pestis, the etiological agent of plague via intradermal fleabites

pestis, the etiological agent of plague via intradermal fleabites or inhalation, and Y. pseudotuberculosis and Y. enterocolitica, which cause self-limiting enteric disease by the oral route. In spite of the differences in route of infection and severity of disease, the three species

share similar pathogenic mechanisms, primarily the ~70 kb virulence plasmid (pCD1 in Y. pestis and pYV in Y. pseudotuberculosis and Y. enterocolitica) that encodes for the Type III secretion system (T3SS) learn more [1]. Upon contact with host cells and a shift to host temperature of 37°C, Yersinia induces T3SS expression to translocate Yersinia outer proteins (Yops) into the host cytosol to modulate the host immune response and promote pathogen

survival [2]. All three Yersinia species target the lymphoid system during infection and replicate in lymphatic tissue as aggregates of extracellular bacteria [3, 4]. Yersinia strains that lack pCD1/pYV do not replicate extracellularly and have been shown to be contained within granulomas that are eventually eliminated [4]. Yersinia are unusual amongst other Gram-negative bacteria that express the T3SS, in that they do not actively induce phagocytosis for entry and intracellular growth in the host [5]. www.selleckchem.com/products/z-vad(oh)-fmk.html Instead, Yersinia inject several Yops, including YopH, E, and T, to disrupt the host actin cytoskeleton and resist uptake via phagocytosis by neutrophils. Although pathogenic Yersinia have been reported to multiply within macrophages early in the infection process [6, 7], Y. pestis exponential growth occurs primarily in the extracellular phase, causing acute septicemia with blood ADP ribosylation factor counts as high as 108 CFU/ml [8]. Thus, in order to establish successful infection, Yersinia is dependent on targeting multiple host ACP-196 purchase signaling pathways to evade

host immune defense and induce host cell death. For example, YopP/J functions as a deubiquitinating protease and acetyltransferase to inhibit both the host NF-κB and mitogen-activated protein kinase (MAPK) signaling pathways, leading to a block in cytokine secretion and apoptosis of host macrophages [9–11]. Although discovery of Yop effector targets have begun to clarify mechanisms of Yersinia virulence, it is likely the case that additional host targets remain to be defined. Identification of host cell factors that are targeted by Yersinia during infection would provide valuable molecular insights in understanding Yersinia pathogenesis, and ultimately, in designing effective host-targeted therapies and antimicrobial agents. In order to systematically identify novel host targets required for Yersinia infection, we performed an RNAi screen using a short hairpin RNA (shRNA) kinome library. The development of RNAi approaches has greatly enabled the examination of the roles of individual human genes by specific gene silencing [12].

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