Project description:Sodalis praecaptivus is a close relative and putative environmental progenitor of the widely distributed, insect-associated, Sodalis-allied symbionts. Mutant strains of S. praecaptivus, lacking critical components of a quorum sensing (QS) apparatus acquire a rapid and potent killing phenotype following microinjection into an insect host. Transcriptomic and genetic analyses indicate that insect killing occurs as a consequence of virulence factors, including insecticidal toxins and enzymes that degrade the insect integument that are normally repressed by QS at high infection densities. This unorthodox method of regulation ensures that virulence factors are only utilized to initiate the insect-bacterial association. Once bacteria reach a sufficient infection density in host tissues, the QS circuit represses the expression of these harmful genes, facilitating a long-lasting and benign association. We discuss the implications of the functionality of this QS system in the context of the establishment and evolution of mutualistic relationships involving these bacteria.

Project description:A thermal stress experiment on Heron Island (Great Barrier Reef) which involved a slow ramp in temperature over one week and then sampling after 4 days at 32 degrees was completed. Control samples were maintained at 27C. The idea of the experiment was to study bleaching from a single cell perspective and thus look at cell condition (both animal and host) in symbio (inside the host tissue) and compare it with the physiological/macromolecular composition of the expelled symbionts (dinoflagellates). Are the cells expelled from the coral host during thermal stress are a result of host stress or algae stress. We took samples for proteomics from the extracted endoderm cells (in symbio) and also of expelled cells. Samples were collected as the symbio left the host. These were flash frozen. Are the symbiont cells expelled from the coral host during thermal stress are a result of host stress or algae stress?

Project description:MARTX toxins are large single polypeptide bacterial toxins that translocate multiple cytotoxic and functionally independent effector domains into the cytosol of a target eukaryotic cell. Pandemic Vibrio cholerae El Tor O1 strains secrete a MARTX toxin with three effector domains — the actin crosslinking domain (ACD), the Rho inactivation domain (RID), and the alpha/beta-hydrolase domain (ABH) — to regulate innate immunity and enhance colonization. The goal of this study was to compare changes in the transcriptome of human intestinal epithelial cells (IECs) treated with V. cholerae modified to secret a toxin with only one effector domain to the transcriptome of cells treated with V. cholerae secreting the wild type MARTX toxin that delivers all three effector domains simultaneously. We demonstrate that when all three effectors are delivered there is no change in transcriptional response of IECs compared to untreated cells. However, when only ACD is delivered, transcriptional profiling revealed a significant proinflammatory response is activated. These data suggests that V. cholerae may utilize co-delivery of RID and/or ABH to silence the intestinal immune response to ACD activity. These data provide insight into how the V. cholerae MARTX toxin effector domains function together to alter the innate immune response of IECs during bacterial infection.

Project description:The bioluminescent bacterium Vibrio fischeri forms a mutually beneficial symbiosis with the Hawaiian bobtail squid, Euprymna scolopes, in which the bacteria, housed inside a specialized light organ, produce light used by the squid in its nocturnal activities. Upon hatching, E. scolopes juveniles acquire V. fischeri from the seawater through a complex process that requires, among other factors, chemotaxis by the bacteria along a gradient of N-acetylated sugars into the crypts of the light organ, the niche in which the bacteria reside. Once inside the light organ, V. fischeri transitions into a symbiotic, sessile state in which the quorum-signaling regulator LitR induces luminescence. In this work we show that expression of litR and luminescence are repressed by a homolog of the V. cholerae virulence factor TcpP, which we have named HbtR. Further, we demonstrate that LitR represses genes involved in motility and chemotaxis into the light organ and activates genes required for exopolysaccharide production. Importance: TcpP homologs are widespread throughout the Vibrio genus; however, the only protein in this family described thus far is a V. cholerae virulence regulator. Here we show that HbtR, the TcpP homolog in V. fischeri, has both a biological role and regulatory pathway completely unlike that in V. cholerae. Through its repression of the quorum-signaling regulator LitR, HbtR affects the expression of genes important for colonization of the E. scolopes light organ. While LitR becomes activated within the crypts, and upregulates luminescence and exopolysaccharide genes and downregulates chemotaxis and motility genes, it appears that HbtR, upon expulsion of V. fischeri cells into seawater, reverses this process to aid the switch from a symbiotic to a planktonic state. The possible importance of HbtR to the survival of V. fischeri outside of its animal host may have broader implications for the ways in which bacteria transition between often vastly different environmental niches.

Project description:Bacteria use quorum sensing (QS) to monitor cell density and coordinate group behaviours. In Vibrio cholerae, the causative agent of cholera disease, QS is linked to virulence gene expression via the autoinducer molecules, AI-2 and CAI-1. Both autoinducers share one signal transduction pathway to control AphA production, a key transcriptional activator of virulence genes. In this study, we demonstrate that the recently identified autoinducer, DPO, also controls AphA production in V. cholerae. DPO acts through the transcriptional activator, VqmA, and the VqmR small RNA to reduce AphA levels at the post-transcriptional level. Consequently, DPO inhibits virulence gene expression in V. cholerae, including repression of the cholera toxin, a key factor required for disease in humans. VqmR-mediated repression of AphA links the AI-2/CAI-1 and DPO-dependent QS pathways of V. cholerae and global transcriptome analysis indicate that all three autoinducers are required for full QS function. Together, our data provide the first view on autoinducer interplay in V. cholerae and highlight the importance of post-transcriptional gene regulation for collective functions in this major human pathogen.

