Double-strand Break Repair Proteins Research Articles

Assessing Somatic Hypermutation in Ramos B Cells after Overexpression or Knockdown of Specific Genes

B cells start their life with low affinity antibodies generated by V(D)J recombination. However, upon detecting a pathogen, the variable (V) region of an immunoglobulin (Ig) gene is mutated approximately 100,000-fold more than the rest of the genome through somatic hypermutation (SHM), resulting in high affinity antibodies. In addition, class switch recombination (CSR) produces antibodies with different effector functions depending on the kind of immune response that is needed for a particular pathogen. Both CSR and SHM are initiated by activation-induced cytidine deaminase (AID), which deaminates cytosine residues in DNA to produce uracils. These uracils are processed by error-prone forms of repair pathways, eventually leading to mutations and recombination. Our current understanding of the molecular details of SHM and CSR come from a combination of studies in mice, primary cells, cell lines, and cell-free experiments. Mouse models remain the gold standard with genetic knockouts showing critical roles for many repair factors (e.g. Ung, Msh2, Msh6, Exo1, and polymerase η). However, not all genes are amenable for knockout studies. For example, knockouts of several double-strand break repair proteins are embryonically lethal or impair B-cell development. Moreover, sometimes the specific function of a protein in SHM or CSR may be masked by more global defects caused by the knockout. In addition, since experiments in mice can be lengthy, altering expression of individual genes in cell lines has become an increasingly popular first step to identifying and characterizing candidate genes. Ramos - a Burkitt lymphoma cell line that constitutively undergoes SHM - has been a popular cell-line model to study SHM. One advantage of Ramos cells is that they have a built-in convenient semi-quantitative measure of SHM. Wild type cells express IgM and, as they pick up mutations, some of the mutations knock out IgM expression. Therefore, assaying IgM loss by fluorescence-activated cell scanning (FACS) provides a quick read-out for the level of SHM. A more quantitative measurement of SHM can be obtained by directly sequencing the antibody genes. Since Ramos cells are difficult to transfect, we produce stable derivatives that have increased or lowered expression of an individual gene by infecting cells with retroviral or lentiviral constructs that contain either an overexpression cassette or a short hairpin RNA (shRNA), respectively. Here, we describe how we infect Ramos cells and then use these cells to investigate the role of specific genes on SHM (Figure 1).

Prognostic Significance of NBS1 and Snail Expression in Esophageal Squamous Cell Carcinoma

Esophageal squamous cell carcinoma (ESCC) is a lethal malignancy, but only limited molecular markers can predict its prognosis. Recently, a DNA double-strand break repair protein Nijmegen breakage syndrome 1 (NBS1) was reported to induce Snail expression and predict poor prognosis in head and neck cancers. However, the clinicopathologic roles of NBS1 and Snail in ESCC remain unclear. From January 1995 to September 1999, tissue samples from 153 patients with ESCC who underwent esophagectomies at our institutions were collected and made into tissue core arrays for study. Expression of NBS1 and Snail was examined by immunohistochemical staining. The clinicopathologic data were analyzed, and some additional studies were performed to explore the relationship between NBS1 and Snail. NBS1 overexpression was observed in 28.1% (43/153) of ESCC, whereas Snail overexpression was observed in 26.1% (40/153) of ESCC. Overexpression of NBS1 correlated inversely with nodal status (P = 0.009) and was associated with better overall survival (P = 0.002). On the other hand, overexpression of Snail correlated positively with lymphovascular invasion (P = 0.034) and was associated with worse overall survival (P = 0.036). Meanwhile, NBS1 overexpression correlated inversely with Snail overexpression marginally (P = 0.084). Using the Cox regression analysis, T status (P = 0.006), M status (P = 0.008), and NBS1 overexpression (P = 0.007) were the independent factors of overall survival. Our results showed that NBS1 overexpression was an independent factor of better survival and Snail overexpression predicted a worse survival in ESCC. Combination of NBS1 plus Snail expression status could be used as a predictor of prognosis in ESCC.

