Sirtuin 1-mediated deacetylation of XPA DNA repair protein enhances its interaction with ATR protein and promotes cAMP-induced DNA repair of UV damage

Blunted melanocortin 1 receptor (MC1R) signaling promotes melanocyte genomic instability in part by attenuating cAMP-mediated DNA repair responses, particularly nucleotide excision repair (NER), which recognizes and clears mutagenic photodamage. cAMP-enhanced NER is mediated by interactions between the ataxia telangiectasia-mutated and Rad3-related (ATR) and xeroderma pigmentosum complementation group A (XPA) proteins. We now report a critical role for sirtuin 1 (SIRT1) in regulating ATR-mediated phosphorylation of XPA. SIRT1 deacetylates XPA at residues Lys-63, Lys-67, and Lys-215 to promote interactions with ATR. Mutant XPA containing acetylation mimetics at residues Lys-63, Lys-67, and Lys-215 exhibit blunted UV-dependent ATR–XPA interactions even in the presence of cAMP signals. ATR-mediated phosphorylation of XPA on Ser-196 enhances cAMP-mediated optimization of NER and is promoted by SIRT1-mediated deacetylation of XPA on Lys-63, Lys-67, and Lys-215. Interference with ATR-mediated XPA phosphorylation at Ser-196 by persistent acetylation of XPA at Lys-63, Lys-67, and Lys-215 delays repair of UV-induced DNA damage and attenuates cAMP-enhanced NER. Our study identifies a regulatory ATR–SIRT1–XPA axis in cAMP-mediated regulation melanocyte genomic stability, involving SIRT1-mediated deacetylation (Lys-63, Lys-67, and Lys-215) and ATR-dependent phosphorylation (Ser-196) post-translational modifications of the core NER factor XPA.

Melanoma is an aggressive and life-threatening malignancy whose incidence has risen steadily over the past several decades (1). UV radiation is the most important environmental risk factor for cutaneous melanoma, as evidenced by the abundance of "UV signature" pyrimidine transition mutations in melanoma (2,3) and the association between such mutations and disease progression (4). A major inherited risk factor for UV skin sensitivity and melanoma is loss of signaling function of the melanocortin 1 receptor (MC1R), 4 a G s protein-coupled receptor that signals via the second messenger cAMP (5)(6)(7)(8). Individuals with germline variant MC1R alleles that diminish cAMP signaling tend to be fair in complexion and burn rather than tan with UV exposure (9,10). Such individuals have a lifetime melanoma risk that averages roughly 4-fold higher than MC1R-intact counterparts (11,12). Indeed, somatic and UV signature mutations were higher in melanomas isolated from persons with heterozygous or homozygous MC1R loss as compared with WT MC1R individuals (13). Thus, the MC1R is a major determinant of melanocytic responses to UV damage. In addition to its role in promoting melanin synthesis (14 -16), a crucial function of MC1R is to enhance nucleotide excision repair (NER) (6,17,18), the principal DNA repair pathway active against UV-induced DNA damage (19).
Genomic integrity is challenged by UV exposure, which generates DNA lesions that if not repaired can give rise to mutations. Ataxia telangiectasia-mutated and Rad3-related (ATR) is an essential regulator of the DNA damage response (20 -23). Upon sensing DNA damage, ATR initiates a signaling cascade via phosphorylation of downstream protein substrates, which ultimately leads to a variety of damage responses, including cell cycle arrest (22,24). Recently, ATR has been identified as a direct participant in NER (25,26), a coordinated repair process mediated by the xeroderma pigmentosum complementation group proteins, which include XPA through XPG. XPA is indispensable in this pathway and has reported functions in DNA damage verification, stabilization of repair intermediates, and positioning of NER factors (19,(27)(28)(29). We and others have documented an NER-relevant ATR-XPA interaction in response to UV (17, 30 -34). We have further linked cAMP signaling to this interaction through a phosphorylation event on ATR at Ser-435, which accelerates repair of UV-induced DNA damage (17).
The silent mating-type information regulation 2 homolog 1 (sirtuin 1; SIRT1) is a nuclear-localized member of the sirtuin family. SIRT1 regulates a variety of cellular processes such as metabolism (35), oxidative stress (36), and DNA repair (37). Emerging evidence highlights an important function of SIRT1 in NER by catalyzing the deacetylation of the NER proteins XPA (38 -40) and replication protein A (RPA) (41). In addition, SIRT1 enhances XPC expression by reducing AKT-dependent nuclear localization of the transcription repressor of XPC (37,42). Despite progress in understanding the role of SIRT1 in NER, the molecular mechanisms by which SIRT1 becomes activated in response to UV and the influence of post-translational modifications, such as acetylation in the regulation of ATR-XPA interactions, remain to be elucidated.
Herein, we present evidence that SIRT1 participates in cAMP-enhanced NER and that SIRT1 deacetylates XPA at the Lys-215 residue, which has not been previously shown. UV exposure promotes ATR-directed SIRT1 localization to sites of DNA damage. Mutant XPA-containing acetylation mimetics at residues Lys-63, Lys-67, and Lys-215 impair the ATR-XPA interaction and blunt NER. Moreover, SIRT1-dependent deacetylation of XPA enhances the ability of ATR to phosphorylate XPA at Ser-196, a molecular event critical to cAMP-enhanced NER. Our study supports a model of cAMP-DNA repair enhancement that utilizes functional cross-talk between deacetylation and phosphorylation and identifies a regulatory ATR-SIRT1-XPA axis in the NER pathway.

