Snapshots of the cystine lyase C-DES during catalysis. Studies in solution and in the crystalline state

The cystine lyase (C-DES) of Synechocystis is a pyridoxal-5'-phosphate-dependent enzyme distantly related to the family of NifS-like proteins. The crystal structure of an N-terminal modified variant has recently been determined. Herein, the reactivity of this enzyme variant was investigated spectroscopically in solution and in the crystalline state to follow the course of the reaction and to determine the catalytic mechanism on a molecular level. Using the stopped-flow technique, the reaction with the preferred substrate cystine was found to follow biphasic kinetics leading to the formation of absorbing species at 338 and 470 nm, attributed to the external aldimine and the alpha-aminoacrylate; the reaction with cysteine also exhibited biphasic behavior but only the external aldimine accumulated. The same reaction intermediates were formed in crystals as seen by polarized absorption microspectrophotometry, thus indicating that C-DES is catalytically competent in the crystalline state. The three-dimensional structure of the catalytically inactive mutant C-DES(K223A) in the presence of cystine showed the formation of an external aldimine species, in which two alternate conformations of the substrate were observed. The combined results allow a catalytic mechanism to be proposed involving interactions between cystine and the active site residues Arg-360, Arg-369, and Trp-251*; these residues reorient during the beta-elimination reaction, leading to the formation of a hydrophobic pocket that stabilizes the enolimine tautomer of the aminoacrylate and the cysteine persulfide product.     

Role of a NifS-like protein from the cyanobacterium Synechocystis PCC 6803 in the maturation of FeS proteins

In Azotobacter vinelandii and Escherichia coli NifS or NifS-like proteins are involved in FeS protein assembly by mobilizing sulfur from free cysteine. This sulfur together with Fe(2+) is then incorporated into apo-FeS proteins to form an FeS center. A different activity termed C-DES [for cyst(e)ine desulfurylase] was recently isolated from the cyanobacterium Synechocystis PCC 6714 which also mobilized sulfur and which was able to incorporate the FeS center into apoferredoxin. In the genome of the cyanobacterium Synechocystis PCC 6803, there are three open reading frames (orfs) that are similar to NifS and one that is similar to C-DES, indicating that this bacterium might contain both activities, NifS and C-DES. One orf from Synechocystis PCC 6803 encoding a NifS-like protein, slr0387, was overexpressed in E. coli and purified. The molecular mass of the recombinant protein was determined to be about 82 kDa, indicating that it is a homodimer. The absorption spectrum was typical for PLP-containing proteins with an absorption maximum at 390 nm at pH 9.0 and at 425 nm at pH 6.5. The pH dependence of the absorption spectrum correlated with enzyme activity. Maximal activity measured as sulfide production was observed between pH 8.5 and 10. The activity decreased at lower pH values and was undetectable at pH 5.5. pH-dependent changes in the absorption spectrum and activity were attributed to protonation of the Schiff base formed by a lysine side chain and the PLP cofactor. Studies on substrate specificity demonstrated that cysteine derivatives other than cysteine methyl ester and cysteine-sulfinic acid could not serve as substrates for this enzyme. In particular, cystine was not a substrate for the Synechocystis NifS-like protein, whereas it is the best substrate for C-DES. In the presence of Fe(2+), cysteine, and a reductant, the NifS-like protein was able to produce holoferredoxin from apoferredoxin. The implications of two different activities for FeS center biosynthesis in Synechocystis are discussed.     

Characterization of the reaction of L-serine and indole with Escherichia coli tryptophan synthase via rapid-scanning ultraviolet-visible spectroscopy

