Diguanylate Cyclases in Vibrio cholerae: Essential Regulators of Lifestyle Switching

Biofilm formation in Vibrio cholerae empowers the bacteria to lead a dual lifestyle and enhances its infectivity. While the formation and dispersal of the biofilm involves multiple components—both proteinaceous and non-proteinaceous, the key to the regulatory control lies with the ubiquitous secondary signaling molecule, cyclic-di-GMP (c-di-GMP). A number of different cellular components may interact with c-di-GMP, but the onus of synthesis of this molecule lies with a class of enzymes known as diguanylate cyclases (DGCs). DGC activity is generally associated with proteins possessing a GGDEF domain, ubiquitously present across all bacterial systems. V. cholerae is also endowed with multiple DGCs and information about some of them have been pouring in over the past decade. This review summarizes the DGCs confirmed till date in V. cholerae, and emphasizes the importance of DGCs and their product, c-di-GMP in the virulence and lifecycle of the bacteria.

N-terminal truncation of VC0395_0300 protein from Vibrio cholerae does not lead to loss of diguanylate cyclase activity

The bacterial secondary messenger bis-(3',5')-cyclic-dimeric-guanosine monophosphate (c-di-GMP) has been implicated in the pathogenesis of Vibrio cholerae, due to its significant role in regulating the virulence, biofilm formation and motility of the host organism. The VC0395_0300 protein from V. cholerae, possessing a GGEEF sequence has been established as a diguanylate cyclase (DGC) capable of catalyzing the conversion of two GTP molecules to form cyclic-di-GMP. This in turn, plays a crucial role in allowing the organism to adopt a dual lifestyle, thriving both in human and aquatic systems. The difficulty in procuring sufficient amounts of homogenous soluble protein for structural assessment of the GGDEF domain in VC0395_0300 and the lack of soluble protein yield, prompted the truncation into smaller constructs (Sebox31 and Sebox32) carrying the GGDEF domain. The truncates retained their diguanylate cyclase activity comparable to the wild type, and were able to form biofilms as well. Fluorescence and circular dichroism spectroscopy measurements revealed that the basic structural elements do not show significant changes in the truncated proteins as compared to the full-length. This has also been confirmed using homology modeling and molecular docking of the wild type and truncates. This led us to conclude that the truncated constructs retain their activity in spite of the deletions in the N terminal region. This is supportive of the fact that DGC activity in GGDEF proteins is predominantly dependent on the presence of the conserved GGD(/E)EF domain and its interaction with GTP.

Putative protein VC0395_0300 from Vibrio cholerae is a diguanylate cyclase with a role in biofilm formation

The hallmark of the lifecycle of Vibrio cholerae is its ability to switch between two lifestyles - the sessile, non-pathogenic form and the motile, infectious form in human hosts. One of these changes is in the formation of surface biofilms, when in sessile aquatic habitats. The cell-cell interactions within a V. cholerae biofilm are stabilized by the production of an exopolysachharide (EPS) matrix, which in turn is regulated by the ubiquitous secondary messenger, cyclic di-GMP (c-di-GMP), synthesized by proteins containing GGD(/E)EF domains in all prokaryotic systems. Here, we report the functional role of the VC0395_0300 protein (Sebox3) encoded by the chromosome I of V. cholerae, with a GGEEF signature sequence, in the formation of surface biofilms. In our study, we have shown that Escherichia coli containing the full-length Sebox3 displays enhanced biofilm forming ability with cellulose production as quantified and visualized by multiple assays, most notably using FEG-SEM. This has also been corroborated with the lack of motility of host containing Sebox3 in semi-solid media. Searching for the reasons for this biofilm formation, we have demonstrated in vitro that Sebox3 can synthesize c-di-GMP from GTP. The homology derived model of Sebox3 displayed significant conservation of the GGD(/E)EF architecture as well. Hence, we propose that the putative protein VC0395_0300 from V. cholerae is a diguanylate cyclase which has an active role in biofilm formation.

Effect of site-directed mutagenesis at the GGEEF domain of the biofilm forming GGEEF protein from Vibrio cholerae

Vibrio cholerae, the cause of seven noted pandemics, leads a dual lifecycle—one in the human host in its virulent form, and the other as a sessile, non-virulent bacterium in aquatic bodies in surface biofilms. Surface biofilms have been attributed to be associated with a ubiquitous protein domain present in all branches of bacteria, known as the GGD(/E)EF domain. While the diguanlyate cyclase activities of these proteins are universally established, the role of these proteins as diguanlyate-specific phosphodiesterases in conjunction with a EAL domain has also been reported. The VC0395_0300 protein from V. cholerae which shows biofilm forming abilities also acts as a phosphodiesterase. Interestingly, this GGD(/E)EF protein contains a EAL site in the reverse orientation. We attempted to mutate the GGEEF signature along the sequence by site-directed mutagenesis. The resultant mutants (Sebox5–7) did not show much difference in phosphodiesterase activity in comparison with the wild type protein (Sebox3), indicating the independence of the phosphodiesterase activity of the protein from the GGD(/E)EF domain. However, the ability of the mutants to form surface biofilm was significantly lesser in the case of mutations in the three central positions of the signature domain.