Substrate-induced Facilitated Dissociation of Competitive Inhibitor from the Active Site of O-acetyl Serine Sulfhydrylase Reveal A Competitive-Allostery Mechanism (original) (raw)
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Cysteine is the main precursor of sulfur-containing biological molecules in bacteria and contributes to the control of the cell redox state. Hence, this amino acid plays an essential role in microbial survival and pathogenicity and the reductive sulfate assimilation pathway is considered a promising target for the development of new antibacterials. Serine acetyltransferase (SAT) and O-acetylserine sulfhydrylase (OASS-A), the enzymes catalyzing the last two steps of cysteine biosynthesis, engage in the formation of the cysteine synthase (CS) complex. The interaction between SAT and OASS-A finely tunes cysteine homeostasis, and the development of inhibitors targeting either protein–protein interaction or the single enzymes represents an attractive strategy to undermine bacterial viability. Given the peculiar mode of interaction between SAT and OASS-A, which exploits the insertion of SAT C-terminal sequence into OASS-A active site, we tested whether a recently developed competitive inh...
Protein Science, 2005
Serine acetyltransferase is a key enzyme in the sulfur assimilation pathway of bacteria and plants, and is known to form a bienzyme complex with O-acetylserine sulfhydrylase, the last enzyme in the cysteine biosynthetic pathway. The biological function of the complex and the mechanism of reciprocal regulation of the constituent enzymes are still poorly understood. In this work the effect of complex formation on the O-acetylserine sulfhydrylase active site has been investigated exploiting the fluorescence properties of pyridoxal 5 0 -phosphate, which are sensitive to the cofactor microenvironment and to conformational changes within the protein matrix. The results indicate that both serine acetyltransferase and its C-terminal decapeptide bind to the a-carboxyl subsite of O-acetylserine sulfhydrylase, triggering a transition from an open to a closed conformation. This finding suggests that serine acetyltransferase can inhibit O-acetylserine sulfhydrylase catalytic activity with a double mechanism, the competition with O-acetylserine for binding to the enzyme active site and the stabilization of a closed conformation that is less accessible to the natural substrate.
Structure and Mechanism of O-Acetylserine Sulfhydrylase
Journal of Biological Chemistry, 2004
The O-acetylserine sulfhydrylase (OASS) from Salmonella typhimurium catalyzes a -replacement reaction in which the -acetoxy group of O-acetyl-L-serine (OAS) is replaced by bisulfide to give L-cysteine and acetate. The kinetic mechanism of OASS is ping-pong with a stable ␣-aminoacrylate intermediate. The enzyme is a homodimer with one pyridoxal 5-phosphate (PLP) bound per subunit deep within the protein in a cleft between the N-and C-terminal domains of each of the monomers. All of the active site residues are contributed by a single subunit. The enzyme cycles through open and closed conformations as it catalyzes its reaction with structural changes largely limited to a subdomain of the N-terminal domain. The elimination of acetic acid from OAS is thought to proceed via an anti-E2 mechanism, and the only catalytic group identified to date is lysine 41, which originally participates in Schiff base linkage to PLP. The transition state for the elimination of acetic acid is thought to be asynchronous and earlier for C-O bond cleavage than for C␣-H bond cleavage. The biosynthesis of L-cysteine in enteric bacteria, such as Salmonella typhimurium and Escherichia coli, and in plants proceeds via a two-step pathway (Fig. 1). The amino acid precursor of L-cysteine is L-serine, which undergoes a substitution of its -hydroxyl with a thiol in two steps. Serine acetyltransferase (EC 2.3.1.30) catalyzes the acetylation (by acetyl-CoA) of the -hydroxyl of L-serine to give O-acetyl-L-serine (OAS) 1 (1). The final step, the ␣,-elimination of acetate from OAS and the addition of H 2 S to give L-cysteine is then catalyzed by Oacetylserine sulfhydrylase (OASS; EC 4.2.99.8). In enteric bacteria, two isozymes of OASS, A and B, are produced under aerobic and anaerobic growth conditions, respectively (2). The A and B isozymes are homodimeric with M r of about 68,900 and 64,000, respectively, and each has one tightly bound pyridoxal 5Ј-phosphate (PLP) per subunit. The structure and mechanism of the A isozyme of OASS from S. typhimurium will be the focus of this minireview. For a more comprehensive review, see Ref. 3. It has recently been shown that OASS-A is negatively regulated by small anions binding to an allosteric site at the dimer interface (4), but because of space limitations this aspect will not be discussed in this article.
