Lysine 238 is an essential residue for alpha,beta-elimination catalyzed by Treponema denticola cystalysin

Treponema denticola cystalysin is a pyridoxal 5'-phosphate (PLP) enzyme that catalyzes the alpha,beta-elimination of l-cysteine to pyruvate, ammonia, and H2S. Similar to other PLP enzymes, an active site Lys residue (Lys-238) forms an internal Schiff base with PLP. The mechanistic role of this residue has been studied by an analysis of the mutant enzymes in which Lys-238 has been replaced by Ala (K238A) and Arg (K238R). Both apomutants reconstituted with PLP bind noncovalently approximately 50% of the normal complement of the cofactor and have a lower affinity for the coenzyme than that of wild-type. Kinetic analyses of the reactions of K238A and K238R mutants with glycine compared with that of wild-type demonstrate the decrease of the rate of Schiff base formation by 103- and 7.5 x 104-fold, respectively, and, to a lesser extent, a decrease of the rate of Schiff base hydrolysis. Thus, a role of Lys-238 is to facilitate formation of external aldimine by transimination. Kinetic data reveal that the K238A mutant is inactive in the alpha,beta-elimination of l-cysteine and beta-chloro-l-alanine, whereas K238R retains 0.3% of the wild-type activity. These data, together with those derived from a spectral analysis of the reaction of Lys-238 mutants with unproductive substrate analogues, indicate that Lys-238 is an essential catalytic residue, possibly participating as a general base abstracting the Calpha-proton from the substrate and possibly as a general acid protonating the beta-leaving group.     

Crystal structure of serine dehydratase from rat liver

SDH (L-serine dehydratase, EC 4.3.1.17) catalyzes the pyridoxal 5'-phosphate (PLP)-dependent dehydration of L-serine to yield pyruvate and ammonia. Liver SDH plays an important role in gluconeogenesis. Formation of pyruvate by SDH is a two-step reaction in which the hydroxyl group of serine is cleaved to produce aminoacrylate, and then the aminoacrylate is deaminated by nonenzymatic hydrolysis to produce pyruvate. The crystal structure of rat liver apo-SDH was determined by single isomorphous replacement at 2.8 A resolution. The holo-SDH crystallized with O-methylserine (OMS) was also determined at 2.6 A resolution by molecular replacement. SDH is composed of two domains, and each domain has a typical alphabeta-open structure. The active site is located in the cleft between the two domains. The holo-SDH contained PLP-OMS aldimine in the active site, indicating that OMS can form the Schiff base linkage with PLP, but the subsequent dehydration did not occur. Apo-SDH forms a dimer by inserting the small domain into the catalytic cleft of the partner subunit so that the active site is closed. Holo-SDH also forms a dimer by making contacts at the back of the clefts so that the dimerization does not close the catalytic cleft. The phosphate group of PLP is surrounded by a characteristic G-rich sequence ((168)GGGGL(172)) and forms hydrogen bonds with the amide groups of those amino acid residues, suggesting that the phosphate group can be protonated. N(1) of PLP participates in a hydrogen bond with Cys303, and similar hydrogen bonds with N(1) participating are seen in other beta-elimination enzymes. These hydrogen bonding schemes indicate that N(1) is not protonated, and thus, the pyridine ring cannot take a quinone-like structure. These characteristics of the bound PLP suggest that SDH catalysis is not facilitated by forming the resonance-stabilized structure of the PLP-Ser aldimine as seen in aminotransferases. A possible catalytic mechanism involves the phosphate group, surrounded by the characteristic sequence, acting as a general acid to donate a proton to the leaving hydroxyl group of serine.     

The pyridoxal 5' -phosphate site in rabbit skeletal muscle glycogen phosphorylase b: an ultraviolet and 1H and 31P nuclear magnetic resonance spectroscopic study.