Intestinal inflammation induces genotoxicity to extraintestinal tissues and cell types in mice.

Chronic intestinal inflammation leads to increased risk of colorectal and small intestinal cancers and is also associated with extraintestinal manifestations such as lymphomas, other solid cancers and autoimmune disorders. We have previously found that acute and chronic intestinal inflammation causes DNA damage to circulating peripheral leukocytes, manifesting a systemic effect in genetically and chemically induced models of intestinal inflammation. Our study addresses the scope of tissue targets and genotoxic damage induced by inflammation-associated genotoxicity. Using several experimental models of intestinal inflammation, we analyzed various types of DNA damage in leukocyte subpopulations of the blood, spleen, mesenteric and peripheral lymph nodes and in intestinal epithelial cells, hepatocytes and the brain. Genotoxicity in the form of DNA single- and double-stranded breaks accompanied by oxidative base damage was found in leukocyte subpopulations of the blood, diverse lymphoid organs, intestinal epithelial cells and hepatocytes. The brain did not demonstrate significant levels of DNA double-stranded breaks as measured by γ-H2AX immunostaining. CD4(+) and CD8(+) T-cells were most sensitive to DNA damage versus other cell types in the peripheral blood. In vivo measurements and in vitro modeling suggested that genotoxicity was induced by increased levels of systemically circulating proinflammatory cytokines. Moreover, genotoxicity involved increased damage rather than reduced repair, as it is not associated with decreased expression of the DNA double-strand break recognition and repair protein, ataxia telangiectasia mutated. These findings suggest that levels of intestinal inflammation contribute to the remote tissue burden of genotoxicity, with potential effects on nonintestinal diseases and cancer.

Potential for targeted therapy in prostate cancers with ERG abnormalities

Potential for targeted therapy in prostate cancers with ERG abnormalities

DNA Repair Biomarker Profiling of Head and Neck Cancer: Ku80 Expression Predicts Locoregional Failure and Death following Radiotherapy

Radiotherapy plays an integral role in the treatment of head and neck squamous cell carcinoma (HNSCC). Although proteins involved in DNA repair may predict HNSCC response to radiotherapy, none has been validated in this context. We examined whether differential expression of double-strand DNA break (DSB) repair proteins in HNSCC, the chief mediators of DNA repair following irradiation, predict for treatment outcomes. Archival HNSCC tumor specimens (n = 89) were assembled onto a tissue microarray and stained with antibodies raised against 38 biomarkers. The biomarker set was enriched for proteins involved in DSB repair, in addition to established mechanistic markers of radioresistance. Staining was correlated with treatment response and survival alongside established clinical and pathologic covariates. Results were validated in an independent intramural cohort (n = 34). Ku80, a key mediator of DSB repair, correlated most closely with clinical outcomes. Ku80 was overexpressed in half of all tumors, and its expression was independent of all other covariates examined. Ku80 overexpression was an independent predictor for both locoregional failure and mortality following radiotherapy (P < 0.01). The predictive power of Ku80 overexpression was confined largely to HPV-negative HNSCC, where it conferred a nine-fold greater risk of death at two years. Ku80 overexpression is a common feature of HNSCC, and is a candidate DNA repair-related biomarker for radiation treatment failure and death, particularly in patients with high-risk HPV-negative disease. It is a promising, mechanistically rational biomarker to select individual HPV-negative HNSCC patients for strategies to intensify treatment.

