The MotA transcriptional activator of bacteriophage T4 binds to its specific DNA site as a monomer.
During bacteriophage T4 middle mode gene expression, the MotA transcription factor binds to T4 middle promoters at a -30 mot box consensus sequence to allow activation. Previous binding studies showed that MotA forms multiple gel-shifted complexes with DNA, and structural evidence suggested that MotA dimerizes upon DNA binding. We have shown that a short (13 bp) mot box DNA substrate binds MotA protein but fails to form slower migrating complexes. Therefore, the slower migrating complexes in gel shift assays are caused by DNA-mediated binding events. Competition experiments indicate that the slower migrating complexes are formed by nonspecific binding events, while the first-shifted complex is caused by specific binding to the mot box. Saturation binding experiments revealed that the stoichiometry of MotA binding to DNA is 1:1 in the first-shifted complex, while the slower complexes apparently contain MotA multimers. Gel shift assays using mixtures of MotA and a GST-MotA fusion protein supported the conclusion that the first-shifted complex contains one protein molecule bound to DNA. Furthermore, MotA monomers were cross-linked by glutaraldehyde under conditions where slower complexes exist, but not under conditions that lead to only the first-shifted complex. We conclude that MotA binds specifically to the mot box as a monomer and that additional nonspecific binding events require flanking DNA.
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Related Subject Headings
- Trans-Activators
- Spectrometry, Fluorescence
- Protein Binding
- Glutaral
- Dimerization
- DNA-Binding Proteins
- DNA, Recombinant
- Cross-Linking Reagents
- Biochemistry & Molecular Biology
- Binding, Competitive
Citation
Published In
DOI
ISSN
Publication Date
Volume
Issue
Start / End Page
Location
Related Subject Headings
- Trans-Activators
- Spectrometry, Fluorescence
- Protein Binding
- Glutaral
- Dimerization
- DNA-Binding Proteins
- DNA, Recombinant
- Cross-Linking Reagents
- Biochemistry & Molecular Biology
- Binding, Competitive