The pre-steady-state reaction of indole and L-serine with the alpha 2 beta 2 complex of Escherichia coli tryptophan synthase has been investigated under different premixing conditions with rapid-scanning stopped-flow (RSSF) UV-visible spectroscopy for the spectral range 300-550 nm. When alpha 2 beta 2 was mixed with indole and L-serine, the reaction of alpha 2 beta 2 was found to occur in three detectable relaxations (1/tau 1 greater than 1/tau 2 greater than 1/tau 3) with rate constants identical with the three relaxations seen in the partial reaction with L-serine [Drewe, W.F., Jr., & Dunn, M.F. (1985) Biochemistry 24, 3977-3987]. Kinetic isotope effects due to substitution of 2H for the alpha-1H of serine were found to be similar to the effects observed in the reaction with serine only. The observed spectral changes and isotope effects indicate that the aldimine of L-serine and PLP and the first quinoid derived from this external aldimine are transient species that accumulate during tau 1. Conversion of these intermediates to the alpha-aminoacrylate Schiff base during tau 2 and tau 3 limits the rate of formation of the second quinoidal species (lambda max 476 nm) generated via C-C bond formation between indole and the alpha-aminoacrylate intermediate. The pre-steady-state reaction of the alpha 2 beta 2-serine mixture with indole is comprised of four relaxations (1/tau 1* greater than 1/tau 2* greater than 1/tau 3* greater than 1/tau 4*).(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure, mechanism, and conformational dynamics of O-acetylserine sulfhydrylase from Salmonella typhimurium: comparison of A and B isozymes

O-Acetylserine sulfhydrylase is a pyridoxal 5'-phosphate-dependent enzyme that catalyzes the final step in the cysteine biosynthetic pathway in enteric bacteria and plants, the replacement of the beta-acetoxy group of O-acetyl-l-serine by a thiol to give l-cysteine. Two isozymes are found in Salmonella typhimurium, with the A-isozyme expressed under aerobic and the B-isozyme expressed under anaerobic conditions. The structure of O-acetylserine sulfhydrylase B has been solved to 2.3 A and exhibits overall a fold very similar to that of the A-isozyme. The main difference between the two isozymes is the more hydrophilic active site of the B-isozyme with two ionizable residues, C280 and D281, replacing the neutral residues S300 and P299, respectively, in the A-isozyme. D281 is above the re face of the cofactor and is within hydrogen-bonding distance to Y286, while C280 is located about 3.4 A from the pyridine nitrogen (N1) of the internal Schiff base. The B-isozyme has a turnover number (V/Et) 12.5-fold higher than the A-isozyme and an approximately 10-fold lower Km for O-acetyl-l-serine. Studies of the first half-reaction by rapid-scanning stopped-flow indicate a first-order conversion of the internal Schiff base to the alpha-aminoacrylate intermediate at any concentration of O-acetyl-l-serine. The Kd values for formation of the external Schiff base with cysteine and serine, obtained by spectral titration, are pH dependent and exhibit a pKa of 7.0-7.5 (for a group that must be unprotonated for optimum binding) with values, above pH 8.0, of about 3.0 and 30.0 mM, respectively. In both cases the neutral enolimine is favored at high pH. Failure to observe the pKa for the alpha-amines of cysteine and serine in the pKESB vs pH profile suggests a compensatory effect resulting from titration of a group on the enzyme with a pKa in the vicinity of the alpha-amine's pKa. The pH dependence of the first-order rate constant for decay of the alpha-aminoacrylate intermediate to give pyruvate and ammonia gives a pKa of about 9 for the active site lysine (K41), a pH unit higher than that of the A-isozyme. The difference in pH dependence of the pKESB for cysteine and serine, the higher pKa for K41, and the preference for the neutral species at high pH compared to the A-isozyme can be explained by titration of C280 to give the thiolate. Subtle conformational differences between O-acetylserine sulfhydrylase A and O-acetylserine sulfhydrylase B are detected by comparing the absorption and emission spectra of the internal aldimine in the absence and presence of the product acetate and of the external aldimine with l-serine. The two isozymes show a different equilibrium distribution of the enolimine and ketoenamine tautomers, likely as a result of a more polar active site for O-acetylserine sulfhydrylase B. The distribution of cofactor tautomers is dramatically affected by the ligation state of the enzyme. In the presence of acetate, which occupies the alpha-carboxylate subsite, the equilibrium between tautomers is shifted toward the ketoenamine tautomer, as a result of a conformational change affecting the structure of the active site. This finding, in agreement with structural data, suggests for the O-acetylserine sulfhydrylase B-isozyme a higher degree of conformational flexibility linked to catalysis.     

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.     

