Mutational analysis of human glutathione transferase A2-2 identifies structural elements supporting high activity with the prodrug azathioprine

Glutathione transferase (GST) A2-2 is the human enzyme displaying the highest catalytic activity with the prodrug azathioprine (Aza). The reaction releases pharmacologically active 6-mercaptopurine by displacing the imidazole moiety from the Aza molecule. The GST-catalyzed reaction is of medical significance, since high rates of Aza activation may lead to adverse side effects in treated patients. The present study involves structure-activity relationships in GST A2-2 variants. Chimeric GSTs were previously generated by DNA shuffling and two peptide segments, one N-terminal and one C-terminal, were identified as primary determinants of Aza activity. The segments contain several residues of the substrate-binding H-site and their significance for supporting high Aza activity was investigated. Substitution of the corresponding two small regions in the low-activity human GST A3-3 or rat GST A3-3 by the human GST A2-2 segments generated chimeras with ～10-fold enhanced Aza activity. The H-site residues Met208 and Leu213 in the C-terminal segment of GST A2-2 were mutated to produce a library with all possible residue combinations. At a calculated 93% library coverage, all of the 1880 mutants examined showed wild-type or decreased Aza activity, even though some retained activities with alternative substrates, further emphasizing the importance of this region for the targeted activity.     

Trp89 in the lid ofHumicola lanuginosa lipase is important for efficient hydrolysis of tributyrin

To determine whether Trp89 located in the lid of the lipase (EC 3.1.1.3) fromHumicola lanuginosa is important for the catalytic property of the enzyme, site-directed mutagenesis at Trp89 was carried out. The kinetic properties of wild type and mutated enzymes were studied with tributyrin as substrate. Lipase variants in which Trp89 was changed to Phe, Leu, Gly or Glu all showed less than 14% of the activity compared to that of the wild type lipase. The Trp89Glu mutant was the least active with only 1% of the activity seen with the wild type enzyme. All Trp mutants had the same binding affinity to the tributyrin substrate interface as did the wild type enzyme. Wild type lipase showed saturation kinetics against tributyrin when activities were measured with mixed emulsions containing different proportions of tributyrin and the nonionic alkyl polyoxyethylene ether surfactant, Triton DF-16. Wild type enzyme showed a V_max=6000±300 mmol·min⁻¹·g⁻¹ and an apparent K_m=16±2% (vol/vol) for tributyrin in Triton DF-16, while the mutants did not show saturation kinetics in an identical assay. The apparent K_m for tributyrin in Triton DF-16 was increased as the result of replacing Trp89 with other residues (Phe, Leu, Gly or Glu). The activities of all mutants were more sensitive to the presence of Triton DF-16 in the tributyrin substrate than was wild type lipase. The activity of the Trp89Glu mutant was decreased to 50% in the presence of 2 vol% Triton DF-16 compared to the activity seen with pure tributyrin as substrate. Wild type lipase and all mutants except Trp89Glu had the same affinity for the substrate interface formed by 15.6 vol% tributyrin in Triton DF-16. The Trp89Glu mutant showed a lower affinity than all the other lipase variants for the interface of 15.6 vol% tributyrin in Triton DF-16. The study showed that Trp89 located in the lid ofH. lanuginosa lipase is important for the efficient hydrolysis of tributyrin and that this residue plays a role in the catalytic steps after adsorption of the lipase to the substrate interface.     

Generation of a broad esterolytic subtilisin using combined molecular evolution and periplasmic expression

Concomitant activity improvement of an evolved enzyme towardtwo very different ester substrates was achieved when a uniquecombination of functional periplasmic enzyme expression in Escherichiacoli, random mutagenesis, DNA shuffling and cell-based kineticscreenings was applied. Specifically, we focused on the conversionof subtilisin E into an enzyme with broader esterase activityas opposed to its native amidase activity. Cell-based microtiterassays were performed on N-acetyl-D,L-phenylalanine p-nitrophenylester (Phe-NPE) and sucrose 1'-adipate (S1'A), as well as onthe tetrapeptide amide substrate N-succinyl-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide.After a single modified cycle of directed molecular evolution,we isolated a number of clones exhibiting increased activitytoward Phe-NPE. In the following rounds of screenings, mutantswith improved activity on Phe-NPE were also tested on S1'A.Three mutants were identified with increased esterolytic activityon Phe-NPE and S1'A, while having similar amidase activity tothat of the parental enzymes. Because the two ester substratesare structurally distinct, we have evolved a more general esterolyticsubtilisin and this may have important applications in synthesis.     

