Effect of Mycobacterium tuberculosis chaperonins on bronchial eosinophilia and hyper-responsiveness in a murine model of allergic inflammation.

BACKGROUND: Epidemiological evidence suggests that infection with Mycobacterium tuberculosis protects children against asthma. Several laboratories have shown that, in mouse models of allergic inflammation, administration of the whole live tuberculosis vaccine, Mycobacterium bovis bacillus Calmette-Guerin (BCG), prevents ovalbumin (OVA)-induced pulmonary eosinophilia. OBJECTIVE: The aim of this study was to characterize specific M. tuberculosis molecules that are known to modulate immune responses to see if they affected pulmonary eosinophilia and bronchial hyper-responsiveness. METHODS: C57Bl/6 mice were sensitized to OVA on days 0 and 7 and subsequently challenged with OVA on day 14 over a 3-day period. Pulmonary eosinophilia and bronchial hyper-responsiveness were measured 24 h following the last antigen challenge. In some groups, mice were pre-treated with M. tuberculosis or M. tuberculosis chaperonins (Cpns)60.1, 60.2 and 10, and the effect of this treatment on the allergic inflammatory response to aerosolized OVA was established. RESULTS: We show that M. tuberculosis Cpns inhibit allergen-induced pulmonary eosinophilia in the mouse. Of the three Cpns produced by M. tuberculosis, Cpn60.1, Cpn10 and Cpn60.2, the first two are effective in preventing eosinophilia when administered by the intra-tracheal route. Furthermore, the increase in airways sensitivity to inhaled methacholine following OVA challenge of immunized mice was suppressed following treatment with Cpn60.1. The allergic inflammatory response was also characterized by an increase in Th2 cytokines IL-4 and IL-5 in bronchoalveolar lavage fluid, which was also suppressed following treatment with Cpn60.1. CONCLUSION: These data show that bacterial Cpns can suppress eosinophil recruitment and bronchial hyper-responsiveness in a murine model of allergic inflammation.

Mycobacterium tuberculosis chaperonin 60.1 is a more potent cytokine stimulator than chaperonin 60.2 (Hsp 65) and contains a CD14-binding domain.

Much attention has focused on the Mycobacterium tuberculosis molecular chaperone chaperonin (Cpn) 60.2 (Hsp 65) in the pathology of tuberculosis because of its immunogenicity and ability to directly activate human monocytes and vascular endothelial cells. However, M. tuberculosis is one of a small group of bacteria that contain multiple genes encoding Cpn 60 proteins. We have now cloned and expressed both M. tuberculosis proteins and report that the novel chaperonin 60, Cpn 60.1, is a more potent inducer of cytokine synthesis than is Cpn 60.2. This is in spite of 76% amino acid sequence similarity between the two mycobacterial chaperonins. The M. tuberculosis Cpn 60.2 protein activates human peripheral blood mononuclear cells by a CD14-independent mechanism, whereas Cpn 60.1 is partially CD14 dependent and contains a peptide sequence whose actions are blocked by anti-CD14 monoclonal antibodies. The cytokine-inducing activity of both chaperonins is extremely resistant to heat. Cpn 60.1 may be an important virulence factor in tuberculosis, able to activate cells by diverse receptor-driven mechanisms.

Overexpression of heat-shock proteins reduces survival of Mycobacterium tuberculosis in the chronic phase of infection.

Elevated expression of heat-shock proteins (HSPs) can benefit a microbial pathogen struggling to penetrate host defenses during infection, but at the same time might provide a crucial signal alerting the host immune system to its presence. To determine which of these effects predominate, we constructed a mutant strain of Mycobacterium tuberculosis that constitutively overexpresses Hsp70 proteins. Although the mutant was fully virulent in the initial stage of infection, it was significantly impaired in its ability to persist during the subsequent chronic phase. Induction of microbial genes encoding HSPs might provide a novel strategy to boost the immune response of individuals with latent tuberculosis infection.

Bacterial selenocysteine synthase--structural and functional properties.

Selenocysteine synthase from Escherichia coli is a pyridoxal-5'-phosphate-containing enzyme which catalyses the conversion of seryl-tRNA(Sec) into selenocysteyl-tRNA(Sec). Analysis of amino acid sequences indicated that selenocysteine synthase belongs to the alpha/gamma superfamily of pyridoxal-5'-phosphate-dependent enzymes. To identify the lysine residue carrying the prosthetic group, the genes coding for the selenocysteine synthases from Moorella thermoacetica and Desulfomicrobium baculatum were cloned and sequenced and their derived amino acid sequences were aligned with those from E. coli and Haemophilus influenzae. Three lysine residues were found to be conserved; they were mutated into asparagine and one of them, Lys295, was found to be essential for activity. Proteolytic fragmentation of the E. coli enzyme reduced with borohydride, and mass-spectrometric and sequence analysis of the chromophoric peptide proved that Lys295 was modified. Kinetic analysis of the enzyme showed that thiophosphate served as a substrate leading to cysteyl-tRNA(Sec) synthesis, albeit with a 330-fold lower catalytic efficiency. Selenide and, to a much lesser degree, sulfide could also be used by the enzyme but only at much higher concentrations. These data together with the finding that selenophosphate synthetase is highly specific for selenide indicate that the phosphate moiety of selenophosphate provides selenocysteine synthase with the discrimination specificity against sulfur.

