Dague Etienne, Duval Jérôme, Jorand Frédéric, Thomas Fabien, Gaboriaud Fabien
Laboratoire de Chimie Physique et Microbiologie pour l'Environnement, UMR 7564, CNRS, UHP Nancy I, F-54600 Villers-lès-Nancy, France.
Biophys J. 2006 Apr 1;90(7):2612-21. doi: 10.1529/biophysj.105.068205. Epub 2006 Jan 13.
Long-range electrostatic forces substantially influence bacterial interactions and bacterial adhesion during the preliminary steps of biofilm formation. The strength of these forces depends strongly on the structure of the bacterium surfaces investigated. The latter may be addressed from appropriate analysis of electrophoretic mobility measurements. Due to the permeable character of the bacterium wall and/or surrounding polymer layer, bacteria may be regarded as paradigms of soft bioparticles. The electrophoretic motion of such particles in a direct-current electric field differs considerably from that of their rigid counterparts in the sense that electroosmotic flow takes place around and within the soft surface layer. Recent developments of electrokinetic theories for soft particles now render possible the evaluation of the softness degree (or equivalently the hydrodynamic permeability) from the raw electrokinetic data. In this article, the electrophoretic mobilities of three Shewanella strains (MR-4, CN32, and BrY) presenting various and well-characterized phenotypes of polymer fringe are reported over a wide range of pH and ionic strength conditions. The data are quantitatively analyzed on the basis of a rigorous numerical evaluation of the governing electrostatic and hydrodynamic equations for soft particles. It is clearly shown how the peculiar surface structures of the bacteria investigated are reflected in their electrohydrodynamic properties.
在生物膜形成的初始阶段,长程静电力对细菌间相互作用及细菌黏附有着显著影响。这些力的强度在很大程度上取决于所研究细菌表面的结构。后者可通过对电泳迁移率测量结果进行适当分析来确定。由于细菌细胞壁和/或周围聚合物层具有可渗透特性,细菌可被视为软生物粒子的范例。此类粒子在直流电场中的电泳运动与其刚性对应物有很大不同,因为在软表面层周围和内部会发生电渗流。目前软粒子电动理论的最新进展使得从原始电动数据评估软度(或等效的流体动力学渗透率)成为可能。在本文中,报道了三种具有不同且特征明确的聚合物边缘表型的希瓦氏菌菌株(MR-4、CN32和BrY)在广泛的pH值和离子强度条件下的电泳迁移率。基于对软粒子控制静电和流体动力学方程的严格数值评估,对数据进行了定量分析。结果清楚地表明了所研究细菌独特的表面结构如何在其电流体动力学性质中得以体现。