Exoproteome and Secretome Derived Broad Spectrum Novel Drug and Vaccine Candidates in Vibrio cholerae Targeted by Piper betel Derived Compounds

Debmalya Barh,Eric R Braverman,Kenneth Blum,Thiago Luiz De Paula Castro,Anil Kumar,Vasco Azevedo,Neha Barve,Anderson Miyoshi,Síntia Almeida,Sandeep Tiwari,Neha Jain,Siomar De Castro Soares,Rommel Thiago Jucá Ramos,Syed Shah Hassan,Adriana Ribeiro Carneiro,Krishnakant Gupta,Sudha Chandra,A N Misra ,Anderson Santos ,Nidia León-Sicairos ,Adrián Canizalez-Roman ,Vinícius Augusto Carvalho De Abreu ,Artur M S Silva

doi:10.1371/journal.pone.0052773

Abstract

Vibrio cholerae is the causal organism of the cholera epidemic, which is mostly prevalent in developing and underdeveloped countries. However, incidences of cholera in developed countries are also alarming. Because of the emergence of new drug-resistant strains, even though several generic drugs and vaccines have been developed over time, Vibrio infections remain a global health problem that appeals for the development of novel drugs and vaccines against the pathogen. Here, applying comparative proteomic and reverse vaccinology approaches to the exoproteome and secretome of the pathogen, we have identified three candidate targets (ompU, uppP and yajC) for most of the pathogenic Vibrio strains. Two targets (uppP and yajC) are novel to Vibrio, and two targets (uppP and ompU) can be used to develop both drugs and vaccines (dual targets) against broad spectrum Vibrio serotypes. Using our novel computational approach, we have identified three peptide vaccine candidates that have high potential to induce both B- and T-cell-mediated immune responses from our identified two dual targets. These two targets were modeled and subjected to virtual screening against natural compounds derived from Piper betel. Seven compounds were identified first time from Piper betel to be highly effective to render the function of these targets to identify them as emerging potential drugs against Vibrio. Our preliminary validation suggests that these identified peptide vaccines and betel compounds are highly effective against Vibrio cholerae. Currently we are exhaustively validating these targets, candidate peptide vaccines, and betel derived lead compounds against a number of Vibrio species.

Highlights

Vibrio cholerae is a noninvasive gram-negative bacterium that causes water borne disease cholera, which is characterized by profuse watery diarrhea and vomiting [1]
The V. cholerae O395 strain is a classical O1 serotype strain responsible for cholera epidemics in Asian countries, and the non-O1 sero-group Vibrio cholerae O139 has been implicated as the causative agent of sporadic cases of gastro-enteritis and extra-intestinal infections [2,3]
II) and 317 secreted (113 from Ch-I and 204 from Ch-II) proteins for a total of 830 proteins based on our exoproteome and secretome analysis of V. cholerae strain O395

Summary

Introduction

Vibrio cholerae is a noninvasive gram-negative bacterium that causes water borne disease cholera, which is characterized by profuse watery diarrhea and vomiting [1]. The V. cholerae O395 strain is a classical O1 serotype strain responsible for cholera epidemics in Asian countries, and the non-O1 sero-group Vibrio cholerae O139 has been implicated as the causative agent of sporadic cases of gastro-enteritis and extra-intestinal infections [2,3]. Both of the strains have been reported to cause significant numbers of morbidities [4,5]. Novel drugs and vaccines must be developed to tackle the Vibrio infection and transmission

Methods

Results

Conclusion