The Mycobacterium leprae hsp65 displays proteolytic activity. Mutagenesis studies indicate that the M. leprae hsp65 proteolytic activity is catalytically related to the HslVU protease.

The present study reports, for the first time, that the recombinant hsp65 from Mycobacterium leprae (chaperonin 2) displays a proteolytic activity toward oligopeptides. The M. leprae hsp65 proteolytic activity revealed a trypsin-like specificity toward quenched fluorescence peptides derived from dynorphins. When other peptide substrates were used (beta-endorphin, neurotensin, and angiotensin I), the predominant peptide bond cleavages also involved basic amino acids in P(1), although, to a minor extent, the hydrolysis involving hydrophobic and neutral amino acids (G and F) was also observed. The amino acid sequence alignment of the M. leprae hsp65 with Escherichia coli HslVU protease suggested two putative threonine catalytic groups, one in the N-domain (T(136), K(168), and Y(264)) and the other in the C-domain (T(375), K(409), and S(502)). Mutagenesis studies showed that the replacement of K(409) by A caused a complete loss of the proteolytic activity, whereas the mutation of K(168) to A resulted in a 25% loss. These results strongly suggest that the amino acid residues T(375), K(409), and S(502) at the C-domain form the catalytic group that carries out the main proteolytic activity of the M. leprae hsp65. The possible pathophysiological implications of the proteolytic activity of the M. leprae hsp65 are now under investigation in our laboratory.

Species variation in ATP-dependent protein degradation: protease profiles differ between mycobacteria and protease functions differ between Mycobacterium smegmatis and Escherichia coli.

We report here that the existence of the potentially broad substrate specificity protease Lon (also called La), is evolutionarily discontinuous within the order Actinomycetales. Lon homologues were identified in the fast-growing species Mycobacterium smegmatis, and the slow-growing species Micobacterium avium and Mycobacterium intracellulare. However, Lon homologues were not detected in the slow-growing species Mycobacterium tuberculosis, Mycobacterium bovis, or Mycobacterium leprae; or in the non-mycobacterial Actinomycetale Corynebacterium glutamica. To characterize the function of the Lon protease within the Actinomycetales, a viable M. smegmatis Deltalon strain was constructed, demonstrating that lon is not essential under certain conditions. Surprisingly, lon was also dispensable in M. smegmatis cells already lacking intact 20S proteasome alpha- and beta-subunit genes (called prcA and prcB, respectively). Creation of the later double deletion strain (prcBA::kan Deltalon) necessitated use of a novel gene deletion strategy that does not require an antibiotic resistance marker. The M. smegmatis prcBA::kan Deltalon double mutants displayed wild type (wt) growth rates and wt stress tolerances. In addition, the M. smegmatis prcBA::kan Deltalon double mutants degraded at wt rates the broad spectrum of truncated proteins induced by treating cells with puromycin. This later result was in sharp contrast to those in Escherichia coli, where either lon or hslUV single mutants are strongly impaired in their degradation of puromycyl peptides (hslV is a prcB homologue). Overall these data suggested that mycobacterial species contain additional ATP-dependent proteases that have broad substrate specificity. Consistent with this suggestion, M. smegmatis and M. tuberculosis each contain at least one homologue of ClpP, the proteolytic subunit common to the ClpAP and ClpXP proteases.

In vivo repackaging of recombinant cosmid molecules for analyses of Salmonella typhimurium, Streptococcus mutans, and mycobacterial genomic libraries.

Strains of Escherichia coli K-12 were constructed that permitted the amplification of in vitro-packaged recombinant cosmid-transducing particles by in vivo repackaging of recombinant cosmid molecules. Thermal induction of these thermoinducible, excision-defective lysogens containing recombinant cosmid molecules yielded high titers of packaged recombinant cosmids and low levels of PFU. These strains were used to amplify packaged recombinant cosmid libraries of Mycobacterium leprae, Mycobacterium vaccae, Salmonella typhimurium, and Streptococcus mutans DNA. Contiguous and noncontiguous libraries were compared for the successful identification of cloned genes. Construction of noncontiguous libraries allowed the dissociation of desired genes from genes that were deleterious to the survival of a cosmid recombinant and permitted selection for unlinked traits that resulted in a selected phenotype. In vivo repackaging of recombinant cosmids permitted amplification of the original in vitro-packaged collection of transducing particles, storage of cosmid libraries as phage lysates, facilitation of complementation screening, expression analysis of repackaged recombinant cosmids after UV-irradiated cells were infected, in situ enzyme or immunological screening, and facilitation of recovery of recombinant cosmid molecules containing transposon inserts.