Cheng Yuanyuan, Wang Dandan, Gu Jingyan, Li Junge, Liu Huihui, Li Fuchuan, Han Wenjun
National Glycoengineering Research Center, Shandong Provincial Key Laboratory of Carbohydrate Chemistry and Glycobiology, and State Key Laboratory of Microbial Technology, Shandong University, Jinan, China.
Department of Food Science and Engineering, Shandong Agriculture and Engineering University, Jinan, China.
Appl Environ Microbiol. 2017 Nov 16;83(23). doi: 10.1128/AEM.01608-17. Print 2017 Dec 1.
Bifunctional alginate lyases can efficiently degrade alginate comprised of mannuronate (M) and guluronate (G), but their substrate-degrading modes have not been thoroughly elucidated to date. In this study, we present Aly1 as a novel bifunctional endolytic alginate lyase of the genus The recombinant enzyme showed optimal activity at 50°C and pH 6.0. The enzyme produced unsaturated disaccharide (UDP2) and trisaccharide fractions as the final main alginate digests. Primary substrate preference tests and further structure identification of various size-defined final oligosaccharide products demonstrated that Aly1 is a bifunctional alginate lyase and prefers G to M. Tetrasaccharide-size fractions are the smallest substrates, and M, G, and UDP2 fractions are the minimal product types. Remarkably, Aly1 can vary its substrate-degrading modes in accordance with the terminus types, molecular sizes, and M/G contents of alginate substrates, producing a series of small size-defined saturated oligosaccharide products from the nonreducing ends of single or different saturated sugar chains and yielding unsaturated products in distinct but restricted patterns. The action mode changes can be partially inhibited by fluorescent labeling at the reducing ends of oligosaccharide substrates. Deletion of the noncatalytic region (NCR) of Aly1 caused weak changes of biochemical characteristics but increased the degradation proportions of small size-defined saturated M-enriched oligosaccharide substrates and unsaturated tetrasaccharide fractions without any size changes of degradable oligosaccharides, thereby enhancing the M preference and enzyme activity. Therefore, our results provided insight into the variable action mode of a novel bifunctional endolytic alginate lyase to inform accurate enzyme use. The elucidated endolytic alginate lyases usually degrade substrates into various size-defined unsaturated oligosaccharide products (≥UDP2), and exolytic enzymes yield primarily unsaturated monosaccharide products. However, it is poorly understood whether endolytic enzymes can produce monosaccharide product types when degrading alginate. In this study, we demonstrated that Aly1, a bifunctional alginate lyase of sp. strain MY04, is endolytic and monosaccharide producing. Using various sugar chains as testing substrates, we also proved that key factors causing Aly1's action mode changes are the terminus types, molecular sizes, and M/G contents of substrates. Furthermore, the NCR fragment's effects on Aly1's biochemical characteristics and alginate-degrading modes and corresponding mechanisms were discovered by gene truncation and enzyme comparison. In summary, this study provides a novel bifunctional endolytic tool and a variable action mode for accurate use in alginate degradation.
双功能海藻酸裂解酶能够高效降解由甘露糖醛酸(M)和古洛糖醛酸(G)组成的海藻酸盐,但其底物降解模式迄今尚未得到充分阐明。在本研究中,我们提出Aly1是一种新型的来自属的双功能内切海藻酸裂解酶。该重组酶在50°C和pH 6.0时表现出最佳活性。该酶产生不饱和二糖(UDP2)和三糖组分作为最终的主要海藻酸盐消化产物。初步底物偏好测试以及对各种大小确定的最终寡糖产物的进一步结构鉴定表明,Aly1是一种双功能海藻酸裂解酶,且对G的偏好高于M。四糖大小的组分是最小的底物,而M、G和UDP2组分是最小的产物类型。值得注意的是,Aly1可以根据海藻酸盐底物的末端类型、分子大小和M/G含量改变其底物降解模式,从单条或不同饱和糖链的非还原端产生一系列大小确定的小饱和寡糖产物,并以独特但有限的模式产生不饱和产物。寡糖底物还原端的荧光标记可部分抑制作用模式的变化。删除Aly1的非催化区域(NCR)导致生化特性的微弱变化,但增加了大小确定的富含饱和M的小寡糖底物和不饱和四糖组分的降解比例,且可降解寡糖的大小没有任何变化,从而增强了对M的偏好和酶活性。因此,我们的结果为一种新型双功能内切海藻酸裂解酶的可变作用模式提供了见解,以指导准确使用该酶。已阐明的内切海藻酸裂解酶通常将底物降解为各种大小确定的不饱和寡糖产物(≥UDP2),而外切酶主要产生不饱和单糖产物。然而,对于内切酶在降解海藻酸盐时是否能产生单糖产物类型知之甚少。在本研究中,我们证明了来自sp.菌株MY04的双功能海藻酸裂解酶Aly1是内切且能产生单糖的。使用各种糖链作为测试底物,我们还证明了导致Aly1作用模式变化的关键因素是底物的末端类型、分子大小和M/G含量。此外,通过基因截短和酶比较发现了NCR片段对Aly1生化特性和海藻酸盐降解模式的影响及相应机制。总之,本研究为海藻酸盐降解提供了一种新型双功能内切工具和可变作用模式以供准确使用。
