Project description:Temperature is a key environmental factor for facultative pathogens during the host adaptation response. To assess the functional role of temperature in Yersinia pestis, a microarray study was conducted comparing the Δpgm (pigmentation-negative) R88 strain grown at 37°C or 30°C.

Project description:E. coli K-12 BW25113 mutant strain hha expression in biofilm cells relative to E. coli wild-type strain expression in biofilm cells. Samples were cultured in LB with glasswool at 37C for 4 hours and in LB glu with glasswool at 37C for 4, 15 and 24 hours. Hha is a temperature- and osmolarity-dependent modulator of gene expression that is induced 30-fold in Escherichia coli biofilms. Here we show through whole-transcriptome analysis that Hha decreases biofilm formation in both LB and LB glu media by (i) repressing fliC encoding the main structural flagellar protein flagellin, (ii) by repressing fimA encoding the major structural subunit of type I fimbriae, (iii) by repressing ihfA encoding a subunit of the transcriptional regulator IHF that induces the transcription of type I fimbriae genes, (iv) by regulating tnaA encoding tryptophanase that inhibits biofilms, and (v) by repressing ybaJ that forms an operon with hha. Corroborating the microarray data, hha deletion increased motility 3.2 ± 0.1-fold, decreased extracellular indole concentrations 12 ± 2-fold, and decreased type I fimbriae (as measured by yeast agglutination). Biofilm tests using single and double mutants of fimA and ihfA and transcriptional studies of the fimA, ihfA and ybaJ-hha promoters confirmed that Hha represses biofilm by inhibiting type I fimbriae production and that it negatively regulates its own transcription and that of ybaJ. Nickel-enhanced DNA microarrays to determine in vivo Hha binding sites confirmed that Hha binds the ybaJ-hha promoter, that it binds fimZ, a positive regulator of fimA, and that it binds to the rare codon tRNAs argU, ileXY, and proL. Sequence analysis of fimZ, fimB, fimE, and the type I fimbriae gene cluster fimAICDFGH revealed a high bias for the rare codons of arginine, isoleucine, proline, leucine, and threonine, and overexpressing Hha leads to cell death. Therefore, it appears Hha decreases biofilms by decreasing type I fimbriae production as a result of inhibiting synthesis of tRNAs for rare codons. Keywords: effect of hha deletion in biofilm formation 4 hr LB and 4,15 and 24 hr LB glu

Project description:The global transcriptional regulator Hha of Escherichia coli controls hemolysin activity, biofilm formation, and virulence expressions. Earlier, we have reported that Hha represses initial biofilm formation and disperses biofilms as well as controls prophage excision in E. coli. Since biofilm dispersal is a promising area to control biofilms, here we rewired Hha to control biofilm dispersal and formation. The Hha variant Hha13D6 was obtained to have enhanced biofilm dispersal activity along with increased toxicity compared to wild-type Hha (Hha13D6 induces dispersal 60%, whereas wild-type Hha induces dispersal at early biofilms but not at mature biofilms). Toxic Hha13D6 caused cell death probably by the activation of proteases HslUV, Lon, and PrlC, and deletion of protease gene hslV with overproducing Hh13D6 repressed biofilm dispersal, indicating Hha13D6 induces biofilm dispersal through the activity of protease HslV. Furthermore, another Hha variant Hha24E9 was also obtained to decrease biofilm formation 4-fold compared to wild-type Hha by regulation of gadW, glpT, and phnF. However, the dispersal variant Hha13D6 did not decrease biofilm formation, while the biofilm variant Hha24E9 did not induce biofilm dispersal. Hence, Hha may have evolved two ways in response to environmental factors to control biofilm dispersal and formation, but both controlling mechanisms come from different regulatory systems.

Project description:Expression of the virulence regulator RovA of Yersinia pseudotuberculosis, is controlled by the ncRNAs CsrB and CsrC through CsrA and RovM. In this study, we show that the regulator YmoA of the Hha family of nucleoid-associated proteins controls expression of the counterregulated Csr-type RNAs and the Csr-RovM-RovA signalling cascade through alterations of the CsrC RNA stability. YmoA-mediated stabilization of CsrC depends on CsrA and H-NS, but not on the RNA chaperone Hfq and involves a stabilizing stem-loop structure within the 5’-region of CsrC. YmoA influence on CsrC stability is complex as YmoA was found to control numerous factors known to affect RNA structures and stability. In addition, YmoA controls temperature-dependent early and later stage virulence genes in an opposite manner and coregulates their expression with bacterial stress responses and metabolic functions. Following oral infections in a mouse model, we demonstrate that a ymoA mutant is strongly reduced in its ability to disseminate to the Peyer’s patches, mesenteric lymph nodes, liver and spleen and exhibits a reduced mortality. We propose a model in which YmoA controls switching from a RovA-dependent early colonization phase towards a virulence plasmid (pYV)-dependent infection phase important for host defense and persistence.