Genetic polymorphisms in DNA double-strand break repair genes XRCC5 , XRCC6 and susceptibility to hepatocellular carcinoma

Environmental risk factors cause DNA damages. Imprecise DNA repair leads to chromosome aberrations, genome destabilization and hepatocarcinogenesis. Ku is a key DNA double-strand break repair protein. We hypothesized that the genetic variants in Ku subunits encoding genes, XRCC5/XRCC6, may contribute to hepatocellular carcinoma (HCC) susceptibility. We genotyped 13 common single nucleotide polymorphisms (SNPs) in XRCC5 and XRCC6 and evaluated their associations with HCC risk in 689 pathologically confirmed cases and 690 cancer-free controls from a Chinese population. We found that a significantly reduced risk for HCC was associated with XRCC5 rs16855458 [odds ratio (OR)=0.59; 95% confidence interval (CI)=0.43-0.81; CA+AA versus CC] and a significantly increased risk for HCC was associated with XRCC5 rs9288516 (OR=2.02; 95% CI=1.42-2.86; TA+AA versus TT) even after Bonferroni correction (Pcorrected=0.026 and 0.002, respectively). The effects of rs16855458 (OR=0.57; 95% CI=0.37-0.86, P=0.008) and rs9288516 (OR=1.86; 95% CI=1.19-2.90, P=0.007) were more significant in hepatitis B surface antigen-infected subjects than non-infected subjects. The haplotype-based analysis revealed that in XRCC5, AA in block 1 (OR=0.63; 95% CI=0.48-0.83) and CGGTT in block 2 (OR=0.52; 95% CI=0.39-0.69) were associated with decreased HCC risk (Pcorrected=0.013 and <0.001, respectively). The aforementioned two SNPs exhibited a significant cumulative risk effect (Ptrend<0.001). Additionally, potential interaction among XRCC5 rs9288516 and rs2267437, rs5751131 in XRCC6 was indicated by the multifactor dimensionality reduction analysis. In conclusion, XRCC5 variants may play a role in determining individual's HCC susceptibility, which warranted validation in larger studies.

Up-regulation of HIV-1 transduction in nondividing cells by double-strand DNA break-inducing agents

Efficient HIV-1 transduction depends on a number of cellular co-factors. Cellular double-strand DNA break (DSB) repair proteins have been proposed, by ourselves and others, to be required for efficient HIV-1 transduction. Expression and/or activity of these DNA repair proteins can be induced by the introduction of DSBs into the host cell genome. HIV-1 transduction was up-regulated by treatment with DSB-inducing agents in both drug-arrested cells and differentiated neuronal cells. The presented data support the hypothesis that DSB repair proteins are involved in the early steps of the retroviral life-cycle.

Methyl Angolensate from Callus of Indian Redwood Induces Cytotoxicity in Human Breast Cancer Cells

AIM: Natural products discovered from medicinal plants have played an important role in the treatment of cancer. Methyl angolensate (MA), a tetranortriterpenoid obtained from the root callus of Indian Redwood tree, Soymida febrifuga Roxb. (A.Juss) was tested for its anticancer properties on breast cancer cells.METHODS: Cell viability was tested using trypan blue, MTT and LDH assays. Tritiated thymidine assay and flowcytometry were used to study effect of MA on cell proliferation. The activation of apoptosis was checked by annexin V and JC-1 staining followed by FACS analysis. Immunoblotting analysis was used for studying expression of apoptotic and DNA double strand break repair proteins. RESULTS: We find that MA inhibited the growth of breast cancer cell line, T47D in a time- and dose-dependent manner. MA treatment led to the inhibition of cell proliferation as detected by tritiated thymidine assay and flowcytometry. Further, MA treated cells exhibited typical apoptotic morphological changes and led to the accumulation of subG1 peak in cell cycle distribution. The induction of apoptosis was further confirmed both by annexin V staining and JC1 staining. We also find that MA activates MAP kinase pathway to induce apoptosis. Besides, we find a time dependent activation followed by degradation of DNA double-strand break repair proteins upon treatment with MA. CONCLUSION: These results suggest that MA induces cytotoxicity in breast cancer cells. Further, the altered expression of DSB repair proteins in MA treated cells may control the induction of apoptosis in these cancer cells.

