Li Jiajing, Pei Xiaojie, Xue Changhu, Chang Yaoguang, Shen Jingjing, Zhang Yuying
College of Food Science and Engineering, Ocean University of China, Qingdao, China.
Qingdao Vland Biotech Group Co. Ltd, Qingdao, China.
J Sci Food Agric. 2024 Jan 15;104(1):134-140. doi: 10.1002/jsfa.12898. Epub 2023 Aug 23.
Alginate lyases are important tools for alginate biodegradation and oligosaccharide production, which have great potential in food and biofuel fields. The alginate polysaccharide utilization loci (PUL) typically encode a series of alginate lyases with a synergistic action pattern. Exploring valuable alginate lyases and revealing the synergistic effect of enzymes in the PUL is of great significance.
An alginate PUL was discovered from the marine bacterium Wenyingzhuangia fucanilytica CZ1127 , and a repertoire of alginate lyases within it was cloned, expressed and characterized. The four alginate lyases in PUL demonstrated similar optimal reaction conditions: maximum enzyme activity at 35-50 °C and pH 8.0-9.0. The results of action pattern indicated that they were two PL7 endolytic bifunctional enzymes (Aly7A and Aly7B), a PL6 exolytic bifunctional enzyme (Aly6A) and a PL17 exolytic M-specific enzyme (Aly17A). Ultra-performance liquid chromatography-mass spectrometry was employed to reveal the synergistic effect of the four enzymes. The end products of Aly7A were further degraded by Aly7B and eventually generated oligosaccharides, from disaccharide to heptasaccharide. The oligosaccharide products were completely degraded to monosaccharides by Aly6A, but it was unable to directly degrade alginate. Aly17A could also produce monosaccharides by cleaving the M-blocks of oligosaccharide products, as well as the M-blocks of polysaccharides. The combination of these enzymes resulted in the complete degradation of alginate to monosaccharides.
A new alginate PUL was mined and four novel alginate lyases in the PUL were expressed and characterized. The four cooperative alginate lyases provide novel tools for alginate degradation and biological fermentation. © 2023 Society of Chemical Industry.
海藻酸盐裂解酶是海藻酸盐生物降解和寡糖生产的重要工具,在食品和生物燃料领域具有巨大潜力。海藻酸盐多糖利用位点(PUL)通常编码一系列具有协同作用模式的海藻酸盐裂解酶。探索有价值的海藻酸盐裂解酶并揭示PUL中酶的协同作用具有重要意义。
从海洋细菌解岩藻文营氏菌CZ1127中发现了一个海藻酸盐PUL,并对其中的一系列海藻酸盐裂解酶进行了克隆、表达和表征。PUL中的四种海藻酸盐裂解酶表现出相似的最佳反应条件:在35 - 50°C和pH 8.0 - 9.0时酶活性最高。作用模式结果表明,它们是两种PL7内切双功能酶(Aly7A和Aly7B)、一种PL6外切双功能酶(Aly6A)和一种PL17外切M特异性酶(Aly17A)。采用超高效液相色谱 - 质谱联用技术揭示了这四种酶的协同作用。Aly7A的终产物被Aly7B进一步降解,最终生成从二糖到七糖的寡糖。寡糖产物被Aly6A完全降解为单糖,但它不能直接降解海藻酸盐。Aly17A也可以通过切割寡糖产物的M片段以及多糖的M片段产生单糖。这些酶的组合导致海藻酸盐完全降解为单糖。
挖掘到一个新的海藻酸盐PUL,并对PUL中的四种新型海藻酸盐裂解酶进行了表达和表征。这四种协同作用的海藻酸盐裂解酶为海藻酸盐降解和生物发酵提供了新工具。© 2023化学工业协会。