Aminoacrylate intermediates in the reaction of Citrobacter freundii tyrosine phenol-lyase

Tyrosine phenol-lyase (TPL) from Citrobacter freundii is a pyridoxal 5'-phosphate (PLP)-dependent enzyme that catalyzes the reversible hydrolytic cleavage of l-Tyr to give phenol and ammonium pyruvate. The proposed reaction mechanism for TPL involves formation of an external aldimine of the substrate, followed by deprotonation of the alpha-carbon to give a quinonoid intermediate. Elimination of phenol then has been proposed to give an alpha-aminoacrylate Schiff base, which releases iminopyruvate that ultimately undergoes hydrolysis to yield ammonium pyruvate. Previous stopped-flow kinetic experiments have provided direct spectroscopic evidence for the formation of the external aldimine and quinonoid intermediates in the reactions of substrates and inhibitors; however, the predicted alpha-aminoacrylate intermediate has not been previously observed. We have found that 4-hydroxypyridine, a non-nucleophilic analogue of phenol, selectively binds and stabilizes aminoacrylate intermediates in reactions of TPL with S-alkyl-l-cysteines, l-tyrosine, and 3-fluoro-l-tyrosine. In the presence of 4-hydroxypyridine, a new absorption band at 338 nm, assigned to the alpha-aminoacrylate, is observed with these substrates. Formation of the 338 nm peaks is concomitant with the decay of the quinonoid intermediates, with good isosbestic points at approximately 365 nm. The value of the rate constant for aminoacrylate formation is similar to k(cat), suggesting that leaving group elimination is at least partially rate limiting in TPL reactions. In the reaction of S-ethyl-l-cysteine in the presence of 4-hydroxypyridine, a subsequent slow reaction of the alpha-aminoacrylate is observed, which may be due to iminopyruvate formation. Both l-tyrosine and 3-fluoro-l-tyrosine exhibit kinetic isotope effects of approximately 2-3 on alpha-aminoacrylate formation when the alpha-(2)H-labeled substrates are used, consistent with the previously reported internal return of the alpha-proton to the phenol product. These results are the first direct spectroscopic observation of alpha-aminoacrylate intermediates in the reactions of TPL.     

Application of rapid-scanning, stopped-flow spectroscopy to the characterization of intermediates formed in the reactions of L- and D-tryptophan and beta-mercaptoethanol with Escherichia coli tryptophan synthase

The reactions of the alpha 2 beta 2 complex of Escherichia coli tryptophan synthase with D- and L-Trp and the presteady-state reaction of L-Ser and beta-mercaptoethanol under different premixing conditions have been investigated by rapid-scanning stopped-flow (RSSF) UV-visible spectroscopy. The reaction of alpha 2 beta 2 with L-Ser and beta-mercaptoethanol occurs in 3 detectable relaxations with rates similar to the 3 relaxations seen in the partial reaction with L-Ser and in the reaction with L-Ser and indole. The presteady-state phase of the reaction of beta-mercaptoethanol with the alpha-aminoacrylate intermediate is characterized by 2 relaxations. The RSSF spectra for this reaction show that the spectral changes that take place in these 2 phases are essentially identical. The L-Trp reaction is biphasic, and the spectral changes occurring in each phase of the reaction also are identical. The 2 new spectral bands formed (lambda max congruent to 420 nm and congruent to 476 nm) are assigned as the L-Trp external aldimine (Schiff's base) and L-Trp quinonoid intermediates, respectively. The reaction of D-Trp also is biphasic. Analysis of first and second derivatives of the RSSF spectral changes give evidence for the formation of spectral bands with lambda max of approximately 423 nm, approximately 450 nm, and approximately 478 nm. The positions and shapes of these bands suggest a D-Trp external aldimine structure (423 nm) and a quinonoidal species (450 and 478 nm). However, product studies do not support this latter assignment. The behavior of the D- and L-Trp reactions and the reaction of beta-mercaptoethanol with the alpha-aminoacrylate strongly indicate the pre-existence of 2 slowly equilibrating forms of the internal aldimine and of the alpha-aminoacrylate.     