Analysis of ionizing radiation‐induced DNA damage and repair in three‐dimensional human skin model system

Knowledge of cellular responses in tissue microenvironment is crucial for the accurate prediction of human health risks following chronic or acute exposure to ionizing radiation (IR). With this objective, we investigated the radio responses for the first time in three-dimensional (3D) artificial human skin tissue microenvironment after gamma-rays radiation. IR-induced DNA damage/repair response was assessed by immunological analysis of well-known DNA double strand break (DSB) repair proteins, i.e. 53BP1 and phosphorylated ataxia telangiectasia mutated(ser1981) (ATM(ser1981)). Efficient 53BP1 and phosphorylated ATM foci formation was observed in human EpiDerm tissue constructs after low and high doses of gamma-rays. Interestingly, EpiDerm tissue constructs displayed less 53BP1 and ATM foci number at all radiation doses (0.1, 1, 2.5 and 5 Gy) than that observed for 2D human fibroblasts. DSB repair efficiency judged by the disappearance of 53BP1 foci declined with increasing doses of gamma-rays and tissue constructs irradiated with 2.5 and 5 Gy of gamma-rays displayed 53BP1 foci persisting up to 72 h of analysis. Pretreatment of EpiDerm tissue constructs with LY294002, [an inhibitor of phosphatidylinositol-3 kinase and PI-3 kinase like kinases (PIKK)] completely abolished IR-induced 53BP1 foci formation and increased the apoptotic death. This observation indicates the importance of PIKK signalling pathway for efficient radiation responses in intact tissue constructs. In summary, we have successfully demonstrated the feasibility of monitoring the DNA damage response in human skin tissue microenvironment. In this system, 53BP1 can be used as a useful marker for monitoring the DSB repair efficiency.

The Caenorhabditis elegans Homolog of Gen1/Yen1 Resolvases Links DNA Damage Signaling to DNA Double-Strand Break Repair

DNA double-strand breaks (DSBs) can be repaired by homologous recombination (HR), which can involve Holliday junction (HJ) intermediates that are ultimately resolved by nucleolytic enzymes. An N-terminal fragment of human GEN1 has recently been shown to act as a Holliday junction resolvase, but little is known about the role of GEN-1 in vivo. Holliday junction resolution signifies the completion of DNA repair, a step that may be coupled to signaling proteins that regulate cell cycle progression in response to DNA damage. Using forward genetic approaches, we identified a Caenorhabditis elegans dual function DNA double-strand break repair and DNA damage signaling protein orthologous to the human GEN1 Holliday junction resolving enzyme. GEN-1 has biochemical activities related to the human enzyme and facilitates repair of DNA double-strand breaks, but is not essential for DNA double-strand break repair during meiotic recombination. Mutational analysis reveals that the DNA damage-signaling function of GEN-1 is separable from its role in DNA repair. GEN-1 promotes germ cell cycle arrest and apoptosis via a pathway that acts in parallel to the canonical DNA damage response pathway mediated by RPA loading, CHK1 activation, and CEP-1/p53–mediated apoptosis induction. Furthermore, GEN-1 acts redundantly with the 9-1-1 complex to ensure genome stability. Our study suggests that GEN-1 might act as a dual function Holliday junction resolvase that may coordinate DNA damage signaling with a late step in DNA double-strand break repair.

