Inactivación de genes de Mycobacterium tuberculosis y su potencial utilidad en la prevención y el control de la tuberculosis

El conocimiento derivado del genoma de Mycobacterium tuberculosis, junto con el desarrollo de sofisticados sistemas para la manipulación genética del bacilo, ofrece la mayor promesa para el desarrollo de herramientas nuevas y más eficientes para prevenir y controlar la tuberculosis. Se han desarrollado métodos más eficientes para la inactivación de genes micobacterianos que se han convertido en el pilar de la genómica funcional micobacteriana. La generación de mutantes mediante la inactivación génica, apoyada directa o indirectamente por el desciframiento del genoma micobacteriano, ha permitido la generación de un número significativo de mutantes de M. tuberculosis. En algunos casos, el análisis de estas mutantes ha establecido relaciones entre los productos génicos y sus funciones en la fisiología y la patogenicidad de la micobacteria. En esta revisión se describen los estudios más representativos basados en dichas mutantes.

Gene inactivation in Mycobacterium tuberculosis and its use in tuberculosis control and prevention Availability of the M. tuberculosis genome sequence and the development of sophisticated systems for genetic manipulation of bacilli offer the potential for new and effective tools to prevent and control tuberculosis. Efficient methods to inactivate mycobacterial genes have been developed. These methods have become the cornerstone for the application and development of mycobacterial functional genomics. Specific mutants are generated to establish the role of targetted genes associated with mycobacterial physiology and pathogenesis. Gene inactivation, supported directly or indirectly by the deciphering of the mycobacterial genome, has permitted the generation of large numbers of M. tuberculosis mutants. Analysis of these mutants has (in some cases) established relationships between gene products and their role in mycobacterial physiology and pathogenesis.

Chemotaxis and flagellar genes of Chromobacterium violaceum

The availability of the complete genome of the Gram-negative beta-proteobacterium Chromobacterium violaceum has increasingly impacted our understanding of this microorganism. This review focuses on the genomic organization and structural analysis of the deduced proteins of the chemosensory adaptation system of C. violaceum. C. violaceum has multiple homologues of most chemotaxis genes, organized mostly in clusters in the bacterial genome. We found at least 67 genes, distributed in 10 gene clusters, involved in the chemotaxis of C. violaceum. A close examination of the chemoreceptors methyl-accepting chemotaxis proteins (MCPs), and the deduced sequences of the members of the two-component signaling system revealed canonical motifs, described as essential for the function of the deduced proteins. The chemoreceptors found in C. violaceum include the complete repertoire of such genes described in bacteria, designated as tsr, tar, trg, and tap; 41 MCP loci were found in the C. violaceum genome. Also, the C. violaceum genome includes a large repertoire of the proteins of the chemosensory transducer system. Multiple homologues of bacterial chemotaxis genes, including CheA, CheB, CheD, CheR, CheV, CheY, CheZ, and CheW, were found in the C. violaceum genome