ATR promotes SIRT1 localization to sites of UV-induced DNA damage
Our previous work documented a cAMP-dependent pathway that regulates NER pertinent to MC1R signaling in melanocytes. Briefly, we found that in the context of cell damage and cAMP activation, PKA phosphorylates ATR (17). PKA-mediated ATR phosphorylation on Ser-435 promotes interactions between XPA and ATR and accelerates their recruitment to UV photodamage (17) or platinum adducts (43). Because our earlier work documented that cAMP-enhanced NER depended on ATR-XPA interactions (17), we considered whether other post-translational modifications in ATR or XPA might regulate this pathway. Since deacetylation of XPA by SIRT1 was reported to be an important regulator of NER following UV radiation (38), we considered whether SIRT1 is involved in cAMP-enhanced NER. To explore whether an ATR-SIRT1 axis may exist, we tested whether ATR regulates co-localization of SIRT1 at sites of UV damage. We documented a robust interaction between SIRT1 and cyclobutane pyrimidine dimers (CPDs) in UV-irradiated A375 melanoma cells (Fig. 1, A and B). However, these interactions were dramatically decreased with expression of a kinase-dead form of ATR compared with WTexpressing ATR (Fig. 1A) or expression of ATR-P2445L, a clinically-relevant inactive ATR mutant identified from the Cancer Genome Atlas database with a base substitution in the kinase domain (Fig. 1, A and B) (44). The specificity of the assay was confirmed by showing lack of nonspecific staining in the negative controls, displayed by the omission of either CPD or SIRT1 antibody alone (Fig. S1). Together, these results suggest that ATR promotes localization of SIRT1 to sites of UV-induced DNA damage.
Since prior work documented UV-dependent interactions between ATR and XPA (17, 32-34, 45, 46), our findings of an ATR-dependent translocation of SIRT1 to UV photodamage prompted us to investigate whether ATR might regulate SIRT1's association with XPA. XPA is a crucial factor in the repair of UV DNA damage and has been previously identified as an important substrate of SIRT1 (38 -40). Therefore, we assessed whether the kinase function of ATR affected interactions between SIRT and XPA (Fig. 1C). We noted robust interaction by co-immunoprecipitation (co-IP) between SIRT1 and XPA in UV-irradiated A375 melanoma cells. However, their interaction was dramatically attenuated by the addition of either a kinase-dead ATR or ATR-P2445L (Fig. 1C). This suggests ATR kinase function is critical to XPA-SIRT1 interaction following UV. In addition, ATR-KD and ATR-P2445L appeared to act in a dominant-negative manner to attenuate native ATR function. To characterize this further, we examined the effect of ATR-KD and ATR-P2445L on Chk1 phosphorylation at Ser-345. As expected, expression of ATR-WT resulted in robust Chk1 phosphorylation (Fig. S2). However, levels of Chk1-pSer-345 were decreased with expression of a kinasedead form of ATR compared with WT-expressing ATR, suggesting that kinase-deficient ATR constructs function in a dominant-negative manner (Fig. S2).
Realizing that XPA deacetylation by SIRT1 optimizes NER (38,40,47), we evaluated the impact of ATR on the acetylation status of XPA by generating SIRT1 CRISPR/Cas9-deleted A375 melanoma cells and testing the acetylation status of XPA. We observed that in the absence of SIRT1, XPA acetylation was unchanged in response to UV; however, with native SIRT expression, UV caused a decrease in acetylated XPA levels ( Fig.  1D). Moreover, we conclude that UV-dependent SIRT1-mediated XPA deacetylation is ATR-dependent, because expression of ATR-KD or ATR-P2445L ablated the SIRT1-dependent deacetylation of XPA following UV-induced DNA damage (Fig.  1D). These data collectively support a UV-induced ATR-SIRT-XPA axis, wherein ATR function is needed for SIRT1 localization to sites of photodamage, association with XPA, and deacetylation of XPA following UV.
To further investigate whether ATR is the predominant phosphatidylinositol 3Ј-kinase-related kinase (PIKK) that controls SIRT1 localization to UV-DNA damage, we probed for SIRT1 in UV-exposed chromatin fractions in the presence of other PIKK family members ATR, ATM, or DNA-PK inhibitors. We determined that SIRT1 localization is reliant upon ATR but does not require ATM or DNA-PK (Fig. S3A). It is unclear how ATR directs SIRT1 to sites of UV DNA damage. To determine whether SIRT1 is a direct phosphorylation target for ATR, we performed co-IPs with an anti-SIRT1 antibody and SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair immunoblotted with an antibody that detects ATR/ATM-phosphorylated SQ sites. Our data indicate SIRT1 is not a direct target of ATR (Fig. S3B).
To provide a greater understanding of the clinical relevance of ATR and SIRT1 in melanoma mutagenesis, we analyzed whole-exome sequence data from melanoma samples obtained from The Cancer Genome Atlas. We identified a higher mutational frequency in melanomas that contain mutations in either ATR or SIRT1 compared with melanomas that express their respective WT proteins (Fig. S4, A and B). Furthermore, mutant ATR-and SIRT1-expressing melanomas are enriched for total mutations at UV-sensitive dipyrimidine sites (i.e. CC-TT), a mutation signature linked to UV exposure (Fig. S4, C and D). Together, these data are consistent in implicating an important role for ATR and SIRT1 in preventing melanoma mutagenesis by UV damage.

