Werner syndrome: association of premature aging and cancer predisposition

Byungchan Ahn; Tinna Stevnsner; Vilhelm A. Bohr

doi:10.1017/CBO9781139046947.036

35 - Werner syndrome: association of premature aging and cancer predisposition

from Part 2.4 - Molecular pathways underlying carcinogenesis: DNA repair

Published online by Cambridge University Press: 05 February 2015

Byungchan Ahn ,

Tinna Stevnsner and

Vilhelm A. Bohr

Edited by

Edward P. Gelmann ,

Charles L. Sawyers and

Frank J. Rauscher, III

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Byungchan Ahn: Affiliation:
Department of Life Sciences, University of Ulsan, Ulsan, Korea
Tinna Stevnsner: Affiliation:
Danish Centre for Molecular Gerontology and Danish Aging Research Center, University of Aarhus, Department of Molecular Biology, Denmark
Vilhelm A. Bohr: Affiliation:
Laboratory of Molecular Gerontology, Gerontology Research Center, National Institute on Aging, NIH, Baltimore, MD, USA
Edward P. Gelmann: Affiliation:
Columbia University, New York
Charles L. Sawyers: Affiliation:
Memorial Sloan-Kettering Cancer Center, New York
Frank J. Rauscher, III: Affiliation:
The Wistar Institute Cancer Centre, Philadelphia

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Summary

Introduction

Werner syndrome (WS) is a rare autosomal recessive disorder in humans characterized by segmental premature aging. Somatic cells from WS individuals show low replicative capacity, hypersensitivity to DNA-damaging agents, increased genome instability, and altered telomere maintenance (1). The incidence of sarcomas is significantly higher in WS patients than in normal individuals (1). Genetic evidence indicates that WS is caused by loss of function mutations in the WRN gene, which encodes a protein that belongs to the RecQ family of DNA helicases. Polymorphisms in WRN have been demonstrated to be associated with breast cancer (2) and soft tissue sarcomas (3,4). The WRN gene has been cloned and the properties of WS cells and WRN protein have been studied extensively. Nevertheless, the pathophysiology of WS and the cellular and molecular mechanisms involved in WS pathogenesis remain poorly understood. Because WS is a progerioid disease, it is used as a model system to better understand the process of aging in humans.

The exact biological role of WRN remains unknown. However, it has been proposed that it plays roles in the response to DNA damage. In particular, WRN may promote rescue of stalled replication forks and help resolve recombination intermediates in cells experiencing replicative stress. WRN also plays a role in telomere replication and alternative lengthening of telomeres. Thus, loss of function mutations in WRN could disrupt DNA replication and DNA-damage processing, resulting in accumulation of DNA double-strand breaks (DSBs) and recombination intermediates. These events could activate cell-cycle checkpoints resulting in senescence, apoptosis, or genetic instability leading to cellular transformation. These molecular endpoints could ultimately lead to features of premature aging and/or increased cancer susceptibility (Figure 35.1). This chapter discusses how WRN may contribute to genome stability and reduce cancer susceptibility.

Type: Chapter
Information: Molecular Oncology
Causes of Cancer and Targets for Treatment
, pp. 423 - 433

DOI: https://doi.org/10.1017/CBO9781139046947.036 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2013

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References

Hisama, FM, Bohr, VA, Oshima, J. WRN's tenth anniversary. Science of Aging Knowledge Environment 2006:pe18.

Wang, Z, Xu, Y, Tang, J, et al. A polymorphism in Werner syndrome gene is associated with breast cancer susceptibility in Chinese women. Breast Cancer Research and Treatment 2009;118:169–75.CrossRef

Hsu, JJ, Kamath-Loeb, AS, Glick, E, et al. Werner syndrome gene variants in human sarcomas. Molecular Carcinogenesis 2010;49:166–74.

