DNA polymerase beta is required for efficient DNA strand break repair induced by methyl methanesulfonate but not by hydrogen peroxide

The most frequent DNA lesions in mammalian genomes are removed by the base excision repair (BER) via multiple pathways that involve the replacement of one or more nucleotides at the lesion site. The biological consequences of a BER defect are at present largely unknown. We report here that mouse cells defective in the main BER DNA polymerase β (Pol β) display a decreased rate of DNA single-strand breaks (ssb) rejoining after methyl methanesulfonate damage when compared with wild-type cells. In contrast, Pol β seems to be dispensable for hydrogen peroxide-induced DNA ssb repair, which is equally efficient in normal and defective cells. By using an in vitro repair assay on single abasic site-containing circular duplex molecules, we show that the long-patch BER is the predominant repair route in Pol β-null cell extract. Our results strongly suggest that the Pol β-mediated single nucleotide BER is the favorite pathway for repair of N-methylpurines while oxidation-induced ssb, likely arising from oxidized abasic sites, are the substrate for long-patch BER.     

The S229L Colon Tumor-associated Variant of DNA Polymerase β Induces Cellular Transformation as a Result of Decreased Polymerization Efficiency

DNA polymerase β (Pol β) plays a key role in base excision repair (BER) by filling in small gaps that are generated after base adducts are excised from the DNA. Pol β is mutated in a large number of colorectal tumors, and these mutations may drive carcinogenesis. In the present study, we wished to determine whether the S229L somatic Pol β variant identified in a stage 3 colorectal tumor is a driver of carcinogenesis. We show that S229L does not possess any defects in binding to either DNA or nucleotides compared with the WT enzyme, but exhibits a significant loss of polymerization efficiency, largely due to an 8-fold decrease in the polymerization rate. S229L participates in BER, but due to its lower catalytic rate, does so more slowly than WT. Expression of S229L in mammalian cells induces the accumulation of BER intermediate substrates, chromosomal aberrations, and cellular transformation. Our results are consistent with the interpretation that S229L is a driver of carcinogenesis, likely as a consequence of its slow polymerization activity during BER in vivo.     

DNA polymerase η promotes nonhomologous end joining upon etoposide exposure dependent on the scaffolding protein Kap1

DNA polymerase eta (Pol η) is a eukaryotic member of the Y-family of DNA polymerase involved in translesion DNA synthesis and genome mutagenesis. Recently, several translesion DNA synthesis polymerases have been found to function in repair of DNA double-strand breaks (DSBs). However, the role of Pol η in promoting DSB repair remains to be well defined. Here, we demonstrated that Pol η could be targeted to etoposide (ETO)-induced DSBs and that depletion of Pol η in cells causes increased sensitivity to ETO. Intriguingly, depletion of Pol η also led to a nonhomologous end joining repair defect in a catalytic activity–independent manner. We further identified the scaffold protein Kap1 as a novel interacting partner of Pol η, the depletion of which resulted in impaired formation of Pol η and Rad18 foci after ETO treatment. Additionally, overexpression of Kap1 failed to restore Pol η focus formation in Rad18-deficient cells after ETO treatment. Interestingly, we also found that Kap1 bound to Rad18 in a Pol η-dependent manner, and moreover, depletion of Kap1 led to a significant reduction in Rad18–Pol η association, indicating that Kap1 forms a ternary complex with Rad18 and Pol η to stabilize Rad18–Pol η association. Our findings demonstrate that Kap1 could regulate the role of Pol η in ETO-induced DSB repair via facilitating Rad18 recruitment and stabilizing Rad18–Pol η association.     

Repair of single-strand DNA interruptions by redundant pathways and its implication in cellular sensitivity to DNA-damaging agents

Single-strand DNA interruptions (SSIs) are produced during the process of base excision repair (BER). Through biochemical studies, two SSI repair subpathways have been identified: a pathway mediated by DNA polymerase β (Pol β) and DNA ligase III (Lig III), and a pathway mediated by DNA polymerase δ/ε (Pol δ/ε) and DNA ligase I (Lig I). In addition, the existence of another pathway, mediated by Pol β and DNA Lig I, has been suggested. Although each pathway may play a unique role in cellular DNA damage response, the functional implications of SSI repair by these three pathways are not clearly understood. To obtain a better understanding of the functional relevance of SSI repair by these pathways, we investigated the involvement of each pathway by monitoring the utilization of DNA ligases in cell-free extracts. Our results suggest that the majority of SSIs produced during the repair of alkylated DNA bases are repaired by the pathway mediated by Pol β and either Lig I or Lig III, although some SSIs are repaired by Pol δ/ε and Lig I. At a cellular level, we found that Lig III over-expression increased the resistance of cells to DNA-damaging agents, while Lig I over-expression had little effect. Thus, repair pathways mediated by Lig III may have a role in the regulation of cellular sensitivity to DNA-damaging agents.     