Sensitivity to Poly(ADP-ribose) Polymerase (PARP) Inhibition Identifies Ubiquitin-specific Peptidase 11 (USP11) as a Regulator of DNA Double-strand Break Repair

DNA damage repair and checkpoint responses prevent genome instability and provide a barrier to the development of cancer. Inherited mutations in DNA damage response (DDR) genes such as those that encode the homologous recombination (HR) proteins BRCA1 and BRCA2 cause cancer predisposition syndromes. PARP inhibitors are an exciting new class of targeted therapy for treating patients with HR repair-defective tumors. In this study, we use an RNAi screen to identify genes that when silenced cause synthetic lethality with the PARP inhibitor AZD2281. This screen identified the deubiquitylating enzyme USP11 as a participant in HR repair of DNA double-strand breaks. Silencing USP11 with siRNA leads to spontaneous DDR activation in otherwise undamaged cells and hypersensitivity to PARP inhibition, ionizing radiation, and other genotoxic stress agents. Moreover, we demonstrate that HR repair is defective in USP11-silenced cells. Finally, the recruitment of a subset of double-strand break repair proteins including RAD51 and 53BP1 to repair foci is misregulated in the absence of USP11 catalytic activity. Thus, our synthetic lethal approach identified USP11 as a component of the HR double-strand break repair pathway.

The radiosensitizing effect of Ku70/80 knockdown in MCF10A cells irradiated with X-rays and p(66)+Be(40) neutrons

BackgroundA better understanding of the underlying mechanisms of DNA repair after low- and high-LET radiations represents a research priority aimed at improving the outcome of clinical radiotherapy. To date however, our knowledge regarding the importance of DNA DSB repair proteins and mechanisms in the response of human cells to high-LET radiation, is far from being complete.MethodsWe investigated the radiosensitizing effect after interfering with the DNA repair capacity in a human mammary epithelial cell line (MCF10A) by lentiviral-mediated RNA interference (RNAi) of the Ku70 protein, a key-element of the nonhomologous end-joining (NHEJ) pathway. Following irradiation of control and Ku-deficient cell lines with either 6 MV X-rays or p(66)+Be(40) neutrons, cellular radiosensitivity testing was performed using a crystal violet cell proliferation assay. Chromosomal radiosensitivity was evaluated using the micronucleus (MN) assay.ResultsRNAi of Ku70 caused downregulation of both the Ku70 and the Ku80 proteins. This downregulation sensitized cells to both X-rays and neutrons. Comparable dose modifying factors (DMFs) for X-rays and neutrons of 1.62 and 1.52 respectively were obtained with the cell proliferation assay, which points to the similar involvement of the Ku heterodimer in the cellular response to both types of radiation beams. After using the MN assay to evaluate chromosomal radiosensitivity, the obtained DMFs for X-ray doses of 2 and 4 Gy were 2.95 and 2.66 respectively. After neutron irradiation, the DMFs for doses of 1 and 2 Gy were 3.36 and 2.82 respectively. The fact that DMFs are in the same range for X-rays and neutrons confirms a similar importance of the NHEJ pathway and the Ku heterodimer for repairing DNA damage induced by both X-rays and p(66)+Be(40) neutrons.ConclusionsInterfering with the NHEJ pathway enhanced the radiosensitivity of human MCF10A cells to low-LET X-rays and high-LET neutrons, pointing to the importance of the Ku heterodimer for repairing damage induced by both types of radiation. Further research using other high-LET radiation sources is however needed to unravel the involvement of DNA double strand break repair pathways and proteins in the cellular response of human cells to high-LET radiation.

Abstract 3927: Distinct roles of hMLH1-hMRE11 in homologous recombination and heteroduplex DNA repair at a single chromosomal locus