Nakayama, R, Sato, Y, Masutani, M, et al. Association of a missense single nucleotide polymorphism, Cys1367Arg of the WRN gene, with the risk of bone and soft tissue sarcomas in Japan. Cancer Science 2008;99:333–9.CrossRef

Goto, M, Ishikawa, Y. [Werner syndrome]. Nippon Rinsho 2000;58:1490–5.

Huang, S, Lee, L, Hanson, NB, et al. The spectrum of WRN mutations in Werner syndrome patients. Human Mutation 2006;27:558–67.CrossRef

Kyng, KJ, May, A, Kolvraa, S, Bohr, VA. Gene expression profiling in Werner syndrome closely resembles that of normal aging. Proceedings of the National Academy of Sciences USA 2003;100:12 259–64.

Gray, MD, Shen, JC, Kamath-Loeb, AS, et al. The Werner syndrome protein is a DNA helicase. Nature Genetics 1997;17:100–3.CrossRef

Huang, S, Li, B, Gray, MD, et al. The premature ageing syndrome protein, WRN, is a 3ʹ→5ʹ exonuclease. Nature Genetics 1998;20:114–16.CrossRef

Machwe, A, Xiao, L, Groden, J, Matson, SW, Orren, DK. RecQ family members combine strand pairing and unwinding activities to catalyze strand exchange. Journal of Biological Chemistry 2005;280:23 397–407.CrossRef Google Scholar PubMed

Brosh, RM, Bohr, VA. Roles of the Werner syndrome protein in pathways required for maintenance of genome stability. Experimental Gerontology 2002;37:491–506.CrossRef

Suzuki, N, Shiratori, M, Goto, M, Furuichi, Y. Werner syndrome helicase contains a 5ʹ→3ʹ exonuclease activity that digests DNA and RNA strands in DNA/DNA and RNA/DNA duplexes dependent on unwinding. Nucleic Acids Research 1999;27:2361–8.CrossRef

Shen, JC, Loeb, LA. Werner syndrome exonuclease catalyzes structure-dependent degradation of DNA. Nucleic Acids Research 2000;28:3260–8.CrossRef

Huang, S, Beresten, S, Li, B, et al. Characterization of the human and mouse WRN 5ʹ→3ʹ exonuclease. Nucleic Acids Research 2000;28:2396–405.CrossRef

Brosh, RM, Orren, DK, Nehlin, JO, et al. Functional and physical interaction between WRN helicase and human replication protein A. Journal of Biological Chemistry 1999;274:1832–50.CrossRef Google Scholar PubMed

Laine, JP, Opresko, PL, Indig, FE, et al. Werner protein stimulates topoisomerase I DNA relaxation activity. Cancer Research 2003;63:7136–46.

Lebel, M, Spillare, EA, Harris, CC, Leder, P. The Werner syndrome gene product co-purifies with the DNA replication complex and interacts with PCNA and topoisomerase I. Journal of Biological Chemistry 1999;274:37 795–9.CrossRef Google Scholar PubMed

Kamath-Loeb, ASJohansson, E, Burgers, PM, Loeb, LA. Functional interaction between the Werner Syndrome protein and DNA polymerase delta. Proceedings of the National Academy of Sciences USA 2000;97:4603–8.CrossRef

Kamath-Loeb, AS, Loeb, LA, Johansson, E, Burgers, PM, Fry, M. Interactions between the Werner syndrome helicase and DNA polymerase delta specifically facilitate copying of tetraplex and hairpin structures of the d(CGG)n trinucleotide repeat sequence. Journal of Biological Chemistry 2001;276:16 439–46.CrossRef Google Scholar

Ahn, B, Harrigan, JA, Indig, FE, Wilson, DM, Bohr, VA. Regulation of WRN helicase activity in human base excision repair. Journal of Biological Chemistry 2004;279:53 465–74.CrossRef Google Scholar PubMed

von Kobbe, C, Harrigan, JA, May, A, et al. Central role for the Werner syndrome protein/poly(ADP-ribose) polymerase 1 complex in the poly(ADP-ribosyl)ation pathway after DNA damage. Molecular and Cellular Biology 2003;23:8601–13.CrossRef

