Plasticity of Escherichia coli porin channels. Dependence of their conductance on strain and lipid environment

Abstract

The conductance properties of three members of the porin family which form channels across the outer membrane of Gram-negative bacteria were compared. With their endogenous lipopolysaccharide (LPS) bound, the closely related porins F and C from Escherichia coli reveal significantly different conductance steps and closing potentials, with values of 0.82 nS (nanosiemens) and 89 mV for F-type channels, and 0.49 nS and 158 mV for C-type pores (1 M NaCl), respectively. On the basis of their closing potentials, the two channel types can be distinguished unequivocally. If reconstituted in asolectin and extraneous LPS, porin C forms F-type in addition to C-type channels. Substitution of asolectin by mitochondrial lipids yields the native C-type pores only. Both channel types can be induced to assume the mutually other channel configuration by variation of ionic strength. A multiplicity of channel subtypes is observed by variation of the pH of the medium. The three channels within a trimer are, however, consistently of the same type. Since structural studies have revealed a single channel per monomer, the several conductance steps observed are likely to reflect distinct configurations of the same channel. Best channel recoveries were observed if endogenous LPS remained associated to porin during purification. Significant yields could nevertheless be obtained also if LPS was removed from porin and replaced with various precursors or chemically synthesized analogues. As function requires the presence of glycolipids, yet crystallization is perturbed by heterodisperse endogenous LPS, the smallest monodisperse analogues yielding good channel recovery were determined. The minimal synthetic moiety is a monoglucosaminetetraacyl compound. The characteristics of porin B from E. coli BE are shown to be indistinguishable from those of porin F. The conductance properties of this porin, refolded from random coil configuration, are indistinguishable from those exhibited by native protein. The formation of channels is thus encoded by the sequence of the mature polypeptide alone.