Multivariate-activity mining for molecular quasi-species in a glutathione transferase mutant library

A library of recombinant glutathione transferases (GSTs) generated by shuffling of DNA encoding human GST M1-1 and GST M2-2 was screened with eight alternative substrates, and the activities were subjected to multivariate analysis. Assays were made in lysates of bacteria in which the GST variants had been expressed. The primary data showed clustering of the activities in eight-dimensional substrate-activity space. For an incisive analysis, the rows of the data matrix, corresponding to the different enzyme variants, were individually scaled to unit length, thus accounting for different expression levels of the enzymes. The columns representing the activities with alternative substrates were subsequently individually normalized to unit variance and a zero mean. By this standardization, the data were adjusted to comparable orders of magnitude. Three molecular quasi-species were recognized by multivariate K-means and principal component analyses. Two of them encompassed the parental GST M1-1 and GST M2-2. A third one diverged functionally by displaying enhanced activities with some substrates and suppressed activities with signature substrates for GST M1-1 and GST M2-2. A fourth cluster contained mutants with impaired functions and was not regarded as a quasi-species. Sequence analysis of representatives of the mutant clusters demonstrated that the majority of the variants in the diverging novel quasi-species were structurally similar to the M1-like GSTs, but distinguished themselves from GST M1-1 by a Ser to Thr substitution in the active site. The data show that multivariate analysis of functional profiles can identify small structural changes influencing the evolution of enzymes with novel substrate-activity profiles.     

Catalytic promiscuity in the alpha/beta-hydrolase superfamily: hydroxamic acid formation, C--C bond formation, ester and thioester hydrolysis in the C--C hydrolase family

The haloperoxidase family of alpha/beta-hydrolases contains enzymes of several different catalytic activities, including esterases, C--C hydrolases and cofactor-independent haloperoxidases (perhydrolases), but the molecular basis of this catalytic promiscuity is not fully understood. The C--C hydrolase enzyme MhpC from E. coli is shown to possess esterase and thioesterase activity, and the ability to activate hydroxylamine as a nucleophile to form hydroxamic acid products. The ratio of these activities was examined for nine site-directed mutant enzymes that contained mutations at nonessential residues in the enzyme active site. Higher levels of esterase and thioesterase activity were found in mutants Phe173Gly and Trp264Gly; this might be due to increased amounts of space in the active site. Higher levels of hydroxamic acid formation activity were found in mutant Asn109His-a mutation found in many haloperoxidase enzymes. Wild-type and mutant MhpC enzymes were also capable of C--C bond formation in organic solvents, and the highest activity was observed in nonpolar solvents. The results provide experimental support for the catalytic promiscuity shown in this family of enzymes, and indicate that differences in catalytic function can be introduced by point mutations.     

Ultrahigh‐Throughput FACS‐Based Screening for Directed Enzyme Evolution

Directed enzyme evolution has proven to be a powerful tool for improving a range of properties of enzymes through consecutive rounds of diversification and selection. However, its success depends heavily on the efficiency of the screening strategy employed. Fluorescence‐activated cell sorting (FACS) has recently emerged as a powerful tool for screening enzyme libraries due to its high sensitivity and its ability to analyze as many as 10⁸ mutants per day. Applications of FACS screening have allowed the isolation of enzyme variants with significantly improved activities, altered substrate specificities, or even novel functions. This review discusses FACS‐based screening for enzymatic activity and its potential application for the directed evolution of enzymes, ribozymes, and catalytic antibodies.     

底物特异性的生物催化与酶设计改造

随着生物产业的发展,生物酶催化发挥着越来越重要的作用。然而,部分酶在应用过程中仍然存在诸多问题,影响了生物催化的进一步发展。本文以酶的底物特异性为切入点,回顾了酶的专一性、高效性和环保性;介绍了酶在药物合成和天然产物改性领域的应用以及所遇到的问题;综述了酶的底物特异性改造过程中各种方法的应用,包括化学修饰、非理性和理性设计。化学修饰作为一种直观的修饰方法,通过化学反应对酶分子进行改造;非理性设计是利用易错PCR和DNA Shuffling等手段获得底物特异性提高的突变体;理性设计是基于序列和结构信息对酶分子进行改造。本文从重塑活性口袋提高酶的底物特异性和重塑活性口袋改变酶促反应类型两个方面出发,详述了理性设计改变酶的底物特异性的方法,为酶的特异性改造提供借鉴。     

