Improving the Product Specificity of Maltotetraose-Forming Amylase from Pseudomonas saccharophila STB07 by Removing the Carbohydrate-Binding Module

Phosphate Limitation Enhances Heterologous Enzyme Production in Bacillus subtilis: Mechanistic Insights and Universal Applicability

Bacillus subtilis is one of the commonly used hosts for heterologous enzyme expression, depending on media rich in carbon, nitrogen, and phosphate sources for optimal growth and enzyme production. Interestingly, our investigation of maltotetraose-forming amylase, a key enzyme for efficient maltotetraose synthesis, revealed that phosphate limitation significantly enhances the growth rate and production of heterologous enzymes in recombinant B. subtilis. Under phosphate-limited conditions in a 15 L fermenter, the enzyme activity reached 679.15 U/mL, an improvement of 101% over the initial levels and a 12 h reduction in fermentation time. Transcriptomic analysis indicated that phosphate limitation promotes sustained enzyme production by upregulating protein synthesis and quality control pathways while optimizing energy utilization. This strategy was validated across various enzyme systems, highlighting its general applicability for enhancing heterologous protein expressions. These findings provide valuable insights for the industrial production of maltotetraose-forming amylase and other high-value enzymes, supporting the advancement of microbial fermentation technology.

Enzymatic modification of wheat starch by a novel maltotetraose-forming amylase from Atopomonas hussainii to retard retrogradation and improve bread quality

To retard starch retrogradation and improve bread quality, a novel maltotetraose-forming amylase (AhMFA) from Atopomonas hussainii was expressed in Komagataella phaffii. After high cell density fermentation, the enzyme activity reached a maximum level of 3032 U mL-1. AhMFA showed optimal activity at pH 6.0 and 55 °C, respectively. After raw wheat starch was treated with AhMFA at 55 °C for 1 h, the relative crystallinity decreased from 24.5 % to 20.8 % without changing the A-type crystalline pattern. The side chain components with A, B1 and B2 chains were reduced to 27.5 %, 44.9 %, and 13.8 %, respectively. The retrogradation enthalpy of wheat starch decreased significantly by 67.8 %. Moreover, the decreased Mixolab parameters (C5 and C5 - C4) indicated that AhMFA reduced starch retrogradation of wheat dough. After addition of AhMFA (3 ppm), the specific volume of bread increased by 29.5 % and its hardness decreased by 46.1 % compared to the control. The AhMFA-added bread exhibited good anti-staling properties with 43.7 % less hardness than the control after storage at 4 °C for 4 days. This study provided a novel maltotetraose-forming amylase for starch modification to retard retrogradation and improve bread quality.

Synergistic action of novel maltohexaose-forming amylase and branching enzyme improves the enzymatic conversion of starch to specific maltooligosaccharide

As attractive functional ingredients, maltooligosaccharides (MOS) are typically prepared by controlled enzymatic hydrolysis of starch. However, the random attack mode of amylase often leads to discrete product distribution, thereby reducing yields and purities. In this study, a novel glycoside hydrolase family 13 amylase AmyEs from marine myxobacteria Enhygromyxa salina was identified efficient maltohexaose (G6)-forming ability (40 %, w/w). By deciphering external chain length, we found that the high density of α-1,6-branching points benefits the G6 formation of AmyEs with high purity (71-82 %), indicating the substrate selectivity of AmyEs toward high-branched starch. Based on this, asynchronous conversion strategy was designed to enhance specific MOS yield from corn starch by exploiting branching enzymes and AmyEs, and the purity and yield of G6 respectively increased by 9.5 % and 5 % compared to single AmyEs treatment. Our results demonstrate that combinatorial catalysis of MOS-forming amylases and branching enzymes provides a favorable industrial preparation of specific MOS.

High-Level Expression and Biochemical Characterization of a Maltotetraose Amylase in Pichia pastoris X-33 for Maltotetraose Production

Maltotetraose amylase, which catalyzes the hydrolysis of amylaceous polysaccharides into maltooligosaccharides with maltotetraose as the main product, is extensively used in the food industry. However, the lack of efficient expression system for maltotetraose amylase has hampered its production and application. In this study, high-level production of a maltotetraose amylase mutant (referred to as Pp-Mta∆CBM) from Pseudomonas saccharophila was achieved in Pichia pastoris X-33. First, the gene of maltotetraose amylase with the carbohydrate-binding module (CBM) removed was codon-optimized and cloned into the pPICZαA vector, followed by transformation into P. pastoris X-33 for expression. Using the promoter PAOX1 and signal peptide α-factor, high-level production of Pp-Mta∆CBM with minimal extracellular impurity proteins was achieved, resulting in an extracellular activity of 367.9 U/mL after 7 days of cultivation in shake flasks. Next, the expressed Pp-Mta∆CBM was purified and characterized. This recombinant enzyme was glycosylated and has maximum activity at 55 ℃ and pH 7.0. Its Km for soluble starch was 4.1 g/L, and its kcat was 3237.6 s-1. Finally, the Pp-Mta∆CBM was found to produce a maximum maltotetraose yield of 57.1% in the presence of 200 g/L of substrate. The findings presented in this study demonstrate the efficient production of Pp-Mta∆CBM in P. pastoris, providing a new expression system for maltotetraose amylase and laying the foundation for its scale-up production and industrial application.