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RESEARCH PRODUCT
Sequence-specific and DNA structure-dependent interactions of Escherichia coli MutS and human p53 with DNA
Andrew M. CobbRichard P. BowaterPhilip L. BondElla KimBrian R. Jacksonsubject
chemistry.chemical_classificationDNA ligaseDNA clampHMG-boxBase pairEscherichia coli ProteinsOsmolar ConcentrationBiophysicsDNACell BiologyBiologyBiochemistryMutS DNA Mismatch-Binding ProteinDNA binding siteBiochemistrychemistryMutS-1Escherichia coliHumansNucleic Acid ConformationProtein–DNA interactionAmino Acid SequenceTumor Suppressor Protein p53Molecular BiologyReplication protein Adescription
Many proteins involved in DNA repair systems interact with DNA that has structure altered from the typical B-form helix. Using magnetic beads to immobilize DNAs containing various types of structures, we evaluated the in vitro binding activities of two well-characterized DNA repair proteins, Escherichia coli MutS and human p53. E. coli MutS bound to double-stranded DNAs, with higher affinity for a G/T mismatch compared to a G/A mismatch and highest affinity for larger non-B-DNA structures. E. coli MutS bound best to DNA between pH 6 and 9. Experiments discriminated between modes of p53-DNA binding, and increasing ionic strength reduced p53 binding to nonspecific double-stranded DNA, but had minor effects on binding to consensus response sequences or single-stranded DNA. Compared to nonspecific DNA sequences, p53 bound with a higher affinity to mismatches and base insertions, while binding to various hairpin structures was similar to that observed to its consensus DNA sequence. For hairpins containing CTG repeats, the extent of p53 binding was proportional to the size of the repeat. In summary, using the flexibility of the magnetic bead separation assay we demonstrate that pH and ionic strength influence the binding of two DNA repair proteins to a variety of DNA structures.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-11-01 | Analytical Biochemistry |