New Insights into the Methylation of Mycobacterium tuberculosis Heparin Binding Hemagglutinin Adhesin Expressed in Rhodococcus erythropolis.

In recent years, knowledge of the role that protein methylation is playing on the physiopathogenesis of bacteria has grown. In Mycobacterium tuberculosis, methylation of the heparin binding hemagglutinin adhesin modulates the immune response, making this protein a subunit vaccine candidate. Through its C-terminal lysine-rich domain, this surface antigen interacts with heparan sulfate proteoglycans present in non-phagocytic cells, leading to extrapulmonary dissemination of the pathogen. In this study, the adhesin was expressed as a recombinant methylated protein in Rhodococcus erythropolis L88 and it was found associated to lipid droplets when bacteria were grown under nitrogen limitation. In order to delve into the role methylation could have in host-pathogen interactions, a comparative analysis was carried out between methylated and unmethylated protein produced in Escherichia coli. We found that methylation had an impact on lowering protein isoelectric point, but no differences between the proteins were found in their capacity to interact with heparin and A549 epithelial cells. An important finding was that HbhA is a Fatty Acid Binding Protein and differences in the conformational stability of the protein in complex with the fatty acid were observed between methylated and unmethylated protein. Together, these results suggest that the described role for this mycobacteria protein in lipid bodies formation could be related to its capacity to transport fatty acids. Obtained results also provide new clues about the role HbhA methylation could have in tuberculosis and point out the importance of having heterologous expression systems to obtain modified proteins.

Interaction of mycobacteria with Plasmin(ogen) affects phagocytosis and granuloma development.

Plasminogen and plasmin are fundamental components of the fibrinolytic system that interact with microorganisms generating different immunopathological effects. The molecules of Mycobacterium tuberculosis interplaying with plasminogen have already been identified and characterized. In this work, we studied the effects of plasmin(ogen) bound toMycobacterium bovisCalmette-Guérin (BCG) on phagocytosis in THP1 macrophages as well as in granuloma formation and development on in vitrohuman granuloma model. For this purpose, BCG was coated with plasminogen and plasmin, obtained after activation of zymogen by tissue plasminogen activator. The results showed a significant reduction in the number of bacteria phagocytosed by macrophages in presence of plasminogen or plasmin on BCG surface. On the other hand, at 3 days BCG/plasminogen/plasmin induced an increase granuloma numbers with respect to those induced by uncoated bacteria. BCG/plasminogen/environments also showed a significant increase of IL-6 secretion. At 7 days, a reduced number of granulomas and an increased number of bacteria was observed with respect to uncoated BCG environment. Altogether, these results showed that plasmin(ogen) on the mycobacterial surface affects phagocytosis, granuloma development and the cytokine context, thus resulting in an increased number of bacteria in granulomas.

Rhodococcus erythropolis as a host for expression, secretion and glycosylation of Mycobacterium tuberculosis proteins.

BACKGROUND: Glycosylation is one of the most abundant posttranslational polypeptide chain modification in nature. Although carbohydrate modification of protein antigens from many microbial pathogens constitutes important components of B cell epitopes, the role in T cell immunity is not completely understood. There is growing evidence about the importance of these modifications in host bacteria interactions in tuberculosis. It is known, that the sugars present in some Mycobacterium tuberculosis glycoproteins play an important role in both humoral and cellular immune response against the pathogen. Since this modification is lost in the recombinant proteins expressed in Escherichia coli, it is fundamental to search for host bacteria with the capacity to modify the foreign proteins. Amongst the bacteria that are likely to have this possibility are some members of Rhodococcus genus which are Gram-positive bacteria, with high GC-content and genetically very close related to M. tuberculosis. RESULTS: In this work, apa, pstS1 and lprG genes that coding for M. tuberculosis glycoproteins were cloned and expressed in Rhodococcus erythropolis. All recombinant proteins were mannosylated as demonstrated by their interaction with mannose binding lectin Concanavalin A. In addition, as native proteins recombinants Apa and PstS1 were secreted to the culture medium in contrast with LprG that was retained in the cell wall. CONCLUSIONS: Together these results, point out R. erythropolis, as a new host for expression of M. tuberculosis glycoproteins.

Nitric oxide not apoptosis mediates differential killing of Mycobacterium bovis in bovine macrophages.

