Directed mutation of β-glucanases from probiotics to enhance enzymatic activity, thermal and pH stability

Engineered L-phenylserine aldolase enhances L-norvaline synthesis within an enzyme cascade

L-Norvaline is a crucial intermediate in the synthesis of antihypertensive agents, and its production via biotechnological methods has garnered significant interest and commercial value in recent years. Here, for the enzymatic cascade synthesis of L-norvaline from propionaldehyde and glycine, an L-phenylserine aldolase gene (designated as ppLPA) from Pseudomonas putida was selected. Following the identification of potential mutation sites via error-prone PCR, coupled with site-directed mutagenesis, a single-site mutant, I18T, was identified, exhibiting a 1.4-fold increase in enzyme activity. Then, the ppLPA mutant I18T was combined with L-threonine deaminase, L-leucine dehydrogenase, and alcohol dehydrogenase to construct a one-pot, multi-enzyme cascade catalytic system for L-norvaline synthesis. The reaction conditions were systematically optimized. To mitigate the inhibitory effects of propionaldehyde, we employed a pH-stat substrate feeding strategy. Under optimal reaction conditions, L-norvaline production achieved a maximum yield of 116.5 g/L after 14 h of reaction, with a conversion rate exceeding 99 % in a 1 L reaction volume. This study highlights significant advancements in improving L-norvaline production, providing potential for more efficient biomanufacturing processes and broader industrial applications.

Overview of various protein engineering strategies to improve the catalytic activity, thermostability, and acid/base stability of β-glucanase

β-Glucan is highly valued in the food and medical industries due to its various physiological functions. However, its aqueous solution tends to have high viscosity, which negatively impacts the brewing and feed industries. By hydrolyzing β-glucosidic bonds, β-glucanase could reduce the adverse effects of β-glucan. For this reason, β-glucanase is widely utilized in the brewing and animal feed production. The limited thermal and acid stability of β-glucanase restricts its applications in industrial settings. Therefore, it is of great importance to enhance the stability of existing β-glucanases through protein engineering. This review summarizes current integrated technical methods for the molecular modification of β-glucanases, including error-prone PCR, site-saturation mutagenesis, DNA recombination, sequence alignment, N- and C-terminal modifications, surface charge optimization, intermolecular force optimization, and rigidity of flexible regions. The aim is to provide a theoretical basis and practical guidance for the further modification of β-glucanases.

Enzymolysis for effective grain processing: Computer-aided optimization of a 1,3-1,4-β-glucanase with improved thermostability and catalytic activity

β-Glucanases, widely applied in grain processing, are commonly restricted for efficient industrial application due to the limited thermostability. In this study, a 1,3-1,4-β-glucanase (BisGlu16B_ΔC) was optimized for thermostability through a computer-aided design of energy optimization. Three variants (T40K, Q53L, and S311Y) were selected and generated a combined mutant T40K/Q53L/S311Y (M3). Comparing with the WT, M3 exhibited better thermostability (with t1/2 at 60 °C extend by 126 min), higher specific activity (1.24 folds; 69,700 vs. 56,200 U/mg), higher catalytic effciency (1.18 folds; 14,100 vs. 11,900 mL‧s-1‧mg-1), and improved protease resistance. For mechanism, more hydrogen bonds, salt bridges, and rigid secondary components in M3 led to an enhanced overall rigidity, boosting the thermostability. While enhanced long-range negative interactions affected some key residues in the catalytic channels, improving the catalytic efficiency. For application, M3 showed superiority with higher dry matter digestibility (1.49 folds; 80.3 % vs. 53.9 %) in simulated gastrointestinal system, together with more reduction of filtration time (1.55 folds; 22.2 % vs. 14.3 %) and viscosity (2.37 folds; 10.2 % vs. 4.3 %) during malting, comparing with the WT. Furthermore, the strongest synergistic effects were found between xylanase and M3, among all β-glucanases tested. All results verified M3 as an efficient β-glucanase for grain processing industry.

Identification of Enzymes and Their Key Action Sites for Histamine Degradation in Mulberry Fruit Wine by Lactiplantibacillus plantarum

In this study, the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and multicopper oxidase (MCO) of Lactiplantibacillus plantarum W155 with histamine degradation ability were expressed. The mulberry fruit wine (MFW) histamine degradation abilities of GAPDH and MCO were 20.81% and 37.67%, respectively. Compared with the control group, the MFW treated by GAPDH showed higher total phenolic (1.17 g GAE/L) and total flavonoid (0.31 g RE/L) contents, while MFW treated by MCO presented similar total phenolic (1.00 g GAE/L) and total flavonoid (0.29 g RE/L) concentrations. Furthermore, the optimal pH and temperature of GAPDH were 6.0 and 40 °C, respectively, while the optimal pH and temperature of MCO were 3.0 and 50 °C, respectively. Meanwhile, the key action sites for histamine degradation of GAPDH and MCO were minded via homology modeling, molecular docking, and site-directed mutagenesis. Val209 and Ile290 were confirmed as the key action sites for GAPDH, while Qln402 and Leu420 were the pivotal action sites for MCO. Above findings indicated that both GAPDH and MCO of L. plantarum W155 could be used to control the histamine of MFW, and the key action sites of these two enzymes could be used as targets for their subsequent modification.