Proton transfers in the beta-reaction catalyzed by tryptophan synthase

Reactions catalyzed by the beta-subunits of the tryptophan synthase alpha(2)beta(2) complex involve multiple covalent transformations facilitated by proton transfers between the coenzyme, the reacting substrates, and acid-base catalytic groups of the enzyme. However, the UV/Vis absorbance spectra of covalent intermediates formed between the pyridoxal 5'-phosphate coenzyme (PLP) and the reacting substrate are remarkably pH-independent. Furthermore, the alpha-aminoacrylate Schiff base intermediate, E(A-A), formed between L-Ser and enzyme-bound PLP has an unusual spectrum with lambda(max) = 350 nm and a shoulder extending to greater than 500 nm. Other PLP enzymes that form E(A-A) species exhibit intense bands with lambda(max) approximately 460-470 nm. To further investigate this unusual tryptophan synthase E(A-A) species, these studies examine the kinetics of H(+) release in the reaction of L-Ser with the enzyme using rapid kinetics and the H(+) indicator phenol red in solutions weakly buffered by substrate L-serine. This work establishes that the reaction of L-Ser with tryptophan synthase gives an H(+) release when the external aldimine of L-Ser, E(Aex(1)), is converted to E(A-A). This same H(+) release occurs in the reaction of L-Ser plus the indole analogue, aniline, in a step that is rate-determining for the appearance of E(Q)(Aniline). We propose that the kinetic and spectroscopic properties of the L-Ser reaction with tryptophan synthase reflect a mechanism wherein the kinetically detected proton release arises from conversion of an E(Aex(1)) species protonated at the Schiff base nitrogen to an E(A-A) species with a neutral Schiff base nitrogen. The mechanistic and conformational implications of this transformation are discussed.     

Characterization of the allosteric anion-binding site of O-acetylserine sulfhydrylase.

A new crystal structure of the A-isozyme of O-acetylserine sulfhydrylase-A (OASS) with chloride bound to an allosteric site located at the dimer interface has recently been determined [Burkhard, P., Tai, C.-H., Jansonius, J. N., and Cook, P. F. (2000) J. Mol. Biol. 303, 279-286]. Data have been obtained from steady state and presteady-state kinetic studies and from UV-visible spectral studies to characterize the allosteric anion-binding site. Data obtained with chloride and sulfate as inhibitors indicate the following: (i) chloride and sulfate prevent the formation of the external aldimines with L-cysteine or L-serine; (ii) chloride and sulfate increase the external aldimine dissociation constants for O-acetyl-L-serine, L-methionine, and 5-oxo-L-norleucine; (iii) chloride and sulfate bind to the allosteric site in the internal aldimine and alpha-aminoacrylate external aldimine forms of OASS; (iv) sulfate also binds to the active site. Sulfide behaves in a manner identical to chloride and sulfate in preventing the formation of the L-serine external aldimine. The binding of chloride to the allosteric site is pH independent over the pH range 7-9, suggesting no ionizable enzyme side chains ionize over this pH range. Inhibition by sulfide is potent (K(d) is 25 microM at pH 8) suggesting that SH(-) is the physiologic inhibitory species.     

Crystals of tryptophan indole-lyase and tyrosine phenol-lyase form stable quinonoid complexes

The binding of substrates and inhibitors to wild-type Proteus vulgaris tryptophan indole-lyase and to wild type and Y71F Citrobacter freundii tyrosine phenol-lyase was investigated in the crystalline state by polarized absorption microspectrophotometry. Oxindolyl-lalanine binds to tryptophan indole-lyase crystals to accumulate predominantly a stable quinonoid intermediate absorbing at 502 nm with a dissociation constant of 35 microm, approximately 10-fold higher than that in solution. l-Trp or l-Ser react with tryptophan indole-lyase crystals to give, as in solution, a mixture of external aldimine and quinonoid intermediates and gem-diamine and external aldimine intermediates, respectively. Different from previous solution studies (Phillips, R. S., Sundararju, B., & Faleev, N. G. (2000) J. Am. Chem. Soc. 122, 1008-1114), the reaction of benzimidazole and l-Trp or l-Ser with tryptophan indole-lyase crystals does not result in the formation of an alpha-aminoacrylate intermediate, suggesting that the crystal lattice might prevent a ligand-induced conformational change associated with this catalytic step. Wild-type tyrosine phenol-lyase crystals bind l-Met and l-Phe to form mixtures of external aldimine and quinonoid intermediates as in solution. A stable quinonoid intermediate with lambda(max) at 502 nm is accumulated in the reaction of crystals of Y71F tyrosine phenol-lyase, an inactive mutant, with 3-F-l-Tyr with a dissociation constant of 1 mm, approximately 10-fold higher than that in solution. The stability exhibited by the quinonoid intermediates formed both by wild-type tryptophan indole-lyase and by wild type and Y71F tyrosine phenol-lyase crystals demonstrates that they are suitable for structural determination by x-ray crystallography, thus allowing the elucidation of a key species of pyridoxal 5'-phosphate-dependent enzyme catalysis.     

