Amol V. Shivange

OmniChange: The Sequence Independent Method for Simultaneous Site-Saturation of Five Codons

Focused mutant library generation methods have been developed to improve mainly “localizable” enzyme properties such as activity and selectivity. Current multi-site saturation methods are restricted by the gene sequence, require subsequent PCR steps and/or additional enzymatic modifications. Here we report, a multiple site saturation mutagenesis method, OmniChange, which simultaneously and efficiently saturates five independent codons. As proof of principle, five chemically cleaved DNA fragments, each carrying one NNK-degenerated codon, were generated and assembled to full gene length in a one-pot-reaction without additional PCR-amplification or use of restriction enzymes or ligases. Sequencing revealed the presence of up to 27 different codons at individual positions, corresponding to 84.4% of the theoretical diversity offered by NNK-degeneration. OmniChange is absolutely sequence independent, does not require a minimal distance between mutated codons and can be accomplished within a day.

Design of an activity and stability improved carbonyl reductase from Candida parapsilosis.

The carbonyl reductase from Candida parapsilosis (CPCR2) is an industrially attractive biocatalyst for producing chiral alcohols from ketones. The homodimeric enzyme has a broad substrate spectrum and an excellent stereoselectivity, but is rapidly inactivated at aqueous-organic interfaces. The latter limits CPCR2s application in biphasic reaction media. Reengineering the protein surface of CPCR2 yielded a variant CPCR2-(A275N, L276Q) with 1.5-fold increased activity, 1.5-fold higher interfacial stability (cyclohexane/buffer system), and increased thermal resistance (ΔT50=+2.7 °C). Site-directed and site-saturation mutagenesis studies discovered that position 275 mainly influences stability and position 276 governs activity. After single site-saturation of position 275, amino acid exchanges to asparagine and threonine were discovered to be stabilizing. Interestingly, both positions are located at the dimer interface and close to the active site and computational analysis identified an inter-subunit hydrogen bond formation at position 275 to be responsible for stabilization. Finally, the variant CPCR2-(A275S, L276Q) was found by simultaneous site-saturation of positions 275 and 276. CPCR2-(A275S, L276Q) has compared to wtCPCR2 a 1.4-fold increased activity, a 1.5-fold higher interfacial stability, and improved thermal resistance (ΔT50=+5.2 °C).

Multi-site saturation by OmniChange yields a pH- and thermally improved phytase.

Directed evolution of Yersinia mollaretii phytase (Ymphytase) yielded an improved variant SM2P3E4 (also named M1; D52N, T77K, K139E, G187S, V298M) in our previous study. Variant M1 retained high specific activity (993U/mg; equivalent to 93% of wild-type activity) and improved thermal resistance (T50 improved by 1.5°C compared to wild-type at 58°C; 20min incubation time), making variant M1 an attractive enzyme for industrial applications. Recently, the OmniChange method was developed for multi-site saturation mutagenesis. The five sites identified in variant M1 were subjected to OmniChange saturation in order to explore whether a variant with higher activity, higher thermal resistance, and higher resistance at low pH (2-3h incubation was performed to mimic the gastric residence time of phytase) could be identified. Screening of a small library of 1100 clones, covering <0.004% of the theoretical sequence space of 3.35×10(7) variants, yielded a Ymphytase variant with 32% improved residual activity (58°C for 20min), 2°C increased apparent melting temperature (Tm), and 2-fold higher pH stability (pH 2.8; 3h incubation time) when compared to the wild-type Ymphytase. Compared to the M1 variant, the pH stability (pH 2.8; 3h incubation time) was improved by 3-fold, and thermal resistance as well as activity was improved slightly (residual activity: 32% compared to 20%; apparent Tm: 2°C compared to 1.5°C; activity difference <4%).

Extending the substrate scope of a Baeyer–Villiger monooxygenase by multiple-site mutagenesis

Baeyer–Villiger monooxygenase-catalysed reactions are attractive for industrial processes. Here we report on expanding the substrate scope of phenylacetone monooxygenase (PAMO). In order to introduce activity on alicyclic ketones in PAMO, we generated and screened a library of 1,500 mutants. Based on recently published structures of PAMO and its mutants, we selected previously uncharacterised positions as well as known hot-spots to be targeted by focused mutagenesis. We were able to mutate 11 positions in a single step by using the OmniChange method for the mutant library generation. Screening of the library using a phosphate-based activity detection method allowed identification of a quadruple mutant (P253F/G254A/R258M/L443F) active on cyclopentanone. The substrate scope of this mutant is extended to several aliphatic ketones while activity on aromatic compounds typical for PAMO was preserved. Moreover, the mutant is as thermostable as PAMO. Our results demonstrate the power of screening structure-inspired, focused mutant libraries for creating Baeyer–Villiger monooxygenases with new specificities.

