Baptista Catarina, Santos Mário A, São-José Carlos
Departamento de Biologia Vegetal, Faculdade de Ciências da Universidade de Lisboa, Instituto de Ciência Aplicada e Tecnologia, Lisbon, Portugal.
J Bacteriol. 2008 Jul;190(14):4989-96. doi: 10.1128/JB.00349-08. Epub 2008 May 16.
Bacteriophage SPP1 targets the host cell membrane protein YueB to irreversibly adsorb and infect Bacillus subtilis. Interestingly, SPP1 still binds to the surface of yueB mutants, although in a completely reversible way. We evaluated here the relevance of a reversible step in SPP1 adsorption and identified the receptor(s) involved. We show that reversible adsorption is impaired in B. subtilis mutants defective in the glucosylation pathway of teichoic acids or displaying a modified chemical composition of these polymers. The results indicate that glucosylated poly(glycerolphosphate) cell wall teichoic acid is the major target for SPP1 reversible binding. Interaction with this polymer is characterized by a fast adsorption rate showing low-temperature dependence, followed by a rapid establishment of an equilibrium state between adsorbed and free phages. This equilibrium is basically determined by the rate of phage dissociation, which exhibits a strong dependence on temperature compatible with an Arrhenius law. This allowed us to determine an activation energy of 22.6 kcal/mol for phage release. Finally, we show that SPP1 reversible interaction strongly accelerates irreversible binding to YueB. Our results support a model in which fast SPP1 adsorption to and desorption from teichoic acids allows SPP1 to scan the bacterial surface for rapid YueB recognition.
噬菌体SPP1靶向宿主细胞膜蛋白YueB,以不可逆地吸附并感染枯草芽孢杆菌。有趣的是,SPP1仍能与yueB突变体的表面结合,尽管这种结合是完全可逆的。我们在此评估了SPP1吸附过程中可逆步骤的相关性,并确定了涉及的受体。我们发现,在磷壁酸糖基化途径有缺陷或这些聚合物化学组成发生改变的枯草芽孢杆菌突变体中,可逆吸附受到损害。结果表明,糖基化的聚(甘油磷酸)细胞壁磷壁酸是SPP1可逆结合的主要靶点。与这种聚合物的相互作用的特点是吸附速率快,显示出对低温的依赖性,随后在吸附的噬菌体和游离噬菌体之间迅速建立平衡状态。这种平衡基本上由噬菌体解离速率决定,该速率表现出与阿伦尼乌斯定律相符的对温度的强烈依赖性。这使我们能够确定噬菌体释放的活化能为22.6千卡/摩尔。最后,我们表明SPP1的可逆相互作用强烈加速了其与YueB的不可逆结合。我们的结果支持了一个模型,即SPP1与磷壁酸的快速吸附和解吸使SPP1能够扫描细菌表面以快速识别YueB。