Abstract

Summary Tuberculosis ( TB ) remains a major cause of morbidity and mortality worldwide. The pathogenesis by the causative agent, M ycobacterium tuberculosis , is still not fully understood. We have previously reported that M . tuberculosis Rv 3586 ( disA ) encodes a diadenylate cyclase, which converts ATP to cyclic di‐AMP ( c‐di‐AMP ). In this study, we demonstrated that a protein encoded by Rv 2837c ( cnpB ) possesses c‐di‐AMP phosphodiesterase activity and cleaves c‐di‐AMP exclusively to AMP . Our results showed that in M . tuberculosis , deletion of disA abolished bacterial c‐di‐AMP production, whereas deletion of cnpB significantly enhanced the bacterial c‐di‐AMP accumulation and secretion. The c‐di‐AMP levels in both mutants could be corrected by expressing the respective gene. We also found that macrophages infected with Δ cnpB secreted much higher levels of IFN ‐β than those infected with the wild type ( WT ) or the complemented mutant. Interestingly, mice infected with M . tuberculosis Δ cnpB displayed significantly reduced inflammation, less bacterial burden in the lungs and spleens, and extended survival compared with those infected with the WT or the complemented mutant. These results indicate that deletion of cnpB results in attenuated virulence, which is correlated with elevated c‐di‐AMP levels.