Abstract Increasing evidence indicates that the mismatch repair protein hMLH1 and DNA double-strand break (DSB) repair protein hMRE11 play multifunctional roles in various processes of DNA repair and damage response in human cells. Our previous studies have revealed a physical interaction between these two proteins and have suggested a role for hMRE11 in heteroduplex DNA repair and hMLH1-dependent DNA damage-induced G2 arrest. Here, we analyzed the effects of hMLH1-hMRE11 on homologous recombinational repair of an induced DSB and consequential heteroduplex repair at a single chromosomal locus by a newly developed reporter system. The results of these studies indicate that hMLH1 and hMRE11 display a synergistic anti-recombination effect and the hMLH1-mediated anti-recombination is at least partially dependent on its interaction with hMRE11, whereas the repair of heteroduplex DNA requires functional hMLH1 and hMRE11. Consistent with these results, chromatin immunoprecipitation (ChIP) analysis of the reporter locus demonstrates that DSB triggers the loading of hMLH1 and hMRE11 proteins to both the proximal region and the site containing heteroduplex DNA. However, in contrast to the proximal regions, loading of hMLH1-hMRE11 at the site of heteroduplex DNA also requires hMSH2, suggesting the involvement of DNA mismatch repair. In summary, our studies have provided evidence to suggest that, in addition to DNA damage response, hMLH1-hMRE11 are involved in at least two other DNA damage repair processes: anti-recombination and heteroduplex DNA repair. Our results implicate that mutations impairing the hMLH1-hMRE11 interaction might promote spontaneous chromosomal recombination between ectopic repetitive sequences and thereby increasing gene conversion and genomic instability. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 3927.

Abstract LB-55: Histone deacetylase inhibitor causes DNA damage and apoptosis by downregulation of repair enzymes in cancer but not normal cells: Basis of resistance of normal cells to HDACi

Abstract Histone deacetylase inhibitors (HDACi) developed as anti-cancer agents have a high degree of selectivity for killing cancer cells. HDACi induce acetylation of histones and many non-histone proteins, affecting gene expression, cell cycle progression, cell migration and cell death. The mechanism of the tumor selective action of HDACi is unclear. Here we show that the HDACi, SAHA (Suberoylanilide hydroxamic acid, vorinostat), induces DNA DSB (double strand break) in normal (HFS) and cancer (LNCaP, A549) cells, but normal cells in contrast to cancer cells repair the DSB despite continued culture with SAHA. In transformed cells, H2AX levels increased with continued culture with SAHA, while in normal cells, this marker of DNA DSB tended to decrease with time. To define the capacity of normal and transformed cells for repair of SAHA induced DNA DSB, cells were cultured for 24hr with SAHA, washed and continued culture without HDACi. In normal cells, the H2AX was undetectable by 2hr (presumably reflecting repair of DNA DSB), while persisting in transformed for duration of culture (presumably reflecting failure to repair DNA DSB) with consequent transformed cell death. Further, we found that SAHA suppressed DNA DSB repair proteins, e.g., RAD50, MRE11, Tip60 and PP2A, in cancer (LNCaP, A549) but not in normal cells (HFS). These findings indicate that the HDACi induces DNA damage in cancer and normal cells, but normal cells have the capacity to repair the DNA DSB, while cancer cells do not owing in part at least to suppression of DNA DSB repair proteins. This selective action of SAHA in inducing transformed cell death points to potential effective therapeutic strategies for combination therapy with HDACi with agents that suppress DNA damage repair proteins. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr LB-55.

Abstract 5379: Mechanism of fludarabine and oxaliplatin combined activity depends on the activity of XPF endonuclease