The accumulation of MMS-induced single strand breaks in G1 phase is recombinogenic in DNA polymerase beta defective mammalian cells

DNA polymerase (Pol) β null mouse embryonic fibroblasts provide a useful cell system to investigate the effects of alterations in base excision repair (BER) on genome stability. These cells are characterized by hypersensitivity to the cytotoxic effects of methyl methanesulfonate (MMS) and by decreased repair of the MMS-induced DNA single strand breaks (SSB). Here, we show that, in the absence of Pol β, SSB accumulate in G₁ phase cells, accompanied by the formation of proliferating cell nuclear antigen foci in the nuclei. When replicating Pol β null cells are treated with MMS, a rapid phosphorylation of histone H2AX is detected in the nuclei of S phase cells, indicating that double strand breaks (DSB) are formed in response to unrepaired SSB. This is followed by relocalization within the nuclei of Rad51 protein, which is essential for homologous recombination (HR). These findings are compatible with a model where, in mammalian cells, unrepaired SSB produced during BER are substrates for the HR pathway via DSB formation. This is an example of a coordinated effort of two different repair pathways, BER and HR, to protect mammalian cells from alkylation-induced cytotoxicity.     

XRCC1-DNA polymerase beta interaction is required for efficient base excision repair

X-ray repair cross-complementing protein-1 (XRCC1)-deficient cells are sensitive to DNA damaging agents and have delayed processing of DNA base lesions. In support of its role in base excision repair, it was found that XRCC1 forms a tight complex with DNA ligase IIIα and also interacts with DNA polymerase β (Pol β) and other base excision repair (BER) proteins. We have isolated wild-type XRCC1–DNA ligase IIIα heterodimer and mutated XRCC1–DNA ligase IIIα complex that does not interact with Pol β and tested their activities in BER reconstituted with human purified proteins. We find that a point mutation in the XRCC1 protein which disrupts functional interaction with Pol β, affected the ligation efficiency of the mutant XRCC1–DNA ligase IIIα heterodimer in reconstituted BER reactions. We also compared sensitivity to hydrogen peroxide between wild-type CHO-9 cells, XRCC1-deficient EM-C11 cells and EM-C11 cells transfected with empty plasmid vector or with plasmid vector carrying wild-type or mutant XRCC1 gene and find that the plasmid encoding XRCC1 protein, that does not interact with Pol β has reduced ability to rescue the hydrogen peroxide sensitivity of XRCC1- deficient cells. These data suggest an important role for the XRCC1–Pol β interaction for coordinating the efficiency of the BER process.     

Reduced levels of DNA polymerase delta induce chromosome fragile site instability in yeast

Specific regions of genomes (fragile sites) are hot spots for the chromosome rearrangements that are associated with many types of cancer cells. Understanding the molecular mechanisms regulating the stability of chromosome fragile sites, therefore, has important implications in cancer biology. We previously identified two chromosome fragile sites in Saccharomyces cerevisiae that were induced in response to the reduced expression of Pol1p, the catalytic subunit of DNA polymerase α. In the study presented here, we show that reduced levels of Pol3p, the catalytic subunit of DNA polymerase δ, induce instability at these same sites and lead to the generation of a variety of chromosomal aberrations. These findings demonstrate that a change in the stoichiometry of replicative DNA polymerases results in recombinogenic DNA lesions, presumably double-strand DNA breaks.     

