Twin RNA polymerase-associated proteins control virulence gene expression in Francisella tularensis.

The MglA protein is the only known regulator of virulence gene expression in Francisella tularensis, yet it is unclear how it functions. F. tularensis also contains an MglA-like protein called SspA. Here, we show that MglA and SspA cooperate with one another to control virulence gene expression in F. tularensis. Using a directed proteomic approach, we show that both MglA and SspA associate with RNA polymerase (RNAP) in F. tularensis, and that SspA is required for MglA to associate with RNAP. Furthermore, bacterial two-hybrid and biochemical assays indicate that MglA and SspA interact with one another directly. Finally, through genome-wide expression analyses, we demonstrate that MglA and SspA regulate the same set of genes. Our results suggest that a complex involving both MglA and SspA associates with RNAP to positively control virulence gene expression in F. tularensis. The F. tularensis genome is unusual in that it contains two genes encoding different alpha subunits of RNAP, and we show here that these two alpha subunits are incorporated into RNAP. Thus, as well as identifying SspA as a second critical regulator of virulence gene expression in F. tularensis, our findings provide a framework for understanding the mechanistic basis for virulence gene control in a bacterium whose transcription apparatus is unique.

A defined O-antigen polysaccharide mutant of Francisella tularensis live vaccine strain has attenuated virulence while retaining its protective capacity.

Francisella tularensis, the causative agent of tularemia, has been designated a CDC category A select agent because of its low infective dose (<10 CFU), its ready transmission by aerosol, and its ability to produce severe morbidity and high mortality. The identification and characterization of this organism's virulence determinants will facilitate the development of a safe and effective vaccine. We report that inactivation of the wbtA-encoded dehydratase of the O-antigen polysaccharide (O-PS) locus of the still-unlicensed live vaccine strain of F. tularensis (LVS) results in a mutant (the LVS wbtA mutant) with remarkably attenuated virulence. Western blot analysis and immune electron microscopy studies associate this loss of virulence with a complete lack of surface O-PS expression. A likely mechanism for attenuation is shown to be the transformation from serum resistance in the wild-type strain to serum sensitivity in the mutant. Despite this significant attenuation in virulence, the LVS wbtA mutant remains immunogenic and confers protective immunity on mice against challenge with an otherwise lethal dose of either F. tularensis LVS or a fully virulent clinical isolate of F. tularensis type B. Recognition and characterization of the pivotal role of O-PS in the virulence of this intracellular bacterial pathogen may have broad implications for the creation of a safe and efficacious vaccine.

Comparative genomic analysis of Vibrio cholerae: genes that correlate with cholera endemic and pandemic disease.

Historically, the first six recorded cholera pandemics occurred between 1817 and 1923 and were caused by Vibrio cholerae O1 serogroup strains of the classical biotype. Although strains of the El Tor biotype caused sporadic infections and cholera epidemics as early as 1910, it was not until 1961 that this biotype emerged to cause the 7th pandemic, eventually resulting in the global elimination of classical biotype strains as a cause of disease. The completed genome sequence of 7th pandemic El Tor O1 strain N16961 has provided an important tool to begin addressing questions about the evolution of V. cholerae as a human pathogen and environmental organism. To facilitate such studies, we constructed a V. cholerae genomic microarray that displays over 93% of the predicted genes of strain N16961 as spotted features. Hybridization of labeled genomic DNA from different strains to this microarray allowed us to compare the gene content of N16961 to that of other V. cholerae isolates. Surprisingly, the results reveal a high degree of conservation among the strains tested. However, genes unique to all pandemic strains as well as genes specific to 7th pandemic El Tor and related O139 serogroup strains were identified. These latter genes may encode gain-of-function traits specifically associated with displacement of the preexisting classical strains in South Asia and may also promote the establishment of endemic disease in previously cholera-free locations.