Harrigan, JA, Opresko, PL, von Kobbe, C, et al. The Werner syndrome protein stimulates DNA polymerase beta strand displacement synthesis via its helicase activity. Journal of Biological Chemistry 2003;278:22 686–95.CrossRef Google Scholar PubMed

Brosh, RM, von Kobbe, C, Sommers, JA, et al. Werner syndrome protein interacts with human flap endonuclease 1 and stimulates its cleavage activity. EMBO Journal 2001;20:5791–801.CrossRef

Baynton, K, Otterlei, M, Bjoras, M, et al. WRN interacts physically and functionally with the recombination mediator protein RAD52. Journal of Biological Chemistry 2003;278:36 476–86.CrossRef Google Scholar PubMed

Cheng, WH, von KC, Opresko PL, et al. Linkage between Werner syndrome protein and the Mre11 complex via Nbs1. Journal of Biological Chemistry 2004;279:21 169–76.CrossRef Google Scholar PubMed

Cooper, MP, Machwe, A, Orren, DK, et al. Ku complex interacts with and stimulates the Werner protein. Genes and Development 2000;14:907–12.

Karmakar, P, Snowden, CM, Ramsden, DA, Bohr, VA. Ku heterodimer binds to both ends of the Werner protein and functional interaction occurs at the Werner N-terminus. Nucleic Acids Research 2002;30:3583–91.CrossRef

Sakamoto, S, Nishikawa, K, Heo, SJ, et al. Werner helicase relocates into nuclear foci in response to DNA damaging agents and co-localizes with RPA and Rad51. Genes and Cells 2001;6:421–30.CrossRef

Mathon, NF, Lloyd, AC. Cell senescence and cancer. Nature Reviews Cancer 2001;1:203–13.CrossRef

Campisi, J, d’Adda di Fagagna, F. Cellular senescence: when bad things happen to good cells. Nature Reviews Molecular and Cellular Biology 2007;8:729–40.CrossRef

Blasco, MA. Telomeres and human disease: ageing, cancer and beyond. Nature Reviews Genetics 2005;6:611–22.CrossRef

de Lange, T. Shelterin: the protein complex that shapes and safeguards human telomeres. Genes and Development 2005;19:2100–10.CrossRef

Salk, D, Bryant, E, Au, K, Hoehn, H, Martin, GM. Systematic growth studies, cocultivation, and cell hybridization studies of Werner syndrome cultured skin fibroblasts. Human Genetics 1981;58:310–16.CrossRef

Salk, D, Bryant, E, Hoehn, H, Johnston, P, Martin, GM. Growth characteristics of Werner syndrome cells in vitro. Advances in Experimental Medicine and Biology 1985;190:305–11.CrossRef

Davis, T, Singhrao, SK, Wyllie, FS, et al. Telomere-based proliferative lifespan barriers in Werner-syndrome fibroblasts involve both p53-dependent and p53-independent mechanisms. Journal of Cell Science 2003;116:1349–57.CrossRef Google Scholar PubMed

Wyllie, FS, Jones, CJ, Skinner, JW, et al. Telomerase prevents the accelerated cell ageing of Werner syndrome fibroblasts. Nature Genetics 2000;24:16–17.CrossRef

Crabbe, L. Telomere dysfunction as a cause of genomic instability in Werner syndrome. Proceedings of the National Academy of Sciences USA 2007;104:2205–10.CrossRef

Bai, Y, Murnane, JP. Telomere instability in a human tumor cell line expressing a dominant-negative WRN protein. Human Genetics 2003;113:337–47.CrossRef

Crabbe, L, Verdun, RE, Haggblom, CI, Karlseder, J. Defective telomere lagging strand synthesis in cells lacking WRN helicase activity. Science 2004;306:1951–3.CrossRef