UV-induced XPA-ATR interaction is promoted by SIRT1 and enhanced by cAMP
Having established that SIRT1 deacetylates XPA in an ATRdependent manner and based on our prior findings document- or mock treatment, co-IP with anti-acetylation (Ac-K) and immunoblot with anti-XPA were performed. Input represents 10% of total cellular level.

SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair
ing cAMP signaling in regulating XPA-ATR interactions (17), we next examined the possibility that cAMP might regulate SIRT1 activity. We first tested whether activation of cAMP signaling would impact intrinsic SIRT1 enzymatic activity. To pharmacologically up-regulate cAMP signaling, as we have used previously (17), we treated A375 cells with forskolin, an agent that potently induces cAMP by directly activating adenylyl cyclase. We performed in vitro deacetylation assays using a SIRT1 fluoro-substrate peptide ( Fig. S5) with lysate isolated from cells treated with either forskolin or vehicle control. Forskolin treatment increased SIRT1 deacetylase function by roughly 2-fold, which was lost in the presence of either the PKA inhibitor H-89 or the selective SIRT1 inhibitor EX 527. In contrast, UV exposure did not significantly modulate SIRT1 activity above baseline levels and did not significantly attenuate forskolin-induced SIRT1 activation (Fig. S5). These data suggest cAMP up-regulates SIRT1 deacetylase activity through a PKAdependent mechanism independently of UV exposure or ATRkinase activity.
To assess whether SIRT1 and cAMP signaling impact NER, we investigated the ability of SIRT1 to regulate repair of the major form of UV-induced DNA damage, CPDs. To do so, we deleted SIRT1 by CRISPR/Cas9 genome editing in A375 cells and measured CPD repair in the presence or absence of SIRT1 in cells exposed to either UV alone or to UV and forskolin. Treatment of SIRT1-WT-expressing cells with forskolin significantly enhanced the repair of CPD at 24 and 48 h postdamage ( Fig. 2A). However, in the absence of SIRT1-WT, both the basal level and forskolin-mediated repair exhibited some degree of delayed repair of UV-induced damage relative to WT-SIRT1-expressing cells. We further delineated the impact of lowering cellular cAMP below basal levels ( Fig. S6A). Treatment of a combination of an PKA inhibitor (H-89; PKAi) and an adenylate cyclase inhibitor 2Ј,3Ј-deoxyadenosine (2Ј,5Ј-dideoxyadenosine), reduced NER activity below basal levels ( Fig.  S6B). Together, our data suggest that SIRT1 and cAMP are important components for both basal repair capacity and cAMP-enhanced repair of UV-induced DNA damage.
We next investigated the ability of SIRT1 to regulate ATR and XPA association in the context of the cell. We deleted SIRT1 by CRISPR/Cas9 genome editing in A375 cells and measured ATR-XPA interactions in the presence or absence of SIRT1 in cells exposed to either UV alone or to UV and forskolin. We observed minimal interaction between ATR and XPA in the SIRT1-deleted background basally or with UV and/or forskolin treatment-assessed proximity ligation assay (PLA) (Fig. 2, B and C, and Fig. S7). In contrast, in A375 cells with SIRT1 endogenously expressed (Fig. S7) or in CRISPR-SIRT1 A375 cells reconstituted with SIRT1 by transfection (Fig. 2, B and C), we noted robust induction of ATR-XPA association, and the effect was enhanced by cAMP stimulation by forskolin. The specificity of the proximity ligation assay was confirmed by showing lack of nonspecific staining in the negative controls, displayed by the omission of either ATR or XPA antibody alone (Fig. S8). These experiments confirmed that expression of SIRT1 enhances the physical interaction between ATR and XPA in the context of UV damage and that cAMP signaling augments their association in a SIRT1-dependent manner.
The immunoprecipitated XPA was rinsed with high salt (0.5 M) to remove low-affinity binding proteins and then incubated with recombinant CREB-binding protein (CBP), an established XPA-acetylating protein (38), followed by incubation with recombinant SIRT1. Acetylation levels were analyzed by Western blotting with anti-acetylated lysine (anti-AcK) (Fig. 3, B and C). Incubation with CBP enhanced acetylation within both Nand C-terminal XPA mutants, and addition of SIRT1 resulted in ϳ20 -30% decrease in acetylation in both mutants (Fig. 3C). These experiments demonstrate that XPA has the potential to be acetylated at both the N-and C-terminal domains and that XPA is a substrate for both CBP-mediated acetylation and SIRT-mediated deacetylation.
To identify important acetylation sites on XPA, we examined specific acetyl-lysine XPA targets using GPS-PAIL 2.0 acetylation prediction analysis. The internal residues of XPA predicted as highly probable reversible acetyl-lysines were Lys-63, Lys-67, and Lys-215. Lysines 63 and 67 were previously identified as substrates for SIRT1 deacetylation (38); however, Lys-215 has yet to be investigated, and the impact of cAMP signaling on modification of these three residues is unknown. To determine the functional impact of these sites in the context of UV-induced DNA damage and cAMP signaling, we deleted XPA from A375 cells by CRISPR/Cas9 genome editing. Using these XPAnull cells, we reconstituted them either with XPA-WT or with K63Q, K67Q, or K215Q mutants to mimic acetylation at Lys-63, Lys-67, or Lys-215, respectively. Cells were exposed to either UV or forskolin alone or a combination of UV and forskolin. PLA (Fig. 3D) confirmed that the acetylation-mimicking mutants individually demonstrated reduced interactions between ATR and XPA in response to UV and cAMP signaling. Furthermore, as acetylation/deacetylation Lys-215 pertinent to XPA function has not been described previously, we assessed whether SIRT1 may be a direct deacetylase for the AcK-215 substrate (Fig. S9A). We tested the ability of SIRT1 to deacetylate a short peptide containing an acetylated Lys-215 and surrounding residues in a cell-free system. The addition of recombinant SIRT1 promoted robust and direct deacetylation of Lys-215, which was ablated in the presence of EX 527, a selective SIRT1 inhibitor. Notably, lysine 215 exists as an acetylation consensus sequence and is highly conserved across species (Fig.  S9B). Collectively, these results indicate residues Lys-63, Lys-67, and Lys-215 of XPA are direct deacetylation targets of SIRT1 and that interference with the deacetylation of any of the three SIRT1 target lysine residues results in a dramatic reduction in UV-dependent and cAMP-enhanced ATR-XPA interactions.

SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair Deacetylation of XPA enhances ATR-mediated phosphorylation of Ser-196
As ATR-mediated phosphorylation of Ser-196 in XPA regulates the repair of UV-induced DNA damage (33,46), we next explored whether cAMP signaling impacts ATR-mediated XPA-pSer-196 generation and assessed whether SIRT1-medi-ated deacetylation of XPA might affect XPA's ability to be phosphorylated on Ser-196 by ATR. HCT116 ATR flox/Ϫ cells (48) containing one conditional ATR allele was deleted by infecting with adenovirus encoding the Cre recombinase. ATR was reintroduced by transfection and treated with UV and/or forskolin and immunoblotted with a phospho-specific antibody gener-

SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair
ated phosphorylation of ATR on the Ser-435 residue may facilitate its subsequent ability to phosphorylate (and activate) XPA at position Ser-196. Furthermore, reducing cellular cAMP below basal levels, by treating cells with both a PKA inhibitor and an adenylate cyclase inhibitor, diminished the levels of UVinduced XPA-pSer-196, below basal levels (Fig. S6D).
As we now had evidence to suggest that SIRT1 activity regulates ATR-mediated XPA phosphorylation in the context of cAMP signaling (e.g. ATR-pSer-435), we next tested whether SIRT1-mediated deacetylation of XPA on Lys-63, Lys-67, and/or Lys-215 is necessary for ATR-mediated XPA-pS196 generation. For these experiments, we used XPA CRISPR/ Cas9-deleted A375 cells either complemented with XPA-WT or with one of the following single XPA mutants: K63Q, K67Q, or K215Q (Fig. 4B). Cells were exposed to either UV or forskolin alone or a combination of UV and forskolin. Co-IP experiments confirmed that the acetylation-mimicking mutants demonstrated a dramatic reduction in XPA-pSer-196 accumulation following UV and little-to-no enhancement by cAMP signaling.
As it has been previously shown that ATR phosphorylates XPA at Ser-196 to enhance XPA stability (46), we chose to examine the possibility that XPA-pSer-196 might also regulate SIRT1 protein stability. To achieve this, we utilized CRIPSR/ Cas9-deleted XPA cells expressing either XPA-WT or XPA-S916A (Fig. S10A) and measured relative SIRT1 protein levels for 9 h after UV treatment, in the presence of cycloheximide. Cells that expressed ATR-S196A demonstrated a reduced halflife of SIRT1 compared with XPA-WT (Fig. S10B), implying that the phosphorylation status of Ser-196 impacts SIRT1 stabilization after UV exposure. Taken together, these results suggest that SIRT1 and ATR are important factors in phosphorylation of XPA at Ser-196, an event known to increase its function in the context of NER. These data further show that cAMP signaling augments XPA-pSer-196 and that deacetylation of XPA promotes phosphorylation of XPA at Ser-196 by ATR. Furthermore, XPA-pSer-196 enhances the stability of SIRT1 following UV DNA damage.

