[Molecular genetic methods of typing of the Bartonellae].

The primer systems for the PCR detection of four house-keeping genes of bartonellae in clinical material were developed and tested. The tactics of the species RFLP typing was also developed and tested. The scheme of the species RFLP typing of bartonellae was tested using as an example two strains for the first time isolated in Russia from patients with endocarditis and fever of uncertain origin. The results of the typing were supported by sequencing of the amplicons obtained. According to the sequencing the isolates were attributed to the sub species Bartonella vinsonii, subsp. arupensis. The necessity of molecular epidemiological analysis of bartonelloses in Russia was substantiated.

[Wild small mammals are the reservoir hosts of the Bartonella genus bacteria in the south of Moscow region].

A total of 103 blood samples collected from wild small mammals captured in the Prioksko-Terrasny Reserve on the south of Moscow region were studied to determine the bartonellae prevalence. The examined species were the yellow-necked mice Apodemus flavicollis (35 samples), the European wood mouse Apodemus uralensis (10 samples), the bank vole Clethrionomys glareolus (51 samples), the house mouse Mus musculus (3 samples), the common vole Microtus arvalis (2 samples), and the shrew Sorex araneus (2 samples). Initially, we obtained 76 bacterial Bartonella-like isolates after plating onto the surface of the solid nutrient media. 66 of them were PCR-positive at least for three of four targets, gltA, ftsZ, ribC and 16S RNA. Thus, the percentage of the infection in the studied community was 64%. Subsequent RFLP assay showed that obtained isolates belonged to the Bartonella grahamii and/or B. taylorii species. In 7 cases we found both bartonellae species in one animal. These data were confirmed by direct sequencing of four ftsZ, four ribC and two gltA amplicons. According to our data, there is no any marked host specificity for these bartonellae species. Now we have laid the bartonellae strain collection consisting of 31 isolates. To our knowledge, this is the first investigation of the bartonellae prevalence in wild small mammals performed in Russia. The comparison of our data with those obtained by European researchers and issues of coinfection by different bartonellae species and host specificity are discussed.

Toxicity and immunogenicity of Neisseria meningitidis lipopolysaccharide incorporated into liposomes.

To obtain nontoxic and highly immunogenic lipopolysaccharide (LPS) for immunization, we incorporated Neisseria meningitidis LPS into liposomes. Native LPS and its salts were incorporated by the method of dehydration-rehydration of vesicles or prolonged cosonication. The most complete incorporation of LPS into liposomes and a decrease in toxicity were achieved by the method of dehydration-rehydration of vesicles. Three forms of LPS (H+ form, Mg2+ salt, and triethanolamine salt) showed different solubilities in water, the acidic form of LPS, with the most pronounced hydrophobic properties, being capable of practically complete association with liposomal membranes. An evaluation of the activity of liposomal LPS in vitro (by the Limulus amoebocyte test) and in vivo (by monitoring the pyrogenic reaction in rabbits) revealed a decrease in endotoxin activity of up to 1,000-fold. In addition, the pyrogenic activity of liposomal LPS was comparable to that of a meningococcal polysaccharide vaccine. Liposomes had a pronounced adjuvant effect on the immune response to LPS. Thus, the level of anti-LPS plaque-forming cells in the spleens of mice immunized with liposomal LPS was 1 order of magnitude higher and could be observed for a longer time (until day 21, i.e., the term of observation) than in mice immunized with free LPS. The same regularity was revealed in a study done with an enzyme-linked immunosorbent assay. This study also established that antibodies induced by immunization belonged to the immunoglobulin M and G classes, which are capable of prolonged circulation. Moreover, liposomal LPS induced a pronounced immune response in CBA/N mice (defective in B lymphocytes of the LyB-5+ subpopulation). The latter results indicate that the immunogenic action of liposomal LPS occurs at an early age.

Glycopeptidolipids--a new class of artificial antigens with carbohydrate determinants. Synthesis of artificial antigen with type-specific oligosaccharide hapten from Neisseria meningitidis group B.

Synthetic lipopeptide N-palmitoyltyrosyl-seryl-seryl-asparaginyl-alanine, an analogue of B-mitogenic tripalmitoyl-pentapeptide from Escherichia coli lipoprotein, was coupled with an oligosaccharide hapten from Neisseria meningitidis lipooligosaccharide to give a glycopeptidolipid conjugate--the artificial antigen of a new type processing the type-specific microbial determinant.

[Formation of microvesicles in meningococcal cells during batch cultivation]. / Formirovanie mikrovezikul u kletok meningokokka v protsesse periodicheskogo kul'tivirovaniia.

Both surface and intracytoplasmic vesiculae have been shown to appear in meningococcal cells, strains 132, 125, and 133 belonging, respectively, to serogroups A, B, and C, in the process of batch cultivation. The surface microvesiculae are formed from the outer membrane of the cell wall during the whole process of batch cultivation. The intracytoplasmic membrane structures are formed in the process of cell autolysis. As revealed in this investigation, the strains under study, irrespective of their serogroup, are characterized by similar mechanisms of the formation of microvesiculae. The surface microvesiculae have been found to fall into three main types: monolamellar, multilamellar, and large spheroid bodies. The presence of specific functional features in each type of surface microvesiculae is suggested, as these microvesiculae, besides having their characteristic ultrastructure, differ in their contents. The attenuated culture of meningococcal strain 133, whose cells are notable among other strains under study for their more active (quantitatively) formation of microvesiculae, has been shown to have the highest toxicity for rabbits.