biostudies-literatureGao FUKRI | Biotechnology and Biological Sciences Research CouncilWellcome TrustBiotechnology and Biological Sciences Research Councile2425868122https://www.ebi.ac.uk/biostudies/studies/S-EPMC12054792biostudies-literatureUnknown122(17)Bacterial RNA polymerase (RNAP) is a multisubunit enzyme that copies DNA into RNA in a process known as transcription. Bacteria use σ factors to recruit RNAP to promoter regions of genes that need to be transcribed, with 60% bacteria containing at least one specialized σ factor, σ⁵⁴. σ⁵⁴ recruits RNAP to promoters of genes associated with stress responses and forms a stable closed complex that does not spontaneously isomerize to the open state where promoter DNA is melted out and competent for transcription. The σ⁵⁴-mediated open complex formation requires specific AAA+ proteins (<u>A</u>TPases <u>A</u>ssociated with diverse cellular <u>A</u>ctivities) known as bacterial enhancer-binding proteins (bEBPs). We have now obtained structures of new intermediate states of bEBP-bound complexes during transcription initiation, which elucidate the mechanism of DNA melting driven by ATPase activity of bEBPs and suggest a mechanistic model that couples the Adenosine triphosphate (ATP) hydrolysis cycle within the bEBP hexamer with σ⁵⁴ unfolding. Our data reveal that bEBP forms a nonplanar hexamer with the hydrolysis-ready subunit located at the furthest/highest point of the spiral hexamer relative to the RNAP. ATP hydrolysis induces conformational changes in bEBP that drives a vectoral transiting of the regulatory N terminus of σ⁵⁴ into the bEBP hexamer central pore causing the partial unfolding of σ⁵⁴, while forming specific bEBP contacts with promoter DNA. Furthermore, our data suggest a mechanism of the bEBP AAA+ protein that is distinct from the hand-over-hand mechanism proposed for many other AAA+ proteins, highlighting the versatile mechanisms utilized by the large protein family.Proceedings of the National Academy of Sciences of the United States of AmericaSubunit specialization in AAA+ proteins and substrate unfolding during transcription complex remodeling.PMC12054792BB/M011178/1Buck MZhang XYe FGao FfalseSubunit specialization in AAA+ proteins and substrate unfolding during transcription complex remodeling.Bacterial RNA polymerase (RNAP) is a multisubunit enzyme that copies DNA into RNA in a process known as transcription. Bacteria use σ factors to recruit RNAP to promoter regions of genes that need to be transcribed, with 60% bacteria containing at least one specialized σ factor, σ⁵⁴. σ⁵⁴ recruits RNAP to promoters of genes associated with stress responses and forms a stable closed complex that does not spontaneously isomerize to the open state where promoter DNA is melted out and competent for transcription. The σ⁵⁴-mediated open complex formation requires specific AAA+ proteins (<u>A</u>TPases <u>A</u>ssociated with diverse cellular <u>A</u>ctivities) known as bacterial enhancer-binding proteins (bEBPs). We have now obtained structures of new intermediate states of bEBP-bound complexes during transcription initiation, which elucidate the mechanism of DNA melting driven by ATPase activity of bEBPs and suggest a mechanistic model that couples the Adenosine triphosphate (ATP) hydrolysis cycle within the bEBP hexamer with σ⁵⁴ unfolding. Our data reveal that bEBP forms a nonplanar hexamer with the hydrolysis-ready subunit located at the furthest/highest point of the spiral hexamer relative to the RNAP. ATP hydrolysis induces conformational changes in bEBP that drives a vectoral transiting of the regulatory N terminus of σ⁵⁴ into the bEBP hexamer central pore causing the partial unfolding of σ⁵⁴, while forming specific bEBP contacts with promoter DNA. Furthermore, our data suggest a mechanism of the bEBP AAA+ protein that is distinct from the hand-over-hand mechanism proposed for many other AAA+ proteins, highlighting the versatile mechanisms utilized by the large protein family.2025-01-01T00:00:00Z2025 Apr2025-08-13T03:06:37.417Z2025-08-13T03:06:37.417ZS-EPMC120547924027310510.1073/pnas.2425868122