Central role for the XRCC1 BRCT I domain in mammalian DNA single-strand break repair

The DNA single-strand break repair (SSBR) protein XRCC1 is required for genetic stability and for embryonic viability. XRCC1 possesses two BRCA1 carboxyl-terminal (BRCT) protein interaction domains, denoted BRCT I and II. BRCT II is required for SSBR during G(1) but is dispensable for this process during S/G(2) and consequently for cell survival following DNA alkylation. Little is known about BRCT I, but this domain has attracted considerable interest because it is the site of a genetic polymorphism that epidemiological studies have associated with altered cancer risk. We report that the BRCT I domain comprises the evolutionarily conserved core of XRCC1 and that this domain is required for efficient SSBR during both G(1) and S/G(2) cell cycle phases and for cell survival following treatment with methyl methanesulfonate. However, the naturally occurring human polymorphism in BRCT I supported XRCC1-dependent SSBR and cell survival after DNA alkylation equally well. We conclude that while the BRCT I domain is critical for XRCC1 to maintain genetic integrity and cell survival, the polymorphism does not impact significantly on this function and therefore is unlikely to impact significantly on susceptibility to cancer.     

Interference of papillomavirus E6 protein with single-strand break repair by interaction with XRCC1

XRCC1 protein is required for the repair of DNA single-strand breaks and genetic stability, and is essential for viability in mammals. XRCC1 functions as a scaffold protein by interacting and modulating polypeptide components of the single-strand break repair machinery, including AP endonuclease-1, DNA ligase IIIalpha, poly (ADP-ribose) polymerase, DNA polymerase beta and human polynucleotide kinase. We show here that the E6 protein of human papillomavirus type 1, 8 and 16 directly binds XRCC1. When tested in CHO derived XRCC1 'knock out' EM9 cells, co-expression of human papillomavirus 16 E6 with human XRCC1 reduced the ability of the latter protein to correct the methyl methane sulfate sensitivity of XRCC1 mutant CHO cell line EM9. These data identify a novel link between small DNA tumour viruses and DNA repair pathways, and suggest a novel explanation for the development of genomic instability in tissue cells persistently infected with papillomaviruses.     

XRCC1 is required for DNA single-strand break repair in human cells

The X-ray repair cross complementing 1 (XRCC1) protein is required for viability and efficient repair of DNA single-strand breaks (SSBs) in rodents. XRCC1-deficient mouse or hamster cells are hypersensitive to DNA damaging agents generating SSBs and display genetic instability after such DNA damage. The presence of certain polymorphisms in the human XRCC1 gene has been associated with altered cancer risk, but the role of XRCC1 in SSB repair (SSBR) in human cells is poorly defined. To elucidate this role, we used RNA interference to modulate XRCC1 protein levels in human cell lines. A reduction in XRCC1 protein levels resulted in decreased SSBR capacity as measured by the comet assay and intracellular NAD(P)H levels, hypersensitivity to the cell killing effects of the DNA damaging agents methyl methanesulfonate (MMS), hydrogen peroxide and ionizing radiation and enhanced formation of micronuclei following exposure to MMS. Lowered XRCC1 protein levels were also associated with a significant delay in S-phase progression after exposure to MMS. These data clearly demonstrate that XRCC1 is required for efficient SSBR and genomic stability in human cells.     

Solution structure of the COMMD1 N-terminal domain

COMMD1 is the prototype of a new protein family that plays a role in several important cellular processes, including NF-kappaB signaling, sodium transport, and copper metabolism. The COMMD proteins interact with one another via a conserved C-terminal domain, whereas distinct functions are predicted to result from a variable N-terminal domain. The COMMD proteins have not been characterized biochemically or structurally. Here, we present the solution structure of the N-terminal domain of COMMD1 (N-COMMD1, residues 1-108). This domain adopts an alpha-helical structure that bears little resemblance to any other helical protein. The compact nature of N-COMMD1 suggests that full-length COMMD proteins are modular, consistent with specific functional properties for each domain. Interactions between N-COMMD1 and partner proteins may occur via complementary electrostatic surfaces. These data provide a new foundation for biochemical characterization of COMMD proteins and for probing COMMD1 protein-protein interactions at the molecular level.     

XRCC1 and DNA polymerase beta interaction contributes to cellular alkylating-agent resistance and single-strand break repair

X-ray cross complementing 1 (XRCC1) protein has been suggested to bind to DNA single-strand breaks (SSBs) and organize protein interactions that facilitate efficient DNA repair. Using four site-specifically modified human XRCC1 mutant expression systems and functional complementation assays in Chinese hamster ovary (CHO) XRCC1-deficient EM9 cells, we evaluated the cellular contributions of XRCC1s proposed N-terminal domain (NTD) DNA binding and DNA polymerase beta (POLbeta) interaction activities. Results within demonstrate that the interaction with POLbeta is biologically important for alkylating agent resistance and SSB repair, whereas the proposed DNA binding function is not critical to these phenotypes. Our data favor a model where the interaction of XRCC1 with POLbeta contributes to efficient DNA repair in vivo, whereas its interactions with target DNA is biologically less relevant.     