Examining reactivity and specificity of cytochrome c peroxidase by using combinatorial mutagenesis

Combinatorial mutagenesis was used to investigate the role of three key residues in cytochrome c peroxidase (CCP) from Saccharomyces cerevisiae, Arg48, Trp51, and Trp191, in control of the reactivity and selectivity of the heme-containing enzyme. Libraries were prepared by randomization of these residues and were subsequently screened for activity against the phenolic substrate guaiacol. Screening conditions were employed that favor either mutants with high activity or those with both high activity and stability of the reactive enzyme intermediates. The results obtained suggest a dual role for Arg48 of CCP: in addition to stabilizing reactive enzyme intermediates, the distal arginine residue plays a major role in restriction of access to the ferryl oxygen atom by small molecules and thereby controls reactivity and substrate specificity of the peroxidase. At position 51 of CCP, either a phenylalanine or a tryptophan residue is required both for catalytic and structural reasons. In contrast, either polar or positively charged residues are accepted at the position of Trp191, which is located inside the core of the protein. The variability at position 191 can be interpreted as a reflection of the mechanism of cytochrome c peroxidase, which transforms the nonpolar Trp191 into a transient cation radical.     

Engineering the xenobiotic substrate specificity of maize glutathione S-transferase I

Glutathione S-transferases (GSTs) are a heterogeneous family of enzymes that catalyse the conjugation of glutathione (GSH) to electrophilic sites on a variety of hydrophobic substrates. In the present study three amino acid residues (Trp12, Phe35 and Ile118) of the xenobiotic binding site (H-site) of maize GST I were altered in order to evaluate their contribution to substrate binding and catalysis. These residues are not conserved and hence may affect substrate specificity and/or product dissociation. The results demonstrate that these residues are important structural moieties that modulate an enzyme's catalytic efficiency and specificity. Phe35 and Ile118 also participate in k(cat) regulation by affecting the rate-limiting step of the catalytic reaction. The effect of temperature on the catalytic activity of the wild-type and mutant enzymes was also investigated. Biphasic Arrhenius and Eyring plots for the wild-type enzyme showed an apparent transition temperature at 35 degrees C, which seems to be the result of a change in the rate-limiting step of the catalytic reaction. Thermodynamic analysis of the activity data showed that the activation energy increases at low temperatures, whereas the entropy change seems to be the main determinant that contributes to the rate-limiting step at high temperatures.     

Alteration of substrate specificity of cholesterol oxidase from Streptomyces sp. by site-directed mutagenesis

Despite the structural similarities between cholesterol oxidasefrom Streptomyces and that from Brevibacterium, both enzymesexhibit different characteristics, such as catalytic activity,optimum pH and temperature. In attempts to define the molecularbasis of differences in catalytic activity or stability, substitutionsat six amino acid residues were introduced into cholesteroloxidase using site-directed mutagenesis of its gene. The aminoacid substitutions chosen were based on structural comparisonsof cholesterol oxidases from Streptomyces and Brevibacterium.Seven mutant enzymes were constructed with the following aminoacid substitutions: L117P, L119A, L119F, V145Q, Q286R, P357Nand S379T. All the mutant enzymes exhibited activity with theexception of that with the L117P mutation. The resulting V145Qmutant enzyme has low activities for all substrates examinedand the S379T mutant enzyme showed markedly altered substratespecificity compared with the wild-type enzyme. To evaluatethe role of V145 and S379 residues in the reaction, mutantswith two additional substitutions in V145 and four in S379 wereconstructed. The mutant enzymes created by the replacement ofV145 by Asp and Glu had much lower catalytic efficiency forcholesterol and pregnenolone as substrates than the wild-typeenzyme. From previous studies and this study, the V145 residueseems to be important for the stability and substrate bindingof the cholesterol oxidase. In contrast, the catalytic efficiencies(k_cat/K_m) of the S379T mutant enzyme for cholesterol and pregnenolonewere 1.8- and 6.0-fold higher, respectively, than those of thewild-type enzyme. The enhanced catalytic efficiency of the S379Tmutant enzyme for pregnenolone was due to a slightly high k_catvalue and a low K_m value. These findings will provide severalideas for the design of more powerful enzymes that can be appliedto clinical determination of serum cholesterol levels and assterol probes.     