Functional properties of the active core of human cystathionine beta-synthase crystals

Human cystathionine beta-synthase is a pyridoxal 5'-phosphate enzyme containing a heme binding domain and an S-adenosyl-l-methionine regulatory site. We have investigated by single crystal microspectrophotometry the functional properties of a mutant lacking the S-adenosylmethionine binding domain. Polarized absorption spectra indicate that oxidized and reduced hemes are reversibly formed. Exposure of the reduced form of enzyme crystals to carbon monoxide led to the complete release of the heme moiety. This process, which takes place reversibly and without apparent crystal damage, facilitates the preparation of a heme-free human enzyme. The heme-free enzyme crystals exhibited polarized absorption spectra typical of a pyridoxal 5'-phosphate-dependent protein. The exposure of these crystals to increasing concentrations of the natural substrate l-serine readily led to the formation of the key catalytic intermediate alpha-aminoacrylate. The dissociation constant of l-serine was found to be 6 mm, close to that determined in solution. The amount of the alpha-aminoacrylate Schiff base formed in the presence of l-serine was pH independent between 6 and 9. However, the rate of the disappearance of the alpha-aminoacrylate, likely forming pyruvate and ammonia, was found to increase at pH values higher than 8. Finally, in the presence of homocysteine the alpha-aminoacrylate-enzyme absorption band readily disappears with the concomitant formation of the absorption band of the internal aldimine, indicating that cystathionine beta-synthase crystals catalyze both beta-elimination and beta-replacement reactions. Taken together, these findings demonstrate that the heme moiety is not directly involved in the condensation reaction catalyzed by cystathionine beta-synthase.     

Mechanism of the addition half of the O-acetylserine sulfhydrylase-A reaction

O-Acetylserine sulfhydrylase (OASS) catalyzes the last step in the cysteine biosynthetic pathway in enteric bacteria and plants, substitution of the beta-acetoxy group of O-acetyl-l-serine (OAS) with inorganic bisulfide. The first half of the sulfhydrylase reaction, formation of the alpha-aminoacrylate intermediate, limits the overall reaction rate, while in the second half-reaction, with bisulfide as the substrate, chemistry is thought to be diffusion-limited. In order to characterize the second half-reaction, the pH dependence of the pseudo-first-order rate constant for disappearance of the alpha-aminoacrylate intermediate was measured over the pH range 6.0-9.5 using the natural substrate bisulfide, and a number of nucleophilic analogues. The rate is pH-dependent for substrates with a pK(a) > 7, while the rate constant is pH-independent for substrates with a pK(a) < 7 suggesting that the pK(a)s of the substrate and an enzyme group are important in this half of the reaction. In D(2)O, at low pD values, the amino acid external Schiff base is trapped, while in H(2)O the reaction proceeds through release of the amino acid product, which is likely rate-limiting for all nucleophilic reactants. A number of new beta-substituted amino acids were produced and characterized by (1)H NMR spectroscopy.     