XRCC1 and DNA strand break repair

DNA single-strand breaks can arise indirectly, as normal intermediates of DNA base excision repair, or directly from damage to deoxyribose. Because single-strand breaks are induced by endogenous reactive molecules such as reactive oxygen species, these lesions pose a continuous threat to genetic integrity. XRCC1 protein plays a major role in facilitating the repair of single-strand breaks in mammalian cells, via an ability to interact with multiple enzymatic components of repair reactions. Here, the protein-protein interactions facilitated by XRCC1, and the repair processes in which these interactions operate, are reviewed. Models for the repair of single-strand breaks during base excision repair and at direct breaks are presented.     

E2F1 is involved in DNA single-strand break repair through cell-cycle-dependent upregulation of XRCC1 expression

The X-ray repair cross complementing group 1 (XRCC1) protein is involved in DNA base excision repair and its expression varies during the cell cycle. Although studies have demonstrated that rapid XRCC1-dependent single-strand break repair (SSBR) takes place specifically during S/G(2) phases, it remains unclear how it is regulated during the cell cycle. We found that XRCC1 is a direct regulatory target of E2F1 and further investigated the role of XRCC1 in DNA repair during the cell cycle. Saos2 primary osteosarcoma cells stably transfected with inducible E2F1-wt or mutant E2F1-132E were treated with hydroxurea (HU) for 36h and were subsequently withdrawn HU for 2-24h to test whether cell-cycle-dependent DNA SSBR requires E2F1-mediated upregulation of XRCC1. We found that SSBR activity, as determined using a qPCR-base method, was correlated with E2F1 levels at different phases of the cell cycle. XRCC1-positive (AA8) and negative (EM9) CHO cells were used to demonstrate that the alterations in SSBR were mediated by XRCC1. The results indicate that E2F1-mediated regulation of XRCC1 is required for cell-cycle-dependent SSBR predominantly in G(1)/S phases. Our observations have provided new mechanistic insight for understanding the role of E2F1 in the maintenance of genomic stability and cell survival during the cell cycle. The regulation of XRCC1 by E2F1 during cell-cycle-dependent SSBR might be an important aspect for practical consideration for resolving the problem of drug resistance in tumor chemotherapies.     

Distinct spatiotemporal patterns and PARP dependence of XRCC1 recruitment to single-strand break and base excision repair

Single-strand break repair (SSBR) and base excision repair (BER) of modified bases and abasic sites share several players. Among them is XRCC1, an essential scaffold protein with no enzymatic activity, required for the coordination of both pathways. XRCC1 is recruited to SSBR by PARP-1, responsible for the initial recognition of the break. The recruitment of XRCC1 to BER is still poorly understood. Here we show by using both local and global induction of oxidative DNA base damage that XRCC1 participation in BER complexes can be distinguished from that in SSBR by several criteria. We show first that XRCC1 recruitment to BER is independent of PARP. Second, unlike SSBR complexes that are assembled within minutes after global damage induction, XRCC1 is detected later in BER patches, with kinetics consistent with the repair of oxidized bases. Third, while XRCC1-containing foci associated with SSBR are formed both in eu- and heterochromatin domains, BER complexes are assembled in patches that are essentially excluded from heterochromatin and where the oxidized bases are detected.     

XRCC1 stimulates human polynucleotide kinase activity at damaged DNA termini and accelerates DNA single-strand break repair

XRCC1 protein is required for DNA single-strand break repair and genetic stability but its biochemical role is unknown. Here, we report that XRCC1 interacts with human polynucleotide kinase in addition to its established interactions with DNA polymerase-beta and DNA ligase III. Moreover, these four proteins are coassociated in multiprotein complexes in human cell extract and together they repair single-strand breaks typical of those induced by reactive oxygen species and ionizing radiation. Strikingly, XRCC1 stimulates the DNA kinase and DNA phosphatase activities of polynucleotide kinase at damaged DNA termini and thereby accelerates the overall repair reaction. These data identify a novel pathway for mammalian single-strand break repair and demonstrate a concerted role for XRCC1 and PNK in the initial step of processing damaged DNA ends.     