XPA acetylation mimetics K63Q, K67Q, and K215Q interfere with cAMP-mediated enhancement of NER
To assess the functional significance of XPA deacetylation at Lys-63, Lys-67, and Lys-215 and phosphorylation at Ser-196 in cAMP-enhanced DNA repair, we measured the effect of forskolin on clearance of CPDs in XPA CRISPR/Cas9-deleted A375 cells that were transfected with either XPAϪWT, single acetylation mimetic mutants (K63Q, K67Q, or K215Q), or a compound mutant of the three lysines (K63Q/K67Q/K215Q) (Fig.  S11A). Treatment of XPA-WT-expressing cells with forskolin significantly enhanced the repair of CPD at 24 and 48 h postdamage compared with vehicle-treated cells (Fig. S11B). Each of the deacetylation mutants exhibited some degree of delayed repair of UV-induced damage relative to WT XPA and reduced the cAMP benefit in damage removal, as measured by repair kinetics (Fig. S11, B-F) and fold change in the time taken to repair half of the initial DNA damage (repair t1 ⁄ 2 ) (Fig. 5, A and  B). These data strongly suggest that deacetylation of XPA's Lys-63, Lys-67, and Lys-215 sites are important for cAMP-enhanced repair of UV-induced DNA damage.
As shown in Fig. 5, the XPA-acetylation mimicking mutants (K63Q, K67Q, or K215Q) reduced UV-and cAMP-induced XPA phosphorylation at Ser-196. As this ATR-mediated phosphorylation is an important event in NER (31), we explored the importance of XPA-pSer-196 in cAMP-enhanced repair. We measured the effect of forskolin on clearance of CPDs in XPA CRISPR/Cas9-deleted A375 cells that were either transfected with a compound acetylation mimetic mutant of the three lysine (K63Q/K67Q/K215Q)-acetylation mimetic containing either S196A or S196D. The expression of the phosphonegative construct XPA-K63Q/67Q/215Q/S196A exhibited blunted repair of UV-induced damage relative to WT XPA and did not exhibit any benefit from forskolin treatment (Fig. 5, A  and B, and Fig. S11G). In contrast, cells expressing the phosphomimetic construct XPA-K63Q/K67Q/K215Q/S196D demonstrated efficient repair of CPDs in both vehicle-and forskolin-treated cells (Fig. 5, A and B, and Fig. S4H). Furthermore, to test whether XPA-K63Q/K67Q/K215Q/S196D can bypass SIRT1 or ATR, we treated A375 cells with either vehicle (Fig.  S12A) EX 527 (SIRTi) (Fig. S12B), or VE-821 (ATRi) (Fig. S12C) in cells transfected with either XPA-WT or XPA-K63Q/ K67Q/K215Q/S196D. The addition of XPA-K63Q/K67Q/ K215Q/S196D expression enhanced the repair kinetics compared with XPA-WT (Fig. S12A). The addition of EX 527 only inhibited the repair of XPA-WT-expressing cells but did not impact the repair kinetics of the XPA-K63Q/K67Q/K215Q/ S196D-expressing cells (Fig. S12B). Treatment with VE-821 impaired the removal of photoproducts in both the XPA-WT and XPA-K63Q/K67Q/K215Q/S196D-expressing cells. This suggests that ATR provides at least another function (in addition to XPA-Ser-196 phosphorylation) involved in regulating the ATR-SIRT1-XPA axis following UV treatment. Taken together, these data indicate that kinase activities of ATR and SIRT1 functionally cooperate to regulate NER by dynamically controlling post-translational modifications within XPA that reduce genomic UV damage downstream of MC1R-cAMP signaling in melanocytes. Moreover, it appears that SIRT1-mediated deacetylation of Lys-63, Lys-67, and Lys-215 promotes ATR-mediated phosphorylation at Ser-196 to enhance XPA's function in NER.