Bryan, TM, Reddel, RR. Telomere dynamics and telomerase activity in in vitro immortalised human cells. European Journal of Cancer 1997;33:767–73.CrossRef Google Scholar PubMed

Dunham, MA, Neumann, AA, Fasching, CL, Reddel, RR. Telomere maintenance by recombination in human cells. Nature Genetics 2000;26:447–50.CrossRef

Yeager, TR, Neumann, AA, Englezou, A, et al. Telomerase-negative immortalized human cells contain a novel type of promyelocytic leukemia (PML) body. Cancer Research 1999;59:4175–9.

Johnson, FB, Marciniak, RA, McVey, M, et al. The Saccharomyces cerevisiae WRN homolog Sgs1p participates in telomere maintenance in cells lacking telomerase. EMBO Journal 2001;20:905–13.CrossRef

Opresko, PL, von Kobbe, C, Laine, JP, et al. Telomere-binding protein TRF2 binds to and stimulates the Werner and Bloom syndrome helicases. Journal of Biological Chemistry 2002;277:41 110–19.CrossRef Google Scholar PubMed

Opresko, PL, Otterlei, M, Graakjaer, J, et al. The Werner syndrome helicase and exonuclease cooperate to resolve telomeric D loops in a manner regulated by TRF1 and TRF2. Molecular Cell 2004;14:763–74.CrossRef

Mendez-Bermudez, A, Hidalgo-Bravo, A, Cotton, VE, et al. The roles of WRN and BLM RecQ helicases in the alternative lengthening of telomeres. Nucleic Acids Research 2012;40:10 809–20.

Eller, MS, Liao, X, Liu, S, et al. A role for WRN in telomere-based DNA damage responses. Proceedings of the National Academy of Sciences USA 2006;103:15 073–8.

Gebhart, E, Bauer, R, Raub, U, et al. Spontaneous and induced chromosomal instability in Werner syndrome. Human Genetics 1988;80:135–9.CrossRef

Pichierri, P, Franchitto, A, Mosesso, P, Palitti, F. Werner's syndrome cell lines are hypersensitive to camptothecin-induced chromosomal damage. Mutation Research 2000;456:45–57.CrossRef

Poot, M, Gollahon, KA, Emond, MJ, Silber, JR, Rabinovitch, PS. Werner syndrome diploid fibroblasts are sensitive to 4-nitroquinoline-N-oxide and 8-methoxypsoralen: implications for the disease phenotype. FASEB Journal 2002;16:757–8.CrossRef

Poot, M, Gollahon, KA, Rabinovitch, PS. Werner syndrome lymphoblastoid cells are sensitive to camptothecin-induced apoptosis in S-phase. Human Genetics 1999;104:10–14.CrossRef

Poot, M, Yom, JS, Whang, SH, et al. Werner syndrome cells are sensitive to DNA cross-linking drugs. FASEB Journal 2001;15:1224–6.CrossRef

Ogburn, CE, Oshima, J, Poot, M, et al. An apoptosis-inducing genotoxin differentiates heterozygotic carriers for Werner helicase mutations from wild-type and homozygous mutants. Human Genetics 1997;101:121–5.CrossRef

Okada, M, Goto, M, Furuichi, Y, Sugimoto, M. Differential effects of cytotoxic drugs on mortal and immortalized B-lymphoblastoid cell lines from normal and Werner's syndrome patients. Biological and Pharmaceutical Bulletin 1998;21:235–9.CrossRef

Grillari, J, Katinger, H, Voglauer, R. Contributions of DNA interstrand cross-links to aging of cells and organisms. Nucleic Acids Research 2007;35:7566–76.CrossRef

Cheng, WH, Kusumoto, R, Opresko, PL, et al. Collaboration of Werner syndrome protein and BRCA1 in cellular responses to DNA interstrand cross-links. Nucleic Acids Research 2006;34:2751–60.CrossRef