Abstract We set out to determine the mechanism by which fludarabine and oxaliplatin exert more than additive cell killing in chronic lymphocytic leukemia (CLL). We postulate that enhanced activity of oxaliplatin and fludarabine combination is based on termination by fludarabine of DNA re-synthesis associated with nucleotide excision repair (NER) following removal of oxaliplatin adducts. The blocked repair would result in single-strand and double-strand DNA breaks which would activate cell DNA damage signaling and apoptosis. More than additive apoptotic killing was observed in 49% (±22) of CLL cells after exposure to oxaliplatin and fludarabine in vitro, although single agents showed minimal increase in cell death (3% ±9 for oxaliplatin, 13% ±14 for fludarabine), as demonstrated by Annexin V and PI staining at 24 hr (expected vs. observed p=0.0003; n=10). Oxaliplatin induced a 2-fold increase in DNA synthesis in CLL cells, which was inhibited by fludarabine, as determined by thymidine incorporation (n=5). Knockdown of XPF, the NER 5′ endonuclease, in CLL patient samples (n=3) eliminated oxaliplatin induced DNA synthesis (3-fold increase in thymidine incorporation with scramble siRNA compared to 1.4-fold increase with XPF siRNA). Wild type CHO (AA8) cells showed more than additive killing after combination treatment similar to the observation with CLL patient samples (predicted survival 50%; observed 21%). In contrast, only additive killing was observed in CHO cells lacking XPF (UV41) with equitoxic doses of oxaliplatin and fludarabine (predicted survival 56%; observed 54%) suggesting that XPF function is essential for the cooperative interaction of the combination. Alkaline assays demonstrated that inhibition of repair by fludarabine was accompanied by DNA strand break formation within 12 hr (n=4) in CLL patients samples. The increase in Olive tail moment ranged from 2- to 5-fold, confirming induction of single-strand breaks. The double-strand break repair proteins ATM, SMC1, H2AX and DNA-PKcs were phosphorylated as early as 2 hr post-treatment with the combination and persisted up to 24 hr (3-fold, 24-fold, 10-fold and 10-fold increase, respectively; n=4). This response suggests that DNA damage generated by fludarabine and oxaliplatin exposure was processed to double-strand DNA breaks in CLL cells. Our work provides evidence that the combination of oxaliplatin and fludarabine results in the formation of toxic DNA damage and that their combined activity depends on a functional NER pathway. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 5379.

Androgen Receptor Interacts with Telomeric Proteins in Prostate Cancer Cells

The telomeric complex, shelterin, plays a critical role in protecting chromosome ends from erosion, and disruption of these complexes can lead to chromosomal instability culminating in cell death or malignant transformation. We reported previously that dominant-negative mutants of one of the telomeric proteins called TIN2 cause death of androgen receptor (AR)-negative but not AR-positive prostate cancer cells, raising the question of a possible role of AR in the structural stability of telomeric complexes. Consistent with this possibility, in the present study, we observed that the AR antagonist Casodex (bicalutamide) disrupted telomeric complexes in AR-positive LNCaP cells but not in AR-negative PC-3 cells. Immunofluorescent studies revealed colocalization of TIN2 and AR. Reciprocal immunoprecipitation studies showed association of AR with telomeric proteins. Furthermore, telomeric proteins were overexpressed in prostate cancer cells compared with normal prostate epithelial cells, and sucrose density gradient analysis showed co-sedimentation of AR with telomeric proteins in a shelterin-like mega complex. Together, these observations suggest an allosteric role of AR in telomere complex stability in prostate cancer cells and suggest that AR-antagonist Casodex-mediated cell death may be due to telomere complex disruption.

Xenopus DNA2 is a helicase/nuclease that is found in complexes with replication proteins And-1/Ctf4 and Mcm10 and DSB response proteins Nbs1 and ATM

We have used the Xenopus laevis egg extract system to study the roles of vertebrate Dna2 in DNA replication and double-strand-break (DSB) repair. We first establish that Xenopus Dna2 is a helicase, as well as a nuclease. We further show that Dna2 is a nuclear protein that is actively recruited to DNA only after replication origin licensing. Dna2 co-localizes in foci with RPA and is found in a complex with replication fork components And-1 and Mcm10. Dna2 interacts with the DSB repair and checkpoint proteins Nbs1 and ATM. We also determine the order of arrival of ATM, MRN, Dna2, TopBP1, and RPA to duplex DNA ends and show that it is the same both in S phase and M phase extracts. Interestingly, Dna2 can bind to DNA ends independently of MRN, but efficient nucleolytic resection, as measured by RPA recruitment, requires both MRN and Dna2. The nuclease activity of Mre11 is required, since its inhibition delays both full Dna2 recruitment and resection. Dna2 depletion inhibits but does not block resection, and Chk1 and Chk2 induction occurs in the absence of Dna2.

