[Structure and function of pore-forming proteins from bacteria of the genus Yersinia: I. Isolation and a comparison of physicochemical properties and functional activity of Yersinia porins].

The molecular organization and functional activity of porins isolated from the outer membrane (OM) of the Yersinia enterocolitica and three phylogenetically close nonpathogenic Yersinia species (Y. intermedia, Y. kristensenii, and Y. frederiksenii) cultured at 6-8 degrees C were comparatively studied for the first time. The proteins were isolated in two molecular forms (trimeric and monomeric), and their spatial structures were characterized by the methods of optical spectroscopy, CD and intrinsic protein fluorescence. The studied porins were shown to belong to the beta-structural proteins (they have 59-96% total beta structures and 0-17% alpha helices). The spatial structures of the proteins were demonstrated to depend on the nature of the detergent used for solubilization. Unlike the enterobacterial pore-forming proteins, the porin trimers are less stable to sodium dodecyl sulfate (SDS). The spatial structures of the porins become more compact after the substitution of octyl beta-D-glucoside for SDS: the content of beta structures increases and the accessibility of Trp residues to solvent decreases. It was established with the use of the technique of bilayer lipid membranes that the functional properties of the porins are similar to those of the OmpF proteins of Gram-negative bacteria. Trimers are functionally active forms of the porins. Special features of the pore-forming activity of the Yersinia porins were revealed to depend on the microorganism species and the value of the membrane potential.

Molecular characteristics of OmpF-like porins from pathogenic Yersinia.

Nonspecific pore-forming proteins (porins) are the major proteins of the outer membrane of Gram-negative bacteria responsible for diffusion of low-molecular-weight compounds. Nucleotide sequences of the OmpF-like porins from the pathogenic bacteria Yersinia pseudotuberculosis (YPS) and Yersinia enterocolitica (YE) were cloned and determined. Values of molecular weights (MW) and isoelectric points (IEP) calculated for these proteins (for OmpF-YPS: MW 37.7 kD, IEP 4.45; for OmpF-YE: MW 39.5 kD, IEP 4.34) are in good agreement with experimental data. The OmpF-like Yersinia porins are highly homologous to each other (83-92%) and also to the OmpF protein from Serratia marcescens (70%); the homology to the OmpF porin from E. coli is significantly lower (52-58%). Multiple alignment of the amino acid sequences of mature OmpF proteins provided the distribution of conservative amino acid residues typical for porins. Moreover, the OmpF-like porins from Yersinia are characterized by the presence of extended regions with high and low homologies, which coincide with the transmembrane domains and "external" loops, respectively, of the topological model of the OmpF porin from E. coli. By predictive methods, the secondary structure of the OmpF-like porins from Yersinia was obtained. This structure is represented by 16 beta-strands connected by short "periplasmic" and longer "external" loops with unordered structure.

[Primary structures of actinoporins from sea anemone Oulactis orientalis].

Partial amino acid sequences of the actinoporins Or-A (136 aa) and Or-G (144 aa) isolated from the Sea of Japan sea anemone Oulactis orientalis were determined by sequencing the clones obtained by the amplification of genomic DNA and cDNA with specific primers to the N-terminal regions of the 0. orientalis actinoporin sequences and to the C-terminal region, which is known to be highly conservative in all the known actinoporin sequences. The complete structures of Or-A (165 aa) and Or-G (173 aa) were established by sequencing the cDNA clones obtained by the fast amplification of 3'-ends of cDNA. A comparative analysis of the amino acid sequences of the Oulactis actinoporins with those of actinoporins from tropical species revealed considerable differences in the structures of their N-terminal fragments and their membrane-binding sites. We believe that these differences could explain lower hemolytic activities of Or-A and Or-G than that of actinoporins from the tropical species.