Single-stranded DNA mimicry in the p53 transactivation domain interaction with replication protein A

Bochkareva, Elena; Kaustov, Lilia; Ayed, Ayeda; Yi, Gwan‐Su; Lu, Ying; Pineda‐Lucena, Antonio; Liao, Jack; Okorokov, Andrei L.; Milner, Jo; Arrowsmith, C.H.; Bochkarev, A.

doi:10.1073/pnas.0504614102

Cited by 260 publications

(384 citation statements)

References 49 publications

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“…The key residues in human p53's DNA binding core domain (including residues 102, 103, 105, 114, 115, 122 and 126) are required for interactions with RAD51, and those in the N-terminal motif (residues 37-57) are required for interactions with RPA. These key amino acid residues are absent in the ∆133p53 protein [36,37]. This might be the reason that ∆133p53 was not co-immunoprecipitated with RAD51 and RPA in this study.…”

Section: Discussionmentioning

confidence: 68%

“…Previous studies have shown that the DNA-binding core domain (94-312) of p53 is required for p53-RAD51 interactions, and its N-terminal domain (37-57) is required for p53-RPA interactions [36,37], which suggests that ∆133p53 may not be able to form a complex with these two proteins. We performed a co-immunoprecipitation (co-IP) experiment to test this hypothesis by co-transfecting HA-RAD51 or HA-RPA2 with p53, ∆133p53 or both, into H1299 cells.…”

Section: Rpamentioning

confidence: 88%

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p53 isoform Δ113p53/Δ133p53 promotes DNA double-strand break repair to protect cell from death and senescence in response to DNA damage

Gong¹,

Gong²,

Pan³

et al. 2015

Cell Res

134

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The inhibitory role of p53 in DNA double-strand break (DSB) repair seems contradictory to its tumor-suppressing property. The p53 isoform ∆113p53/∆133p53 is a p53 target gene that antagonizes p53 apoptotic activity. However, information on its functions in DNA damage repair is lacking. Here we report that ∆113p53 expression is strongly induced by γ-irradiation, but not by UV-irradiation or heat shock treatment. Strikingly, ∆113p53 promotes DNA DSB repair pathways, including homologous recombination, non-homologous end joining and single-strand annealing. To study the biological significance of ∆113p53 in promoting DNA DSB repair, we generated a zebrafish ∆113p53 M/M mutant via the transcription activator-like effector nuclease technique and found that the mutant is more sensitive to γ-irradiation. The human ortholog, ∆133p53, is also only induced by γ-irradiation and functions to promote DNA DSB repair. ∆133p53-knockdown cells were arrested at the G2 phase at the later stage in response to γ-irradiation due to a high level of unrepaired DNA DSBs, which finally led to cell senescence. Furthermore, ∆113p53/∆133p53 promotes DNA DSB repair via upregulating the transcription of repair genes rad51, lig4 and rad52 by binding to a novel type of p53-responsive element in their promoters. Our results demonstrate that ∆113p53/∆133p53 is an evolutionally conserved pro-survival factor for DNA damage stress by preventing apoptosis and promoting DNA DSB repair to inhibit cell senescence. Our data also suggest that the induction of ∆133p53 expression in normal cells or tissues provides an important tolerance marker for cancer patients to radiotherapy.

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Section: Discussionmentioning

confidence: 68%

Section: Rpamentioning

confidence: 88%

p53 isoform Δ113p53/Δ133p53 promotes DNA double-strand break repair to protect cell from death and senescence in response to DNA damage

Gong¹,

Gong²,

Pan³

et al. 2015

Cell Res

134

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“…It is unlikely that the T21A mutation creates a defect in the general conformation of the RPA2 N terminus, because this region is thought to be unstructured (16,17). It is also highly unlikely that antibody recognition of any of the RPA2 phosphoresidues is directly affected by mutation of other sites for the following reasons.…”

Section: Signal (Lane 2)mentioning

confidence: 99%

“…The N-terminal 33 residues of RPA2 undergo both cell cycle-and stress-dependent phosphorylation on approximately nine sites (Fig. 1A), which are thought to exist in an unstructured conformation (16,17). Ser 23 and Ser 29 are constitutively modified during mitosis by cyclin B-Cdk1 (18, 19) and have been suggested to be partially modified beginning at the G 1 /S boundary by the cyclin A-Cdk2 complex (18,20,21).…”

mentioning

confidence: 99%

Sequential and Synergistic Modification of Human RPA Stimulates Chromosomal DNA Repair