Project description:The biogenesis and functions of Leptospira's extracellular vesicles (EVs) remain unclear. The study aimed to characterize EVs that were naturally released from intact leptospires during in vitro culture, as well as under conditions mimicking the host environment during infection, including temperature or osmolarity shift. The EVs were found to contain a group of proteins from the outer membrane and various cytoplasmic proteins, suggesting that they originated from the outer membrane and cytoplasm. These proteins were primarily involved in Leptospira's growth, survival, adaptation, and pathogenicity. Interestingly, the study revealed that Leptospira secreted multifunctional proteins through EVs but might maintain several virulence and virulence-associated proteins in their cells in response to temperature and osmotic stresses. Thus, native leptospiral EVs might act as decoys for the host immune system, while the virulence factors crucial for direct interaction with host components might be preserved in whole cells. This knowledge may contribute to understanding the role of EVs in the pathogenicity of Leptospira and the development of vaccines against leptospirosis in the future.

Project description:Gene expression analysis of Yersinia Pestis temperature shift.

Project description:Bacterial pathogens, such as in Yersinia pseudotuberculosis, encounter temperature fluctuations during host infection and upon return to the environment. These temperature shifts impact RNA structures globally. While previous transcriptome-wide studies have focused on RNA thermometers in the 5’-untranslated region of virulence-related mRNAs, our investigation revealed temperature-driven structural rearrangements in the small RNA (sRNA) CyaR. At 25°C, CyaR primarily adopts a conformation that occludes its seed region, but transitions to a liberated state at 37°C. By RNA-sequencing and in-line probing experiments, we identified the Shine-Dalgarno sequence of ompX as a direct target of CyaR. Interestingly, the ompX transcript itself exhibits RNA thermometer-like properties, facilitating CyaR base pairing at elevated temperatures. This interaction impedes ribosome binding to ompX and accelerates degradation of the ompX transcript. Furthermore, we observed induced proteolytic turnover of the OmpX protein at higher temperatures. Collectively, our study uncovered multi-layered posttranscriptional mechanisms governing ompX expression, resulting in lower OmpX levels at 37°C compared to 25°C. We propose that CyaR remains mostly passive at 25°C but becomes primed to repress ompX at 37°C, thereby expediting outer membrane remodelling in anticipation of pathogenesis.

Project description:Bacterial genomes encode in many instances more than one copy of genes coding for global modulators. In the Enterobacteriaceae, cells express the global modulator H-NS and its paralogue StpA. The enteroaggregative E. coli strain 042 encodes, in addition to the hns and stpA genes, an additional hns gene. We used RNA-seq to compare the transcriptome of the wt strain and its hns, hns2 and double hns hns2 derivatives, as well as of an hha null mutant (hhahha2). It is well known that the Hha protein co-modulates gene expression with H-NS. The results obtained have shown that the main role of H-NS2 is to modulate a subset of H-NS modulated genes, those that also are targeted by Hha, which are mainly HGT genes. When compared with H-NS, H-NS2 also shows a differential expression level and a different regulatory pattern.

Project description:Whole transcriptome assessment of the Yersinia pseudotuberculosis strain YPIII. The Y. pseudotuberculosis rovA regulon was determined in Yersinia minimal minimum developed for the study. RovA is a key regulator for Yersinia virulence.

Project description:To investigate the molecular basis of fluctuating temperature induced phenotypic plasticity, we ran genome-wide transcriptomic analysis on Drosophila melanogaster subjected to acclimation at constant (19 +/- 0 degree Celcius) and fluctuating (19 +/- 8 degree Celcius) temperatures and contrasted the induction of molecular mechanisms in adult males, adult females, and larvae. We investigated whether fluctuations act by permanently activating the involved mechanisms, or whether fluctuations repeatedly activate and repress mechanisms, during the hot (or heating) and the cold (or cooling) phase of thermal fluctuations. We show that adult flies acclimated to fluctuating temperatures tolerate high temperatures better than the constant temperature acclimated controls. Differential gene expression indicated that responses to thermal variability rely partly on life stage and sex specific mechanisms. Our results show that some of the involved mechanisms were permanently activated, while others tracked the thermal fluctuations. Further, for a number of genes, fluctuating temperature resulted in canalization of gene expression. Molecular mechanisms related to environmental sensing and chromatin reorganization seems to be important components of adaptive responses to thermal variability.