Characterization of Mycobacterium tuberculosis rhodanese-like sulfurtransferase SseA and its newly identified activator Rv3284: A new pathway to exploit as a drug target?

Tuberculosis (TB) remains a critical global health challenge, with Mycobacterium tuberculosis (Mtb) causing 10.8 million cases and 1.25 million deaths in 2023. Key issues include the dormant state of Mtb, resistant to drugs and immune responses, and the emergence of multi-drug-resistant strains. This underscores the need for new therapeutic targets and deeper research into Mtb pathogenesis and immunology.

A potential drug target is the enzyme thiosulfate-sulfurtransferase SseA, which plays a role in macrophage infection by Mtb and its resistance to oxidative stress. SseA belongs to the rhodanese-like enzyme family, which catalyzes sulfur transfer reactions essential for Mtb survival.

In our research, we identified a new protein (Rv3284), hereinafter referred to as SufE _Mtb due to its high homology with E. coli SufE, that interacts with SseA and modulates its activity. Sequence analysis and AI molecular modelling revealed detailed insights into their interaction that can contribute to the modulation of SseA activity. This research provides a mechanistic explanation to the need of a partner for SseA activation. Indeed, we propose that SufE _Mtb enhances SseA enzymatic function by binding to its non-catalytic N-terminal domain and bringing the active sites of the two proteins in close proximity, thus preparing for the activation-enhancing conformational change in a regulatory loop of SseA. This interaction is crucial for the effective enzyme activity and the maintenance of redox homeostasis in Mtb, making the SseA-SufE _Mtb protein complex a potential target for new TB therapies.