Anantha

Vassin

Borowiec

2007

Journal of Biological Chemistry

149

211

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The activity of human replication protein A (RPA) in DNA replication and repair is regulated by phosphorylation of the middle RPA2 subunit. It has previously been shown that up to nine different N-terminal residues are modified in vivo and in response to genotoxic stress. Using a novel antibody against phospho-Ser 29 , a moiety formed by cyclin-Cdk, we observed that RPA2 was phosphorylated during mitosis in nonstressed cells. Robust phosphorylation of Ser 29 was also seen in interphase cells following treatment with the DNA-damaging agent camptothecin, a rare example of stress stimulating the modification of a repair factor by cyclin-Cdk. RPA2 phosphorylation is regulated both in cis and trans. Cis-phosphorylation follows a preferred pathway. (That is, the initial modification of Ser 33 by ATR stimulates subsequent phosphorylation of Cdk sites Ser 23 and Ser 29 ). These events then facilitate modification of Thr 21 and extreme N-terminal sites Ser 4 and Ser 8 , probably by DNA-PK. Our data also indicate that the phosphorylation of one RPA molecule can influence the phosphorylation of other RPA molecules in trans. Cells in which endogenous RPA2 was "replaced" with a double S23A/S29A-RPA2 mutant were seen to have an abnormal cell cycle distribution both in normal and in stressed cells. Such cells also showed aberrant DNA damage-dependent RPA foci and had persistent staining of ␥H2AX following DNA damage. Our data indicate that RPA phosphorylation facilitates chromosomal DNA repair. We postulate that the RPA phosphorylation pattern provides a means to regulate the DNA repair pathway utilized.Replication protein A (RPA) 2 is a heterotrimeric singlestranded DNA-binding factor that is critical for the "three Rs" of eukaryotic DNA enzymology: DNA replication, DNA recombination, and DNA repair (1, 2). For DNA replication, the study of cellular and viral model systems demonstrates that RPA is needed both for origin denaturation and replication elongation, in the latter case to facilitate the switch from DNA polymerase ␣ to DNA polymerase ␦ during Okazaki fragment synthesis (3). RPA acts in homologous recombination (HR) to stimulate DNA annealing using physical interactions with Rad52 (4 -7) and in HR-mediated DNA repair, probably employing specific interactions with BRCA2 (8, 9). RPA is a required factor in both the nucleotide excision (10, 11) and mismatch repair pathways (12, 13) and in somatic hypermutation (14). Because of these many roles, it is of significant interest to understand the mechanisms that regulate RPA activity.Of the ϳ70-kDa (RPA1), 30-kDa (RPA2), and 14-kDa (RPA3) subunits, human RPA is subject to extensive phosphorylation on RPA2 (2) and at one RPA1 site (15). The N-terminal 33 residues of RPA2 undergo both cell cycle-and stress-dependent phosphorylation on approximately nine sites (Fig. 1A), which are thought to exist in an unstructured conformation (16,17). Ser 23 and Ser 29 are constitutively modified during mitosis by cyclin B-Cdk1 (18, 19) and have been suggested to be partially modified beginni...

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“…Given that hSSB1 regulates p53 stability and that the hSSB1 homolog RPA has been shown to interact with p53 [29][30][31][32], we examined whether hSSB1 also associates with p53. Following co-immunoprecipitation (co-IP) using Flag-agarose or Myc-agarose, a complex containing hSSB1 and p53 was clearly detected in HEK293T cells overexpressing both exogenous hSSB1 and p53 ( Figure 2A).…”

Section: Hssb1 Interacts With P53 Both In Vitro and In Vivomentioning

confidence: 99%

hSSB1 regulates both the stability and the transcriptional activity of p53

Chen

et al. 2012

Cell Res

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The tumor suppressor p53 is essential for several cellular processes that are involved in the response to diverse genotoxic stress, including cell cycle arrest, DNA repair, apoptosis and senescence. Studies of the regulation of p53 have mostly focused on its stability and transactivation; however, new regulatory molecules for p53 have also been frequently identified. Here, we report that human ssDNA binding protein SSB1 (hSSB1), a novel DNA damageassociated protein, can interact with p53 and protect p53 from ubiquitin-mediated degradation. Furthermore, hSSB1 also associates with the acetyltransferase p300 and is required for efficient transcriptional activation of the p53 target gene p21 by affecting the acetylation of p53 at lysine382. Functionally, the hSSB1 knockdown-induced abrogation of the G2/M checkpoint is partially dependent on p53 or p300. Collectively, our results indicate that hSSB1 may regulate DNA damage checkpoints by positively modulating p53 and its downstream target p21.

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Single-stranded DNA mimicry in the p53 transactivation domain interaction with replication protein A

Cited by 260 publications

References 49 publications

p53 isoform Δ113p53/Δ133p53 promotes DNA double-strand break repair to protect cell from death and senescence in response to DNA damage

p53 isoform Δ113p53/Δ133p53 promotes DNA double-strand break repair to protect cell from death and senescence in response to DNA damage

Sequential and Synergistic Modification of Human RPA Stimulates Chromosomal DNA Repair

hSSB1 regulates both the stability and the transcriptional activity of p53

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