Project description:To study the consequences of MAK-2 activity modulation during vegetative cell fusion, we took advantage of a previously constructed allele of MAK-2 (MAK-2Q100G) to specifically perturb kinase signaling during germling vegetative cell fusion (inhibition of MAK-2Q100G activity by addition of the ATP analog 1NM-PP1 results in a phenotype indistinguishable from mak-2 deletion strains). Whole genome microarrays of mak-2Q100G cells following 20 min 1NM-PP1 treatment were performed.

Project description:RNA-sequencing of Vibrio cholerae A1552 wild-type and ∆VCA0257 (∆rvvA) strains grown under virulence-inducing conditions (AKI).

Project description:The transcriptional factor ToxR initiates a virulence regulatory cascade required for V. cholerae to express critical host colonization factors and cause disease. Genome-wide expression studies suggest that ToxR regulates many genes important for V. cholerae pathogenesis, yet our knowledge of the direct regulon controlled by ToxR is limited to just four genes. Here, we determine ToxR’s genome-wide DNA-binding profile and show that ToxR is a global regulator of both progenitor genome-encoded genes and horizontally acquired islands encoding the majority of V. cholerae’s major virulence factors. Our results suggest that ToxR has gained regulatory control over important acquired elements that not only drive V. cholerae pathogenesis but that also define the major transitions of V. cholerae pandemic lineages. We demonstrate that ToxR shares nearly half its regulon with the histone-like nucleoid structuring protein H-NS, and antagonizes H-NS for control of critical colonization functions. This regulatory interaction is the major role of ToxR in V. cholerae colonization since deletion of H-NS abrogates the need of ToxR in V. cholerae host colonization. By comparing the genome-wide binding profiles of ToxR and other critical virulence regulators, we show that despite similar predicted DNA binding requirements, ToxR is unique in its global control of progenitor-encoded and acquired genes. Our results suggest that, like H-NS, factors in addition to linear DNA sequence drive selection of ToxR binding sites.

Project description:The transcriptional factor ToxR initiates a virulence regulatory cascade required for V. cholerae to express critical host colonization factors and cause disease. Genome-wide expression studies suggest that ToxR regulates many genes important for V. cholerae pathogenesis, yet our knowledge of the direct regulon controlled by ToxR is limited to just four genes. Here, we determine ToxR’s genome-wide DNA-binding profile and show that ToxR is a global regulator of both progenitor genome-encoded genes and horizontally acquired islands encoding the majority of V. cholerae’s major virulence factors. Our results suggest that ToxR has gained regulatory control over important acquired elements that not only drive V. cholerae pathogenesis but that also define the major transitions of V. cholerae pandemic lineages. We demonstrate that ToxR shares nearly half its regulon with the histone-like nucleoid structuring protein H-NS, and antagonizes H-NS for control of critical colonization functions. This regulatory interaction is the major role of ToxR in V. cholerae colonization since deletion of H-NS abrogates the need of ToxR in V. cholerae host colonization. By comparing the genome-wide binding profiles of ToxR and other critical virulence regulators, we show that despite similar predicted DNA binding requirements, ToxR is unique in its global control of progenitor-encoded and acquired genes. Our results suggest that, like H-NS, factors in addition to linear DNA sequence drive selection of ToxR binding sites.

Project description:The transcriptional factor ToxR initiates a virulence regulatory cascade required for V. cholerae to express critical host colonization factors and cause disease. Genome-wide expression studies suggest that ToxR regulates many genes important for V. cholerae pathogenesis, yet our knowledge of the direct regulon controlled by ToxR is limited to just four genes. Here, we determine ToxR’s genome-wide DNA-binding profile and show that ToxR is a global regulator of both progenitor genome-encoded genes and horizontally acquired islands encoding the majority of V. cholerae’s major virulence factors. Our results suggest that ToxR has gained regulatory control over important acquired elements that not only drive V. cholerae pathogenesis but that also define the major transitions of V. cholerae pandemic lineages. We demonstrate that ToxR shares nearly half its regulon with the histone-like nucleoid structuring protein H-NS, and antagonizes H-NS for control of critical colonization functions. This regulatory interaction is the major role of ToxR in V. cholerae colonization since deletion of H-NS abrogates the need of ToxR in V. cholerae host colonization. By comparing the genome-wide binding profiles of ToxR and other critical virulence regulators, we show that despite similar predicted DNA binding requirements, ToxR is unique in its global control of progenitor-encoded and acquired genes. Our results suggest that, like H-NS, factors in addition to linear DNA sequence drive selection of ToxR binding sites.