Proteolytic Antibodies

Catalytic activities are known to arise naturally in antibodies. Several naturally-occurring peptides, synthetic protease substrates, DNA, and esters are known to be cleaved by antibodies. There is increased production of antigen-specific catalytic antibodies in autoimmune disease. Polyreactive catalytic antibodies are present in unimmunized donors. Antibody light chains isolated from multiple myeloma patients frequently express proteolytic activity. Immunization protocols using as immunogens the ground state of a naturally-occurring polypeptide, anti-enzyme antibodies, or the enzyme itself are known to provoke catalytic antibody synthesis. Active site residues in the light chain subunit serve as the catalytic residues in a model antibody with peptide bond cleaving activity. A split-site model in which distinct amino acids serve as the essential catalytic residues and substrate ground-state recognition residues has been developed from mutagenesis studies. Engineering of the available antibodies could potentially generate improved catalysts. The possible mechanisms underlying proteolysis by natural antibodies and evolution of the catalytic activity are reviewed.     

Kinetic and structural characterization of thermostabilized mutants of human carbonic anhydrase II

Carbonic anhydrases (CAs) are ubiquitous enzymes that catalyze the reversible hydration/dehydration of carbon dioxide/bicarbonate. As such, there is enormous industrial interest in using CA as a bio-catalyst for carbon sequestration and biofuel production. However, to ensure cost-effective use of the enzyme under harsh industrial conditions, studies were initiated to produce variants with enhanced thermostability while retaining high solubility and catalytic activity. Kinetic and structural studies were conducted to determine the structural and functional effects of these mutations. X-ray crystallography revealed that a gain in surface hydrogen bonding contributes to stability while retaining proper active site geometry and electrostatics to sustain catalytic efficiency. The kinetic profiles determined under a variety of conditions show that the surface mutations did not negatively impact the carbon dioxide hydration or proton transfer activity of the enzyme. Together these results show that it is possible to enhance the thermal stability of human carbonic anhydrase II by specific replacements of surface hydrophobic residues of the enzyme. In addition, combining these stabilizing mutations with strategic active site changes have resulted in thermostable mutants with desirable kinetic properties.     

Effects of non-conservative changes to tyrosine 76, a key DNA binding residue of DNase I, on phosphodiester bond cleavage and DNA hydrolysis selectivity

Non-conservative changes, consisting of Y76E, Y76L, Y76Q and Y76W, have been made to tyrosine 76, one of the key DNA binding residues in DNase I. Normally Y76 inserts into the minor groove of DNA and makes an unusual, hydrophobic, stacking interaction with one of the sugars. All four mutants bind to DNA more tightly than the wild type, but cut it more slowly as assessed by Kunitz assays. This gives a rather small decrease in the specificity constants (Vmax/K(m)) for the hydrolysis of DNA, which is roughly paralleled by the loss of activity towards the non-DNA small chromophoric substrate, thymidine-3',5'-di(p- nitrophenyl)phosphate. These non-conservative mutants, therefore, show different behaviour to Y76A and Y76G, studied previously [Doherty A.J., Worrall A.F. and Connolly B.A. (1995) J: Mol. Biol., 251, 366-377]. These two mutants both bind to and cut DNA poorly, resulting in large decreases in Vmax/K(m) values. However, they showed little reduction in rates with the chromophoric substrate. It is likely that the altered side chains in the non-conservative mutants are still able to interact productively with the DNA and contribute to the observed DNA distortion that is essential for efficient catalysis. However, these mutations disrupt the active site, most probably by interference with the hydrogen bonded Y76-E78-H134 triad. H134 is a critical hydrolytic residue of DNase I that is essential for catalysis. The DNA cleavage selectivity of the Y76E, Y76L, Y76Q and Y76W mutants were little altered as compared with the wild-type enzyme as measured using the cutting patterns of a 160 base-pair Escherichia coli Tyr T promoter DNA fragment. This confirms earlier observations, with Y76F, Y76A and Y76G, that showed that this tyrosine has little role in DNA cleavage specificity.      

