Autoproteolytic Activation of ThnT Results in Structural Reorganization Necessary for Substrate Binding and Catalysis

Buller, Andrew R.; Labonte, Jason W.; Freeman, Michael F.; Wright, Nathan T.; Schildbach, Joel F.; Townsend, Craig A.

doi:10.1016/j.jmb.2012.06.012

Cited by 11 publications

(15 citation statements)

References 47 publications

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“…5, the γ-methyl accelerates catalysis by intrinsically favoring the reactive g− rotamer. These rotamer distributions may be further shifted by interactions with residues proximal to the active site (48). This rationale explains the reduction in k cat observed upon Thr→Ser mutation of PβS (20) and glycosylasparaginase (44).…”

Section: Reactive Rotamer Determines the Identity Of The Local Oxyanionmentioning

confidence: 95%

Intrinsic evolutionary constraints on protease structure, enzyme acylation, and the identity of the catalytic triad

Buller

Townsend

2013

Proc. Natl. Acad. Sci. U.S.A.

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134

117

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The study of proteolysis lies at the heart of our understanding of biocatalysis, enzyme evolution, and drug development. To understand the degree of natural variation in protease active sites, we systematically evaluated simple active site features from all serine, cysteine and threonine proteases of independent lineage. This convergent evolutionary analysis revealed several interrelated and previously unrecognized relationships. The reactive rotamer of the nucleophile determines which neighboring amide can be used in the local oxyanion hole. Each rotamer-oxyanion hole combination limits the location of the moiety facilitating proton transfer and, combined together, fixes the stereochemistry of catalysis. All proteases that use an acyl-enzyme mechanism naturally divide into two classes according to which face of the peptide substrate is attacked during catalysis. We show that each class is subject to unique structural constraints that have governed the convergent evolution of enzyme structure. Using this framework, we show that the γ-methyl of Thr causes an intrinsic steric clash that precludes its use as the nucleophile in the traditional catalytic triad. This constraint is released upon autoproteolysis and we propose a molecular basis for the increased enzymatic efficiency introduced by the γ-methyl of Thr. Finally, we identify several classes of natural products whose mode of action is sensitive to the division according to the face of attack identified here. This analysis of protease structure and function unifies 50 y of biocatalysis research, providing a framework for the continued study of enzyme evolution and the development of inhibitors with increased selectivity.peptidase | antibiotic stereochemistry | N-terminal nucleophile T he acceleration of chemical reactions is essential to all biochemistry. The generation of reactive species by enzymes is tightly controlled and limited by the chemical makeup of the 20 proteinogenic amino acids. In isolation, no protein residue harbors a strong nucleophile at physiological pH. Rather, enzymatic activity arises after protein folding introduces cooperative interactions that selectively amplify the reactivity of their otherwise weakly active functional groups. The preeminent system through which this phenomenon has been studied is the Ser-His-Asp catalytic triad of the Ser proteases (1). Several distinct molecular strategies have been identified that contribute to rate enhancement. Substrate binding increases the local concentration of interacting species, general acids and bases facilitate proton transfer, and a high-energy step can be split into multiple lowerenergy steps (2). These distinct molecular strategies may be unified through the formalism of transition-state theory (3) and the idea that the active site is electrostatically preorganized for transition-state stabilization (4, 5). Although the biophysics of rate acceleration are intricate and sensitive to even minor structural perturbations, evolution has converged on a catalytic triad (or diad) with a rea...

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Section: Reactive Rotamer Determines the Identity Of The Local Oxyanionmentioning

confidence: 95%

Intrinsic evolutionary constraints on protease structure, enzyme acylation, and the identity of the catalytic triad

Buller

Townsend

2013

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

134

117

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“…A. An enzyme assisted hydrogen bond donated by the reacting NH group of the pantetheinylated carbapenem substrate and accepted by S320 has been suggested for the enzyme ThnT . ThnT is involved in antibiotic synthesis and contains an N‐terminal Thr dyad with a distinct fold compared with the proteasome β‐unit and penicillin acylase.…”