To identify the resistance phenotype against Mycobacterium bovis in cattle, we used a bactericidal assay that has been considered a marker of this trait. Three of 24 cows (12.5%) were phenotyped as resistant and 21 as susceptible. Resistance of bovine macrophages (MΦ) to BCG challenge was evaluated for its association with SLC11A1 GT microsatellite polymorphisms within 3'UTR region. Twenty-three cows (95.8%) had a GT13 genotype, reported as resistant, consequently the SLC11A1 polymorphism was not in agreement with our bactericidal assay results. MΦ of cows with resistant or susceptible phenotype were challenged in vitro with virulent M. bovis field strain or BCG, and nitric oxide production, bacterial killing and apoptosis induction were measured in resting and LPS-primed states. M. bovis field strain induced more apoptosis than BCG, although the difference was not significant. Resistant MΦ controlled better the replication of M. bovis (P<0.01), produced more nitric oxide (P<0.05) and were slightly more prone to undergo apoptosis than susceptible cells. LPS pretreatment of MΦ enhanced all the functional parameters analyzed. Inhibition of nitric oxide production with n (G)-monomethyl-L-arginine monoacetate enhanced replication of M. bovis but did not modify apoptosis rates in both resistant and susceptible MΦ. We conclude that nitric oxide production not apoptosis is a major determinant of macrophage resistance to M. bovis infection in cattle and that the influence of SLC11A1 gene 3'UTR polymorphism is not associated with this event.

Mycobacterium tuberculosis glycoproteomics based on ConA-lectin affinity capture of mannosylated proteins.

A Mycobacterium tuberculosis culture filtrate enriched with mannose-containing proteins was resolved by 2-DE gel. After ConA ligand blotting, 41 proteins were identified by mass spectrometry as putative glycoproteins with 34 of them new probably mannosylated proteins. These results contribute to the construction of the ConA affinity glycoprotein database of M. tuberculosis, and provide useful information for understanding the biological role of glycoproteins in mycobacteria.

Expression of Mycobacterium tuberculosis pe_pgrs33 is repressed during stationary phase and stress conditions, and its transcription is mediated by sigma factor A.

Although recent work shows that the expression of the PE/PE_PGRS protein family occur both in vitro and in vivo under stress conditions, very little is known about their promoter and how they are regulated. In this work, the promoter region of a member of PE_PGRS family, the PE_PGRS33 was identified and the promoter boxes were determined. To date, this is one of the few reports that describe a promoter region of a PE_PGRS member. In addition, the gene promoter functionality was assayed in Mycobacterium smegmatis with the green fluorescent protein reporter gene fused to different lengths of pe_pgrs33 promoter sequences. The GFP was down-regulated in the stationary phase, under nutrient starvation and oxygen depletion, suggesting that, in stress conditions, regulation of the gene could be under control of a repressor molecule. A 5' rapid amplification of cDNA end assay of transcriptional fusions evaluated in M. smegmatis and in Mycobacterium tuberculosis mRNA revealed a transcription start point 75 nt upstream of the ATG codon and a -10 like-SigA box. Furthermore, a transcription run assay confirmed that SigA mediates in vitro transcription of pe_pgrs33. Interestingly, conserved -10 SigA boxes were found in the intergenic region of several PE_PGRS genes. These results suggest that expression of some PE_PGRS genes may be mediated by SigA, and the differences in expression observed in the gene family could be explained by the participation of additional regulatory genetic elements.

Identification of novel bacterial plasminogen-binding proteins in the human pathogen Mycobacterium tuberculosis.

Binding and activation of human plasminogen (Plg) to generate the proteolytic enzyme plasmin (Plm) have been associated with the invasive potential of certain bacteria. In this work, proteomic analysis together with ligand blotting assays identified several major Plg-binding spots in Mycobacterium tuberculosis soluble extracts (SEs) and culture filtrate proteins. The identity of 15 different proteins was deduced by N-terminal and/or MS and corresponded to DnaK, GroES, GlnA1, Ag85 complex, Mpt51, Mpt64, PrcB, MetK, SahH, Lpd, Icl, Fba, and EF-Tu. Binding of Plg to recombinant M. tuberculosis DnaK, GlnA1, and Ag85B was further confirmed by ELISA and ligand blotting assays. The binding was inhibited by epsilon-aminocaproic acid, indicating that the interaction involved lysine residues. Plg bound to recombinant mycobacterial proteins was activated to Plm by tissue-type Plg activator. In contrast with recombinant proteins, M. tuberculosis SE enhanced several times the Plg activation mediated by the activator. Interestingly, GlnA1 was able to bind the extracellular matrix (ECM) protein fibronectin. Together these results show that M. tuberculosis posses several Plg receptors suggesting that bound Plg to bacteria surface, can be activated to Plm, endowing bacteria with the ability to break down ECM and basal membranes proteins contributing to tissue injury in tuberculosis.