Domain structure of the selenocysteine-specific translation factor SelB in prokaryotes.

Translation factor SelB is the key component for the specific decoding of UGA codons with selenocysteine at the ribosome. SelB binds selenocysteyl-tRNA(Sec), guanine nucleotides and a secondary structure of the selenoprotein mRNA following the UGA at the 3' side. A comparison of the amino acid sequences of SelB species from E. coli, Desulfomicrobium baculatum, Clostridium thermoaceticum and Haemophilus influenzae showed that the proteins consist of at least four structural domains from which the N-terminal three are well conserved and share homology with elongation factor Tu whereas the C-terminal one is more variable and displays no similarity to any protein known. With the aid of the coordinates of EF-Tu the N-terminal part has been modelled into a 3D structure which exhibits intriguing features concerning its interaction with guanine nucleotides and other components of the translational apparatus. Cloning and expression of fragments of SelB and biochemical analysis of the purified truncated proteins showed that the C-terminal 19 kDa protein fragment is able to specifically bind to the selenoprotein mRNA. SelB, thus, is a translation factor functionally homologous to EF-Tu hooked up to the mRNA with its C-terminal end. The formation by SelB of a quaternary complex in vivo has been proven by overexpression of truncated genes of SelB and by demonstration that fragments comprising the mRNA or the tRNA binding domain inhibit selenocysteine insertion.

Barriers to heterologous expression of a selenoprotein gene in bacteria.

The specificity parameters counteracting the heterologous expression in Escherichia coli of the Desulfomicrobium baculatum gene (hydV) coding for the large subunit of the periplasmic hydrogenase which is a selenoprotein have been studied. hydV'-'lacZ fusions were constructed, and it was shown that they do not direct the incorporation of selenocysteine in E. coli. Rather, the UGA codon is efficiently suppressed by some other aminoacyl-tRNA in an E. coli strain possessing a ribosomal ambiguity mutation. The suppression is decreased by the strA1 allele, indicating that the hydV selenocysteine UGA codon has the properties of a "normal" and suppressible nonsense codon. The SelB protein from D. baculatum was purified; in gel shift experiments, D. baculatum SelB displayed a lower affinity for the E. coli fdhF selenoprotein mRNA than E. coli SelB did and vice versa. Coexpression of the hydV'-'lacZ fusion and of the selB and tRNA(Sec) genes from D. baculatum, however, did not lead to selenocysteine insertion into the protein, although the formation of the quaternary complex between SelB, selenocysteyl-tRNA(Sec), and the hydV mRNA recognition sequence took place. The results demonstrate (i) that the selenocysteine-specific UGA codon is readily suppressed under conditions where the homologous SelB protein is absent and (ii) that apart from the specificity of the SelB-mRNA interaction, a structural compatibility of the quaternary complex with the ribosome is required.

Domain structure of the prokaryotic selenocysteine-specific elongation factor SelB.

Incorporation of the non-canonical amino acid selenocysteine into proteins requires the activity of the elongation factor SelB which substitutes for the function of EF-Tu in contrast to EF-Tu, SelB binds selenocystylated tRNASec and an mRNA secondary structure adjacent to the UGA selenocysteine codon. To gain information on the domain structure of this specialized translation factor, the selB genes from two bacteria unrelated to Escherichia coli (Clostridium thermoaceticum and Desulfomicrobium baculatum) were cloned and sequenced. The derived amino acid residue sequences were compared to those of SelB from E. coli and Haemophilus influenzae and to EF-Tu sequences. The alignment revealed that SelB contains all three domains characterized for EF-Tu. A fourth, C-terminally located domain shows only limited sequence conservation within the four SelB proteins. To elucidate the function of this C-terminal part a structure-function analysis of SelB from E. coli was performed. It showed that a C-terminal 17 kDa subdomain of the translation factor, when expressed separately, specifically binds the mRNA secondary structure. The recognition motif itself could be reduced to a 17 nucleotide minihelix without loss of binding affinity and specificity. A truncated SelB lacking the mRNA binding domain was still able to interact with selenocysteyl-tRNASec. Expression of the mRNA binding domain alone suppressed selenocysteine insertion in vivo by competing with SelB for its binding site at the mRNA. The results indicate that SelB can be considered as an EF-Tu homolog hooked to the mRNA via its C-terminal domain.

Role of stoichiometry between mRNA, translation factor SelB and selenocysteyl-tRNA in selenoprotein synthesis.

