Arora S K, Bangera M, Lory S, Ramphal R
Department of Medicine/Infectious Diseases, University of Florida, Gainesville, FL 32610, USA.
Proc Natl Acad Sci U S A. 2001 Jul 31;98(16):9342-7. doi: 10.1073/pnas.161249198.
Protein glycosylation has been long recognized as an important posttranslational modification process in eukaryotic cells. Glycoproteins, predominantly secreted or surface localized, have also been identified in bacteria. We have identified a cluster of 14 genes, encoding the determinants of the flagellin glycosylation machinery in Pseudomonas aeruginosa PAK, which we called the flagellin glycosylation island. Flagellin glycosylation can be detected only in bacteria expressing the a-type flagellin sequence variants, and the survey of 30 P. aeruginosa isolates revealed coinheritance of the a-type flagellin genes with at least one of the flagellin glycosylation island genes. Expression of the b-type flagellin in PAK, an a-type strain carrying the glycosylation island, did not lead to glycosylation of the b-type flagellin of PAO1, suggesting that flagellins expressed by b-type bacteria not only lack the glycosylation island, they cannot serve as substrates for glycosylation. Providing the entire glycosylation island of PAK, including its a-type flagellin in a flagellin mutant of a b-type strain, results in glycosylation of the heterologous flagellin. These results suggest that some or all of the 14 genes on the glycosylation island are the genes that are missing from strain PAO1 to allow glycosylation of an appropriate flagellin. Inactivation of either one of the two flanking genes present on this island abolished flagellin glycosylation. Based on the limited homologies of these gene products with enzymes involved in glycosylation, we propose that the island encodes similar proteins involved in synthesis, activation, or polymerization of sugars that are necessary for flagellin glycosylation.
蛋白质糖基化长期以来一直被认为是真核细胞中一种重要的翻译后修饰过程。糖蛋白主要是分泌型或定位于细胞表面的,在细菌中也已被鉴定出来。我们已经鉴定出一组14个基因,它们编码铜绿假单胞菌PAK中鞭毛蛋白糖基化机制的决定因素,我们将其称为鞭毛蛋白糖基化岛。鞭毛蛋白糖基化仅在表达a型鞭毛蛋白序列变体的细菌中才能检测到,对30株铜绿假单胞菌分离株的调查显示,a型鞭毛蛋白基因与至少一个鞭毛蛋白糖基化岛基因共遗传。在携带糖基化岛的a型菌株PAK中表达b型鞭毛蛋白,并未导致PAO1的b型鞭毛蛋白糖基化,这表明b型细菌表达的鞭毛蛋白不仅缺乏糖基化岛,而且不能作为糖基化的底物。在b型菌株的鞭毛蛋白突变体中提供PAK的整个糖基化岛,包括其a型鞭毛蛋白,会导致异源鞭毛蛋白糖基化。这些结果表明,糖基化岛上的14个基因中的一些或全部是PAO1菌株中缺失的基因,这些基因使得合适的鞭毛蛋白能够进行糖基化。该岛上存在的两个侧翼基因中的任何一个失活都会消除鞭毛蛋白糖基化。基于这些基因产物与参与糖基化的酶的有限同源性,我们提出该岛编码参与鞭毛蛋白糖基化所需的糖合成、激活或聚合的类似蛋白质。