A Mycobacterium leprae Hsp65 mutant as a candidate for mitigating lupus aggravation in mice.

Hsp60 is an abundant and highly conserved family of intracellular molecules. Increased levels of this family of proteins have been observed in the extracellular compartment in chronic inflammation. Administration of M. leprae Hsp65 [WT] in [NZBxNZW]F(1) mice accelerates the Systemic Lupus Erythematosus [SLE] progression whereas the point mutated K(409)A Hsp65 protein delays the disease. Here, the biological effects of M. leprae Hsp65 Leader pep and K(409)A pep synthetic peptides, which cover residues 352-371, are presented. Peptides had immunomodulatory effects similar to that observed with their respective proteins on survival and the combined administration of K(409)A+Leader pep or K(409)A pep+WT showed that the mutant forms were able to inhibit the deleterious effect of WT on mortality, indicating the neutralizing potential of the mutant molecules in SLE progression. Molecular modeling showed that replacing Lysine by Alanine affects the electrostatic potential of the 352-371 region. The number of interactions observed for WT is much higher than for Hsp65 K(409)A and mouse Hsp60. The immunomodulatory effects of the point-mutated protein and peptide occurred regardless of the catalytic activity. These findings may be related to the lack of effect on survival when F(1) mice were inoculated with Hsp60 or K(409)A pep. Our findings indicate the use of point-mutated Hsp65 molecules, such as the K(409)A protein and its corresponding peptide, that may minimize or delay the onset of SLE, representing a new approach to the treatment of autoimmune diseases.

Secreted proteins of Mycobacterium leprae.

In mycobacteria, secreted proteins represent a distinct group, probably of particular importance for development of immune responses following infection. Quantification of individual proteins in culture fluid and corresponding disrupted bacilli permits determination of a localization index for identification of secreted proteins. This procedure cannot be applied to Mycobacterium leprae because secreted proteins are lost during isolation of bacilli from tissues. The DNA sequences of secreted proteins of Mycobacterium tuberculosis were compared with sequences of M. leprae. Genes for homologues of the 85a, 85b, 85c, mpt32 (apa), mpt51, erp, mtc28, Rv2376c, Rv3354 and Rv0526 genes were identified. All of these contain signal sequences typical for secretion in M. leprae. In several instances the local distance between marker genes and occurrence on the same or the complementary DNA strand was similar in these two species. The genomic organisation of genes for secreted proteins is thus very similar in M. leprae and M. tuberculosis, the homology being higher for the mature polypeptide chains than for the corresponding signal peptides.

Identification of mycobacterium tuberculosis DNA sequences encoding exported proteins by using phoA gene fusions.

The activity of bacterial alkaline phosphatase (PhoA) is dependent on it being exported across the plasma membrane. A plasmid vector (pJEM11) allowing fusions between phoA and genes encoding exported proteins was constructed to study protein export in mycobacteria. Introduction of the Mycobacterium fortuitum beta-lactamase gene (blaF*) into this vector led to the production in M. smegmatis of protein fusions with PhoA activity. A genomic library from M. tuberculosis was constructed in pJEM11 and screened in M. smegmatis for clones with PhoA activity. Sequences of the M. tuberculosis inserts directing the production of protein fusions in these PhoA-positive clones were determined. They include part of the already-known exported 19-kDa lipoprotein, a sequence with similarities to the exported 28-kDa antigen from M. leprae, a sequence encoding a protein sharing conserved amino acid motifs with stearoyl-acyl-carrier-protein desaturases, and unknown sequences. This approach thus appears to identify sequences directing protein export, and we expect that more extensive screening of such libraries will lead to a better understanding of protein export in M. tuberculosis.

High level expression of genes cloned in phage lambda gt11.

Plasmid cloning vectors have been constructed which allow genes originally cloned in lambda gt11 to be expressed at a high level in Escherichia coli. They are based on the pEMBL and pUC vectors, with the genes transcribed from the lac promoter. The EcoRI site in the vector has been altered to be in the same reading frame as the site used for cloning in lambda gt11. Cloned proteins are expressed fused to a 2-kDa leader sequence containing a run of six Aparagine residues which considerably improves the stability of the recombinant proteins, but does not interfere with immunological assays. Using these vectors, the Mycobacterium leprae 18-kDa protein was expressed at 20 mg per litre of culture and constituted 15% of total cell protein.