DNA polymerase β is critical for mouse meiotic synapsis

We have shown earlier that DNA polymerase β (Pol β) localizes to the synaptonemal complex (SC) during Prophase I of meiosis in mice. Pol β localizes to synapsed axes during zygonema and pachynema, and it associates with the ends of bivalents during late pachynema and diplonema. To test whether these localization patterns reflect a function for Pol β in recombination and/or synapsis, we used conditional gene targeting to delete the PolB gene from germ cells. We find that Pol β-deficient spermatocytes are defective in meiotic chromosome synapsis and undergo apoptosis during Prophase I. We also find that SPO11-dependent γH2AX persists on meiotic chromatin, indicating that Pol β is critical for the repair of SPO11-induced double-strand breaks (DSBs). Pol β-deficient spermatocytes yielded reduced steady-state levels of the SPO11-oligonucleotide complexes that are formed when SPO11 is removed from the ends of DSBs, and cytological experiments revealed that chromosome-associated foci of replication protein A (RPA), RAD51 and DMC1 are less abundant in Pol β-deficient spermatocyte nuclei. Localization of Pol β to meiotic chromosomes requires the formation of SPO11-dependent DSBs. Taken together, these findings strongly indicate that Pol β is required at a very early step in the processing of meiotic DSBs, at or before the removal of SPO11 from DSB ends and the generation of the 3′ single-stranded tails necessary for subsequent strand exchange. The chromosome synapsis defects and Prophase I apoptosis of Pol β-deficient spermatocytes are likely a direct consequence of these recombination defects.     

Focus: 50 Years of DNA Repair: The Yale Symposium Reports: Cellular Roles of DNA Polymerase Beta

Since its discovery and purification in 1971, DNA polymerase ß (Pol ß) is one of the most well-studied DNA polymerases. Pol ß is a key enzyme in the base excision repair (BER) pathway that functions in gap filling DNA synthesis subsequent to the excision of damaged DNA bases. A major focus of our studies is on the cellular roles of Pol ß. We have shown that germline and tumor-associated variants of Pol ß catalyze aberrant BER that leads to genomic instability and cellular transformation. Our studies suggest that Pol ß is critical for the maintenance of genomic stability and that it is a tumor suppressor. We have also shown that Pol ß functions during Prophase I of meiosis. Pol ß localizes to the synaptonemal complex and is critical for removal of the Spo11 complex from the 5’ ends of double-strand breaks. Studies with Pol ß mutant mice are currently being undertaken to more clearly understand the function of Pol ß during meiosis. In this review, we will highlight our contributions from our studies of Pol ß germline and cancer-associated variants.     

Overexpression of human DNA polymerase mu (Pol mu) in a Burkitt's lymphoma cell line affects the somatic hypermutation rate

DNA polymerase μ (Pol μ) is a DNA-dependent DNA polymerase closely related to terminal deoxynucleotidyl transferase (TdT), and prone to induce template/primer misalignments and misincorporation. In addition to a proposed general role in non-homologous end joining of double-strand breaks, its mutagenic potential and preferential expression in secondary lymphoid tissues support a role in somatic hypermutation (SHM) of immunoglobulin genes. Here, we show that human Pol μ protein is expressed in the nucleus of centroblasts obtained from human tonsils, forming a characteristic foci pattern resembling that of other DNA repair proteins in response to DNA damage. Overexpression of human Pol μ in Ramos cells, in which the SHM process is constitutive, augmented the somatic mutations specifically at the variable (V) region of the immunoglobulin genes. The nature of the mutations introduced, mostly base substitutions, supports the contribution of Pol μ to mutation of G and C residues during SHM. In vitro analysis of Pol μ misincorporation on specific templates, that mimic DNA repair intermediates and correspond to mutational hotspots, indicated that many of the mutations observed in vivo can be explained by the capacity of Pol μ to induce transient template/primer misalignments.     

Deletion of Individual Ku Subunits in Mice Causes an NHEJ-Independent Phenotype Potentially by Altering Apurinic/Apyrimidinic Site Repair

Ku70 and Ku80 form a heterodimer called Ku that forms a holoenzyme with DNA dependent-protein kinase catalytic subunit (DNA-PK_CS) to repair DNA double strand breaks (DSBs) through the nonhomologous end joining (NHEJ) pathway. As expected mutating these genes in mice caused a similar DSB repair-defective phenotype. However, ku70^-/- cells and ku80^-/- cells also appeared to have a defect in base excision repair (BER). BER corrects base lesions, apurinic/apyrimidinic (AP) sites and single stand breaks (SSBs) utilizing a variety of proteins including glycosylases, AP endonuclease 1 (APE1) and DNA Polymerase β (Pol β). In addition, deleting Ku70 was not equivalent to deleting Ku80 in cells and mice. Therefore, we hypothesized that free Ku70 (not bound to Ku80) and/or free Ku80 (not bound to Ku70) possessed activity that influenced BER. To further test this hypothesis we performed two general sets of experiments. The first set showed that deleting either Ku70 or Ku80 caused an NHEJ-independent defect. We found ku80^-/- mice had a shorter life span than dna-pkcs^-/- mice demonstrating a phenotype that was greater than deleting the holoenzyme. We also found Ku70-deletion induced a p53 response that reduced the level of small mutations in the brain suggesting defective BER. We further confirmed that Ku80-deletion impaired BER via a mechanism that was not epistatic to Pol β. The second set of experiments showed that free Ku70 and free Ku80 could influence BER. We observed that deletion of either Ku70 or Ku80, but not both, increased sensitivity of cells to CRT0044876 (CRT), an agent that interferes with APE1. In addition, free Ku70 and free Ku80 bound to AP sites and in the case of Ku70 inhibited APE1 activity. These observations support a novel role for free Ku70 and free Ku80 in altering BER.     

