Project description:Obligate intracellular pathogen that causes Rocky Mountain Spotted Fever

Project description:Obligate intracellular pathogen that causes Rocky Mountain Spotted Fever

Project description:Causative agent for Rocky Mountain spotted fever

Project description:Rickettsia conorii is the etiologic agent of Mediterranean spotted fever, a re-emerging disease with significant mortality. This obligate, gram-negative intracellular pathogen is transmitted via tick bites, resulting in disseminated vascular endothelial cell infection with vascular leakage. In the infected human, Rickettsia conorii infects endothelial cells, stimulating expression of cytokines and pro-coagulant factors. However, the integrated proteomic response of human endothelial cells to R. conorii infection is not known. In this study, we performed quantitative proteomic profiling of R conorii –infected primary HUVECs vs those stimulated with LPS alone.

Project description:Rickettsia conorii is the etiologic agent of Mediterranean spotted fever, a re-emerging disease with significant mortality. This obligate, gram-negative intracellular pathogen is transmitted via tick bites, resulting in disseminated vascular endothelial cell infection with vascular leakage. In the infected human, Rickettsia conorii infects endothelial cells, stimulating expression of cytokines and pro-coagulant factors. However, the integrated proteomic response of human endothelial cells to R. conorii infection is not known. In this study, we performed quantitative proteomic profiling of R conorii â??infected primary HUVECs vs those stimulated with LPS alone.

Project description:Causative agent for Rocky Mountain Spotted Fever

Project description:Obligate intracellular pathogen that causes African Tick-Bite Fever

Project description:Rickettsia conorii are obligate intracellular bacteria responsible for the Mediterranean spotted fever. Their adaptation to highly divergent environments ranging from the arthropod vector to the human beings is essential to survival and virulence. Through a combination of total RNA purification and random prokaryotic cDNA amplification, we successfully analyzed transcription profiles by microarrays starting from 100 ng of R. conorii RNA. Real-time quantitative PCR results performed on unpurified total RNA was consistent with microarray measurements. Here, from the selected targets spotted on our microarray, we showed that in R. conorii, nutrient stress is accompanied by over-expression of the virB operon. Regulation of these genes could be mediated by the stringent response through ppGpp, consistent with the observed up-regulation of spoT and gmk. Exposure of R. conorii to a nutrient stress paradoxically reduced the expression of both GroEL and its transcriptional regulator RpoH. This shows that the over-expression of this chaperonin is a part of the natural life of intracellular growing rickettsiae. Our findings also evidenced that, unexpectedly, many atypical sequences, including small-size split genes, ORFans genes and highly conserved intergenic regions contains expressed sequences that are differentially regulated. The notable deficiency of transcriptional regulators within R. conorii genome does not reflect its incapability to undergo transcriptional changes but rather the existence of an alternative adaptation strategy. Keywords: Global transcriptional analysis

Project description:Rickettsiae are strict obligate intracellular pathogens that alternate between arthropod and mammalian hosts in a zoonotic cycle. Typically, pathogenic bacteria that cycle between environmental sources and mammalian hosts adapt to the respective environments by coordinately regulating gene expression such that genes essential for survival and virulence are expressed only upon infection of mammals. Temperature is a common environmental signal for upregulation of virulence gene expression although other factors may also play a role. We examined the transcriptional responses of Rickettsia rickettsii, the agent of Rocky Mountain spotted fever, to a variety of environmental signals expected to be encountered during its life cycle. R. rickettsii exposed to differences in growth temperature (25o C vs. 37o C), iron limitation, and host cell species displayed nominal changes in gene expression under any of these conditions with only 0, 5, or 7 genes, respectively, changing more than 3-fold in expression levels. R. rickettsii is not totally devoid of ability to respond to temperature shifts as cold shock (37o C vs. 4o C) induced a change greater than 3-fold in up to 57 genes. Rickettsiae continuously occupy a relatively stable environment which is the cytosol of eukaryotic cells. Because of their obligate intracellular character, rickettsiae are believed to be undergoing reductive evolution to a minimal genome. We propose that their relatively constant environmental niche has led to a minimal requirement for R. rickettsii to respond to environmental changes with a consequent deletion of non-essential transcriptional response regulators. A minimal number of transcriptional regulators in the R. rickettsii genome is consistent with this hypothesis. various growth and environmental condition comparisons

Project description:Rickettsiae are strict obligate intracellular pathogens that alternate between arthropod and mammalian hosts in a zoonotic cycle. Typically, pathogenic bacteria that cycle between environmental sources and mammalian hosts adapt to the respective environments by coordinately regulating gene expression such that genes essential for survival and virulence are expressed only upon infection of mammals. Temperature is a common environmental signal for upregulation of virulence gene expression although other factors may also play a role. We examined the transcriptional responses of Rickettsia rickettsii, the agent of Rocky Mountain spotted fever, to a variety of environmental signals expected to be encountered during its life cycle. R. rickettsii exposed to differences in growth temperature (25o C vs. 37o C), iron limitation, and host cell species displayed nominal changes in gene expression under any of these conditions with only 0, 5, or 7 genes, respectively, changing more than 3-fold in expression levels. R. rickettsii is not totally devoid of ability to respond to temperature shifts as cold shock (37o C vs. 4o C) induced a change greater than 3-fold in up to 57 genes. Rickettsiae continuously occupy a relatively stable environment which is the cytosol of eukaryotic cells. Because of their obligate intracellular character, rickettsiae are believed to be undergoing reductive evolution to a minimal genome. We propose that their relatively constant environmental niche has led to a minimal requirement for R. rickettsii to respond to environmental changes with a consequent deletion of non-essential transcriptional response regulators. A minimal number of transcriptional regulators in the R. rickettsii genome is consistent with this hypothesis.