Charon N W, Greenberg E P, Koopman M B, Limberger R J
West Virginia University, Department of Microbiology and Immunology, Morgantown 26506.
Res Microbiol. 1992 Jul-Aug;143(6):597-603. doi: 10.1016/0923-2508(92)90117-7.
Spirochetes have a unique motility system that is characterized by flagellar filaments contained within the outer membrane sheath. Direct evidence using video microscopy has recently been obtained which indicates that these periplasmic flagella (PF) rotate in several spirochetal species. This rotation generates thrust. As shown for one spirochete, Spirochaeta aurantia, motility is driven by a proton motive force. Spirochete chemotaxis has been most thoroughly studied in S. aurantia. This spirochete exhibits three distinct behaviours, runs of smooth swimming, reversals and flexing. These behaviours are modulated by addition of attractants such that S. aurantia swims towards higher concentrations of attractants in a spatial gradient. Unlike the prototypical bacterium, Escherichia coli, chemotaxis in S. aurantia involves fluctuations in membrane potential. The PF of a number of spirochetes have been examined in considerable detail. For most species, the PF filaments are complex, consisting of an assembly of several different polypeptides. There are several antigenically related core polypeptides surrounded by an outer layer consisting of a different polypeptide. Borrelia burgdorferi and Spirochaeta zuelzerae represent exceptions where the filaments are composed of a single major polypeptide species. The genes encoding the filament polypeptides from several spirochete species have been cloned and analysed. Apparently, the outer layer polypeptides of S. aurantia, Treponema pallidum and Serpulina hyodysenteriae are transcribed from sigma-70-like promoters, whereas the core polypeptide genes are transcribed from sigma-28-like promoters. A gene encoding the hook polypeptide in Treponema phagedenis has been cloned and analysed. The product of this gene shows significant similarity to the E. coli hook protein, FlgE, and homologs have been identified in T. pallidum and B. burgdorferi.(ABSTRACT TRUNCATED AT 250 WORDS)
螺旋体具有独特的运动系统,其特征是鞭毛丝包含在外膜鞘内。最近通过视频显微镜获得的直接证据表明,这些周质鞭毛(PF)在几种螺旋体物种中会旋转。这种旋转产生推力。正如一种螺旋体——金色螺旋体所示,其运动由质子动力驱动。螺旋体趋化性在金色螺旋体中得到了最深入的研究。这种螺旋体表现出三种不同行为:平稳游动、反转和弯曲。这些行为会因添加引诱剂而受到调节,使得金色螺旋体在空间梯度中朝着引诱剂浓度更高的方向游动。与典型细菌大肠杆菌不同,金色螺旋体的趋化性涉及膜电位的波动。许多螺旋体的周质鞭毛已得到相当详细的研究。对于大多数物种而言,周质鞭毛丝很复杂,由几种不同多肽的组合构成。有几种抗原相关的核心多肽被一层由不同多肽组成的外层包围。伯氏疏螺旋体和祖氏螺旋体是例外,其鞭毛丝由单一主要多肽物种组成。编码几种螺旋体物种鞭毛丝多肽的基因已被克隆和分析。显然,金色螺旋体、梅毒螺旋体和猪痢疾蛇形螺旋体的外层多肽是从类似σ-70的启动子转录而来,而核心多肽基因是从类似σ-28的启动子转录而来。一个编码噬菌密螺旋体钩状多肽的基因已被克隆和分析。该基因的产物与大肠杆菌钩状蛋白FlgE具有显著相似性,并且在梅毒螺旋体和伯氏疏螺旋体中也鉴定出了同源物。(摘要截选至250词)
