Mycobacterium tuberculosis virulence-regulator PhoP interacts with alternative sigma factor SigE during acid-stress response.

The ability to sense acid stress and mount an appropriate adaptive response by Mycobacterium tuberculosis, which adapts a long-term residence in the macrophage phagosome, remains one of the critical features that defines mycobacterial physiology and its intracellular location. To understand the mechanistic basis of adaptation of the intracellular pathogen, we studied global regulation of M. tuberculosis gene expression in response to acid stress. Although recent studies indicate a role for the virulence-associated phoP locus in pH-driven adaptation, in this study, we discovered a strikingly novel regulatory mechanism, which controls acid-stress homeostasis. Using mycobacterial protein fragment complementation and in vitro interaction analyses, we demonstrate that PhoP interacts with acid-inducible extracytoplasmic SigE (one of the 13 M. tuberculosis sigma factors) to regulate a complex transcriptional program. Based on these results, we propose a model to suggest that PhoP-SigE interaction represents a major requirement for the global acid stress response, absence of which leads to strongly reduced survival of the bacilli under acidic pH conditions. These results account for the significant growth attenuation of the phoP mutant in both cellular and animal models, and unravel the underlying global mechanism of how PhoP induces an adaptive program in response to acid stress.

EspR-dependent ESAT-6 Protein Secretion of Mycobacterium tuberculosis Requires the Presence of Virulence Regulator PhoP.

Attenuation of Mycobacterium bovis BCG strain is related to the loss of the RD1-encoded ESX-1 secretion system. The ESX-1 system secretes virulence factor ESAT-6 that plays a critical role in modulation of the host immune system, which is essential for establishment of a productive infection. Previous studies suggest that among the reasons for attenuation of Mycobacterium tuberculosis H37Ra is a mutation in the phoP gene that interferes with the ESX-1 secretion system and inhibits secretion of ESAT-6. Here, we identify a totally different and distinct regulatory mechanism involving PhoP and transcription regulator EspR on transcriptional control of the espACD operon, which is required for ESX-1-dependent ESAT-6 secretion. Although both of these regulators are capable of influencing espACD expression, we show that activation of espACD requires direct recruitment of both PhoP and EspR at the espACD promoter. The most fundamental insights are derived from the inhibition of EspR binding at the espACD regulatory region of the phoP mutant strain because of PhoP-EspR protein-protein interactions. Based on these results, a model is proposed suggesting how PhoP and EspR protein-protein interactions contribute to activation of espACD expression and, in turn, control ESAT-6 secretion, an essential pathogenic determinant of M. tuberculosis Together, these results have significant implications on the mechanism of virulence regulation of M. tuberculosis.

A transcriptional co-repressor regulatory circuit controlling the heat-shock response of Mycobacterium tuberculosis.

The co-ordinated regulation of heat shock proteins is critically important for the stress response of M. tuberculosis, failure of which results in enhanced immune recognition of the tubercle bacilli with reduced survival during chronic infections. In this study, we show that PhoP regulates the transcription of α-crystallin 2 (acr2), expression of which increases more than any other gene of M. tuberculosis during heat-shock or following macrophage infection. We also show that regulation of acr2 by PhoP is attributable to direct regulator-promoter interactions at specific sites proximal to a sequence motif comprising the target site of another virulence factor, HspR. While both these regulators, on their own, are capable of influencing acr2 expression, remarkably our results show that the two virulence regulators PhoP and HspR interact with each other to influence their in vivo recruitment at the acr2 regulatory region, and in turn, contribute to stress-specific regulation of acr2 expression. We propose a model to suggest how protein-protein interactions between PhoP and HspR influence the regulation of α-crystallin 2, an essential pathogenic determinant of M. tuberculosis.