Repression of transcription initiation at 434 P(R) by 434 repressor: effects on transition of a closed to an open promoter complex
- PMID: 11397081
- DOI: 10.1006/jmbi.2001.4702
Repression of transcription initiation at 434 P(R) by 434 repressor: effects on transition of a closed to an open promoter complex
Abstract
The lambdoid bacteriophage repressors function both as transcription activators and repressors. Regulation of transcription at the adjacent, but divergent promoters, P(RM) and P(R), determines the phage's choice between the lytic and lysogenic development pathways. Here, we demonstrate that 434 repressor bound at 434 O(R)1 alone is not sufficient to repress transcription from 434 P(R,) but that 434 repressor bound at 434 O(R)2 alone is necessary and sufficient to repress P(R )transcription. This is different from what occurs in the related bacteriophage lambda, in which binding of lambda repressor to either lambdaO(R)1 or lambdaO(R)2 represses transcription from lambdaP(R). The combined results of gel mobility shift and KMnO(4) footprinting assays show that while 434 repressor binding to 434 O(R)2 does not preclude RNA polymerase binding at the P(R) promoter, it does prevent it from forming open complexes at this promoter. The RNA polymerase-P(R) complexes that form in the presence of repressor are heparin-resistant and the DNA is not melted. This observation indicates that 434 repressor bound at 434 O(R)2 inhibits transcription initiation at the P(R) promoter by "locking" the RNA polymerase-P(R) complex into an inactive state instead of "blocking" the access of RNA polymerase to promoter DNA.
Copyright 2001 Academic Press.
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