[A locus involved in tuberculosis infection control in mice locates in the proximal part of the H2 complex].

One of genetic loci involved in tuberculosis (TB) infection control in mice is located within the segment of Chr. 17 occupied by the H2 complex, the mouse MHC. As far as this region includes approximately 40 Mb and contains hundreds of genes affecting immune responses and host-parasite interactions, narrowing the interval by genetic recombination is pre-requisite for identification of particular gene(s). We have developed a panel of recombinant congenic strains bearing different parts of the H2 complex from TB-susceptible I/St mice on the genetic background of TB-resistant C57BL/6 mice. By superposing the phenotype "severe vs. mild infectious course" against the chart of alleles inherited by these new strains from the two parental strains, we have mapped a locus involved in TB control within the segment 33.305-34.479 Mb (-1.1 Mb) of the Chr. 17. Such a location indicates that allelic variants of the prominent pro-inflammatory factor TNF do not affect TB course in our experimental system. This result was confirmed by the assessment of the TNF level in the lung tissue of infected mice of different strains. The QTL (quantitative trait locus) mapped in our study influences several important parameters of TB infection: multiplication of mycobacteria in the lungs, severity of lung pathology and regulation of the early inflammatory response.

RNA-dependent RNA polymerase of hepatitis C virus: study on inhibition by alpha,gamma-diketo acid derivatives.

It is supposed that alpha,gamma-diketo acids (DKAs) inhibit the activity of hepatitis C virus RNA-dependent RNA polymerase (RdRP HCV) via chelation of catalytic magnesium ions in the active center of the enzyme. However, DKAs display noncompetitive mode of inhibition with respect to NTP substrate, which contradicts the proposed mechanism. We have examined the NTP substrate entry channel and the active site of RdRP HCV for their possible interaction with DKAs. The substitutions R48A, K51A, and R222A greatly facilitated RdRP inhibition by DKAs and simultaneously increased K(m) values for UTP substrate. Interestingly, C223A was the only one of a number of substitutions that decreased K(m)(UTP) but facilitated the inhibitory action of DKAs. The findings allowed us to model an enzyme-inhibitor complex. According to the proposed model, DKAs introduce an additional Mg2+ ion into the active site of the enzyme at a stage of phosphodiester bond formation, which results in displacement of the NTP substrate triphosphate moiety to a catalytically inactive binding mode. This mechanism, in contrast to the currently adopted one, explains the noncompetitive mode of inhibition.

[Efficiency of anti-inflammatory therapy for experimental tuberculosis in genetically tuberculosis-sensitive mice].

The study assessed trends in death rates in genetically tuberculosis-sensitive I/St mice, mycobacterial seeding from their organs, and the magnitude of abnormal changes in the lung after intratracheal Mycobacterium tuberculosis infection of recipients. The experimental animals received two anti-inflammatory regimens: 1) a very small-dose intravenous injection of immature antigen-loaded bone marrow-derived syngeneic dendritic cells; 2) the nonsteroidal anti-inflammatory drug diclofenac injected intramuscularly in the course of disease development. Both anti-inflammatory regimens caused a significant increase in the animals' survival, a reduction in the amount of mycobacteria in the lung and the pulmonary infiltration with lymphoid cells as compared with untreated infected control animals. These findings indicate that suppression of an excessive inflammatory process in the lung may have a beneficial antituberculous effect in tuberculosis-sensitive animals.

I/St mice hypersusceptible to Mycobacterium tuberculosis are resistant to M. avium.

We previously demonstrated that mice of the I/St strain are extremely susceptible to Mycobacterium tuberculosis, as well as to the taxonomically distant intracellular bacteria Chlamydia pneumoniae and Salmonella enterica. To broaden our knowledge about the control of susceptibility to intracellular pathogens, we studied the infection caused by Mycobacterium avium virulent strain 724 in a panel of inbred mouse strains and found that I/St mice are resistant to M. avium. By comparing I/St mice with B6 mice, we demonstrated that (i) B6 mice are much more susceptible to infection caused by M. avium in terms of bacterial multiplication in the lung tissue and severity of lung pathology; (ii) in B6 mice but not in I/St mice infection leads to prolonged leukocyte infiltration of the lung tissue, development of necrotic lung granulomata, and lethality; and (iii) the unfavorable infectious course in B6 mice is accompanied by elevated production of gamma interferon, tumor necrosis factor alpha, and especially interleukin-12 in the lungs. Importantly, M. avium-resistant I/St mice carry a functional r allele of the Slc11a1 (formerly Nramp1) gene, while B6 mice have the Slc11a1(s) genotype. Segregation genetic analysis of (I/St x B6) F2 hybrids demonstrated that susceptibility or resistance to infection caused by M. avium largely depended upon the Slc11a1 genotype and that other genetic traits had a relatively weak influence. This close-to-monogenic pattern differs sharply from the host control of many other intracellular bacterial infections, for which the involvement of numerous quantitative trait loci has been ubiquitously observed.