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Identification of the Mycobacterium tuberculosis SUF Machinery as the Exclusive Mycobacterial System of [Fe-S] Cluster Assembly: Evidence for Its Implication in the Pathogen's Survival

The worldwide recrudescence of tuberculosis and widespread antibiotic resistance have strengthened the need for the rapid development of new antituberculous drugs targeting essential functions of its etiologic agent, Mycobacterium tuberculosis. In our search for new targets, we found that the M. tuberculosis pps1 gene, which contains an intein coding sequence, belongs to a conserved locus of seven open reading frames. In silico analyses indicated that the mature Pps1 protein is orthologous to the SufB protein of many organisms, a highly conserved component of the [Fe-S] cluster assembly and repair SUF (mobilization of sulfur) machinery. We showed that the mycobacterial pps1 locus constitutes an operon which encodes Suf-like proteins. Interactions between these proteins were demonstrated, supporting the functionality of the M. tuberculosis SUF system. The noticeable absence of any alternative [Fe-S] cluster assembly systems in mycobacteria is in agreement with the apparent essentiality of the suf operon in Mycobacterium smegmatis. Altogether, these results establish that Pps1, as a central element of the SUF system, could play an essential function for M. tuberculosis survival virtually through its implication in the bacterial resistance to iron limitation and oxidative stress. As such, Pps1 may represent an interesting molecular target for new antituberculous drugs.

Specificities and Functions of the recA and pps1 Intein Genes of Mycobacterium tuberculosis and Application for Diagnosis of Tuberculosis

ABSTRACT The worldwide recrudescence of tuberculosis and the widespread appearance of antibiotic resistance have strengthened the need for rapid and specific diagnostic tools. The prevailing microbiological identification of Mycobacterium tuberculosis, the causative agent of tuberculosis, which implies the use of in vitro cultures and acid-fast staining microscopy, is time-consuming. Detection of M. tuberculosis directly in clinical samples through PCR amplification of mycobacterium-specific genes, designed to shorten diagnostic delay, demonstrated reliability and high sensitivity. However, the quality of the diagnosis depends on the specificity of the target sequence for M. tuberculosis complex strains. In the present study, we demonstrated the specificity of recA and pps1 inteins for this complex and thus the feasibility of using intein-coding sequences as a new target for PCR diagnosis. Indeed, the recA and pps1 genes of 36 clinical isolates of M. tuberculosis and 10 field strains of M. bovis were found to be interrupted by an intein sequence at the RecA-a and Pps1-b sites, respectively, while a large number of nontuberculous mycobacterial species failed to demonstrate these insertions. Besides, the MtuPps1, which was cloned and expressed in Escherichia coli, was shown to possess an endonuclease activity. The intein cleaves the 40-bp sequence spanning the intein insertion site Pps1-b in the inteinless pps1 gene. In addition to the PCR amplification of recA and pps1 intein genes as a tool for diagnosis, the specific endonuclease activity could represent a new molecular approach to identify M. tuberculosis.

Inteins of Thermococcus fumicolans DNA Polymerase Are Endonucleases with Distinct Enzymatic Behaviors

The DNA polymerase gene of Thermococcus fumicolans harbors two intein genes. Both inteins have been produced in Escherichia coli and purified either as naturally spliced products from the expression of the complete DNA polymerase gene or directly from the cloned inteins genes. Both recombinant inteins exhibit endonuclease activity, with an optimal temperature of 70 °C. The Tfu pol-1 intein, which belongs to the Psp KOD pol-1 allelic family, recognizes and cleaves a minimal sequence of 16 base pairs (bp) on supercoiled DNA with either Mn2+ or Mg2+ as cofactor. It cleaves linear DNA only with Mn2+ and requires a 19-bp minimal recognition sequence. The Tfu pol-2 intein, which belongs to the Tli pol-2 allelic family, is a highly active homing endonuclease using Mg2+ as cofactor. Its minimal recognition and cleavage site is 21 bp long either on linear or circular DNA substrates. Its endonuclease activity is strongly inhibited by the 3′ digestion product, which remains bound to the enzyme after the cleavage reaction. According to current nomenclature, these endonucleases were named PI-TfuI and PI-TfuII. These two inteins thus exhibit different requirements for metal cofactor and substrate topology as well as different mechanism of action.

STRUCTURAL BASIS OF EXTENDED SPECTRUM TEM BETA -LACTAMASES : CRYSTALLOGRAPHIC, KINETIC, AND MASS SPECTROMETRIC INVESTIGATIONS OF ENZYME MUTANTS

The E166Y and the E166Y/R164S TEM-1 β-lactamase mutant enzymes display extended spectrum substrate specificities. Electrospray mass spectrometry demonstrates that, with penicillin G as substrate, the rate-limiting step in catalysis is the hydrolysis of the E166Y acyl-enzyme complex. Comparison of the 1.8-Å resolution x-ray structures of the wild-type and of the E166Y mutant enzymes shows that the binding of cephalosporin substrates is improved, in the mutant enzyme, by the enlargement of the substrate binding site. This enlargement is due to the rigid body displacement of 60 residues driven by the movement of the -loop. These structural observations strongly suggest that the link between the position of the -loop and that of helix H5, plays a central role in the structural events leading to extended spectrum TEM-related enzymes. The increased -loop flexibility caused by the R164S mutation, which is found in several natural mutant TEM enzymes, may lead to similar structural effects. Comparison of the kinetic data of the E166Y, E166Y/R164S, and R164S mutant enzymes supports this hypothesis.

Protein Splicing of SufB Is Crucial for the Functionality of the Mycobacterium tuberculosis SUF Machinery

The SufBCD complex is an essential component of the SUF machinery of [Fe-S] cluster biogenesis in many organisms. We show here that in Mycobacterium tuberculosis the formation of this complex is dependent on the protein splicing of SufB, suggesting that this process is a potential new target for antituberculous drugs.