cholerae strains having an El Tor backbone, but possessing the classical ctxB gene, indeed produced more CT. In addition, a typical El Tor strain P130 and a non-O1/non-O139 strain VC82 isolated from an outbreak in Peru and from patients with severe diarrhea in India, respectively, produced
a higher amount of CT. It should be emphasized that capsaicin was able to effectively inhibit CT production not only in El Tor variants but also in typical El Tor, O139, classical as well selleck inhibitor as in non-O1/non-O139 strains (Fig. 1). Thus, the inhibitory effect of capsaicin appears to be a general phenomenon and not strain specific. In the presence of red chilli methanol extract and capsaicin, the transcription of the ctxA gene was drastically repressed in the V. cholerae CRC41 strain (Fig. 2). The higher inhibitory impact of red chilli methanol extract than capsaicin (43- and 23-fold inhibition, respectively) indicates the possibility of other unidentified compound(s) in red chilli that can directly inhibit or synergistically act with capsaicin. The transcription of the ctxAB gene is regulated with that of tcpA by a regulator protein called ToxT (DiRita et al., 1991). In the present study, reduction in the transcription of tcpA and toxT genes indicates that capsaicin may work in a ToxT-dependent manner (Fig. 2). Previous study with a synthetic compound virstatin showed similar HM781-36B research buy results (Hung et al., 2005). However, it has also been Cobimetinib molecular weight demonstrated that hns,
but not toxT, is responsible for the repression of ctxAB and tcpA transcriptions in the presence of bile (Chatterjee et al., 2007). Enhancement of hns gene transcription in the presence of capsaicin supports the idea that hns may play
a critical role in the reduction of transcriptions of ctxA and tcpA (Fig. 3). It has been shown earlier that H-NS negatively regulates the transcription of toxT, ctxAB and tcpA genes (Nye et al., 2000). We hypothesized that capsaicin might directly or indirectly activate the hns transcription, resulting in the downregulation of the transcription of toxT, ctxA and tcpA genes (Fig. 3). There is another possibility that capsaicin may directly repress the transcription of these three genes (Fig. 3). In addition, our qRT-PCR results showed that capsaicin did not inhibit the transcription of toxR/toxS regulatory genes, but repressed tcpP/tcpH transcription to a certain extent (Fig. 2). ToxR is believed to act via ToxT to regulate CT production (Hase & Mekalanos, 1998). These data suggest that capsaicin could repress transcription of virulence genes via induction of hns in a ToxR-independent manner (Fig. 3). In conclusion, red chilli contained compound(s) that can inhibit CT production in V. cholerae strains regardless of their serogroups and biotypes. Capsaicin is one of the active compounds of red chilli that can drastically suppress CT production. The inhibitory mechanism of CT production by capsaicin is probably due to the enhancement of transcription of the hns gene.