porphyrin production in vivo and suggest the possibility of an as yet undiscovered means of allosteric regulation.

SummaryA major nutritional drawback of many crop plants is their low content of several essential amino acids, particularly lysine. The biosynthesis of lysine in plants is regulated by several feedback loops. Dihydrodipicolinate synthase (DHPS) from Escherichia coli, a key enzyme in lysine biosynthesis, which is considerably less sensitive to lysine accumulation than the endogenous plant enzyme has been expressed in chloroplasts of tobacco leaves. Expression of the bacterial enzyme was accompanied by a significant increase in the level of free lysine. No increase in protein‐bound lysine was evident. Free lysine accumulation was positively correlated with the level of DHPS activity in various transgenic plants. Compartmentalization of DHPS in the chloroplast was essential for its participation in lysine biosynthesis as no lysine overproduction was obtained in transgenic plants that expressed the bacterial enzyme in the cytoplasm. The elevated level of free lysine in the transgenic plants was sufficient to inhibit, in vivo, a second key enzyme in lysine biosynthesis, namely, aspartate kinase, with no apparent influence on lysine accumulation. The present report not only provides a better understanding of the regulation of lysine biosynthesis in higher plants but also offers a new strategy to improve the production of this essential amino acid.

5-Aminolevulinate synthase catalyzes the pyridoxal 5'-phosphate-dependent condensation of glycine and succinyl-CoA to produce carbon dioxide, CoA, and 5-aminolevulinate, in a reaction cycle involving the mechanistically unusual successive cleavage of two amino acid substrate alpha-carbon bonds. Single and multiple turnover rapid scanning stopped-flow experiments have been conducted from pH 6.8-9.2 and 5-35 degrees C, and the results, interpreted within the framework of the recently solved crystal structures, allow refined characterization of the central kinetic and chemical steps of the reaction cycle. Quinonoid intermediate formation occurs with an apparent pK(a) of 7.7 +/- 0.1, which is assigned to His-207 acid-catalyzed decarboxylation of the alpha-amino-beta-ketoadipate intermediate to form an enol that is in rapid equilibrium with the 5-aminolevulinate-bound quinonoid species. Quinonoid intermediate decay occurs in two kinetic steps, the first of which is acid-catalyzed with a pK(a) of 8.1 +/- 0.1, and is assigned to protonation of the enol by Lys-313 to generate the product-bound external aldimine. The second step of quinonoid decay defines k(cat) and is relatively pH-independent and is assigned to opening of the active site loop to allow ALA dissociation. The data support important refinements to both the chemical and kinetic mechanisms and indicate that 5-aminolevulinate synthase operates under the stereoelectronic control predicted by Dunathan's hypothesis.

Structural basis for substrate specificity of meso-diaminopimelic acid decarboxylase from Corynebacterium glutamicum

Numerous enzymes, such as the pyridoxal 5'-phosphate (PLP)-dependent enzymes, require cofactors for their activities. Using X-ray crystallography, structural snapshots of the L-serine dehydratase catalytic reaction of a bacterial PLP-dependent enzyme were determined. In the structures, the dihedral angle between the pyridine ring and the Schiff-base linkage of PLP varied from 18° to 52°. It is proposed that the organic cofactor PLP directly catalyzes reactions by active conformational changes, and the novel catalytic mechanism involving the PLP cofactor was confirmed by high-level quantum-mechanical calculations. The conformational change was essential for nucleophilic attack of the substrate on PLP, for concerted proton transfer from the substrate to the protein and for directing carbanion formation of the substrate. Over the whole catalytic cycle, the organic cofactor catalyzes a series of reactions, like the enzyme. The conformational change of the PLP cofactor in catalysis serves as a starting point for identifying the previously unknown catalytic roles of organic cofactors.