1 H NMR spectra of the 3-0-methylpyridoxal 5'-phosphate-n-butylamine reaction product indicated that this analogue forms a Schiff base in aprotic solvent. The uv spectral properties of 3-0-methylpyridoxal-5'-phosphate phosphorylase b correspond to those of the n-butylamine Schiff base derivative in dimethyl sulfoxide. On the basis of that and auxiliary uv and 1H NMR spectra of pyridoxal and pyridoxal 5'-phosphate and the corresponding Schiff base derivatives we have verified that pyridoxal 5' -phosphate is also bound as a Schiff base to phosphorylase and not as an aldamine. Since 3-0-methylpyridoxal-5'-phosphate phosphorylase is active, a proton shuttle between the 3-hydroxyl group and the pyridine nitrogen is excluded. This directs attention to the 5' -phosphate group of the cofactor as a candidate for a catalytic function. 31P NMR spectra of pyridoxal 5' -phosphate in phosphorylase b indicated that deprotonation of the 5' -phosphate group was unresponsive to external pH. Interaction of phosphorylase b with adenosine 5' -monophosphate, the allosteric effector required activity, and arsenate, which substitutes for phosphate as substrate, triggered a conformational change which resulted in deprotonation of the 5' -phosphate group of pyridoxal 5' at pH 7.6. It now behaved like in the pyridoxal-phosphate-epsilon-aminocaproate Schiff base in aqueous buffer, where the diionized form is dominant at this pH. Differences of line widths of the adenosine 5' -monophosphate signal point to different life times of the allosteric effector- enzyme complexes in the presence and absence of substrate (arsenate).     

pH dependence of tryptophan synthase catalytic mechanism: I. The first stage, the beta-elimination reaction

The pyridoxal 5'-phosphate-dependent beta-subunit of the tryptophan synthase alpha(2)beta(2) complex catalyzes the condensation of L-serine with indole to form L-tryptophan. The first stage of the reaction is a beta-elimination that involves a very fast interconversion of the internal aldimine in a highly fluorescent L-serine external aldimine that decays, via the alpha-carbon proton removal and beta-hydroxyl group release, to the alpha-aminoacrylate Schiff base. This reaction is influenced by protons, monovalent cations, and alpha-subunit ligands that modulate the distribution between open and closed conformations. In order to identify the ionizable residues that might assist catalysis, we have investigated the pH dependence of the rate of the external aldimine decay by rapid scanning UV-visible absorption and single wavelength fluorescence stopped flow. In the pH range 6-9, the reaction was found to be biphasic with the first phase (rate constants k(1)) accounting for more than 70% of the signal change. In the absence of monovalent cations or in the presence of sodium and potassium ions, the pH dependence of k(1) exhibits a bell shaped profile characterized by a pK(a1) of about 6 and a pK(a2) of about 9, whereas in the presence of cesium ions, the pH dependence exhibits a saturation profile characterized by a single pK(a) of 9. The presence of the allosteric effector indole acetylglycine increases the rate of reaction without altering the pH profile and pK(a) values. By combining structural information for the internal aldimine, the external aldimine, and the alpha-aminoacrylate with kinetic data on the wild type enzyme and beta-active site mutants, we have tentatively assigned pK(a1) to betaAsp-305 and pK(a2) to betaLys-87. The loss of pK(a1) in the presence of cesium ions might be due to a shift to lower values, caused by the selective stabilization of a closed form of the beta-subunit.     

Possible roles of beta-elimination and delta-elimination reactions in the repair of DNA containing AP (apurinic/apyrimidinic) sites in mammalian cells.

Histones and polyamines nick the phosphodiester bond 3' to AP (apurinic/apyrimidinic) sites in DNA by inducing a beta-elimination reaction, which can be followed by delta-elimination. These beta- and delta-elimination reactions might be important for the repair of AP sites in chromatin DNA in either of two ways. In one pathway, after the phosphodiester bond 5' to the AP site has been hydrolysed with an AP endonuclease, the 5'-terminal base-free sugar 5'-phosphate is released by beta-elimination. The one-nucleotide gap limited by 3'-OH and 5'-phosphate ends is then closed by DNA polymerase-beta and DNA ligase. We have shown in vitro that such a repair is possible. In the other pathway, the nicking 3' to the AP site by beta-elimination occurs first. We have shown that the 3'-terminal base-free sugar so produced cannot be released by the chromatin AP endonuclease from rat liver. But it can be released by delta-elimination, leaving a gap limited by 3'-phosphate and 5'-phosphate. After conversion of the 3'-phosphate into a 3'-OH group by the chromatin 3'-phosphatase, there will be the same one-nucleotide gap, limited by 3'-OH and 5'-phosphate, as that formed by the successive actions of the AP endonuclease and the beta-elimination catalyst in the first pathway.     