Engineered human carboxypeptidase B enzymes that hydrolyse hippuryl-L- glutamic acid: reversed-polarity mutants

Variants of human pancreatic carboxypeptidase B (HCPB), with specificity for hydrolysis of C-terminal glutamic acid and aspartic acid, were prepared by site-directed mutagenesis of the human gene and expressed in the periplasm of Escherichia coli. By changing residues in the lining of the S1' pocket of the enzyme, it was possible to reverse the substrate specificity to give variants able to hydrolyse prior to C- terminal acidic amino acid residues instead of the normal C-terminal basic residues. This was achieved by mutating Asp253 at the base of the S1' specificity pocket, which normally interacts with the basic side- chain of the substrate, to either Lys or Arg. The resulting enzymes had the desired reversed polarity and enzyme activity was improved significantly with further mutations at residue 251. The [G251T,D253K]HCPB double mutant was 100 times more active against hippuryl-L-glutamic acid (hipp-Glu) as substrate than was the single mutant, [D253K]HCPB. Triple mutants, containing additional changes at Ala248, had improved activity against hipp-Glu substrate when position 251 was Asn. These reversed-polarity mutants of a human enzyme have the potential to be used in antibody-directed enzyme prodrug therapy of cancer.      

Random mutagenesis improves the low-temperature activity of the tetrameric 3-isopropylmalate dehydrogenase from the hyperthermophile Sulfolobus tokodaii

In general, the enzymes of thermophilic organisms are more resistant to thermal denaturation than are those of mesophilic or psychrophilic organisms. Further, as is true for their mesophilic and psychrophilic counterparts, the activities of thermophilic enzymes are smaller at temperatures that are less than the optimal temperature. In an effort to characterize the properties that would improve its activity at temperatures less than the optimal, we subjected the thermostable Sulfolobus tokodaii (S. tokodaii) 3-isopropylmalate dehydrogenase to two rounds of random mutagenesis and selected for improved low-temperature activity using an in vivo recombinant Escherichia coli system. Five dehydrogenase mutants were purified and their catalytic properties and thermostabilities characterized. The mutations favorably affect the K(m) values for NAD (nicotinamide adenine dinucleotide) and/or the k(cat) values. The results of thermal stability measurements show that, although the mutations somewhat decrease the stability of the enzyme, the mutants are still very resistant to heat. The locations and properties of the mutations found for the S. tokodaii enzyme are compared with those found for the previously isolated low-temperature adapted mutants of the homologous Thermus thermophilus enzyme. However, there are few, if any, common properties that enhance the low-temperature activities of both enzymes; therefore, there may be many ways to improve the low-temperature catalytic activity of a thermostable enzyme.     

Synthetic artificial peptidases and nucleases using macromolecular catalytic systems

Effective artificial enzymes have been designed by adopting macromolecular systems for catalyst-substrate complexes. Artificial active sites comprising two or more organic functional groups were built on macromolecular backbones, leading to several types of organic artificial proteases. The activity of metal centers for peptide or DNA hydrolysis was greatly enhanced by attachment to polystyrene, leading to artificial metallopeptidases with substrate selectivity as well as artificial metallonucleases with high catalytic activity for double stranded DNA. A small artificial protease selective for a macromolecular target protein was synthesized. Target-specific artificial proteases can be used as protein-cleaving catalytic drugs.     

Alteration of catalytic properties of chymosin by site-directed mutagenesis

Artificial mutations of chymosin by recombinant DNA techniqueswere generated to analyze the structure–function relationshipin this characteristic aspartk proteinase. In order to preparethe mutant enzymes in their active form, we established proceduresfor purification of correctly refolded prochymosin from inclusionbodies produced in Escherichia coli transformants and for itssubsequent activation. Mutagenesis by linker insertion intocDNA produced several mutants with an altered ratio of milkclotting activity to proteolytic activity and a different extentof stability. In addition to these mutants, several mutantswith a single amino acid exchange were also constructed by site-directedmutagenesis and kinetic parameters of these mutant enzymes weredetermined by using synthetic hexa- and octa-peptides as substrates.Exchange of Tyr75 on the flap of the enzyme to Phe caused amarked change of substrate specificity due to the change ofk_cat or K_m, depending on the substrate used. Exchange of Val110and Phe111 also caused a change of kinetic parameters, whichindicates functional involvement of these hydrophobic residuesin both the catalytic function and substrate binding. The mutantLys220–Leu showed a marked shift of the optimum pH tothe acidic side for hydrolysis of acid-denatured haemoglobinalong with a distinct increase in k_cat for the octa-peptidein a wide pH range.     

