The interaction did not occur if full-length ClpV was used, which

The interaction did not occur if full-length ClpV was used, which may be a Selleckchem Natural Product Library consequence of the rather low expression of the latter construct (data not shown). In addition, also the VipA homologues PA2365 of P. aeruginosa (30% id to selleck kinase inhibitor VipA) and YPTB1483 of Y. pseudotuberculosis (41% id to VipA) were shown to interact with the N-domain of V. cholerae ClpV in yeast, however the interaction was noticeably stronger, as it resulted in more prominent growth on medium lacking histidine (Figure 7). The ClpV interaction did not require an intact VipB-interaction site, since all of VipA Δ104-113, PA2365 Δ109-118 and YPTB1483

Δ105-114, carrying deletions within α-helix H2 [6], maintained their ClpV-interacting ability. Thus, similar to the VipA-VipB interaction, also the VipA-ClpV interaction may be conserved among T6S-containing species. Moreover, the ClpV- and VipB-interaction sites within the VipA proteins appear distinct. No interaction between ClpV and VipB or its homologues could be detected in either the B2H or the Y2H system (Figure 7 and data not shown). Figure 7 VipA interacts with the N-terminus of ClpV (ClpV N´) in yeast. VipA, VipB and their homologous proteins from P. aeruginosa PA01 (locus tag PA2365 and PA2366 respectively) or Y. pseudotuberculosis IP 32953 (locus tag YPTB1483 and YPTB1484 respectively)

were fused to the GAL4 activation domain of plasmid pGADT7 and co-transformed with ClpV (aa 1–178) on the GAL4 DNA-binding domain pGBKT7 into the S. cerevisiae two-hybrid FRAX597 price assay reporter strain AH109. A positive interaction will result in the activation of the two independent reporter genes, ADE2 and HIS3,

to permit growth of yeast on minimal medium devoid of adenine and histidine respectively recorded after day 5 at 25°C. Results reflect trends in growth from two independent experiments in which several individual transformants were tested on each occasion. Discussion V. cholerae depends on virulence factors like toxin co-regulated pili (TCP) and cholera toxin (CT), to cause the severe, life-threatening diarrheal disease, cholera [22, 23]. A T6SS was recently implicated as an additional virulence determinant Tyrosine-protein kinase BLK of V. cholerae that is required for Hcp secretion [12], for killing of amoeba and bacteria [12, 20], and also contributes to the inflammatory diarrhea in infant mice and rabbits [24, 25]. The large majority of T6SS genes (12 out of 17), including VipA, VipB, ClpV, VasF and VasK, are required for Hcp secretion, killing of amoeba and bacteria and are predicted to encode structural T6SS components [9, 12, 20]. In addition, regulatory proteins, VasH and VCA0122 [12, 20], as well as effector proteins, VgrG-1 and possibly VCA0118, have also been identified [20, 24, 26, 27]. By using an in silico approach analyzing the F. tularensis VipA-VipB homologues, we previously identified four distinct α-helices (H1 to H4) in the VipA homologue, IglA [6].

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