Evidence for multiple imino intermediates and identification of reactive nucleophiles in peptide-catalyzed beta-elimination at abasic sites

Prior investigations have demonstrated that peptides containing a single aromatic residue flanked by basic ones, such as Lys-Trp-Lys, can incise the phosphodiester backbone of duplex DNA at an AP site via beta-elimination. An amine serves as the reactive nucleophile to attack C1' on the ring-open deoxyribose sugar to form a transient peptide-DNA imino (Schiff base) intermediate, which may be isolated as a stable covalent species under reducing conditions. In the current study, we use this methodology to demonstrate that peptide-catalyzed beta-elimination proceeds via the formation of two Schiff base intermediates, one of which was covalently trapped prior to strand incision and the other following strand incision. N-Terminal acetylation of reactive peptides significantly inhibited formation of a trapped Schiff base complex; thus, we demonstrate for the first time that the preferred reactive nucleophile for peptides catalyzing strand incision is the N-terminal alpha-amino group, not an epsilon-amino group located on a lysine residue as previously postulated. Trapping reactions in which the central tryptophan residue was changed to alanine did not have a significant impact on the efficiency of Schiff base formation, indicating that the presence of an aromatic residue is dispensable for the step prior to peptide-catalyzed beta-elimination. Interestingly, the methodology presented here affords a convenient means for covalently attaching an array of peptides onto AP site-containing DNA in a site-specific fashion. We suggest that the generation of such DNA-peptide cross-links may provide utility in studying the repair of biologically significant DNA-protein cross-link damage as DNA-peptide complexes may mimic intermediate structures along a repair pathway for DNA-protein cross-links.     

Reaction of serine-glyoxylate aminotransferase with the alternative substrate ketomalonate indicates rate-limiting protonation of a quinonoid intermediate

Serine-glyoxylate aminotransferase (SGAT) from Hyphomicrobium methylovorum is a pyridoxal 5'-phosphate (PLP) enzyme that catalyzes the interconversion of L-serine and glyoxylate to hydroxypyruvate and glycine. The primary deuterium isotope effect using L-serine 2-D is one on (V/K)serine and V in the steady state. Pre-steady-state experiments also indicate that there is no primary deuterium isotope effect with L-serine 2-D. The results suggest there is no rate limitation by abstraction of the alpha proton of L-serine in the SGAT reaction. In the steady-state a solvent deuterium isotope effect of about 2 was measured on (V/K)L-serine and (V/K)ketomalonate and about 5.5 on V. Similar solvent isotope effects were observed in the pre-steady-state for the natural substrates and the alternative substrate ketomalonate. In the pre-steady-state, no reaction intermediates typical of PLP enzymes were observed with the substrates L-serine, glyoxylate, and hydroxypyruvate. The data suggest that breakdown and formation of the ketimine intermediate is the primary rate-limiting step with the natural substrates. In contrast, using the alternative substrate ketomalonate, pre-steady-state experiments display the transient formation of a 490 nm absorbing species typical of a quinonoid intermediate. The solvent isotope effect results also suggest that with ketomalonate as substrate protonation at C(alpha) is the slowest step in the SGAT reaction. This is the first report of a rate-limiting protonation of a quinonoid at C(alpha) of the external Schiff base in an aminotransferase reaction.     

Active-site-directed inactivation of wheat-germ aspartate transcarbamoylase by pyridoxal 5''-phosphate.