BetaQ114N and betaT110V mutations reveal a critically important role of the substrate alpha-carboxylate site in the reaction specificity of tryptophan synthase

In the PLP-requiring alpha2beta2 tryptophan synthase complex, recognition of the substrate l-Ser at the beta-site includes a loop structure (residues beta110-115) extensively H-bonded to the substrate alpha-carboxylate. To investigate the relationship of this subsite to catalytic function and to the regulation of substrate channeling, two loop mutants were constructed: betaThr110 --> Val, and betaGln114 --> Asn. The betaT110V mutation greatly impairs both catalytic activity in the beta-reaction, and allosteric communication between the alpha- and beta-sites. The crystal structure of the betaT110V mutant shows that the modified l-Ser carboxylate subsite has altered protein interactions that impair beta-site catalysis and the communication of allosteric signals between the alpha- and beta-sites. Purified betaQ114N consists of two species of mutant protein, one with a reddish color (lambdamax = 506 nm). The reddish species is unable to react with l-Ser. The second betaQ114N species displays significant catalytic activities; however, intermediates obtained on reaction with substrate l-Ser and substrate analogues exhibit perturbed UV/vis absorption spectra. Incubation with l-Ser results in the formation of an inactive species during the first 15 min with lambdamax approximately 320 nm, followed by a slower conversion over 24 h to the species with lambdamax = 506 nm. The 320 and 506 nm species originate from conversion of the alpha-aminoacrylate external aldimine to the internal aldimine and alpha-aminoacrylate, followed by the nucleophilic attack of alpha-aminoacrylate on C-4' of the internal aldimine to give a covalent adduct with PLP. Subsequent treatment with sodium hydroxide releases a modified coenzyme consisting of a vinylglyoxylic acid moiety linked through C-4' to the 4-position of the pyridine ring. We conclude that the shortening of the side chain accompanying the replacement of beta114-Gln by Asn relaxes the steric constraints that prevent this reaction in the wild-type enzyme. This study reveals a new layer of structure-function interactions essential for reaction specificity in tryptophan synthase.     

AtSufE is an essential activator of plastidic and mitochondrial desulfurases in Arabidopsis

Iron-sulfur (Fe-S) clusters are vital prosthetic groups for Fe-S proteins involved in fundamental processes such as electron transfer, metabolism, sensing and signaling. In plants, sulfur (SUF) protein-mediated Fe-S cluster biogenesis involves iron acquisition and sulfur mobilization, processes suggested to be plastidic. Here we have shown that AtSufE in Arabidopsis rescues growth defects in SufE-deficient Escherichia coli. In contrast to other SUF proteins, AtSufE localizes to plastids and mitochondria interacting with the plastidic AtSufS and mitochondrial AtNifS1 cysteine desulfurases. AtSufE activates AtSufS and AtNifS1 cysteine desulfurization, and AtSufE activity restoration in either plastids or mitochondria is not sufficient to rescue embryo lethality in AtSufE loss-of-function mutants. AtSufE overexpression induces AtSufS and AtNifS1 expression, which in turn leads to elevated cysteine desulfurization activity, chlorosis and retarded development. Our data demonstrate that plastidic and mitochondrial Fe-S cluster biogenesis shares a common, essential component, and that AtSufE acts as an activator of plastidic and mitochondrial desulfurases in Arabidopsis.     

Stereoelectronic control of bond formation in Escherichia coli tryptophan synthase: substrate specificity and enzymatic synthesis of the novel amino acid dihydroisotryptophan

The reactions of the indole analogues indoline and aniline with the Escherichia coli tryptophan synthase alpha-aminoacrylate Schiff base intermediate have been characterized by UV-visible and 1H NMR absorption spectroscopy and compared with the interactions of indole and the potent inhibitor benzimidazole. Indole, via the enamine functionality of the pyrrole ring, reacts with the alpha-aminoacrylate intermediate, forming a transient quinonoid species with lambda max 476 nm as the new C-C bond is synthesized. Conversion of this quinonoid to L-tryptophan is the rate-limiting step in catalysis [Lane, A., & Kirschner, K. (1981) Eur. J. Biochem. 120, 379-398]. Both aniline and indoline undergo rapid N-C bond formation with the alpha-aminoacrylate to form quinonoid intermediates; benzimidazole binds rapidly and tightly to the alpha-aminoacrylate but does not undergo covalent bond formation. The indoline and aniline quinonoids (lambda max 464 and 466 nm, respectively) are formed via nucleophilic attack on the electrophilic C-beta of the alpha-aminoacrylate. The indoline quinonoid decays slowly, yielding a novel, new amino acid, dihydroisotryptophan. The aniline quinonoid is quasi-stable, and no new amino acid product was detected. We conclude that nucleophilic attack requires the precise alignment of bonding orbitals between nucleophile and the alpha-aminoacrylate intermediate. The constraints imposed by the geometry of the indole subsite force the aromatic rings of indoline, aniline, and benzimidazole to bind in the same plane as indole; thus nucleophilic attack occurs with the N-1 atoms of indoline and aniline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structures of aspartate aminotransferase reconstituted with 1-deazapyridoxal 5'-phosphate: internal aldimine and stable L-aspartate external aldimine