Interaction between DNA Polymerase β and BRCA1

The breast cancer 1 (BRCA1) protein is a tumor suppressor playing roles in DNA repair and cell cycle regulation. Studies of DNA repair functions of BRCA1 have focused on double-strand break (DSB) repair pathways and have recently included base excision repair (BER). However, the function of BRCA1 in BER is not well defined. Here, we examined a BRCA1 role in BER, first in relation to alkylating agent (MMS) treatment of cells and the BER enzyme DNA polymerase β (pol β). MMS treatment of BRCA1 negative human ovarian and chicken DT40 cells revealed hypersensitivity, and the combined gene deletion of BRCA1 and pol β in DT40 cells was consistent with these factors acting in the same repair pathway, possibly BER. Using cell extracts and purified proteins, BRCA1 and pol β were found to interact in immunoprecipitation assays, yet in vivo and in vitro assays for a BER role of BRCA1 were negative. An alternate approach with the human cells of immunofluorescence imaging and laser-induced DNA damage revealed negligible BRCA1 recruitment during the first 60 s after irradiation, the period typical of recruitment of pol β and other BER factors. Instead, 15 min after irradiation, BRCA1 recruitment was strong and there was γ-H2AX co-localization, consistent with DSBs and repair. The rapid recruitment of pol β was similar in BRCA1 positive and negative cells. However, a fraction of pol β initially recruited remained associated with damage sites much longer in BRCA1 positive than negative cells. Interestingly, pol β expression was required for BRCA1 recruitment, suggesting a partnership between these repair factors in DSB repair.     

Phosphorylation of human DNA polymerase lambda by the cyclin-dependent kinase Cdk2/cyclin A complex is modulated by its association with proliferating cell nuclear antigen

DNA polymerase (Pol) λ is a member of the Pol X family and possesses four different enzymatic activities, being DNA polymerase, terminal transferase, deoxyribose phosphate lyase and polynucleotide synthetase, all localized in its C-terminal region. On the basis of its biochemical properties, Pol λ has been implicated in various DNA repair pathways, such as abasic site translesion DNA synthesis, base excision repair and non-homologous end joining of double strand breaks. However, its role in vivo has not yet been elucidated. In addition, Pol λ has been shown to interact with the replication clamp proliferating cell nuclear antigen (PCNA) in vitro and in vivo. In this work, we searched by affinity chromatography for novel partners and we identified the cyclin-dependent kinase Cdk2 as novel partner of Pol λ. Pol λ is phosphorylated in vitro by several Cdk/cyclin complexes, including Cdk2/cyclin A, in its proline-serine-rich domain. While the polymerase activity of Pol λ was not affected by Cdk2/cyclin A phosphorylation, phosphorylation of Pol λ was decreased by its interaction with PCNA. Finally, Pol λ is also phosphorylated in vivo in human cells and this phosphorylation is modulated during the cell cycle.     

The beta clamp targets DNA polymerase IV to DNA and strongly increases its processivity

The recent discovery of a new family of ubiquitous DNA polymerases involved in translesion synthesis has shed new light onto the biochemical basis of mutagenesis. Among these polymerases, the dinB gene product (Pol IV) is involved in mutagenesis in Escherichia coli. We show here that the activity of native Pol IV is drastically modified upon interaction with the β subunit, the processivity factor of DNA Pol III. In the absence of the β subunit Pol IV is strictly distributive and no stable complex between Pol IV and DNA could be detected. In contrast, the β clamp allows Pol IV to form a stable initiation complex (t_1/2 ≈ 2.3 min), which leads to a dramatic increase in the processivity of Pol IV reaching an average of 300–400 nucleotides. In vivo, the β processivity subunit may target DNA Pol IV to its substrate, generating synthesis tracks much longer than previously thought.     