A natural compound, methyl angolensate, induces mitochondrial pathway of apoptosis in Daudi cells

Natural products discovered from medicinal plants have played an important role in the treatment of cancer. In an effort to identify novel small molecules which can affect the proliferation of lymphoma cells, we tested methyl angolensate (MA), a plant derived tetranortriterpenoid, purified from the crude extract of the root callus of Soymida febrifuga commonly known as Indian red wood tree. We have tested MA for its cytotoxic properties on Burkitt's lymphoma cell lines, using various cellular assays. We observed that MA induces cytotoxicity in Daudi cells in a dose-dependent manner using trypan blue, MTT and LDH assays. We find that the treatment with MA led to activation of DNA double-strand break repair proteins including KU70 and KU80, suggesting the activation of nonhomologous DNA end joining pathway in surviving cells. Further, we find that methyl angolensate could induce apoptosis by cell cycle analysis, annexin V-FITC staining, DNA fragmentation and PARP cleavage. Besides, MA treatment led to reactive oxygen species generation and loss of mitochondrial transmembrane potential. These results suggest the activation of mitochondrial pathway of apoptosis. Hence, we identify MA as a potential chemotherapeutic agent against Daudi cells.

Proteasome Nuclear Activity Affects Chromosome Stability by Controlling the Turnover of Mms22, a Protein Important for DNA Repair

To expand the known spectrum of genes that maintain genome stability, we screened a recently released collection of temperature sensitive (Ts) yeast mutants for a chromosome instability (CIN) phenotype. Proteasome subunit genes represented a major functional group, and subsequent analysis demonstrated an evolutionarily conserved role in CIN. Analysis of individual proteasome core and lid subunit mutations showed that the CIN phenotype at semi-permissive temperature is associated with failure of subunit localization to the nucleus. The resultant proteasome dysfunction affects chromosome stability by impairing the kinetics of double strand break (DSB) repair. We show that the DNA repair protein Mms22 is required for DSB repair, and recruited to chromatin in a ubiquitin-dependent manner as a result of DNA damage. Moreover, subsequent proteasome-mediated degradation of Mms22 is necessary and sufficient for cell cycle progression through the G2/M arrest induced by DNA damage. Our results demonstrate for the first time that a double strand break repair protein is a proteasome target, and thus link nuclear proteasomal activity and DSB repair.

Role of SIRT1 in homologous recombination

The class III histone deacetylase (HDAC) SIRT1 plays a role in the metabolism, aging, and carcinogenesis of organisms and regulates senescence and apoptosis in cells. Recent reports revealed that SIRT1 also deacetylates several DNA double-strand break (DSB) repair proteins. However, its exact functions in DNA repair remained elusive. Using nuclear foci analysis and fluorescence-based, chromosomal DSB repair reporter, we find that SIRT1 activity promotes homologous recombination (HR) in human cells. Importantly, this effect is unrelated to functions of poly(ADP-ribose) polymerase 1 (PARP1), another NAD(+)-catabolic protein, and does not correlate with cell cycle changes or apoptosis. Interestingly, we demonstrate that inactivation of Rad51 does not eliminate the effect of SIRT1 on HR. By epistasis-like analysis through knockdown and use of mutant cells of distinct SIRT1 target proteins, we show that the non-homologous end joining (NHEJ) factor Ku70 as well as the Nijmegen Breakage Syndrome protein (nibrin) are not needed for this SIRT1-mediated effect, even though a partial contribution of nibrin cannot be excluded. Strikingly however, the Werner helicase (WRN), which in its mutated form causes premature aging and cancer and which was linked to the Rad51-independent single-strand annealing (SSA) DSB repair pathway, is required for SIRT1-mediated HR. These results provide first evidence that links SIRT1's functions to HR with possible implications for genomic stability during aging and tumorigenesis.