The 1.8 ? resolution crystal structures of Escherichia coli aspartate aminotransferase reconstituted with 1-deazapyridoxal 5'-phosphate (deazaPLP; 2-formyl-3-hydroxy-4-methylbenzyl phosphate) in the internal aldimine and L-aspartate external aldimine forms are reported. The L-aspartate·deazaPLP external aldimine is extraordinarily stable (half-life of >20 days), allowing crystals of this intermediate to be grown by cocrystallization with L-aspartate. This structure is compared to that of the α-methyl-L-aspartate·PLP external aldimine. Overlays with the corresponding pyridoxal 5'-phosphate (PLP) aldimines show very similar orientations of deazaPLP with respect to PLP. The lack of a hydrogen bond between Asp222 and deazaPLP, which serves to "anchor" PLP in the active site, releases strain in the deazaPLP internal aldimine that is enforced in the PLP internal aldimine [Hayashi, H., Mizuguchi, H., Miyahara, I., Islam, M. M., Ikushiro, H., Nakajima, Y., Hirotsu, K., and Kagamiyama, H. (2003) Biochim. Biophys. Acta1647, 103] as evidenced by the planarity of the pyridine ring and the Schiff base linkage with Lys258. Additionally, loss of this anchor causes a 10° greater tilt of deazaPLP toward the substrate in the external aldimine. An important mechanistic difference between the L-aspartate·deazaPLP and α-methyl-L-aspartate·PLP external aldimines is a hydrogen bond between Gly38 and Lys258 in the former, positioning the catalytic base above and approximately equidistant between Cα and C4'. In contrast, in the α-methyl-L-aspartate·PLP external aldimine, the ε-amino group of Lys258 is rotated ~70° to form a hydrogen bond to Tyr70 because of the steric bulk of the methyl group.     

The K258R mutant of aspartate aminotransferase stabilizes the quinonoid intermediate.

Lys-258 of aspartate aminotransferase forms a Schiff base with pyridoxal phosphate and is responsible for catalysis of the 1,3-prototropic shift central to the transamination reaction sequence. Substitution of arginine for Lys-258 stabilizes the otherwise elusive quinonoid intermediate, as assessed by the long wavelength absorption bands observed in the reactions of this mutant with several amino acid substrates. The external aldimine intermediate is not detectable during reactions of this mutant with amino acids, although the inhibitor alpha-methylaspartate does slowly and stably form this species. These results suggest that external aldimine formation is one of the rate-determining steps of the reaction. The pyridoxamine-5'-phosphate-like enzyme form (330-nm absorption maximum) is unreactive toward keto acid substrates, and the coenzyme bound to this species is not dissociable from the protein.     

Structural and Functional Studies of the Mitochondrial Cysteine Desulfurase from Arabidopsis thaliana

AtNfs1 is the Arabidopsis thaliana mitochondrial homolog of the bacterial cysteine desulfurases NifS and IscS, having an essential role in cellular Fe-S cluster assembly. Homology modeling of AtNfs1m predicts a high global similarity with E. coli IscS showing a full conservation of residues involved in the catalytic site, whereas the chloroplastic AtNfs2 is more similar to the Synechocystis sp. SufS. Pull-down assays showed that the recombinant mature form, AtNfs1m, specifically binds to Arabidopsis frataxin (AtFH). A hysteretic behavior, with a lag phase of several minutes, was observed and hysteretic parameters were affected by pre-incubation with AtFH. Moreover, AtFH modulates AtNfs1m kinetics, increasing V (max) and decreasing the S (0.5) value for cysteine. Results suggest that AtFH plays an important role in the early steps of Fe-S cluster formation by regulating AtNfs1 activity in plant mitochondria.     

