Tobias Brandt scite author profile

Lys120 in the DNA-binding domain (DBD) of p53 becomes acetylated in response to DNA damage. But, the role and effects of acetylation are obscure. We prepared p53 specifically acetylated at Lys120, AcK120p53, by in vivo incorporation of acetylated lysine to study biophysical and structural consequences of acetylation that may shed light on its biological role. Acetylation had no affect on the overall crystal structure of the DBD at 1.9-Å resolution, but significantly altered the effects of salt concentration on specificity of DNA binding. p53 binds DNA randomly in vitro at effective physiological salt concentration and does not bind specifically to DNA or distinguish among its different response elements until higher salt concentrations. But, on acetylation, AcK120p53 exhibited specific DNA binding and discriminated among response elements at effective physiological salt concentration. AcK120p53 and p53 had the highest affinity to the same DNA sequence, although acetylation reduced the importance of the consensus C and G at positions 4 and 7, respectively. Mass spectrometry of p53 and AcK120p53 DBDs bound to DNA showed they preferentially segregated into complexes that were either DNAðp53DBDÞ 4 or DNA ðAcK120DBDÞ 4 , indicating that the different DBDs prefer different quaternary structures. These results are consistent with electron microscopy observations that p53 binds to nonspecific DNA in different, relaxed, quaternary states from those bound to specific sequences. Evidence is accumulating that p53 can be sequestered by random DNA, and target search requires acetylation of Lys120 and/or interaction with other factors to impose specificity of binding via modulating changes in quaternary structure.

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Electron microscopy studies on the quaternary structure of p53 reveal different binding modes for p53 tetramers in complex with DNA

Melero

Rajagopalan

Lázaro

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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The multidomain homotetrameric tumor suppressor p53 has two modes of binding dsDNA that are thought to be responsible for scanning and recognizing specific response elements (REs). The C termini bind nonspecifically to dsDNA. The four DNA-binding domains (DBDs) bind REs that have two symmetric 10 base-pair sequences. p53 bound to a 20-bp RE has the DBDs enveloping the DNA, which is in the center of the molecule surrounded by linker sequences to the tetramerization domain (Tet). We investigated by electron microscopy structures of p53 bound to DNA sequences consisting of a 20-bp RE with either 12 or 20 bp nonspecific extensions on either end. We found a variety of structures that give clues to recognition and scanning mechanisms. The 44-and 60-bp sequences gave rise to three and four classes of structures, respectively. One was similar to the known 20-bp structure, but the DBDs in the other classes were loosely arranged and incompatible with specific DNA recognition. Some of the complexes had density consistent with the C termini extending from Tet to the DNA, adjacent to the DBDs. Single-molecule fluorescence resonance energy transfer experiments detected the approach of the C termini towards the DBDs on addition of DNA. The structural data are consistent with p53 sliding along DNA via its C termini and the DNA-binding domains hopping on and off during searches for REs. The loose structures and posttranslational modifications account for the affinity of nonspecific DNA for p53 and point to a mechanism of enhancement of specificity by its binding to effector proteins.protein | recognition | specificity

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Conservation of DNA-binding specificity and oligomerisation properties within the p53 family

Brandt¹,

Petrovich²,

Joerger³

et al. 2009

BMC Genomics

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Background: Transcription factors activate their target genes by binding to specific response elements. Many transcription factor families evolved from a common ancestor by gene duplication and subsequent divergent evolution. Members of the p53 family, which play key roles in cell-cycle control and development, share conserved DNA binding and oligomerisation domains but exhibit distinct functions. In this study, the molecular basis of the functional divergence of related transcription factors was investigated.

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Tobias Brandt

Acetylation of lysine 120 of p53 endows DNA-binding specificity at effective physiological salt concentration

Electron microscopy studies on the quaternary structure of p53 reveal different binding modes for p53 tetramers in complex with DNA

Conservation of DNA-binding specificity and oligomerisation properties within the p53 family

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