D,L-Propargylglycine (PAG) has been widely used as a selective inhibitor to investigate the biological functions of cystathionine γ-lyase (CSE), which catalyzes the formation of reactive sulfur species (RSS). However, PAG also inhibits other PLP (pyridoxal-5′-phosphate)-dependent enzymes such as methionine γ-lyase (MGL) and L-alanine transaminase (ALT), so highly selective CSE inhibitors are still required. Here, we performed high-throughput screening (HTS) of a large chemical library and identified oxamic hydrazide 1 as a potent inhibitor of CSE (IC50 = 13 ± 1 μM (mean ± S.E.)) with high selectivity over other PLP-dependent enzymes and RSS-generating enzymes. Inhibitor 1 inhibited the enzymatic activity of human CSE in living cells, indicating that it is sufficiently membrane-permeable. X-Ray crystal structure analysis of the complex of rat CSE (rCSE) with 1 revealed that 1 forms a Schiff base linkage with the cofactor PLP in the active site of rCSE. PLP in the active site may be a promising target for development of selective inhibitors of PLP-dependent enzymes, including RSS-generating enzymes such as cystathionine β-synthase (CBS) and cysteinyl-tRNA synthetase 2 (CARS2), which have unique substrate binding pocket structures.

Extracts from Chlamydomonas, corn, soybean and tobacco were tested for enzymes of the lysine biosynthetic pathway. Dihydrodipicolinic acid (DHD) synthase, DHD reductase, diaminopimelate (DAP) epimerase and DAP decarboxylase were present in all. However, in contrast to the report of Wenko et al., meso-DAP dehydrogenase could not be detected in extracts prepared from soybean. Moreover, it was not found in Chlamydomonas, corn and tobacco as well. In order to set an upper limit to the amount of meso-DAP dehydrogenase that might be present, reconstruction experiments were performed with soybean and corn extracts in which the conversion of dihydrodipicolinate to lysine was made dependent on the addition of limited amounts of the meso-DAP dehydrogenase purified from Bacillus sphaericus. The presence of DAP epimerase and the absence of meso-DAP dehydrogenase indicates that the meso-DAP dehydrogenase abbreviated pathway for lysine synthesis is not operative in plants.

Crystal structure of an aspartate aminotransferase (TM1255) from Thermotoga maritima at 1.90 A resolution.

Dihydrodipicolinate synthase (DHDPS) catalyzes the first committed step of the lysine biosynthetic pathway. The tetrameric structure of DHDPS is thought to be essential for enzymatic activity, as isolated dimeric mutants of Escherichia coli DHDPS possess less than 2.5% that of the activity of the wild-type tetramer. It has recently been proposed that the dimeric form lacks activity due to increased dynamics. Tetramerization, by buttressing two dimers together, reduces dynamics in the dimeric unit and explains why all active bacterial DHDPS enzymes to date have been shown to be homo-tetrameric. However, in this study we demonstrate for the first time that DHDPS from methicillin-resistant Staphylococcus aureus (MRSA) exists in a monomer-dimer equilibrium in solution. Fluorescence-detected analytical ultracentrifugation was employed to show that the dimerization dissociation constant of MRSA-DHDPS is 33 nm in the absence of substrates and 29 nm in the presence of (S)-aspartate semialdehyde (ASA), but is 20-fold tighter in the presence of the substrate pyruvate (1.6 nm). The MRSA-DHDPS dimer exhibits a ping-pong kinetic mechanism (k(cat)=70+/-2 s(-1), K(m)(Pyruvate)=0.11+/-0.01 mm, and K(m)(ASA)=0.22+/-0.02 mm) and shows ASA substrate inhibition with a K(si)(ASA) of 2.7+/-0.9 mm. We also demonstrate that unlike the E. coli tetramer, the MRSA-DHDPS dimer is insensitive to lysine inhibition. The near atomic resolution (1.45 A) crystal structure confirms the dimeric quaternary structure and reveals that the dimerization interface of the MRSA enzyme is more extensive in buried surface area and noncovalent contacts than the equivalent interface in tetrameric DHDPS enzymes from other bacterial species. These data provide a detailed mechanistic insight into DHDPS catalysis and the evolution of quaternary structure of this important bacterial enzyme.