Substitution of glutamine for lysine at the pyridoxal phosphate binding site of bacterial D-amino acid transaminase. Effects of exogenous amines on the slow formation of intermediates

In bacterial D-amino acid transaminase, Lys-145, which binds the coenzyme pyridoxal 5'-phosphate in Schiff base linkage, was changed to Gln-145 by site-directed mutagenesis (K145Q). The mutant enzyme had 0.015% the activity of the wild-type enzyme and was capable of forming a Schiff base with D-alanine; this external aldimine was formed over a period of minutes depending upon the D-alanine concentration. The transformation of the pyridoxal-5'-phosphate form of the enzyme to the pyridoxamine-5'-phosphate form (i.e. the half-reaction of transamination) occurred over a period of hours with this mutant enzyme. Thus, information on these two steps in the reaction and on the factors that influence them can readily be obtained with this mutant enzyme. In contrast, these reactions with the wild-type enzyme occur at much faster rates and are not easily studied separately. The mutant enzyme shows distinct preference for D- over L-alanine as substrates but it does so about 50-fold less effectively than the wild-type enzyme. Thus, Lys-145 probably acts in concert with the coenzyme and other functional side chain(s) to lead to efficient and stereochemically precise transamination in the wild-type enzyme. The addition of exogenous amines, ethanolamine or methyl amine, increased the rate of external aldimine formation with D-alanine and the mutant enzyme but the subsequent transformation to the pyridoxamine-5'-phosphate form of the enzyme was unaffected by exogenous amines. The wild-type enzyme displayed a large negative trough in the circular dichroic spectrum at 420 nm, which was practically absent in the mutant enzyme. However, addition of D-alanine to the mutant enzyme generated this negative Cotton effect (due to formation of the external aldimine with D-alanine). This circular dichroism band gradually collapsed in parallel with the transformation to the pyridoxamine-5'-phosphate enzyme. Further studies on this mutant enzyme, which displays the characteristics of the wild-type enzyme but at attenuated rates, may yield information on the factors controlling the stereochemistry of the reaction as well as on the catalytic steps of the transaminase pathway.     

Escherichia coli SufE Sulfur Transfer Protein Modulates the SufS Cysteine Desulfurase through Allosteric Conformational Dynamics

Fe-S clusters are critical metallocofactors required for cell function. Fe-S cluster biogenesis is carried out by assembly machinery consisting of multiple proteins. Fe-S cluster biogenesis proteins work together to mobilize sulfide and iron, form the nascent cluster, traffic the cluster to target metalloproteins, and regulate the assembly machinery in response to cellular Fe-S cluster demand. A complex series of protein-protein interactions is required for the assembly machinery to function properly. Despite considerable progress in obtaining static three-dimensional structures of the assembly proteins, little is known about transient protein-protein interactions during cluster assembly or the role of protein dynamics in the cluster assembly process. The Escherichia coli cysteine desulfurase SufS (EC 2.8.1.7) and its accessory protein SufE work together to mobilize persulfide from l-cysteine, which is then donated to the SufB Fe-S cluster scaffold. Here we use amide hydrogen/deuterium exchange mass spectrometry (HDX-MS) to characterize SufS-SufE interactions and protein dynamics in solution. HDX-MS analysis shows that SufE binds near the SufS active site to accept persulfide from Cys-364. Furthermore, SufE binding initiates allosteric changes in other parts of the SufS structure that likely affect SufS catalysis and alter SufS monomer-monomer interactions. SufE enhances the initial l-cysteine substrate binding to SufS and formation of the external aldimine with pyridoxal phosphate required for early steps in SufS catalysis. Together, these results provide a new picture of the SufS-SufE sulfur transferase pathway and suggest a more active role for SufE in promoting the SufS cysteine desulfurase reaction for Fe-S cluster assembly.