A lineage-specific heat-induced feedback loop controls HrcA to promote chlamydial fitness under stress.

Bacterial stress responses rely on transcriptional regulation by sigma factors and repressors. In Chlamydia, which lacks a dedicated heat shock sigma factor, repressor HrcA limits chaperone gene expression under non-stressed conditions. While HrcA function may be enhanced by the chaperone GroESL in a positive feedback loop, here we identify a heat-induced negative feedback loop mediated by HagF, a protein unique to Chlamydiota and conserved across Chlamydia species. We show that HrcA represses hagF, but heat shock induces hagF expression, leading to HagF accumulation and binding to HrcA. Structural modeling and pulldown assays indicate that HagF blocks HrcA dimerization, impairing DNA binding. This relieves repression of the hrcA-grpE-dnaK operon and promotes secondary differentiation in the developmental cycle, enabling infectious elementary bodies to form under heat stress. Our findings reveal dual feedback regulation that tunes chaperone gene expression and illustrate how transcriptional repression can be modulated in a minimal-genome pathogen.