CK2 phosphorylation of XRCC1 facilitates dissociation from DNA and single-strand break formation during base excision repair

CK2 phosphorylates the scaffold protein XRCC1, which is required for efficient DNA single-strand break (SSB) repair. Here, we express an XRCC1 protein (XRCC1(ckm)) that cannot be phosphorylated by CK2 in XRCC1 mutated EM9 cells and show that the role of this post-translational modification gives distinct phenotypes in SSB repair and base excision repair (BER). Interestingly, we find that fewer SSBs are formed during BER after treatment with the alkylating agent dimethyl sulfate (DMS) in EM9 cells expressing XRCC1(ckm) (CKM cells) or following inhibition with the CK2 inhibitor 2-dimethylamino-4,5,6,7-tetrabromo-1H-benzimidazole (DMAT). We also show that XRCC1(ckm) protein has a higher affinity for DNA than wild type XRCC1 protein and resides in an immobile fraction on DNA, in particular after damage. We propose a model whereby the increased affinity for DNA sequesters XRCC1(ckm) and the repair enzymes associated with it, at the repair site, which retards kinetics of BER. In conclusion, our results indicate that phosphorylation of XRCC1 by CK2 facilitates the BER incision step, likely by promoting dissociation from DNA.     

A cell cycle-specific requirement for the XRCC1 BRCT II domain during mammalian DNA strand break repair

XRCC1 protein is essential for viability in mammals and is required for efficient DNA single-strand break repair and genetic stability following DNA base damage. We report here that XRCC1-dependent strand break repair in G(1) phase of the cell cycle is abolished by mutations created within the XRCC1 BRCT domain that interact with DNA ligase III. In contrast, XRCC1-dependent DNA strand break repair in S phase is largely unaffected by these mutations. These data describe a cell cycle-specific role for a BRCT domain, and we conclude that the XRCC1-DNA ligase III complex is required for DNA strand break repair in G(1) phase of the cell cycle but is dispensable for this process in S phase. The S-phase DNA repair process can remove both strand breaks induced in S phase and those that persist from G(1) and can in part compensate for lack of repair in G(1). This process correlates with the appearance of XRCC1 nuclear foci that colocalize with Rad51 and may thus function in concert with homologous recombination.     

Base excision repair processing of abasic site/single-strand break lesions within clustered damage sites associated with XRCC1 deficiency

Ionizing radiation induces clustered DNA damage, which presents a challenge to the cellular repair machinery. The repair efficiency of a single-strand break (SSB) is ~4× less than that for repair of an abasic (AP) site when in a bistranded cluster containing 8-oxoG. To explore whether this difference in repair efficiency involves XRCC1 or other BER proteins, synthetic oligonucleotides containing either an AP site or HAP1-induced SSB (HAP1-SSB) 1 or 5 bp 5′ or 3′ to 8-oxoG on the opposite strand were synthesized and the repair investigated using either nuclear extracts from hamster cells proficient (AA8) or deficient (EM7) in XRCC1 or purified BER proteins. XRCC1 is important for efficient processing of an AP site in clustered damage containing 8-oxoG but does not affect the already low repair efficiency of a SSB. Ligase I partly compensates for the absence of the XRCC1/ligaseIII during short-patch BER of an AP site when in a cluster but only weakly if at all for a HAP1-SSB. The major difference between the repair of an AP site and a HAP1-SSB when in a 8-oxoG containing cluster is the greater efficiency of short-patch BER with the AP site compared with that for a HAP1-SSB.     

DNA single-strand break repair and spinocerebellar ataxia

DNA single-strand break repair (SSBR) is critical for the survival and genetic stability of mammalian cells. Three papers have recently associated mutations in putative human SSBR genes with hereditary spinocerebellar ataxia. The emerging links between SSBR and neurodegenerative disorders are discussed.     

BRCT domain interactions in the heterodimeric DNA repair protein XRCC1-DNA ligase III

Proteins involved in DNA repair, or its coordination with DNA replication and mitosis through cell cycle checkpoints, are vital in the concerted cellular response to DNA damage that maintains the integrity of the genome. The "BRCT" domain (BRCA1 carboxy terminal) was noted as a putative protein-protein interaction motif in the breast cancer suppressor gene, BRCA1, and subsequently identified in over 50 proteins involved in DNA repair, recombination, or cell cycle control. The heterodimer of the DNA repair proteins, XRCC1 and DNA ligase III, was the first example of a functional interaction via BRCT modules. The only three-dimensional crystal structure of a BRCT domain was solved for this region of XRCC1. Key amino acid residues mediating the interaction with DNA ligase III were identified here by targeted mutagenesis of the XRCC1 BRCT domain. The consequences of these mutations on protein folding were assessed. A structural model of the DNA ligase III BRCT domain was constructed and similarly tested by mutation of corresponding residues required for the interaction with XRCC1. These data identify the XRCC1-DNA ligase III heterodimer interface and provide the first demonstration of the surface contacts coordinating a functional BRCT-BRCT protein interaction.     

The N-terminal domain influences the structure and property of protein phosphatase 1

Molecular and Cellular Biochemistry - The protein phosphatase 1 has conserved cores in PPP gene family flanked by non-conserved N-terminal domains. PP1 with residues 1–8 deleted or...