Treatment of 1 microM wheat-germ aspartate transcarbamoylase with 1 mM-pyridoxal 5'-phosphate caused a rapid loss of activity, concomitant with the formation of a Schiff base. Complete loss of activity occurred within 10 min when the Schiff base was reduced with a 100-fold excess of NaBH4. Concomitantly, one amino group per chain was modified. No further residues were modified in the ensuing 30 min. The kinetics of inactivation were examined under conditions where the Schiff base was reduced before assay. Inactivation was apparently first-order. The pseudo-first-order rate constant, kapp., showed a hyperbolic dependence upon the concentration of pyridoxal 5'-phosphate, suggesting that the enzyme first formed a non-covalent complex with the reagent, modification of a lysine then proceeding within this complex. Inactivation of the enzyme by pyridoxal was 20 times slower than that by pyridoxal 5'-phosphate, indicating that the phosphate group was important in forming the initial complex. Partial protection against pyridoxal phosphate was provided by the leading substrate, carbamoyl phosphate, and nearly complete protection was provided by the bisubstrate analogue, N-phosphonoacetyl-L-aspartate, and the ligand-pair carbamoyl phosphate plus succinate. Steady-state kinetic studies, under conditions that minimized inactivation, showed that pyridoxal 5'-phosphate was also a competitive inhibitor with respect to the leading substrate, carbamoyl phosphate. Pyridoxal 5'-phosphate therefore appears to be an active-site-directed reagent. A sample of the enzyme containing one reduced pyridoxyl group per chain was digested with trypsin, and the labelled peptide was isolated and shown to contain a single pyridoxyl-lysine residue. Partial sequencing around the labelled lysine showed little homology with the sequence surrounding lysine-84, an active-centre residue of the catalytic subunit of aspartate transcarbamoylase from Escherichia coli, whose reaction with pyridoxal 5'-phosphate shows many similarities to the results described in the present paper. Arguably the reactive lysine is conserved between the two enzymes whereas the residues immediately surrounding the lysine are not. The same conclusion has been drawn in a comparison of reactive histidine residues in the two enzymes [Cole & Yon (1986) Biochemistry 25, 7168-7174].     

Probing the role of Tyr 64 of Treponema denticola cystalysin by site-directed mutagenesis and kinetic studies

Tyr 64, hydrogen-bonded to coenzyme phosphate in Treponema denticola cystalysin, was changed to alanine by site-directed mutagenesis. Spectroscopic and kinetic properties of the Tyr 64 mutant were investigated in an effort to explore the differences in coenzyme structure and kinetic mechanism relative to those of the wild-type enzyme. The wild type displays coenzyme absorbance bands at 418 and 320 nm, previously attributed to ketoenamine and substituted aldamine, respectively. The Tyr 64 mutant exhibits absorption maxima at 412 and 325 nm. However, the fluorescence characteristics of the latter band are consistent with its assignment to the enolimine form of the Schiff base. pK(spec) values of approximately 8.3 and approximately 6.5 were observed in a pH titration of the wild-type and mutant coenzyme absorbances, respectively. Thus, Tyr 64 is probably the residue involved in the nucleophilic attack on C4' of pyridoxal 5'-phosphate (PLP) in the internal aldimine. Although the Tyr 64 mutant exhibits a lower affinity for PLP and lower turnover numbers for alpha,beta-elimination and racemization than the wild type, the pH profiles for their Kd(PLP) and kinetic parameters are very similar. Rapid scanning stopped-flow and chemical quench experiments suggest that, in contrast to the wild type, for which the rate-determining step of alpha,beta-elimination of beta-chloro-L-alanine is the release of pyruvate, the rate-determining step for the mutant in the same reaction is the formation of alpha-aminoacrylate. Altogether, these results provide new insights into the catalytic mechanism of cystalysin and highlight the functional role of Tyr 64.     

Water is required for proton transfer from aspartate-96 to the bacteriorhodopsin Schiff base.

During the M in equilibrium with N----BR reaction sequence in the bacteriorhodopsin photocycle, proton is exchanged between D96 and the Schiff base, and D96 is reprotonated from the cytoplasmic surface. We probed these and the other photocycle reactions with osmotically active solutes and perturbants and found that the M in equilibrium with N reaction is specifically inhibited by withdrawing water from the protein. The N----BR reaction in the wild-type protein and the direct reprotonation of the Schiff base from the cytoplasmic surface in the site-specific mutant D96N are much less affected. Thus, it appears that water is required inside the protein for reactions where a proton is separated from a buried electronegative group, but not for those where the rate-limiting step is the capture of a proton at the protein surface. In the wild type, the largest part of the barrier to Schiff base reprotonation is the enthalpy of separating the proton from D96, which amounts to about 40 kJ/mol. We suggest that in spite of this D96 confers an overall kinetic advantage because when this residue becomes anionic in the N state its electric field near the cytoplasmic surface lowers the free energy barrier of the capture of a proton in the next step. In the D96N protein, the barrier to the M----BR reaction is 20 kJ/mol higher than what would be expected from the rates of the M----N and N----BR partial reactions in the wild type, presumably because this mechanism is not available.     