Discussion
Inherited dysfunction of the MC1R, a G s protein-coupled receptor that signals through cAMP, is a bona fide melanoma risk factor (11,13). We and others have documented that MC1R signaling or cAMP induction promotes clearance of DNA damage by enhancing DNA repair (6,8,17,18,49,50). Our previous work identified that in the context of cellular damage, PKA phosphorylates ATR at Ser-435 through the involvement of the AKAP12 scaffolding protein (17,51). Subsequently, enhanced levels of ATR-pSer-435 associate with XPA at sites of UV photodamage and promote NER (17,51). Our study supports a model of cAMP-DNA repair enhancement that involves a functional cross-talk between acetylation and phosphorylation and identifies a regulatory ATR-SIRT1-XPA axis in the NER pathway.
Acetylation at lysine residues and its removal have emerged as critical post-translational modifications that enable fine-

SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair
tuning of UV-induced DNA damage repair response (41,52). We provide evidence that SIRT1 acts as a direct positive regulator of NER, supporting previous studies demonstrating SIRT1 in UV (37,38,41) and cisplatin (40) damage/repair responses. It is important to note, however, that SIRT1 may impact NER by more than one mechanism. Work by He and co-workers (37) demonstrated that SIRT1 inhibition impairs NER by suppressing transcription of the NER-initiating factor XPC, and it is possible that SIRT1 may regulate NER proteins using both transcriptional and nontranscriptional mechanisms (37,38,40). SIRT1's influence on NER may be complex, because others found that SIRT1 negatively regulates the interaction between RPA70 and XPA by deacetylating RPA post-repair (41). The function of SIRT1 in DNA repair may be influenced by multiple factors, including cell type, protein interactions, repair context, and type or extent of damage (37-40, 53). A context-specific role for SIRT1 in NER is not surprising, as tightly regulated control of protein deacetylation is required to prevent incorrect protein-protein binding at inappropriate times, which may obstruct normal DNA repair functions. Our data suggest that in the context of melanocytes, cAMP signaling acts as an activating factor for SIRT1 catalytic activity, which may prime the cell to more effectively deal with UV exposure.
We further identified that SIRT1-mediated deacetylation of XPA promotes the interaction between ATR and XPA. In addition to deacetylation at the Lys-63 and Lys-67 sites (previously reported to alter XPA's interaction with RPA32 (38)), SIRT1 also deacetylates XPA on the Lys-215 residue. We provide evidence that Lys-215, which is located within the ATR-binding region of XPA (54), is relevant to the XPA-ATR association. Our cell-free experiments documented that CBP acetylates XPA at the Lys-215 site; however, we cannot rule out the possibility that other acetyltransferases are able to modify Lys-215. A previous study incubating the histone acetyltransferase

SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair
domain of p300 with XPA did not detect acetylation past amino acid 97 on XPA (38). This suggests XPA may be a substrate for multiple acetyltransferases and/or a full-length p300 protein may be required to enable appropriate interactions with XPA. Our observations, taken together with previous studies (38), suggest that XPA acetylation appears to play a negative role in regulating XPA-protein interactions to attenuate NER capacity. Our data further support previous studies that have demonstrated expression of kinase-dead or reduced kinase forms of ATR result in a dominant-negative phenotype (55)(56)(57). In our case, we show a dominant-negative impact on the SIRT1 and XPA interaction. Expression of kinase-dead mutant forms of ATR (55, 58 -61) have been previously shown to have a dominant-negative impact on Chk1 phosphorylation (55)(56)(57). This phenotype could result from the fact that ATR exists in a multiprotein complex (60). Thus, a mixed complex existing of both mutant ATR and ATR-WT may impart dominant-negative effects on kinase activation and/or sequestration of proteins in the ATR-signaling pathway.
Our study provides evidence that ATR has at least two functions involved in regulating the ATR-SIRT1-XPA axis following UV treatment. One is that ATR acts upstream of SIRT1 to enhance SIRT1-DNA damage association and the other is that ATR promotes phosphorylation of XPA at Ser-196. As phosphatidylinositol 3Ј-kinase-related kinases (such as ATR and ATM) are activated in response to DNA damage and subsequently phosphorylate target proteins (62), it is plausible that ATR can facilitate a signaling cascade in multiple ways. A previous study described a multifunctional response of ATM in response to DNA damage. SIRT1 was recruited to doublestrand breaks in an ATM-mediated manner, which in turn facilitated SIRT1 to promote the kinase activity of ATM (63). The signaling events required to localize SIRT1 to UV and double-strand break damage and repair proteins remain to be fully elucidated.
SIRT1-mediated deacetylation of XPA dramatically increased phosphorylation of XPA at Ser-196. ATR has been previously identified as the kinase responsible for this modification (31), and our data support this finding because in the absence of ATR-WT or in the presence of an ATR-kinase inhibitor XPA-pSer-196 levels are severely diminished. We reason that SIRT1mediated deacetylation of XPA at Lys-63, Lys-67, and Lys-215 may promote conformational changes in XPA to favor phosphorylation of Ser-196 by ATR. In agreement with other studies (31,46,64), we found that the phosphorylation of Ser-196 on XPA enhances NER, and we extend their observations by placing the post-translational modification at Ser-196 squarely in the mechanism by which cAMP enhances NER. Interestingly, enhanced repair kinetics afforded by expression of the XPA-K63Q/K67Q/K215Q/S196D were lost in the presence of an ATR kinase inhibitor, providing evidence that ATR provides other functions(s) in addition to phosphorylation of XPA at Ser-196.
We previously linked cAMP signaling to the ATR-XPA interaction through PKA-mediated phosphorylation of ATR at Ser-435 (17). In our current study, we found that phosphorylation of ATR at Ser-435 facilitates cAMP-enhanced accumula-tion of XPA-pSer-196. However, it is unclear how ATR-pSer-435 enhances levels of XPA-pSer-196. One explanation is that ATR-pSer-435 may be able to stabilize interactions with XPA via a conformational change to aid the ability of ATR to phosphorylate XPA. This hypothesis is supported by a recent study that showed phosphorylation at a nearby serine (Ser-428) results in a conformational change in the N-terminal region of ATR (65). It is also possible that Ser-435 phosphorylation may influence the structure of ATR to enable a greater domain accessibility between ATR and XPA. In any case, our findings suggest that phosphorylation of ATR at Ser-435 is an important event that facilitates cAMP-enhanced XPA-pSer-196 accumulation. In addition, our data suggest ATR might regulate the SIRT1-XPA interaction by providing a larger pool of SIRT1 to be available to interact with XPA.
Our studies support the possibility that pharmacological cAMP activation may be a useful preventative strategy for enhanced melanocyte genomic stability. Conversely, as NER activity can be impaired through post-translational modifications on XPA (e.g. acetylation of Lys-63, Lys-65, and/or Lys-215), manipulation of these modifications via pharmacological targeting may selectively inhibit DNA repair activities to develop novel melanoma therapeutics.