The Transition of Closely Opposed Lesions to Double-Strand Breaks during Long-Patch Base Excision Repair Is Prevented by the Coordinated Action of DNA Polymerase δ and Rad27/Fen1

DNA double-strand breaks can result from closely opposed breaks induced directly in complementary strands. Alternatively, double-strand breaks could be generated during repair of clustered damage, where the repair of closely opposed lesions has to be well coordinated. Using single and multiple mutants of Saccharomyces cerevisiae (budding yeast) that impede the interaction of DNA polymerase δ and the 5′-flap endonuclease Rad27/Fen1 with the PCNA sliding clamp, we show that the lack of coordination between these components during long-patch base excision repair of alkylation damage can result in many double-strand breaks within the chromosomes of nondividing haploid cells. This contrasts with the efficient repair of nonclustered methyl methanesulfonate-induced lesions, as measured by quantitative PCR and S1 nuclease cleavage of single-strand break sites. We conclude that closely opposed single-strand lesions are a unique threat to the genome and that repair of closely opposed strand damage requires greater spatial and temporal coordination between the participating proteins than does widely spaced damage in order to prevent the development of double-strand breaks.Endogenous metabolism or environmental factors such as oxidizing and alkylating agents can produce a wide variety of lesions in DNA. The genomes of mammalian cells experience from 10,000 to as many as 200,000 modifications per day (37, 44). Most lesions are repaired by a complex network of proteins that are part of an elaborate, multistep base excision repair (BER) system that generates single-strand break (SSB) intermediates. Importantly, defects in BER can lead to malignancies and can be associated with age-associated disease, especially neurodegeneration (60).BER is initiated by specific DNA N-glycosylases that remove damaged bases, yielding apurinic/apyrimidinic (AP) sites. Subsequent incision by AP endonucleases results in SSBs, and excision results in a single base gap as a repair intermediate (33, 53). SSBs are expected to be frequent in the genome due to the abundance of base damage as well as intermediates of repair, recombination, replication, and other DNA transactions (15, 16). Because they are generally repaired efficiently by BER and SSB repair enzymes (16, 57), SSBs per se may not be a major source of genome instability. However, if lesions are clustered, the formation of two closely spaced SSBs on opposing strands (or a single SSB and a modified nucleotide or AP site) might pose a special risk in terms of the potential to generate mutations or the possibility of conversion to double-strand breaks (DSBs), which are potent genotoxic lesions. Clustered lesions can arise within cells by chance association of random DNA lesions in a small region or the induction of multiple events in a narrow region, as found for ionizing radiation and various chemicals, such as those used in cancer treatments (47, 58, 59). While efficient BER is important for genome integrity, the repair must be well coordinated to avoid the generation of closely opposed SSB intermediates at closely spaced lesions that could result in the secondary generation of DSBs, especially since cells have limited DSB repair capacity (<50 DSBs/cell in the case of Saccharomyces cerevisiae) (48). While the impact of clustered lesions on repair of DNA has been examined in vitro by use of purified enzymes or cell extracts (13, 14, 27, 39, 56), there has been little opportunity to address specifically the repair of clustered lesions, except for those arising from UV damage (49).Whether formed directly from sugar damage or as BER intermediates, SSBs formed during the repair of base damage often possess 5′-deoxyribose phosphate (5′-dRP) ends that are not suitable for rejoining by DNA ligases (9, 15). In humans, removal and repair of 5′-dRP are accomplished by different combinations of proteins (3, 15) that result in short-patch repair, involving replacement of a single nucleotide (nt), or long-patch repair, involving 2 to 10 nt. The budding yeast Saccharomyces cerevisiae lacks a DNA polymerase β that provides AP lyase activity required for short-patch repair in mammalian cells. Instead, removal and repair of a 5′-dRP rely on the long-patch pathway, involving the successive actions of DNA polymerase δ (Pol δ) for strand displacement, the Rad27/Fen1 endonuclease to remove 5′ flaps, and DNA ligase (Cdc9) to rejoin the resulting nicks (9). The sliding clamp protein PCNA, which interacts with all three players, has been proposed to play a central role in coordinating these processes (18, 19, 34). The coupling between the strand displacement reaction by Pol δ and the flap cutting reaction by Fen1 is highly efficient, with over 90% of the products released by Fen1 being mononucleotides (17).Although the coordination of Pol δ, PCNA, and Rad27/Fen1 provides efficient processing of individual lesions in DNA, closely opposed SSBs that arise during repair of base damage could manifest as DSBs, either directly or as a result of SSB processing. A DNA damaging agent that has been used frequently to characterize long- and short-patch BER is methyl methanesulfonate (MMS). Recently, we described the detection of closely opposed MMS-induced lesions in yeast (42). Since the closely opposed lesions might represent a special challenge to BER, we considered the possibility that they might specifically impact long-patch repair through Pol δ and/or coordination of events with Rad27/Fen1. Pol δ of S. cerevisiae is a heterotrimeric enzyme consisting of Pol3, Pol31, and Pol32 (23). The nonessential Pol32 subunit is involved in translesion DNA synthesis (TLS) (24, 30) and also break-induced replication (41). However, its role in other types of DNA repair remains unclear. Using our in vivo assay for specifically detecting closely spaced methylated DNA lesions (42) and SSBs, we examined the role of Pol32 as well as the cooperation between Pol δ, Rad27/Fen1, and PCNA in the repair of clustered DNA lesions induced by MMS in G₁ stationary-phase haploid yeast. We found that Pol32 plays an important role in ensuring that clustered lesions are efficiently repaired and do not transition to DSBs.     