Comparative Analysis of Exo- and Endonuclease Activities of APE1-like Enzymes

Apurinic/apyrimidinic (AP)-endonucleases are multifunctional enzymes that are required for cell viability. AP-endonucleases incise DNA 5′ to an AP-site; can recognize and process some damaged nucleosides; and possess 3′-phosphodiesterase, 3′-phosphatase, and endoribonuclease activities. To elucidate the mechanism of substrate cleavage in detail, we analyzed the effect of mono- and divalent metal ions on the exo- and endonuclease activities of four homologous APE1-like endonucleases (from an insect (Rrp1), amphibian (xAPE1), fish (zAPE1), and from humans (hAPE1)). It was found that the enzymes had similar patterns of dependence on metal ions’ concentrations in terms of AP-endonuclease activity, suggesting that the main biological function (AP-site cleavage) was highly conserved among evolutionarily distant species. The efficiency of the 3′-5′ exonuclease activity was the highest in hAPE1 among these enzymes. In contrast, the endoribonuclease activity of the enzymes could be ranked as hAPE1 ≈ zAPE1 ≤ xAPE1 ≤ Rrp1. Taken together, the results revealed that the tested enzymes differed significantly in their capacity for substrate cleavage, even though the most important catalytic and substrate-binding amino acid residues were conserved. It can be concluded that substrate specificity and cleavage efficiency were controlled by factors external to the catalytic site, e.g., the N-terminal domain of these enzymes.     

Mutational analysis of a key residue in the substrate specificity of a cephalosporin acylase

beta-Lactam acylases are crucial for the synthesis of semisynthetic cephalosporins and penicillins. Unfortunately, there are no cephalosporin acylases known that can efficiently hydrolyse the amino-adipic side chain of Cephalosporin C. In a previous directed evolution experiment, residue Asn266 of the glutaryl acylase from Pseudomonas SY-77 was identified as being important for substrate specificity. In order to explore the function of this residue in substrate specificity, we performed a complete mutational analysis of position 266. Codons for all amino acids were introduced in the gene, 16 proteins that could be functionally expressed in Escherichia coli were purified to homogeneity and their catalytic parameters were determined. The mutant enzymes displayed a broad spectrum of affinities and activities, pointing to the flexibility of the enzyme at this position. Mutants in which Asn266 was changed into Phe, Gln, Trp and Tyr displayed up to twofold better catalytic efficiency (k(cat)/K(m))than the wild-type enzyme when adipyl-7-aminodesacetoxycephalosporanic acid (adipyl-7-ADCA) was used as substrate, due to a decreased K(m). Only mutants SY-77(N266H) and SY-77(N266M) showed an improvement of both catalytic parameters, resulting in 10- and 15-times higher catalytic efficiency with adipyl-7-ADCA, respectively. Remarkably, the catalytic activity (k(cat)) of SY-77(N266M) when using adipyl-7-ADCA as substrate was as high as when glutaryl-7-aminocephalosporanic acid (glutaryl-7-ACA) was used, and approaches commercially interesting activity. SY-77(N266Q), SY-77(N266H) and SY-77(N266M) mutants showed a modest improvement in hydrolysing Cephalosporin C. Since these mutants also have a good catalytic efficiency when adipyl-7-ADCA is used and are still active towards glutaryl-7-ACA, they can be regarded as broad substrate acylases. These results demonstrate that the combination of directed evolution for the identification of important positions, together with saturation mutagenesis for finding the optimal amino acid, is a very effective method for finding improved biocatalysts.     

Focused directed evolution of pentaerythritol tetranitrate reductase by using automated anaerobic kinetic screening of site-saturated libraries

This work describes the development of an automated robotic platform for the rapid screening of enzyme variants generated from directed evolution studies of pentraerythritol tetranitrate (PETN) reductase, a target for industrial biocatalysis. By using a 96‐well format, near pure enzyme was recovered and was suitable for high throughput kinetic assays; this enabled rapid screening for improved and new activities from libraries of enzyme variants. Initial characterisation of several single site‐saturation libraries targeted at active site residues of PETN reductase, are described. Two mutants (T26S and W102F) were shown to have switched in substrate enantiopreference against substrates (E)‐2‐aryl‐1‐nitropropene and α‐methyl‐trans‐cinnamaldehyde, respectively, with an increase in ee (62 % (R) for W102F). In addition, the detection of mutants with weak activity against α,β‐unsaturated carboxylic acid substrates showed progress in the expansion of the substrate range of PETN reductase. These methods can readily be adapted for rapid evolution of enzyme variants with other oxidoreductase enzymes.