Highly efficient conversion of 1-cyanocycloalkaneacetonitrile using a “super nitrilase mutant”

Isolation and Characterization of a Nitrilase-Producing Geotrichum Strain and Optimization of the Fermentation Conditions

Glufosinate ammonium is a fast-acting herbicide that was originally discovered as a natural product and is currently the only herbicide that targets glutamine synthetase. Nitrilase was found to catalyze synthesis of glufosinate ammonium. In this study, a fungus, Ytz23, with higher nitrilase activity, was isolated from seabed silt samples and was found to belong to the Geotrichum genus based on morphological, biochemical, and molecular characterization. It was found that Ytz23 had high specificity for the catalysis of fatty nitriles, including acrylonitrile, 3-aminopropanenitrile, and 2-amino-4-(hydroxymethylphosphono)-butanenitrile. The optimal concentrations of variables in the fermentation reaction were assessed. It was found that the optimal carbon and nitrogen sources were glycerol 20 g/L, yeast extract 20, and 0.2 g/L of 2-amino-4-(hydroxymethylphosphono)-butanenitrile, with optimal fermentation conditions of pH 7.0, 30 °C, and shaking at 220 rpm. Under these optimal conditions, the enzyme activity of the nitrilase was 10.2 U/mL. These findings provide a basis for the biosynthesis of glufosinate ammonium and have potential for application in the industrial production of glufosinate ammonium.

Protein Engineering of Substrate Specificity toward Nitrilases: Strategies and Challenges

Nitrilase is extensively applied across diverse sectors owing to its unique catalytic properties. Nevertheless, in industrial production, nitrilases often face issues such as low catalytic efficiency, limited substrate range, suboptimal selectivity, and side reaction products, which have garnered heightened attention. With the widespread recognition that the structure of enzymes has a direct impact on their catalytic properties, an increasing number of researchers are beginning to optimize the functional characteristics of nitrilases by modifying their structures, in order to meet specific industrial or biotechnology application needs. Particularly in the artificial intelligence era, the innovative application of computer-aided design in enzyme engineering offers remarkable opportunities to tailor nitrilases for the widespread production of high-value products. In this discussion, we will briefly examine the structural mechanism of nitrilase. An overview of the protein engineering strategies of substrate preference, regioselectivity and stereoselectivity are explored combined with some representative examples recently in terms of the substrate specificity of enzyme. The future research trends in this field are also prospected.

Enlightening the Path to Protein Engineering: Chemoselective Turn-On Probes for High-Throughput Screening of Enzymatic Activity

Many successful stories in enzyme engineering are based on the creation of randomized diversity in large mutant libraries, containing millions to billions of enzyme variants. Methods that enabled their evaluation with high throughput are dominated by spectroscopic techniques due to their high speed and sensitivity. A large proportion of studies relies on fluorogenic substrates that mimic the chemical properties of the target or coupled enzymatic assays with an optical read-out that assesses the desired catalytic efficiency indirectly. The most reliable hits, however, are achieved by screening for conversions of the starting material to the desired product. For this purpose, functional group assays offer a general approach to achieve a fast, optical read-out. They use the chemoselectivity, differences in electronic and steric properties of various functional groups, to reduce the number of false-positive results and the analytical noise stemming from enzymatic background activities. This review summarizes the developments and use of functional group probes for chemoselective derivatizations, with a clear focus on screening for enzymatic activity in protein engineering.

Shortening Synthetic Routes to Small Molecule Active Pharmaceutical Ingredients Employing Biocatalytic Methods

Biocatalysis, using enzymes for organic synthesis, has emerged as powerful tool for the synthesis of active pharmaceutical ingredients (APIs). The first industrial biocatalytic processes launched in the first half of the last century exploited whole-cell microorganisms where the specific enzyme at work was not known. In the meantime, novel molecular biology methods, such as efficient gene sequencing and synthesis, triggered breakthroughs in directed evolution for the rapid development of process-stable enzymes with broad substrate scope and good selectivities tailored for specific substrates. To date, enzymes are employed to enable shorter, more efficient, and more sustainable alternative routes toward (established) small molecule APIs, and are additionally used to perform standard reactions in API synthesis more efficiently. Herein, large-scale synthetic routes containing biocatalytic key steps toward >130 APIs of approved drugs and drug candidates are compared with the corresponding chemical protocols (if available) regarding the steps, reaction conditions, and scale. The review is structured according to the functional group formed in the reaction.