Reengineered carbonyl reductase for reducing methyl-substituted cyclohexanones

The carbonyl reductase from Candida parapsilosis (CPCR2) is a versatile biocatalyst for the production of optically pure alcohols from ketones. Prochiral ketones like 2-methyl cyclohexanone are, however, only poorly accepted, despite CPCR2s large substrate spectrum. The substrate spectrum of CPCR2 was investigated by selecting five amino positions (55, 92, 118, 119 and 262) and exploring them by single site-saturation mutagenesis. Screening of CPCR2 libraries with poor (14 compounds) and well-accepted (2 compounds) substrates showed that only position 55 and position 119 showed an influence on activity. Saturation of positions 92, 118 and 262 yielded only wild-type sequences for the two well-accepted substrates and no variant converted one of the 14 other compounds. Only the variant (L119M) showed a significantly improved activity (7-fold on 2-methyl cyclohexanone; vmax = 33.6 U/mg, Km = 9.7 mmol/l). The L119M substitution exhibited also significantly increased activity toward reduction of 3-methyl (>2-fold), 4-methyl (>5-fold) and non-substituted cyclohexanone (>4-fold). After docking 2-methyl cyclohexanone into the substrate-binding pocket of a CPCR2 homology model, we hypothesized that the flexible side chain of M119 provides more space for 2-methyl cyclohexanone than branched L119. This report represents the first study on CPCR2 engineering and provides first insights how to redesign CPCR2 toward a broadened substrate spectrum.

P-LinK: A method for generating multicomponent cytochrome P450 fusions with variable linker length.

Fusion protein construction is a widely employed biochemical technique, especially when it comes to multi-component enzymes such as cytochrome P450s. Here we describe a novel method for generating fusion proteins with variable linker lengths, protein fusion with variable linker insertion (P-LinK), which was validated by fusing P450cin monooxygenase (CinA) to the flavodoxin shuttle protein (CinC). CinC was fused to the C terminus of CinA through a series of 16 amino acid linkers of different lengths in a single experiment employing 3 PCR amplifications. Screening for 2-β-hydroxy-1,8-cineole production by CinA-CinC fusion proteins revealed that enzymatically active variants possessed linker lengths of more than 5 amino acids, reaching optimum enzyme activity at a linker length of 10 amino acids. Our P-LinK method not only minimizes experimental effort and significantly reduces time demands but also requires only a single cloning and transformation step in order to generate multiple linker variants (1 to 16 amino acids long), making the approach technically simple and robust.

Conformational dynamics of active site loop in Escherichia coli phytase

Phytases catalyze the release of phosphate by stepwise hydrolysis of phytate, a major source of phosphate in cereal grains, legumes, and oilseeds. Phytase improves, as a feed supplement, the nutritional quality of phytate rich diets and eventually reduce environmental pollution. Recently, phytases from enterobacteriaceae family have attracted industrial interest due to their high specific activity (2500-4000 U/mg). However, only limited information is available concerning structural dynamics of this class of enzymes. In this study, 50 nanosecond molecular dynamics simulation was performed on two Escherichia coli phytase structures (closed and open active site loop) to investigate conformational dynamics of the active site loop. Cluster analysis and principal component analysis (PCA) reveal significant difference in the conformational dynamics of active site compared to reported crystal structure. Molecular dynamic studies indicated that the movement in the active site of E. coli phytase is mainly confined by the active site loop resulted in wider opening of the loop in absence of phytate. The molecular dynamics studies highlight the possible role of loop residues as prerequisite for highly active phytases.

Recent Advances in Directed Phytase Evolution and Rational Phytase Engineering

Phytases are hydrolytic enzymes that initiate stepwise removal of phosphate from phytate. Phytate is the major phosphorous storage compound in cereal gains, oilseeds, and legumes and is indigestible by monogastric animals such as poultry and swine. Supplementation of phytase in animal feed proved to improve animal nutrition and decrease phosphorous pollution. Several phytases were discovered in the last century, and today a highly competitive market situation emerged the demands for phytases that are redesigned to excellently match industrial demands. Phytase engineering by directed evolution and rational design has offered a robust approach to tailor-made phytases with high specific activity, broad thermal and pH profile, and protease resistance. In this chapter, we summarized challenges and successful approaches employed in phytase engineering. Factors influencing phytase thermostability, pH stability, pH optima, and protease resistance have been discussed with respect to structural perspective and potential molecular mechanism for improvement. Importance of cooperative substitutions and a way to identify these interactions are discussed. Recent development in screening technology and molecular insights in combining key beneficial substitutions are detailed. In addition, strategies and approaches for rapid and efficient evolution of phytases and to understand structure function relationships on a molecular level have been proposed.

Protein consensus-based surface engineering (ProCoS): a computer-assisted method for directed protein evolution

Protein consensus-based surface engineering (ProCoS) is a simple and efficient method for directed protein evolution combining computational analysis and molecular biology tools to engineer protein surfaces. ProCoS is based on the hypothesis that conserved residues originated from a common ancestor and that these residues are crucial for the function of a protein, whereas highly variable regions (situated on the surface of a protein) can be targeted for surface engineering to maximize performance. ProCoS comprises four main steps: (i) identification of conserved and highly variable regions; (ii) protein sequence design by substituting residues in the highly variable regions, and gene synthesis; (iii) in vitro DNA recombination of synthetic genes; and (iv) screening for active variants. ProCoS is a simple method for surface mutagenesis in which multiple sequence alignment is used for selection of surface residues based on a structural model. To demonstrate the techniques utility for directed evolution, the surface of a phytase enzyme from Yersinia mollaretii (Ymphytase) was subjected to ProCoS. Screening just 1050 clones from ProCoS engineering-guided mutant libraries yielded an enzyme with 34 amino acid substitutions. The surface-engineered Ymphytase exhibited 3.8-fold higher pH stability (at pH 2.8 for 3 h) and retained 40% of the enzymes specific activity (400 U/mg) compared with the wild-type Ymphytase. The pH stability might be attributed to a significantly increased (20 percentage points; from 9% to 29%) number of negatively charged amino acids on the surface of the engineered phytase.