Genetic Dissection of the Fermentative and Respiratory Contributions Supporting Vibrio cholerae Hypoxic Growth
Emilio Cendejas‐Bueno, Brandon Sit, Matthew K. Waldor, Felipe Cava
Abstract
Bacteria reprogram their metabolism in environments with low oxygen levels (hypoxia). Typically, this occurs via regulation of two major, but largely independent, metabolic pathways: fermentation and respiration. In this study, we found that the diarrheal pathogen Vibrio cholerae has a respiratory chain for NO 3 − that consists largely of components found in other NO 3 − respiratory systems but also contains several proteins not previously linked to this process. Both AdhE-dependent fermentation and NO 3 − respiration were required for efficient pathogen growth under both laboratory conditions and in an animal infection model. These observations provide a specific example of fermentative respiratory interactions and identify metabolic vulnerabilities that may be targetable for new antimicrobial agents in V. cholerae and related pathogens.