Biochemistry, 2010
O-Acetylserine sulfhydrylase is a pyridoxal 5 0 -phosphate (PLP)-dependent enzyme that catalyzes the final step in the cysteine biosynthetic pathway in enteric bacteria and plants, the replacement of the βacetoxy group of O-acetyl-L-serine (OAS) by a thiol to give L-cysteine. Previous studies of the K41A mutant enzyme showed L-methionine bound in an external Schiff base (ESB) linkage to PLP as the enzyme was isolated. The mutant enzyme exists in a closed form, optimizing the orientation of the cofactor PLP and properly positioning active site functional groups for reaction. The trigger for closing the active site upon formation of the ESB is thought to be interaction of the substrate R-carboxylate with the substrate-binding loop comprised of T68, S69, G70, and N71, and Q142, which is positioned above the cofactor as one looks into the active site. To probe the contribution of these residues to the active site closing and orientation of PLP in the ESB, T68, S69, N71, and Q142 were changed to alanine. Absorbance, fluorescence, near UV-visible CD, and 31 P NMR spectral studies and pre-steady state kinetic studies were used to characterize the mutant enzymes. All of the mutations affect closure of the active site, but to differing extents. In addition, the site appears to be more hydrophilic given that the ESBs do not exhibit a significant amount of the enolimine tautomer. No buildup of the R-aminoacrylate intermediate (AA) is observed for the T68A and Q142A mutant enzymes. However, pyruvate is produced at a rate much greater than that of the wild-type enzyme. Data suggest that T68 and Q142 play a role in stabilizing the AA. Both residues donate a hydrogen bond to one of the carboxylate oxygens of the methionine ESB and may also be responsible for the proper orientation of the ESB to generate the AA. The S69A and N71A mutants exhibit formation of the AA, but the rate constant for its formation from the ESB is decreased by 1 order of magnitude compared to that of the wild type. S69 donates a hydrogen bond to the substrate carboxylate in the ESB, while N71 donates hydrogen bonds to O3 0 of the cofactor and the carboxylate of the ESB; these side chains may also affect the orientation of the ESB. Data suggest that interaction of intermediates with the substrate-binding loop and Q142 gives a properly aligned Michaelis complex and facilitates the β-elimination reaction.
Design of O -Acetylserine Sulfhydrylase Inhibitors by Mimicking Nature
Journal of Medicinal Chemistry, 2010
The inhibition of cysteine biosynthesis in prokaryotes and protozoa has been proposed to be relevant for the development of antibiotics. Haemophilus influenzae O-acetylserine sulfhydrylase (OASS), catalyzing L-cysteine formation, is inhibited by the insertion of the C-terminal pentapeptide (MNLNI) of serine acetyltransferase into the active site. 400 MNXXI pentapeptides were generated, docked into OASS active site using GOLD and scored with HINT. The terminal P5 Ile accounts for about 50% of the binding energy. Glu or Asp at position P4, and to a lesser extent, at position P3, also significantly contribute to the binding interaction. The predicted affinity of 14 selected pentapeptides correlated well with the experimentally determined dissociation constants. The X-ray structure of three high affinity pentapeptides-OASS complexes were compared with the docked poses. These results, combined with a GRID analysis of the active site, allowed us to define a pharmacophoric scaffold for the design of peptidomimetic inhibitors.
Journal of enzyme inhibition and medicinal chemistry, 2016
Cysteine is a building block for many biomolecules that are crucial for living organisms. O-Acetylserine sulfhydrylase (OASS), present in bacteria and plants but absent in mammals, catalyzes the last step of cysteine biosynthesis. This enzyme has been deeply investigated because, beside the biosynthesis of cysteine, it exerts a series of "moonlighting" activities in bacteria. We have previously reported a series of molecules capable of inhibiting Salmonella typhimurium (S. typhymurium) OASS isoforms at nanomolar concentrations, using a combination of computational and spectroscopic approaches. The cyclopropane-1,2-dicarboxylic acids presented herein provide further insights into the binding mode of small molecules to OASS enzymes. Saturation transfer difference NMR (STD-NMR) was used to characterize the molecule/enzyme interactions for both OASS-A and B. Most of the compounds induce a several fold increase in fluorescence emission of the pyridoxal 5'-phosphate (PLP) co...