UV exposure
UV radiation was measured via a Model IL1400A handheld flash measurement photometer (International Light) with UV lamps emitting a spectral output in the 290 -400 nm range SIRT1 deacetylation of XPA mediates cAMP-enhanced DNA repair (72% UVB, 27% UVA, and Ͻ0.01% UVC) (UVP, Upland, CA). UV exposure was performed when media were removed from the cells. A dose of 10 J/m 2 of UVB was delivered to cell cultures.

Subcellular fractionation, immunoprecipitation, and immunoblotting
Subcellular fractionation was performed with ϳ1 ϫ 10 6 cells. Nuclear extraction was performed using manufacturer's instructions (Active Motif). Immunoprecipitations were performed with overnight incubations of the primary antibody at 4°C, followed by a 3-h incubation with protein A beads (GE Healthcare). The precipitates were then washed with PBS and boiled in 2ϫ SDS loading buffer. Samples were resolved on SDS-PAGE, transferred to a polyvinylidene difluoride filter membrane, and immunoblotted with the indicated antibodies. For Western blotting acquisition analysis, Storm860 was used; Western blottings were scanned using channel 2 with blue excitation at 450 nm and emission at 520 nm; sensitivity was set to normal, and photomultiplier was voltage set to 400 V.

Immunofluorescence and proximity ligation assay
Following UV-induced DNA damage, cells were either processed immediately or medium was replaced, and DNA repair was allowed for the indicated periods. Following fixation in 4% paraformaldehyde and cell permeabilization with 0.3% Triton X-100, cells were blocked overnight in 10% donkey serum at 4°C. Proximity ligation assay (DuoLink, Sigma) was performed using the manufacturer's instructions. All fluorescence images were obtained using a Leica DMI 6000 confocal microscope using ϫ100 objective (1.4 numerical aperture) with LAS AF 2.7.2.9586 software (Leica Application Suite Advanced Fluorescence). Maximum intensity images from focal plane z-stacks (spaced 0.2 m apart) were acquired and deconvoluted. Fluorescent signals were counted and expressed as either foci number or percent nuclear stain.

Peptide deacetylation assay
Acetylation assays were performed using a biotinylated peptide substrate that had been acetylated at Lys-215 of XPA and surrounding residues, RQENRRMKQRRF (all other lysines were changed to arginine, to confirm specificity to Lys-215) (Genscript), and bound to streptavidin-coated 96-well plates (ThermoFisher Scientific). Recombinant SIRT1 was incubated for 10 min at 30°C. The reaction buffer consisted of 50 mM Tris-HCl (pH 9.0), 50 mM NaCl, 4 mM MgCl 2 , 0.1 mM DTT, 0.01% Nonidet P-40, and 100 M NAD. After indicated treatments of either recombinant SIRT1 and EX 527, wells were washed with 40 mM Tris-HCl (pH 7.5) containing 0.01% BSA (wash buffer) followed by fixation in 4% paraformaldehyde. After three washes, 2 g of anti-acetyl-lysine was added for 1 h. Detection was accomplished using an HRP-conjugated antirabbit secondary antibody (Abcam) for 1 h followed by the addition of 1-Step Ultra TMB ELISA Substrate (Pierce), and absorbance was measured at 400 nm.

DNA repair kinetics
Cells were exposed to 10 J/m 2 of UVB, and immunoslot blots or protamine sulfate-coated ELISA plates were performed with CPD antibodies as described previously (17). Detection was accomplished using an HRP-conjugated anti-rabbit secondary antibody (Abcam) for 1 h followed by the addition of 1-Step Ultra TMB ELISA Substrate (Pierce) to each well, and absorbance was measured at 400 nm. All repair data are expressed as percent repair compared with initial damage.

Statistical analysis
Student's t tests and one-way ANOVA were performed with GraphPad Prism 5.0. Data were considered statistically significant if p values were less than 0.05.