Reinvestigation into the role of lipopolysaccharide Glycosyltransferases in Helicobacter pylori protein glycosylation.

IF 12.2 1区医学 Q1 GASTROENTEROLOGY & HEPATOLOGY

Gut Microbes Pub Date : 2025-01-20 DOI:10.1080/19490976.2025.2455513

Hong Li,Xiaoqiong Tang,Tiandi Yang,Tingting Liao,Aleksandra W Debowski,Tiankuo Yang,Yalin Shen,Hans-Olof Nilsson,Stuart M Haslam,Barbara Mulloy,Anne Dell,Keith A Stubbs,Wolfgang Fischer,Rainer Haas,Hong Tang,Barry J Marshall,Mohammed Benghezal

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Abstract

Protein glycosylation has been considered as a fundamental phenomenon shared by all domains of life. In Helicobacter pylori, glycosylation of flagellins A and B with pseudaminic acid have been rigorously confirmed and shown to be essential for flagella assembly and bacterial colonization. In addition to flagellins, several other proteins including RecA, AlpA/B, and BabA/B in H. pylori have also been reported to be glycosylated and to be dependent on the lipopolysaccharide (LPS) biosynthetic pathway. However, these proteins have not been purified for sugar-specific staining or structural analysis to confirm the existence of carbohydrate motifs. Here, using a combined approach of genetics, protein purification, and sugar-specific staining, we demonstrate that RecA is not a glycoprotein. Moreover, using LPS-protein reconstitution experiments, we demonstrate that the presence of O-antigen containing full-length LPS interferes with the electrophoretic mobility of H. pylori RecA and many other proteins including AlpA/B on SDS-PAGE. Finally, we demonstrate that full-length LPS extracted from E. coli affects electrophoretic migration of H. pylori proteins, while full-length LPS extracted from H. pylori similarly influences the electrophoretic migration of E. coli proteins. The impact is more subtle with E. coli LPS compared to H. pylori LPS, indicating that the magnitude of effect of LPS effects on protein mobility is dependent on bacterial source of the LPS. These findings suggest that the effects of full-length LPS on protein electrophoresis may represent a more general phenomenon. As LPS is a unique component of virtually all Gram-negative bacteria, our data suggest that when observing protein electrophoretic mobility shifts between wild-type and LPS mutant strains or between subcellular fractionation samples, the influence of LPS on protein electrophoretic migration should be considered first, rather than interpreting it as potential protein glycosylation that is dependent upon LPS biosynthetic pathway.

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脂多糖糖基转移酶在幽门螺杆菌蛋白糖基化中的作用。

蛋白质糖基化被认为是所有生命领域共有的一种基本现象。在幽门螺杆菌中，鞭毛蛋白A和B与假氨基酸的糖基化已被严格证实，并被证明是鞭毛组装和细菌定植所必需的。除鞭毛蛋白外，幽门螺杆菌中的RecA、AlpA/B和BabA/B等蛋白也被报道为糖基化，并依赖于脂多糖（LPS）生物合成途径。然而，这些蛋白质还没有被纯化用于糖特异性染色或结构分析，以确认碳水化合物基序的存在。在这里，使用遗传学，蛋白质纯化和糖特异性染色的联合方法，我们证明了RecA不是糖蛋白。此外，通过LPS蛋白重构实验，我们证明含有全长LPS的o抗原的存在干扰了幽门螺杆菌RecA和许多其他蛋白质（包括SDS-PAGE上的AlpA/B）的电泳迁移率。最后，我们证明了从大肠杆菌中提取的全长LPS会影响幽门螺杆菌蛋白的电泳迁移，而从幽门螺杆菌中提取的全长LPS同样会影响大肠杆菌蛋白的电泳迁移。与幽门螺杆菌LPS相比，大肠杆菌LPS对蛋白质迁移的影响更为微妙，这表明LPS对蛋白质迁移的影响程度取决于LPS的细菌来源。这些发现表明，全长LPS对蛋白质电泳的影响可能代表了一种更普遍的现象。由于LPS是几乎所有革兰氏阴性菌的独特成分，我们的数据表明，当观察野生型菌株和LPS突变菌株之间或亚细胞分离样品之间的蛋白质电泳迁移时，应首先考虑LPS对蛋白质电泳迁移的影响，而不是将其解释为依赖于LPS生物合成途径的潜在蛋白质糖基化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Gut Microbes Medicine-Microbiology (medical)

CiteScore

18.20

自引率

3.30%

发文量

196

审稿时长

10 weeks

期刊介绍： The intestinal microbiota plays a crucial role in human physiology, influencing various aspects of health and disease such as nutrition, obesity, brain function, allergic responses, immunity, inflammatory bowel disease, irritable bowel syndrome, cancer development, cardiac disease, liver disease, and more. Gut Microbes serves as a platform for showcasing and discussing state-of-the-art research related to the microorganisms present in the intestine. The journal emphasizes mechanistic and cause-and-effect studies. Additionally, it has a counterpart, Gut Microbes Reports, which places a greater focus on emerging topics and comparative and incremental studies.