Catalysis of Hydrolysis and Transesterification Reactions of <i>p</i>-Nitrophenyl Esters by a Designed Helix−Loop−Helix Dimer

Broo, Klas; Brive, Lars; Ahlberg, Per; Baltzer, Lars

doi:10.1021/ja970854s

Cited by 117 publications

(119 citation statements)

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“…23 The overall catalytic efficiency (kcat/KM = 3.7 ± 0.6 M -1 s -1 ) is approximately equal to previous redesign attempts (Table 2 entries 3, 8&9). In our case, the reaction is turned over expelling acetate, and it is not driven by other nucleophilic side chains near the active site, which can become irreversibly acylated as the reaction proceeds contributing to observed kinetic profiles.…”

Section: Discussionmentioning

confidence: 49%

“…[20][21][22] Although more challenging, this would carry advantages over redesign approaches: firstly, the designer could select and control all, or at least many of the residues, and so engineer the complete construct predictably; secondly, the resulting proteins could be made to function under conditions away from those required by natural proteins; and finally, success in this area would provide the acid test of our understanding of enzyme structure and function. Towards this fully de novo effort, successful designs of hydrolases have included: the decoration of small protein-folding motifs with His residues; 23,24 the employment of Zn 2+ cations as Lewisacidic cofactors; [25][26][27][28] and the identification of catalytically active proteins in combinatorial libraries of sequences patterned to form to all- or all- protein folds. 29 One of the most productive areas in the de novo design of protein structure has been for coiled-coil assemblies.…”

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confidence: 99%

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Installing hydrolytic activity into a completely de novo protein framework

et al. 2016

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Designing enzyme-like catalysts tests our understanding of sequence-tostructure/function relationships in proteins. Here, we install hydrolytic activity predictably into a completely de novo and thermo-stable -helical barrel, which comprises 7 helices arranged around an accessible channel. We show that the lumen of the barrel accepts 21 mutations to functional polar residues. The resulting variant, which has cysteine-histidine-glutamic acid triads on each helix, hydrolyses pnitrophenyl acetate with catalytic efficiencies matching the most-efficient redesigned hydrolases based on natural protein scaffolds. This is the first report of a functional catalytic triad engineered into a de novo protein framework. The flexibility of our system also allows the facile incorporation of unnatural side chains to improve activity and probe the catalytic mechanism. Such predictable and robust construction of truly de novo biocatalysts holds promise for applications in chemical and biochemical synthesis.(134 words)

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Section: Discussionmentioning

confidence: 49%

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confidence: 99%

Installing hydrolytic activity into a completely de novo protein framework

et al. 2016

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“…The second-order rates for these peptides were determined under different conditions than those used here, making direct comparisons difficult. At pH 5.1, rates of 0.29 M Ϫ1 sec Ϫ1 and 0.056 M Ϫ1 sec Ϫ1 have been reported (39,40). Extrapolation based on the pH rate profiles (39) reported for the hydrolysis of similarly activated esters suggests rates of Ϸ0.7 and 0.2 M Ϫ1 sec Ϫ1 for PNPA hydrolysis at pH 7, respectively.…”

Section: Resultsmentioning

confidence: 98%

Enzyme-like proteins by computational design

Bolon

Mayo

2001

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

373

299

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We report the development and initial experimental validation of a computational design procedure aimed at generating enzymelike protein catalysts called ''protozymes.'' Our design approach utilizes a ''compute and build'' strategy that is based on the physical͞chemical principles governing protein stability and catalytic mechanism. By using the catalytically inert 108-residue Escherichia coli thioredoxin as a scaffold, the histidine-mediated nucleophilic hydrolysis of p-nitrophenyl acetate as a model reaction, and the ORBIT protein design software to compute sequences, an active site scan identified two promising catalytic positions and surrounding active-site mutations required for substrate binding. Experimentally, both candidate protozymes demonstrated catalytic activity significantly above background. One of the proteins, PZD2, displayed ''burst'' phase kinetics at high substrate concentrations, consistent with the formation of a stable enzyme intermediate. The kinetic parameters of PZD2 are comparable to early catalytic Abs. But, unlike catalytic Ab design, our design procedure is independent of fold, suggesting a possible mechanism for examining the relationships between protein fold and the evolvability of protein function.A prominent goal of protein design is the generation of proteins with novel functions, including the catalytic rate enhancement of chemical reactions. The ability to design an enzyme to perform a given chemical reaction has considerable practical application for industry and medicine, particularly for the synthesis of pharmaceuticals (1). Significant progress has been made at enhancing the catalytic properties of existing enzymes through directed evolution (2). In contrast, the design of proteins with novel catalytic properties has met with relatively limited success (3-5). We present a general computational approach for the design of enzyme-like proteins with novel catalytic activities.The use of transition-state analogs as haptens to elicit catalytic Abs has been the most successful technique to date for generating novel protein catalysts (6). Natural enzymes combine transition-state stabilization with precisely oriented catalytic side chains. Although a reactive hapten has been used in the generation of an Ab with a powerful nucleophile at the active site (7), current catalytic Ab technology does not efficiently select for both catalytic side chains and tight noncovalent affinity in the same molecule. The relationship between the general backbone fold of an enzyme and its catalytic properties is not well understood. This observation is particularly relevant to catalytic Abs that are currently constrained to the Ab fold and which have yet to show catalytic activity on par with natural enzymes.Rational design efforts have recently succeeded at altering the catalytic reactions of two different enzymes (8, 9). Cyclophilin, a cis-trans isomerase of X-Pro peptide bonds, was engineered into an endopeptidase by grafting a triad of catalytic residues commonly found in serine proteases at the...