Participation of glutamic acid 23 of T4 endonuclease V in the beta-elimination reaction of an abasic site in a synthetic duplex DNA.

T4 endonuclease V catalyzes the hydrolysis of the glycosyl bond of a thymine dimer in a DNA duplex and the cleavage of the 3'-phosphate by beta-elimination. We have previously identified a catalytic site for the first reaction (pyrimidine dimer-glycosylase activity) by systematic mutagenesis (Doi et al. Proc. Natl. Acad. Sci. USA 1992 in press) and by x-ray crystallography (Morikawa et al. Science, 256: 523-526, 1992). The results showed that replacement of Glu23 with either glutamine or aspartic acid completely abolished the glycosylase activity. We describe the investigation of the second reaction (apurinic/apyrimidinic endonuclease activity), using twenty two mutants of T4 endonuclease V plus a DNA mini duplex containing an abasic site. Replacement of Glu23 by glutamine abolished the second reaction, but replacement with aspartic acid did not. The pH optima of the mutant (23 Asp) and the wild type were found to be 5.0 and 5.5, respectively. We conclude that the carboxylate anion in position 23 may act as a general base in the beta-elimination reaction of the endonuclease.     

Studies of 6-fluoropyridoxal and 6-fluoropyridoxamine 5'-phosphates in cytosolic aspartate aminotransferase

The chemical and spectroscopic properties of 6-fluoropyridoxal 5'-phosphate, of its Schiff base with valine, and of 6-fluoropyridoxamine 5'-phosphate have been investigated. The modified coenzymes have also been combined with the apo form of cytosolic aspartate aminotransferase, and the properties of the resulting enzymes and of their complexes with substrates and inhibitors have been recorded. Although the presence of the 6-fluoro substituent reduces the basicity of the ring nitrogen over 10 000-fold, the modified coenzymes bind predominately in their dipolar ionic ring forms as do the natural coenzymes. Enzyme containing the modified coenzymes binds substrates and dicarboxylate inhibitors normally and has about 42% of the catalytic activity of the native enzyme. The fluorine nucleus provides a convenient NMR probe that is sensitive to changes in the state of protonation of both the ring nitrogen and the imine or the -OH group of free enzyme and of complexes with substrates or inhibitors. The NMR measurements show that the ring nitrogen of bound 6-fluoropyridoxamine phosphate is protonated at pH 7 or below but becomes deprotonated at high pH around a pKa of 8.2. The bound 6-fluoropyridoxal phosphate, which exists as a Schiff base with a dipolar ionic ring at high pH, becomes protonated with a pKa of approximately 7.1, corresponding to the pKa of approximately 6.4 in the native enzyme. Below this pKa a single 19F resonance is seen, but there are two light absorption bands corresponding to ketoenamine and enolimine tautomers of the Schiff base. The tautomeric ratio is altered markedly upon binding of dicarboxylate inhibitors. From the chemical shift values, we conclude that during the rapid tautomerization a proton is synchronously moved from the ring nitrogen (in the ketoenamine) onto the aspartate-222 carboxylate (in the enolimine). The possible implications for catalysis are discussed.     

