Modulation of Binding of DNA to the C-Terminal Domain of p53 by Acetylation

The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which is subject to acetylation and phosphorylation at several residues as part of control. To measure the effect of covalent modification on bindin...

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Published inStructure (London) Vol. 13; no. 4; pp. 629 - 636
Main Authors Friedler, Assaf, Veprintsev, Dmitry B., Freund, Stefan M.V., von Glos, Karoly I., Fersht, Alan R.
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 01.04.2005
Subjects
Acetylation
Amino Acid Sequence
DNA - metabolism
Molecular Sequence Data
Osmolar Concentration
Phosphorylation
Protein Binding
Spectrometry, Fluorescence
Tumor Suppressor Protein p53 - chemistry
Tumor Suppressor Protein p53 - metabolism
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Abstract The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which is subject to acetylation and phosphorylation at several residues as part of control. To measure the effect of covalent modification on binding to DNA, we synthesized a series of fluorescein-labeled CTD peptides with single and multiple acetylations at lysine residues that we had identified by NMR as making contact with DNA, and developed an analytical ultracentrifugation method to study their binding to DNA. Binding depended on ionic strength, indicating an electrostatic contribution. Monoacetylation weakened DNA binding at physiological ionic strength 2- to 3-fold, diacetylations resulted in further 2- to 3-fold decrease in the affinity, and tri- and tetraacetylations rendered DNA binding undetectable. Phosphorylation at S392 did not affect DNA binding. NMR spectroscopy showed binding to DNA did not induce significant structure into CTD, apart possibly from local helix formation.
AbstractList The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which is subject to acetylation and phosphorylation at several residues as part of control. To measure the effect of covalent modification on binding to DNA, we synthesized a series of fluorescein-labeled CTD peptides with single and multiple acetylations at lysine residues that we had identified by NMR as making contact with DNA, and developed an analytical ultracentrifugation method to study their binding to DNA. Binding depended on ionic strength, indicating an electrostatic contribution. Monoacetylation weakened DNA binding at physiological ionic strength 2- to 3-fold, diacetylations resulted in further 2- to 3-fold decrease in the affinity, and tri- and tetraacetylations rendered DNA binding undetectable. Phosphorylation at S392 did not affect DNA binding. NMR spectroscopy showed binding to DNA did not induce significant structure into CTD, apart possibly from local helix formation.The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which is subject to acetylation and phosphorylation at several residues as part of control. To measure the effect of covalent modification on binding to DNA, we synthesized a series of fluorescein-labeled CTD peptides with single and multiple acetylations at lysine residues that we had identified by NMR as making contact with DNA, and developed an analytical ultracentrifugation method to study their binding to DNA. Binding depended on ionic strength, indicating an electrostatic contribution. Monoacetylation weakened DNA binding at physiological ionic strength 2- to 3-fold, diacetylations resulted in further 2- to 3-fold decrease in the affinity, and tri- and tetraacetylations rendered DNA binding undetectable. Phosphorylation at S392 did not affect DNA binding. NMR spectroscopy showed binding to DNA did not induce significant structure into CTD, apart possibly from local helix formation.
The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which is subject to acetylation and phosphorylation at several residues as part of control. To measure the effect of covalent modification on binding to DNA, we synthesized a series of fluorescein-labeled CTD peptides with single and multiple acetylations at lysine residues that we had identified by NMR as making contact with DNA, and developed an analytical ultracentrifugation method to study their binding to DNA. Binding depended on ionic strength, indicating an electrostatic contribution. Monoacetylation weakened DNA binding at physiological ionic strength 2- to 3-fold, diacetylations resulted in further 2- to 3-fold decrease in the affinity, and tri- and tetraacetylations rendered DNA binding undetectable. Phosphorylation at S392 did not affect DNA binding. NMR spectroscopy showed binding to DNA did not induce significant structure into CTD, apart possibly from local helix formation.
Author Friedler, Assaf
Freund, Stefan M.V.
Fersht, Alan R.
von Glos, Karoly I.
Veprintsev, Dmitry B.
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  givenname: Stefan M.V.
  surname: Freund
  fullname: Freund, Stefan M.V.
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  givenname: Karoly I.
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  givenname: Alan R.
  surname: Fersht
  fullname: Fersht, Alan R.
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/15837201$$D View this record in MEDLINE/PubMed
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Snippet The binding of nonspecific DNA to the C-terminal negative regulatory domain (CTD) of p53 modulates its activity. The CTD is a natively unfolded region, which...
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SubjectTerms Acetylation
Amino Acid Sequence
DNA - metabolism
Molecular Sequence Data
Osmolar Concentration
Phosphorylation
Protein Binding
Spectrometry, Fluorescence
Tumor Suppressor Protein p53 - chemistry
Tumor Suppressor Protein p53 - metabolism
Title Modulation of Binding of DNA to the C-Terminal Domain of p53 by Acetylation
URI https://dx.doi.org/10.1016/j.str.2005.01.020
https://www.ncbi.nlm.nih.gov/pubmed/15837201
https://www.proquest.com/docview/17579486
https://www.proquest.com/docview/67753097
Volume 13
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