The specialized translation factor SelB forms a quaternary complex in vitro with selenocysteyl-tRNA(Sec), the selenoprotein mRNA and guanine nucleotides. To gain information on whether this complex is required for selenocysteine insertion in vivo we have studied the effect of unbalanced ratios of the individual components of the complex on UGA readthrough. It was found that overproduction of SelB in an otherwise wild-type genetic background reduced UGA readthrough to less than 1%. Concomitant overexpression of selC (the gene for selenocysteine-specific tRNA(Sec)) completely reversed the inhibition. Truncation of SelB from the C-terminal end abolished function as a translation factor but the truncated molecules, when overproduced, were still able to suppress UGA read-through. The inhibition was also reversed by overproduction of tRNA(Sec). The most plausible explanation is that overproduction of SelB impairs the statistics of formation of the quaternary complex and that the C-terminally truncated molecules are still able to bind selenocysteyl-tRNA(Sec) and remove it from the pool. The mRNA-binding capacity, therefore, is physically separated from the selenocysteyl-tRNA-binding domain.

Genes coding for the selenocysteine-inserting tRNA species from Desulfomicrobium baculatum and Clostridium thermoaceticum: structural and evolutionary implications.

The genes (selC) coding for the selenocysteine-inserting tRNA species (tRNA(Sec)) from Clostridium thermoaceticum and Desulfomicrobium baculatum were cloned and sequenced. Although they differ in numerous positions from the sequence of the Escherichia coli selC gene, they were able to complement the selC lesion of an E. coli mutant and to promote selenoprotein formation in the heterologous host. The tRNA(Sec) species from both organisms possess all of the unique primary, secondary, and tertiary structural features exhibited by E. coli tRNA(Sec) (C. Baron, E. Westhof, A. Böck, and R. Giegé, J. Mol. Biol. 231:274-292, 1993). The structural and functional properties of the tRNA(Sec) species from prokaryotes analyzed thus far support the notion that tRNA(Sec) may be an evolutionarily conserved structure whose function in the primordial genetic code was to decode UGA with selenocysteine.

Identification of the formate dehydrogenases and genetic determinants of formate-dependent nitrite reduction by Escherichia coli K12.

The formate dehydrogenases of Escherichia coli involved in electron transfer from formate to nitrite (Nrf activity: nitrite reduction by formate) have been identified. No previously undescribed selenoprotein was detected in bacteria grown under conditions optimal for the expression of Nrf activity. The Nrf activities of single mutants defective in either FdhN or FdhH were between 50 and 60% that of the parental strain. A double mutant defective in both FdhN and FdhH retained less than 10% of the activity of the FdhN+ FdhH+ strain. No Nrf activity was detected in a triple mutant defective in FdhN, FdhH and FdhO or in the selC strain. It is concluded that all three of the known formate dehydrogenases of E. coli can contribute to the transfer of electrons from formate to the Nrf pathway. Mutants defective in Nrf activity and cytochrome c552 synthesis were isolated by insertion mutagenesis or identified amongst strains received from the E. coli Genetic Stock Center. The mutations were located in at least three regions of the chromosome, including the 92 to 94 minute region which includes fdhF, the gene encoding FdhH required for formate hydrogenlyase activity. Fine structure mapping by P1 transduction established that the nrf mutations in the fdhF region were due to defects in three separable loci, all of which were independent of but close to fdhF. Clones were isolated from a cosmid library that complemented a deletion extending from fdhF into a region essential for Nrf activity. From these clones, plasmids were isolated that complemented only some of the Nrf- mutations in the 92 to 94 minute region, confirming the presence of different operons essential for Nrf activity and cytochrome c552 synthesis in this region. Suggested reasons for this genetic complexity include the need for proteins involved in electron transfer from the various formate dehydrogenases to cytochrome c552, for the attachment of the haem group to the apocytochrome and for cytochrome c552 export into the periplasm.

Selenoprotein synthesis in E. coli. Purification and characterisation of the enzyme catalysing selenium activation.

The product of the selD gene from Escherichia coli catalyses the formation of an activated selenium compound which is required for the synthesis of Sec-tRNA (Sec, selenocysteine) from Ser-tRNA and for the formation of the unusual nucleoside 5-methylaminomethyl-2-selenouridine in several tRNA species. selD was overexpressed in a T7 promoter/polymerase system and purified to apparent homogeneity. Purified SELD protein is a monomer of 37 kDa in its native state and catalyses a selenium-dependent ATP-cleavage reaction delivering AMP and releasing the beta-phosphate as orthophosphate. The gamma-phosphate group of ATP was not liberated in a form able to form a complex with molybdate. It was precluded that any putative covalent or non-covalent ligand of SELD not removed during purification participated in the reaction. In a double-labelling experiment employing [75Se]selenite plus dithiothreitol and [gamma-32P]ATP the 75Se and 32P radioactivities co-chromatographed on a poly(ethyleneimine)-cellulose column. No radioactivity originating from ATP eluted in this position when [alpha-32P]ATP or [beta-32P]ATP or [14C]ATP were offered as substrates. The results support the speculation that the product of SELD is a phosphoselenoate with the phosphate moiety derived phosphoselenoate from the gamma-phosphate group of ATP. The alpha,beta cleavage of ATP is also supported by the finding that neither adenosine 5'-[alpha,beta-methylene]triphosphate nor adenosine 5'-[beta,gamma-methylene]triphosphate served as substrates in the reaction.