Structural analysis of the substrate recognition mechanism in O-phosphoserine sulfhydrylase from the hyperthermophilic archaeon Aeropyrum pernix K1

L-Cysteine is synthesized from O-acetyl-L-serine (OAS) and sulfide by O-acetylserine sulfhydrylase (OASS; EC 2.5.1.47) in plants and bacteria. O-phosphoserine sulfhydrylase (OPSS; EC 2.5.1.65) is a novel enzyme from the hyperthermophilic aerobic archaeon Aeropyrum pernix K1 (2003). OPSS can use OAS or O-phospho-L-serine (OPS) to synthesize L-cysteine. To elucidate the mechanism of the substrate specificity of OPSS, we analyzed three-dimensional structures of the active site of the enzyme. The active-site lysine (K127) of OPSS forms an internal Schiff base with pyridoxal 5'-phosphate. Therefore, crystals of the complexes formed by the K127A mutant with the external Schiff base of pyridoxal 5'-phosphate with either OPS or OAS were prepared and examined by X-ray diffraction analysis. In contrast to that observed for OASS, no significant difference was seen in the overall structure between the free and complexed forms of OPSS. The side chains of T152, S153, and Q224 interacted with the carboxylate of the substrates, as a previous study has suggested. The side chain of R297 has been proposed to recognize the phosphate group of OPS. Surprisingly, however, the position of R297 was significantly unchanged in the complex of the OPSS K127A mutant with the external Schiff base, allowing enough space for an interaction with OPS. The positively charged environment around the entrance of the active site including S153 and R297 is important for accepting negatively charged substrates such as OPS.     

EPR non-detectable copper in pyridoxal biogenic amine Schiff base complexes.

Schiff bases formed with octopamine, pyridoxal and pyridoxal phosphate react with copper ions to give various pH-dependent species. The outstanding feature of these complexes is their absence of EPR spectra at physiological pH values. We propose dimeric dipolar coupled structures for the EPR non-detectable copper complexes, involving hydroxyde anions and vitamin B-6 Schiff bases. These results establish that EPR non-detectable copper in enzymes may arise from dipolar coupling between metal ions involved in Schiff base type complexes.     

Probing the general base catalysis in the first step of BamHI action by computer simulations.

BamHI is a type II restriction endonuclease that catalyzes the scission of the phoshodiester bond in the GAGTCC cognate sequence in the presence of two divalent metal ions. The first step of the reaction is the preparation of water for nucleophilic attack by Glu-113, which has been proposed to abstract the proton from the attacking water molecule. Alternatively, the 3'-phosphate group to the susceptible phosphodiester bond has been suggested to play a role as the general base. The two hypotheses have been tested by computer simulations using the semiempirical protein dipoles Langevin dipoles (PDLD/S) method. Deprotonation of water by Glu-113 has been found to be less favorable by 5.7 kcal/mol than metal-catalyzed deprotonation with a concomitant proton transfer to bulk solvent. The preparation of the nucleophile by the 3'-phosphate group is less favorable by 12.3 kcal/mol. These results suggest that both the general base and the substrate-assisted mechanisms in the first step of BamHI action are less likely than the metal-catalyzed reaction. The metal ions in the active site of BamHI make the largest contributions to the reduction of the free energy of hydroxide ion formation. On the basis of these findings we propose that the first step of endonuclease catalysis does not require a general base; rather, the essential attacking nucleophile in BamHI catalytic action is stabilized by the metal ions.     

The mechanism of binding of L-serine to tryptophan synthase from Escherichia coli

The mechanism of binding of L-serine to tryptophan synthase, which is the initial phase of the catalytic mechanism, has been studied by steady-state and stopped-flow kinetic techniques. The dependence of three separable rate processes on the concentration of L-serine is compatible with four different enzyme-substrate complexes, one of which lies on a branch in the pathway. By use of L-serine deuterated at the alpha carbon, it is possible to assign the deprotonation of the external aldimine of L-serine with pyridoxal 5'-phosphate to the most rapid observable binding step. Measurements at two pH values show that the rate-determining step in the synthesis of L-tryptophan changes from release of L-tryptophan at the optimal pH of 7.6 to the binding of L-serine at pH 6.5. Measurements at pH 7.6 in the presence of the substrate analogue indolepropanol phosphate show that the stronger binding of L-serine is probably due to stabilization of the catalytically competent enzyme--L-serine complex. At pH 7.6 L-serine is bound far more slowly to the beta 2 subunit than to the alpha 2 beta 2 complex of tryptophan synthase and retains its alpha carbon proton. For the beta 2 subunit, the rate-determining step of tryptophan synthesis is deprotonation of bound L-serine. The effect of bound alpha subunit is to increase both the rate of deprotonation and beta-elimination, shifting the rate-limiting step to the release of L-tryptophan.     