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“…protein design | catalysis | pKa T he design of enzyme-like catalytic proteins is a challenging endeavour that has been approached using combinatorial (1) and computational strategies (2), as well as by following simple chemical principles (3,4). The Kemp elimination (5) (Scheme 1) is an extensively studied benchmark for catalyst design (6)(7)(8) as a model for enzymatic C-H bond abstraction.…”

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confidence: 99%

Design of a switchable eliminase

Korendovych

Kulp

et al. 2011

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

120

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The active sites of enzymes are lined with side chains whose dynamic, geometric, and chemical properties have been finely tuned relative to the corresponding residues in water. For example, the carboxylates of glutamate and aspartate are weakly basic in water but become strongly basic when dehydrated in enzymatic sites. The dehydration of the carboxylate, although intrinsically thermodynamically unfavorable, is achieved by harnessing the free energy of folding and substrate binding to reach the required basicity. Allosterically regulated enzymes additionally rely on the free energy of ligand binding to stabilize the protein in a catalytically competent state. We demonstrate the interplay of protein folding energetics and functional group tuning to convert calmodulin (CaM), a regulatory binding protein, into AlleyCat, an allosterically controlled eliminase. Upon binding Ca(II), native CaM opens a hydrophobic pocket on each of its domains. We computationally identified a mutant that (i) accommodates carboxylate as a general base within these pockets, (ii) interacts productively in the Michaelis complex with the substrate, and (iii) stabilizes the transition state for the reaction. Remarkably, a single mutation of an apolar residue at the bottom of an otherwise hydrophobic cavity confers catalytic activity on calmodulin. AlleyCat showed the expected pH-rate profile, and it was inactivated by mutation of its active site Glu to Gln. A variety of control mutants demonstrated the specificity of the design. The activity of this minimal 75-residue allosterically regulated catalyst is similar to that obtained using more elaborate computational approaches to redesign complex enzymes to catalyze the Kemp elimination reaction.protein design | catalysis | pKa T he design of enzyme-like catalytic proteins is a challenging endeavour that has been approached using combinatorial (1) and computational strategies (2), as well as by following simple chemical principles (3, 4). The Kemp elimination (5) (Scheme 1) is an extensively studied benchmark for catalyst design (6-8) as a model for enzymatic C-H bond abstraction. Previously, computational methods were employed to alter the active sites of natural enzymes to catalyze this reaction (7). Mutation of a dozen or more side chains resulted in catalysts that showed rate enhancements of 10 4 to 10 5 relative to a given reference rate. Here, by combining a few physical principles with modern computational tools, we show that a single mutation can confer similar catalytic efficiency into a much simpler and allosterically switchable scaffold that previously had no catalytic activity. This approach circumvents often contentious questions concerning residual activities of the enzymatic framework or the appropriate reference background rate for expression of a "rate enhancement" while also suggesting a practical approach to the design of catalytically amplified sensors.Here we applied a minimalist approach to protein design (9-11), which emphasizes the use of the simple scaffolds and the min...

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Catalysis of Hydrolysis and Transesterification Reactions of p-Nitrophenyl Esters by a Designed Helix−Loop−Helix Dimer

Cited by 117 publications

References 27 publications

Installing hydrolytic activity into a completely de novo protein framework

Installing hydrolytic activity into a completely de novo protein framework

Enzyme-like proteins by computational design

Design of a switchable eliminase

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