AI Article Synopsis
- RNAP faces obstacles during transcription that impact its movement, requiring assistance from associated factors like the protein Mfd.
- Mfd, known for DNA repair, is also important in regulating transcription and influences RNAP's association with chromosomal regions, often causing increased RNAP pausing in harder-to-transcribe areas.
- Mfd's regulation primarily affects regions with complex regulatory RNAs, which are involved in various biological functions and can influence mutagenesis, indicating its role in promoting evolution within certain genetic systems.
Article Abstract
RNA polymerase (RNAP) encounters various roadblocks during transcription. These obstacles can impede RNAP movement and influence transcription, ultimately necessitating the activity of RNAP-associated factors. One such factor is the bacterial protein Mfd, a highly conserved DNA translocase and evolvability factor that interacts with RNAP. Although Mfd is thought to function primarily in the repair of DNA lesions that stall RNAP, increasing evidence suggests that it may also be important for transcription regulation. However, this is yet to be fully characterized. To shed light on Mfd's in vivo functions, we identified the chromosomal regions where it associates. We analyzed Mfd's impact on RNAP association and transcription regulation genome-wide. We found that Mfd represses RNAP association at many chromosomal regions. We found that these regions show increased RNAP pausing, suggesting that they are hard to transcribe. Interestingly, we noticed that the majority of the regions where Mfd regulates transcription contain highly structured regulatory RNAs. The RNAs identified regulate a myriad of biological processes, ranging from metabolism to transfer RNA regulation to toxin-antitoxin (TA) functions. We found that cells lacking Mfd are highly sensitive to toxin overexpression. Finally, we found that Mfd promotes mutagenesis in at least one toxin gene, suggesting that its function in regulating transcription may promote evolution of certain TA systems and other regions containing strong RNA secondary structures. We conclude that Mfd is an RNAP cofactor that is important, and at times critical, for transcription regulation at hard-to-transcribe regions, especially those that express structured regulatory RNAs.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7817204 | PMC |
| http://dx.doi.org/10.1073/pnas.2008498118 | DOI Listing |
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