Understanding non-enzymatic aminophospholipid glycation and its inhibition. Polar head features affect the kinetics of Schiff base formation

Non-enzymatic aminophospholipid glycation is an especially important process because it alters the stability of lipid bilayers and interferes with cell function and integrity as a result. However, the kinetic mechanism behind this process has scarcely been studied. As in protein glycation, the process has been suggested to involve the formation of a Schiff base as the initial, rate-determining step. In this work, we conducted a comparative kinetic study of Schiff base formation under physiological conditions in three low-molecular weight analogues of polar heads in the naturally occurring aminophospholipids O-phosphorylethanolamine (PEA), O-phospho-DL-serine (PSer) and 2-aminoethylphenethylphosphate (APP) with various glycating carbonyl compounds (glucose, arabinose and acetol) and the lipid glycation inhibitor pyridoxal 5'-phosphate (PLP). Based on the results, the presence of a phosphate group and a carboxyl group in α position respect to the amino group decrease the formation constant for the Schiff base relative to amino acids. On the other hand, esterifying the phosphate group with a non-polar substituent in APP increases the stability of its Schiff base. The observed kinetic formation constants of aminophosphates with carbonyl groups were smaller than those for PLP. Our results constitute an important contribution to understanding the competitive inhibition effect of PLP on aminophospholipid glycation.     

Gene cloning,purification, and characterization of 2,3-diaminopropionate ammonia-lyase from Escherichia coli

2,3-Diaminopropionate ammonia-lyase (DAPAL), which catalyzes alpha,beta-elimination of 2,3-diaminopropionate regardless of its stereochemistry, was purified from Salmonella typhimurium. We cloned the Escherichia coli ygeX gene encoding a putative DAPAL and purified the gene product to homogeneity. The protein obtained contained pyridoxal 5'-phosphate and was composed of two identical subunits with a calculated molecular weight of 43,327. It catalyzed the alpha,beta-elimination of both D- and L-2,3-diaminopropionate. The results confirmed that ygeX encoded DAPAL. The enzyme acted on D-serine, but its catalytic efficiency was only 0.5% that with D-2,3-diaminopropionate. The enzymologic properties of E. coli DAPAL resembled those of Salmonella DAPAL, except that L-serine, D-and L-beta-Cl-alanine were inert as substrates of the enzyme from E. coli. DAPAL had significant sequence similarity with the catalytic domain of L-threonine dehydratase, which is a member of the fold-type II group of pyridoxal phosphate enzymes, together with D-serine dehydratase and mammalian serine racemase.     

Isotope effect studies of the pyruvate-dependent histidine decarboxylase from Lactobacillus 30a

The decarboxylation of histidine by the pyruvate-dependent histidine decarboxylase of Lactobacillus 30a shows a carbon isotope effect of k12/k13 = 1.0334 +/- 0.0005 and a nitrogen isotope effect k14/k15 = 0.9799 +/- 0.0006 at pH 4.8, 37 degrees C. The carbon isotope effect is slightly increased by deuteriation of the substrate and slightly decreased in D2O. The observed nitrogen isotope effect indicates that the imine nitrogen in the substrate-Schiff base intermediate complex is ordinarily protonated, and the pH dependence of the carbon isotope effect indicates that both protonated and unprotonated forms of this intermediate are capable of undergoing decarboxylation. As with the pyridoxal 5'-phosphate dependent enzyme, Schiff base formation and decarboxylation are jointly rate-limiting, with the intermediate histidine-pyruvate Schiff base showing a decarboxylation/Schiff base hydrolysis ratio of 0.5-1.0 at pH 4.8. The decarboxylation transition state is more reactant-like for the pyruvate-dependent enzyme than for the pyridoxal 5'-phosphate dependent enzyme. These studies find no particular energetic or catalytic advantage to the use of pyridoxal 5'-phosphate over covalently bound pyruvate in catalysis of the decarboxylation of histidine.