Section: H‐bond Strategy: a General Additional Catalytic Element In Nmentioning

confidence: 99%

The solution of nitrogen inversion in amidases

Syrén

2013

The FEBS Journal

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An important mechanistic aspect of enzyme catalyzed amide bond hydrolysis is the specific orientation of the lone pair of the nitrogen of the scissile amide bond during catalysis. As discussed in the literature during the last decades, stereoelectronic effects cause the single lone pair in the formed tetrahedral intermediate to be situated in a non-productive conformation in the enzyme active site and hence nitrogen inversion or rotation is necessary. By discussing recent mechanistic findings in the literature relevant for the conformation of the lone pair of the reacting amide nitrogen atom, it will be demonstrated that nature has evolved at least two catalytic strategies to cope with the stereoelectronic constraints inherent to amide bond hydrolysis regardless of the fold or catalytic mechanism. One solution to the inversion problem is to stabilize the transition state of inversion by hydrogen bond formation; another is to introduce a concerted proton shuttle mechanism that avoids inversion and delivers a hydrogen to the lone pair. By using molecular modeling it is demonstrated that the H-bond strategy is general and can be expanded to include many amidases/proteases with important metabolic functions, including the proteasome. Some examples of the proton shuttle mechanism will also be mentioned. To complete the picture of efficient enzyme catalyzed amide bond hydrolysis, general interactions in the active site of these catalysts will be discussed. An expanded knowledge of the prerequisites of efficient amide bond hydrolysis beyond the oxyanion hole and the catalytic dyad/triad will be of importance for enzyme and drug design.

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“…This unanticipated conformation was identical to that observed in the postautoproteolysis structure of wild-type ThnT and is necessary for substrate binding in the mature enzyme. 34 Stepwise inclusion of higher-resolution data during model refinement resulted in numerous peaks in the F o – F c map indicative of structural heterogeneity (Figure 3 C). Given that modeling of weak density results in a phase bias, we were concerned that modeling with multiple conformations would be impossible.…”

Section: Resultsmentioning

confidence: 99%

“…The trans isomer dominates in the structure of T282A and is the only one observed in the postautoproteolysis wild-type enzyme. 34 The cis isomer is more prevalent in the T282C structure, and we hypothesized that it facilitates efficient autoprocessing. Specifically, the data show that the backbone carbonyl of Gly77 in the cis isomer positions a water molecule to aid in the activation of the nucleophile for the N → O acyl shift.…”

Section: Resultsmentioning

confidence: 99%

“…Expression and purification of all ThnT proteins were similar to reported procedures. 34 Proteins were bound to a Ni-nitriloacetate column and eluted in 250 mM imidazole, 50 mM sodium phosphate (pH 7.5), 40 mM NaCl, and 10% glycerol. Protein was concentrated in a 10 KDa molecular weight cutoff Amicon filtration device (Bio-Rad) and buffer exchanged into 10 mM potassium phosphate (pH 7.5) with 10% glycerol (for kinetic experiments) or 20 mM potassium phosphate (pH 7.5) with 5% glycerol (for crystallography).…”

Section: Methodsmentioning

confidence: 99%

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Exploring the Role of Conformational Heterogeneity in cis-Autoproteolytic Activation of ThnT

et al. 2014

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In the past decade, there have been major achievements in understanding the relationship between enzyme catalysis and protein structural plasticity. In autoprocessing systems, however, there is a sparsity of direct evidence of the role of conformational dynamics, which are complicated by their intrinsic chemical reactivity. ThnT is an autoproteolytically activated enzyme involved in the biosynthesis of the β-lactam antibiotic thienamycin. Conservative mutation of ThnT results in multiple conformational states that can be observed via X-ray crystallography, establishing ThnT as a representative and revealing system for studing how conformational dynamics control autoactivation at a molecular level. Removal of the nucleophile by mutation to Ala disrupts the population of a reactive state and causes widespread structural changes from a conformation that promotes autoproteolysis to one associated with substrate catalysis. Finer probing of the active site polysterism was achieved by EtHg derivatization of the nucleophile, which indicates the active site and a neighboring loop have coupled dynamics. Disruption of these interactions by mutagenesis precludes the ability to observe a reactive state through X-ray crystallography, and application of this insight to other autoproteolytically activated enzymes offers an explanation for the widespread crystallization of inactive states. We suggest that the N → O(S) acyl shift in cis-autoproteolysis might occur through a si-face attack, thereby unifying the fundamental chemistry of these enzymes through a common mechanism.

show abstract

Autoproteolytic Activation of ThnT Results in Structural Reorganization Necessary for Substrate Binding and Catalysis

Cited by 11 publications

References 47 publications

Intrinsic evolutionary constraints on protease structure, enzyme acylation, and the identity of the catalytic triad

Intrinsic evolutionary constraints on protease structure, enzyme acylation, and the identity of the catalytic triad

The solution of nitrogen inversion in amidases

Exploring the Role of Conformational Heterogeneity in cis-Autoproteolytic Activation of ThnT

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