Efficient biocatalytic hydrolysis of 2-chloronicotinamide for production of 2-chloronicotinic acid by recombinant amidase

Microbial amidases: Characterization, advances and biotechnological applications

The amidases (EC 3.5.1.4) are versatile hydrolase biocatalysts that have been the attention of academia and industries for stereo-selective synthesis and bioremediation. These are categorized based on the amino acid sequence and substrate specificity. Notably, the Signature amidase family is distinguished by a characteristic signature sequence, GGSS(S/G)GS, which encompasses highly conserved Ser-Ser-Lys catalytic residues, and the amidases belonging to this family typically demonstrate a broad substrate spectrum activity. The amidases classified within the nitrilase superfamily possess distinct Glu-Lys-Cys catalytic residues and exhibit activity towards small aliphatic substrates. Recent discoveries have underscored the potential role of amidases in the degradation of toxic amides present in polymers, insecticides, and food products. This expands the horizons for amidase-mediated biodegradation of amide-laden pollutants and fosters sustainable development alongside organic synthesis. The burgeoning global production facilities are expected to drive a heightened demand for this enzyme, attributable to its promising chemo-, regio-, and enantioselective hydrolysis capabilities for a variety of amides. Advances in protein engineering have enhanced the catalytic efficiency, structural stability, and substrate selectivity of amidases. Concurrently, the heterologous expression of amidase genes sourced from thermophiles has facilitated the development of highly stable amidases with significant industrial relevance. Beyond their biotransformation capabilities concerning amides, through amido-hydrolase and acyltransferase activities, recent investigations have illuminated the potential of amidase-mediated degradation of amide-containing pollutants in soil and aquatic environments. This review offers a comprehensive overview of recent advancements pertaining to microbial amidases (EC 3.5.1.4), focusing on aspects such as their distribution, gene mining methodologies, enzyme stability, protein engineering, reusability, and biocatalytic efficacy in organic synthesis and biodegradation.

Improvement of multi-catalytic properties of nitrilase from Paraburkholderia graminis for efficient biosynthesis of 2-chloronicotinic acid

Nitrilase-catalyzed hydrolysis of nitriles is the promising approach for green and efficient biosynthesis of high value-added carboxylic acids. However, undesirable catalytic efficiency toward non-natural substrates restricts their wide-spread applications. Until now, very few robust nitrilases have been reported for 2-chloronicotinic acid (2-CA) production since the enzymes always show low activity and sometimes with poor reaction specificity. Herein, a nitrilase from Paraburkholderia graminis (PgNIT) was engineered to improve its catalytic properties. We identified the beneficial residues via computational analysis and constructed the mutant library. A series positive mutants were obtained and the "best" mutant F164G/I130L/N167Y/A55S exhibited 6000-folds higher catalytic efficiency to 2-chloronicotinonitrile (2-CN). Its reaction specificity was improved with elimination of hydration activity and meanwhile, the half-lives (t_1/2 ) against different temperatures were increased. Molecular docking and molecular dynamics simulation revealed that the steric hindrance, conformational flexibility, as well as nucleophilic attack distance between the enzyme and substrate were the main reason alternating the catalytic properties of PgNIT. With the mutant as biocatalyst, a product yield of 130 g/L 2-CA was produced from 2-CN after 60 h, laying the foundation for constructing the nitrilase-catalyzed route of 2-CA. This article is protected by copyright. All rights reserved.

Biocatalytic routes to anti-viral agents and their synthetic intermediates

An assessment of biocatalytic strategies for the synthesis of anti-viral agents, offering guidelines for the development of sustainable production methods for a future COVID-19 remedy.

Amidase as a versatile tool in amide-bond cleavage: From molecular features to biotechnological applications

Amidases (EC 3. 5. 1. X) are versatile biocatalysts for synthesis of chiral carboxylic acids, α-amino acids and amides due to their hydrolytic and acyl transfer activity towards the C-N linkages. They have been extensively exploited and studied during the past years for their high specific activity and excellent enantioselectivity involved in various biotechnological applications in pharmaceutical and agrochemical industries. Additionally, they have attracted considerable attentions in biodegradation and bioremediation owing to environmental pressures. Motivated by industrial demands, crystallographic investigations and catalytic mechanisms of amidases based on structural biology have witnessed a dramatic promotion in the last two decades. The protein structures showed that different types of amidases have their typical stuctural elements, such as the conserved AS domains in signature amidases and the typical architecture of metal-associated active sites in acetamidase/formamidase family amidases. This review provides an overview of recent research advances in various amidases, with a focus on their structural basis of phylogenetics, substrate specificities and catalytic mechanisms as well as their biotechnological applications. As more crystal structures of amidases are determined, the structure/function relationships of these enzymes will also be further elucidated, which will facilitate molecular engineering and design of amidases to meet industrial requirements.

Structure-Based Engineering of Amidase from Pantoea sp. for Efficient 2-Chloronicotinic Acid Biosynthesis

2-Chloronicotinic acid is a key intermediate of pharmaceuticals and pesticides. Amidase-catalyzed hydrolysis provides a promising enzymatic method for 2-chloronicotinic acid production from 2-chloronicotinamide. However, biocatalytic hydrolysis of 2-chloronicotinamide is difficult due to the strong steric and electronic effect caused by 2-position chlorine substituent of the pyridine ring. In this study, an amidase from a Pantoea sp. (Pa-Ami) was designed and engineered to have improved catalytic properties. Single mutant G175A and double mutant G175A/A305T strains exhibited 3.2- and 3.7-fold improvements in their specific activity for 2-chloronicotinamide, and the catalytic efficiency was significantly increased, with k _cat/K_m values 3.1 and 10.0 times higher than that of the wild type, respectively. Structure-function analysis revealed that the distance between Oγ of Ser177 (involved in the catalytic triad) and the carbonyl carbon of 2-chloronicotinamide was shortened in the G175A mutant, making the nucleophilic attack on the Oγ of Ser177 easier by virtue of proper orientation. In addition, the A305T mutation contributed to a suitable tunnel formation to facilitate the substrate entry and product release, resulting in improved catalytic efficiency. With the G175A/A305T double mutant as a biocatalyst, a maximum of 1,220 mM 2-chloronicotinic acid was produced with a 94% conversion, and the space-time yield reached as high as 575 g_product liter^-1 day^-1 These results provide not only a novel robust biocatalyst for the production of 2-chloronicotinic acid but also new insights into amidase structure-function relationships.IMPORTANCE In recent years, the demand for 2-chloronicotinic acid has been greatly increased. To date, several chemical methods have been used for the synthesis of 2-chloronicotinic acid, but all include tedious steps and/or drastic reaction conditions, resulting in both economic and environmental issues. It is requisite to develop an efficient and green synthesis route. We recently screened Pa-Ami and demonstrated its potential for synthesis of 2-chloronicotinic acid from 2-chloronicotinamide. However, chlorine substitution on the pyridine ring of nicotinamide significantly affected the activity of Pa-Ami. Especially for 2-chloronicotinamide, the enzyme activity and catalytic efficiency were relatively low. In this study, based on structure-function analysis, we succeeded in engineering the amidase by structure-guided saturation mutagenesis. The engineered Pa-Ami exhibited quite high catalytic activity toward 2-chloronicotinamide and could serve as a promising biocatalyst for the biosynthesis of 2-chloronicotinic acid.