Advances in molecular enzymology of β-1,3-glucanases: A comprehensive review

β-1,3-Glucanases are essential enzymes involved in the hydrolysis of β-1,3-glucans, with significant biological and industrial relevance. These enzymes are derived from diverse sources, including bacteria, fungi, plants, and animals, each exhibiting unique substrate specificities and biochemical properties. This review provides an in-depth analysis of the natural sources and ecological roles of β-1,3-glucanases, exploring their enzymatic properties such as optimal pH, temperature, molecular weight, isoelectric points, and kinetic parameters, which are crucial for understanding their functionality and stability. Advances in molecular enzymology are discussed, focusing on gene cloning, expression in systems like Escherichia coli and Pichia pastoris, and structural-functional relationships. The reaction mechanisms and the role of non-catalytic carbohydrate-binding modules in enhancing substrate hydrolysis are examined. Industrial applications of β-1,3-glucanases are highlighted, including the production of β-1,3-glucooligosaccharides, uses in the food industry, biological control of plant pathogens, and nutritional roles. This review aims to provide a foundation for future research, improving the efficiency and robustness of β-1,3-glucanases for various industrial applications.

Fungus reduces tetracycline-resistant genes in manure treatment by predation of bacteria

New strategies to remove antibiotic resistance genes (ARGs), one of the most pressing threats to public health, are urgently needed. This study showed that the fungus Phanerochaete chrysosporium seeded to a composting reactor (CR) could remarkably reduce tetracycline-resistant genes (TRGs). The reduction efficiencies for the five main TRGs (i.e., tetW, tetO, tetM, tetPA, and tet(32)) increased by 8 to 100 folds compared with the control without P. chrysosporium, and this could be attributed to the decrease in the quantity of bacteria. Enumeration based on green fluorescence protein labeling further showed that P. chrysosporium became dominant in the CR. Meanwhile, the bacteria in the CR invaded the fungal cells via the cell wall defect of chlamydospore or active invasion. Most of the invasive bacteria trapped inside the fungus could not survive, resulting in bacterial death and the degradation of their TRGs by the fungal nucleases. As such, the predation of tetracycline-resistant bacteria by P. chrysosporium was mainly responsible for the enhanced removal of TRGs in the swine manure treatment. This study offers new insights into the microbial control of ARGs.

Lactic acid bacteria-derived exopolysaccharide: Formation, immunomodulatory ability, health effects, and structure-function relationship

Exopolysaccharides (EPSs) synthesized by lactic acid bacteria (LAB) have implications for host health and act as food ingredients. Due to the variability of LAB-EPS (lactic acid bacteria-derived exopolysaccharide) gene clusters, especially the glycosyltransferase genes that determine monosaccharide composition, the structure of EPS is very rich. EPSs are synthesized by LAB through the extracellular synthesis pathway and the Wzx/Wzy-dependent pathway. LAB-EPS has a strong immunomodulatory ability. The EPSs produced by different genera of LAB, especially Lactobacillus, Leuconostoc, and Streptococcus, have different immunomodulatory abilities because of their specific structures. LAB-EPS possesses other health effects, including antitumor, antioxidant, intestinal barrier repair, antimicrobial, antiviral, and cholesterol-lowering activities. The bioactivities of LAB-EPS are tightly related to their structures such us monosaccharide composition, glycosidic bonds, and molecular weight (MW). For the excellent physicochemical property, LAB-EPS acts as product improvers in dairy, bakery food, and meat in terms of stability, emulsification, thickening, and gelling. We systematically summarize the detailed process of EPS from synthesis to application, with emphasis on physiological mechanisms of EPS, and specific structure-function relationship, which provides theoretical support for the potential commercial value in the pharmaceutical, chemical, food, and cosmetic industries.

Microbial β-glucanases: production, properties, and engineering

Lignocellulosic biomass, which mainly consists of cellulose and hemicellulose, is the most abundant renewable biopolymer on earth. β-Glucanases are glycoside hydrolases (GHs) that hydrolyze β-glucan, one of the dominant components of the plant cell wall, into cello-oligosaccharides and glucose. Among them, endo-β-1,4-glucanase (EC 3.2.1.4), exo-glucanase/cellobiohydrolase (EC 3.2.1.91), and β-glucosidase (EC 3.2.1.21) play critical roles in the digestion of glucan-like substrates. β-Glucanases have attracted considerable interest within the scientific community due to their applications in the feed, food, and textile industries. In the past decade, there has been considerable progress in the discovery, production, and characterization of novel β-glucanases. Advances in the development of next-generation sequencing techniques, including metagenomics and metatranscriptomics, have unveiled novel β-glucanases isolated from the gastrointestinal microbiota. The study of β-glucanases is beneficial for research and development of commercial products. In this study, we review the classification, properties, and engineering of β-glucanases.

One-step production of functional branched oligoglucosides with coupled fermentation of Pichia pastoris GS115 and Sclerotium rolfsii WSH-G01

Endo-β-1,3-glucanase with high specific activity is a prerequisite for enzymatic preparation of valuable β-oligoglucosides. Heterologous expression in Pichia pastoris GS115 with error-prone PCR technology was implemented, and the mutant strain 7 N12 was obtained. The mutant endo-β-1,3-glucanase showed efficient specific activities for degrading curdlan (366 U mg^-1) and scleroglucan (274.5 U mg^-1). Thereafter, one-step production of functional branched oligoglucosides was established with coupled fermentation of Pichia pastoris and Sclerotium rolfsii. During the fermentation process, the endo-β-1,3-glucanase secreted by Pichia pastoris GS115 can efficiently hydrolyse scleroglucan metabolized by Sclerotium rolfsii WSH-G01. The maximum yields of β-oligoglucosides in the shake flasks and 7-L bioreactor reached 1.73 g L^-1 and 12.71 g L^-1, respectively, with polymerization degrees of 2-17. The successful implementation of heterologous expression with error-prone PCR and the coupled fermentation simplified the multi-step enzymatic β-oligoglucoside preparation procedures, which makes it a potential strategy for industrial production of functional oligosaccharides.