Abstract
Bacteriophage Mu utilizes two converging promoters to regulate the lytic and lysogenic pathways. Messenger RNA encoding the repressor gene is synthesized leftward from a promoter (PcM) located 1066 base pairs from the Mu left end. This transcript overlaps and is complementary to RNA synthesized rightward from the early promoter (PE) for transposase and replication proteins which initiates transcription at base pair 1028. Purified Mu repressor binds to three distinct operator sites (O1, O2, and O3); repressor binding at O2 blocks RNA polymerase binding at PE and repressor binding at O3 blocks RNA polymerase binding at PcM. O1 and O2 have higher affinity for repressor than O3, and transcription from PE is blocked at repressor concentrations that do not affect PcM. Thus, maintenance of the lysogenic state and autoregulation of the repressor gene is achieved by RNA polymerase transcription through DNA-repressor ensembles at O1 and O2. Integration host factor (IHF) encoded by the Escherichia coli him A and him D genes binds to Mu operator DNA between sites O1 and O2. IHF enhances transcription from PE 3-5-fold on supercoiled plasmid substrates in vitro and in Mu monolysogens in vivo. In vitro, IHF simultaneously decreases transcription from PcM 5-10-fold which results in a 25-fold change in lytic transcription relative to repressor transcription. A model for regulating the Mu lysis-lysogeny decision is presented.
Highlights
From the Department of Biochemistry, Schoolsof Medicine and Dentistry, University of Alabama at Birmingham, University Station, Birmingham, Alabama 35294
In order to understand the role of hostproteins in Mu development, we have examined the interaction of the Mu operon with purified Mu repressor and Integration host factor (IHF) proteins
Complex reactions containing IHF and/or repressor were in- Transcription Starts for the Mu Repressor Gene--In order cubated first for 10 min at 37 "C; RNA polymerase was added to study regulation of the Mu early genes we developed an S
Summary
The temperate properties of bacteriophage Mu make it a transcription patterns, we show that thealternative developpowerful tool for studying gene regulation in bacteria. Inte- mental programs of Mu are organized into opposing and gration occurs by a nearly random transposition mechanism overlapping transcription units. This organization and the and requires production of the Mu transposase encoded by influence of IHF suggests a model for host cell modulation of the viral A gene (see Toussaintand Resibois (1983) for the Mu life cycle. Transcription of replication-transposition proteins is initiated and regulated from a single promoter (PE)located approximately 1kilobase from the left end of Mu (Krause et al, 1983). Purified integration host factor protein (IHF) was a gift from Howard Nash (National Institutes of Health).
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