Immobilization of Escherichia coli cells harboring a nitrilase with improved catalytic properties though polyethylenemine-induced silicification on zeolite

In the chemical-biological synthesis route of gabapentin, immobilized Escherichia coli cells harboring nitrilase are used to catalyze the biotransformation of intermediate 1-cyanocyclohexaneacetonitile to 1-cyanocyclohexaneacetic acid. Herein, we present a novel cell immobilization method, which is based on cell adsorption using 75 g/L Escherichia coli cells and 6 g/L zeolite, cell crosslinking using 3 g/L polyethylenemine and biomimetic silicification using 18 g/L hydrolyzed tetramethylorthosilicate. The constructed "hybrid biomimetic silica particles (HBSPs)" with core-shell structure showed a specific activity of 147.2 ± 2.3 U/g, 82.6 ± 2.8% recovery of nitrilase activity and a half-life of 19.1 ± 1.9 h at 55 °C. 1-Cyanocyclohexaneacetonitrile (1.0 M) could be completely hydrolyzed by 50 g/L of HBSPs at pH 7.5, 35 °C in 4 h, providing 92.1 ± 3.2% yield of 1-cyanocyclohexaneacetic acid. In batch reactions, the HBSPs could be reused for 13 cycles and maintained 79.9 ± 4.1% residual activity after the 10th batch, providing an average product yield of 92.6% in the first 10 batches with a productivity of 619.3 g/L/day. In addition, multi-layer structures consisting of silica coating and polyethylenemine/glutaraldehyde crosslinking were constructed to enhance the mechanical strength of immobilized cells, and the effects of coating layers on the catalytic properties of immobilized cells was discussed.

Biocatalysis: Enzymatic Synthesis for Industrial Applications

Biocatalysis has found numerous applications in various fields as an alternative to chemical catalysis. The use of enzymes in organic synthesis, especially to make chiral compounds for pharmaceuticals as well for the flavors and fragrance industry, are the most prominent examples. In addition, biocatalysts are used on a large scale to make specialty and even bulk chemicals. This review intends to give illustrative examples in this field with a special focus on scalable chemical production using enzymes. It also discusses the opportunities and limitations of enzymatic syntheses using distinct examples and provides an outlook on emerging enzyme classes.

Nitrilase: a promising biocatalyst in industrial applications for green chemistry

Nitrilases are widely distributed in nature and are able to hydrolyze nitriles into their corresponding carboxylic acids and ammonia. In industry, nitrilases have been used as green biocatalysts for the production of high value-added products. To date, biocatalysts are considered to be important alternatives to chemical catalysts due to increasing environmental problems and resource scarcity. This review provides an overview of recent advances of nitrilases in aspects of distribution, enzyme screening, molecular structure and catalytic mechanism, protein engineering, and their potential applications in industry.

Recent research advancements on regioselective nitrilase: fundamental and applicative aspects

Nitrilase-mediated biocatalysis reactions have been continuously arousing wide interests by scholars and entrepreneurs in organic synthesis over the past six decades. Since regioselective nitrilases could hydrolyze only one cyano group of dinitriles into corresponding cyanocarboxylic acids, which are virtually impossible by chemical hydrolysis and of interest for a variety of applications, it becomes particularly appealing to synthetic chemists. The aim of the current review is to summarize the recent advancements on regioselective nitrilases concerning their fundamental researches and applications in synthesis of a series of high-value fine chemicals and pharmaceuticals. Carbon chain lengths and substituent group positions of substrates are found to be two crucial factors in affecting regioselectivity of nitrilase. Practical applications of regioselective nitrilases in synthesis of 1,5-dimethyl-2-piperidone (1,5-DMPD), atorvastatin, gabapentin, (R)-baclofen, and (S)-pregabalin were systematically reviewed. Future perspectives clearly elucidating the mechanism of regioselectivity and further molecular modifications of regioselective nitrilases integrating within silico technology for industrial applications were discussed.