DNA polymerase theta suppresses mitotic crossing over

Polymerase theta-mediated end joining (TMEJ) is a chromosome break repair pathway that is able to rescue the lethality associated with the loss of proteins involved in early steps in homologous recombination (e.g., BRCA1/2). This is due to the ability of polymerase theta (Pol θ) to use resected, 3’ single stranded DNA tails to repair chromosome breaks. These resected DNA tails are also the starting substrate for homologous recombination. However, it remains unknown if TMEJ can compensate for the loss of proteins involved in more downstream steps during homologous recombination. Here we show that the Holliday junction resolvases SLX4 and GEN1 are required for viability in the absence of Pol θ in Drosophila melanogaster, and lack of all three proteins results in high levels of apoptosis. Flies deficient in Pol θ and SLX4 are extremely sensitive to DNA damaging agents, and mammalian cells require either Pol θ or SLX4 to survive. Our results suggest that TMEJ and Holliday junction formation/resolution share a common DNA substrate, likely a homologous recombination intermediate, that when left unrepaired leads to cell death. One major consequence of Holliday junction resolution by SLX4 and GEN1 is cancer-causing loss of heterozygosity due to mitotic crossing over. We measured mitotic crossovers in flies after a Cas9-induced chromosome break, and observed that this mutagenic form of repair is increased in the absence of Pol θ. This demonstrates that TMEJ can function upstream of the Holiday junction resolvases to protect cells from loss of heterozygosity. Our work argues that Pol θ can thus compensate for the loss of the Holliday junction resolvases by using homologous recombination intermediates, suppressing mitotic crossing over and preserving the genomic stability of cells.     

A Variant of GJD2, Encoding for Connexin 36, Alters the Function of Insulin Producing β-Cells

Signalling through gap junctions contributes to control insulin secretion and, thus, blood glucose levels. Gap junctions of the insulin-producing β-cells are made of connexin 36 (Cx36), which is encoded by the GJD2 gene. Cx36-null mice feature alterations mimicking those observed in type 2 diabetes (T2D). GJD2 is also expressed in neurons, which share a number of common features with pancreatic β-cells. Given that a synonymous exonic single nucleotide polymorphism of human Cx36 (SNP rs3743123) associates with altered function of central neurons in a subset of epileptic patients, we investigated whether this SNP also caused alterations of β-cell function. Transfection of rs3743123 cDNA in connexin-lacking HeLa cells resulted in altered formation of gap junction plaques and cell coupling, as compared to those induced by wild type (WT) GJD2 cDNA. Transgenic mice expressing the very same cDNAs under an insulin promoter revealed that SNP rs3743123 expression consistently lead to a post-natal reduction of islet Cx36 levels and β-cell survival, resulting in hyperglycemia in selected lines. These changes were not observed in sex- and age-matched controls expressing WT hCx36. The variant GJD2 only marginally associated to heterogeneous populations of diabetic patients. The data document that a silent polymorphism of GJD2 is associated with altered β-cell function, presumably contributing to T2D pathogenesis.     