PLOS Computational Biology, 2015
Cysteine residues have a rich chemistry and play a critical role in the catalytic activity of a plethora of enzymes. However, cysteines are susceptible to oxidation by Reactive Oxygen and Nitrogen Species, leading to a loss of their catalytic function. Therefore, cysteine oxidation is emerging as a relevant physiological regulatory mechanism. Formation of a cyclic sulfenyl amide residue at the active site of redox-regulated proteins has been proposed as a protection mechanism against irreversible oxidation as the sulfenyl amide intermediate has been identified in several proteins. However, how and why only some specific cysteine residues in particular proteins react to form this intermediate is still unknown. In the present work using in-silico based tools, we have identified a constrained conformation that accelerates sulfenyl amide formation. By means of combined MD and QM/MM calculation we show that this conformation positions the NH backbone towards the sulfenic acid and promotes the reaction to yield the sulfenyl amide intermediate, in one step with the concomitant release of a water molecule. Moreover, in a large subset of the proteins we found a conserved beta sheet-loop-helix motif, which is present across different protein folds, that is key for sulfenyl amide production as it promotes the previous formation of sulfenic acid. For catalytic activity, in several cases, proteins need the Cysteine to be in the cysteinate form, i.e. a low pKa Cys. We found that the conserved motif stabilizes the cysteinate by hydrogen bonding to several NH backbone moieties. As cysteinate is also more reactive toward ROS we propose that the sheet-loop-helix motif and the constraint conformation have been selected by evolution for proteins that need a reactive Cys protected from irreversible oxidation. Our results also highlight how fold conservation can be correlated to redox chemistry regulation of protein function.
2003
O-Acetylserine sulfhydrylase is a homodimeric enzyme catalyzing the last step of cysteine biosynthesis via a Bi Bi ping-pong mechanism. The subunit is composed of two domains, each containing one tryptophan residue, Trp 50 in the N-terminal domain and Trp 161 in the C-terminal domain. Only Trp 161 is highly conserved in eucaryotes and bacteria. The coenzyme pyridoxal 5-phosphate is bound in a cleft between the two domains. The enzyme undergoes an open to closed conformational transition upon substrate binding. The effect of single Trp to Tyr mutations on O-acetylserine sulfhydrylase structure, function, and stability was investigated with a variety of spectroscopic techniques. The mutations do not significantly alter the enzyme secondary structure but affect the catalysis, with a predominant influence on the second half reaction. The W50Y mutation strongly affects the unfolding pathway due to the destabilization of the intersubunit interface. The W161Y mutation, occurring in the C-terminal domain, produces a reduction of the accessibility of the active site to acrylamide and stabilizes thermodynamically the N-terminal domain, a result consistent with stronger interdomain interactions.
Isozyme-specific ligands for O-acetylserine sulfhydrylase, a novel antibiotic target
The last step of cysteine biosynthesis in bacteria and plants is catalyzed by O-acetylserine sulfhydrylase. In bacteria, two isozymes, O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B, have been identified that share similar binding sites, although the respective specific functions are still debated. O-acetylserine sulfhydrylase plays a key role in the adaptation of bacteria to the host environment, in the defense mechanisms to oxidative stress and in antibiotic resistance. Because mammals synthesize cysteine from methionine and lack O-acetylserine sulfhydrylase, the enzyme is a potential target for antimicrobials. With this aim, we first identified potential inhibitors of the two isozymes via a ligand-and structure-based in silico screening of a subset of the ZINC library using FLAP. The binding affinities of the most promising candidates were measured in vitro on purified O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B from Salmonella typhimurium by a direct method that exploits the change in the cofactor fluorescence. Two molecules were identified with dissociation constants of 3.7 and 33 mM for O-acetylserine sulfhydrylase-A and O-acetylserine sulfhydrylase-B, respectively. Because GRID analysis of the two isoenzymes indicates the presence of a few common pharmacophoric features, cross binding titrations were carried out. It was found that the best binder for O-acetylserine sulfhydrylase-B exhibits a dissociation constant of 29 mM for O-acetylserine sulfhydrylase-A, thus displaying a limited selectivity, whereas the best binder for O-acetylserine sulfhydrylase-A exhibits a dissociation constant of 50 mM for O-acetylserine sulfhydrylase-B and is thus 8-fold selective towards the former isozyme. Therefore, isoform-specific and isoform-independent ligands allow to either selectively target the isozyme that predominantly supports bacteria during infection and long-term survival or to completely block bacterial cysteine biosynthesis.