Werner S, Colin D A, Coraiola M, Menestrina G, Monteil H, Prévost G
Laboratoire de Physiopathologie et d'Antibiologie des Infections Bactériennes Emergentes et Nosocomiales, Institut de Bactériologie de la Faculté de Médecine, Université Louis Pasteur, F-67000 Strasbourg, France.
Infect Immun. 2002 Mar;70(3):1310-8. doi: 10.1128/IAI.70.3.1310-1318.2002.
Bicomponent leucotoxins, such as Panton-Valentine leucocidin, are composed of two classes of proteins, a class S protein such as LukS-PV, which bears the cell membrane binding function, and a class F protein such as LukF-PV, which interacts to form a bipartite hexameric pore. These leucotoxins induce cell activation, linked to a Ca(2+) influx, and pore formation as two consecutive and independently inhibitable events. Knowledge of the LukF-PV monomer structure has indicated that the stem domain is folded into three antiparallel beta-strands in the water-soluble form and has to refold into a transmembrane beta-hairpin during pore formation. To investigate the requirements for the cooperative assembly of the stems of the S and F components to produce biological activity, we introduced multiple deletions or single point mutations into the stem domains of LukF-PV and HlgB. While the binding of the mutated proteins was weakly dependent on these changes, Ca(2+) influx and pore formation were affected differently, confirming that they are independent events. Ca(2+) entry into human polymorphonuclear cells requires oligomerization and may follow the formation of a prepore. The activity of some of the LukF-PV mutants, carrying the shorter deletions, was actually improved. This demonstrated that a crucial event in the action of these toxins is the transition of the prefolded stem into the extended beta-hairpins and that this step may be facilitated by small deletions that remove some of the interactions stabilizing the folded structure.
双组分白细胞毒素,如杀白细胞素(Panton-Valentine leucocidin),由两类蛋白质组成,一类是具有细胞膜结合功能的S类蛋白,如LukS-PV,另一类是相互作用形成二分体六聚体孔道的F类蛋白,如LukF-PV。这些白细胞毒素诱导细胞活化,这与Ca(2+)内流相关,并且孔道形成是两个连续且可独立抑制的事件。LukF-PV单体结构的研究表明,茎域在水溶性形式下折叠成三条反平行的β链,并且在孔道形成过程中必须重新折叠成跨膜β发夹结构。为了研究S和F组分的茎协同组装以产生生物活性的要求,我们在LukF-PV和HlgB的茎域中引入了多个缺失或单点突变。虽然突变蛋白的结合对这些变化的依赖性较弱,但Ca(2+)内流和孔道形成受到的影响不同,这证实它们是独立的事件。Ca(2+)进入人多形核细胞需要寡聚化,并且可能在预孔形成之后发生。一些携带较短缺失的LukF-PV突变体的活性实际上有所提高。这表明这些毒素作用中的一个关键事件是预折叠茎向延伸的β发夹结构的转变,并且这一步骤可能通过去除一些稳定折叠结构的相互作用的小缺失而得到促进。