Involvement of the nuclear proteasome activator PA28γ in the cellular response to DNA double-strand breaks

The DNA damage response (DDR) is a complex signaling network that leads to damage repair while modulating numerous cellular processes. DNA double-strand breaks (DSBs), a highly cytotoxic DNA lesion, activate this system most vigorously. The DSB response network is orchestrated by the ATM protein kinase, which phosphorylates key players in its various branches. Proteasome-mediated protein degradation plays an important role in the proteome dynamics following DNA damage induction. Here, we identify the nuclear proteasome activator PA28γ (REGγ; PSME3) as a novel DDR player. PA28γ depletion leads to cellular radiomimetic sensitivity and a marked delay in DSB repair. Specifically, PA28γ deficiency abrogates the balance between the two major DSB repair pathways—nonhomologous end-joining and homologous recombination repair. Furthermore, PA28γ is found to be an ATM target, being recruited to the DNA damage sites and required for rapid accumulation of proteasomes at these sites. Our data reveal a novel ATM-PA28γ-proteasome axis of the DDR that is required for timely coordination of DSB repair.Key words: genomic stability, DNA repair, double-strand breaks, ATM, proteasome, PA28γ (PSME3)     

The role of DNA polymerase beta in determining sensitivity to ionizing radiation in human tumor cells

Lethal lesions after ionizing radiation are thought to be mainly unrepaired or misrepaired DNA double-strand breaks, ultimately leading to lethal chromosome aberrations. However, studies with radioprotectors and repair inhibitors indicate that single-strand breaks, damaged nucleotides or abasic sites can also influence cell survival. This paper reports on studies to further define the role of base damage and base excision repair on the radiosensitivity of human cells. We retrovirally transduced human tumor cells with a dominant negative form of DNA polymerase β, comprising the 14 kDa DNA-binding domain of DNA polymerase β but lacking polymerase function. Radiosensitization of two human carcinoma cell lines, A549 and SQD9, was observed, achieving dose enhancement factors of 1.5–1.7. Sensitization was dependent on expression level of the dominant negative and was seen in both single cell clones and in unselected virally transduced populations. Sensitization was not due to changes in cell cycle distribution. Little or no sensitization was seen in G₁-enriched populations, indicating cell cycle specificity for the observed sensitization. These results contrast with the lack of effect seen in DNA polymerase β knockout cells, suggesting that polDN also inhibits the long patch, DNA polymerase β-independent repair pathway. These data demonstrate an important role for BER in determining sensitivity to ionizing radiation and might help identify targets for radiosensitizing tumor cells.     

Segregation of Replicative DNA Polymerases during S Phase: DNA POLYMERASE ?, BUT NOT DNA POLYMERASES α/δ, ARE ASSOCIATED WITH LAMINS THROUGHOUT S PHASE IN HUMAN CELLS*

DNA polymerases (Pol) α, δ, and ϵ replicate the bulk of chromosomal DNA in eukaryotic cells, Pol ϵ being the main leading strand and Pol δ the lagging strand DNA polymerase. By applying chromatin immunoprecipitation (ChIP) and quantitative PCR we found that at G₁/S arrest, all three DNA polymerases were enriched with DNA containing the early firing lamin B2 origin of replication and, 2 h after release from the block, with DNA containing the origin at the upstream promoter region of the MCM4 gene. Pol α, δ, and ϵ were released from these origins upon firing. All three DNA polymerases, Mcm3 and Cdc45, but not Orc2, still formed complexes in late S phase. Reciprocal ChIP of the three DNA polymerases revealed that at G₁/S arrest and early in S phase, Pol α, δ, and ϵ were associated with the same nucleoprotein complexes, whereas in late S phase Pol ϵ and Pol α/δ were largely associated with distinct complexes. At G₁/S arrest, the replicative DNA polymerases were associated with lamins, but in late S phase only Pol ϵ, not Pol α/δ, remained associated with lamins. Consistently, Pol ϵ, but not Pol δ, was found in nuclear matrix fraction throughout the cell cycle. Therefore, Pol ϵ and Pol α/δ seem to pursue their functions at least in part independently in late S phase, either by physical uncoupling of lagging strand maturation from the fork progression, or by recruitment of Pol δ, but not Pol ϵ, to post-replicative processes such as translesion synthesis or post-replicative repair.