Otterlei, M, Bruheim, P, Ahn, B, et al. Werner syndrome protein participates in a complex with RAD51, RAD54, RAD54B and ATR in response to ICL-induced replication arrest. Journal of Cell Science 2006;119:5137–46.CrossRef Google Scholar

Cheng, WH, Muftic, D, Muftuoglu, M, et al. WRN is required for ATM activation and the S-phase checkpoint in response to interstrand cross-link-induced DNA double-strand breaks. Molecular Biology of the Cell 2008;19:3923–33.CrossRef

Shin, DS, Chahwan, C, Huffman, JL, Tainer, JA. Structure and function of the double-strand break repair machinery. DNA Repair (Amsterdan) 2004;3:863–73.CrossRef

West, SC. Molecular views of recombination proteins and their control. Nature Reviews Molecular and Cellular Biology 2003;4:435–45.CrossRef

O’Driscoll, M, Jeggo, PA. The role of double-strand break repair – insights from human genetics. Nature Reviews Genetics 2006;7:45–54.CrossRef

Cheng, WH, Sakamoto, S, Fox, JT, et al. Werner syndrome protein associates with gamma H2AX in a manner that depends upon Nbs1. FEBS Letters 2005;579:1350–6.CrossRef

Pichierri, P, Rosselli, F, Franchitto, A. Werner's syndrome protein is phosphorylated in an ATR/ATM-dependent manner following replication arrest and DNA damage induced during the S phase of the cell cycle. Oncogene 2003;22:1491–500.CrossRef

Ammazzalorso, F, Pirzio, LM, Bignami, M, Franchitto, A, Pichierri, P. ATR and ATM differently regulate WRN to prevent DSBs at stalled replication forks and promote replication fork recovery. EMBO Journal 2010;29:3156–69.CrossRef

Cliby, WA, Lewis, KA, Lilly, KK, Kaufmann, SH. S phase and G2 arrests induced by topoisomerase I poisons are dependent on ATR kinase function. Journal of Biological Chemistry 2002;277:1599–606.CrossRef Google Scholar PubMed

Flatten, K, Dai, NT, Vroman, BT, et al. The role of checkpoint kinase 1 in sensitivity to topoisomerase I poisons. Journal of Biological Chemistry 2005;280:14 349–55.CrossRef Google Scholar PubMed

Pichierri, P, Franchitto, A, Mosesso, P, Palitti, F. Werner's syndrome protein is required for correct recovery after replication arrest and DNA damage induced in S-phase of cell cycle. Molecular Biology of the Cell 2001;12:2412–21.CrossRef

Patro, BS, Frohlich, R, Bohr, VA, Stevnsner, T. WRN helicase regulates the ATR-CHK1-induced S-phase checkpoint pathway in response to topoisomerase-I-DNA covalent complexes. Journal of Cell Science 2011;124:3967–79.CrossRef Google Scholar PubMed

Oshima, J, Huang, S, Pae, C, Campisi, J, Schiestl, RH. Lack of WRN results in extensive deletion at nonhomologous joining ends. Cancer Research 2002;62:547–51.

Fukuchi, K, Martin, GM, Monnat, RJ Mutator phenotype of Werner syndrome is characterized by extensive deletions. Proceedings of the National Academy of Sciences USA 1989;86:5893–7.CrossRef

Salk, D, Au, K, Hoehn, H, Martin, GM. Cytogenetics of Werner's syndrome cultured skin fibroblasts: variegated translocation mosaicism. Cytogenetics and Cell Genetics 1981;30:92–107.CrossRef

Salk, D, Au, K, Hoehn, H, Martin, GM. Cytogenetic aspects of Werner syndrome. Advances in Experimental Medicine and Biology 1985;190:541–6.CrossRef

Prince, PR, Emond, MJ, Monnat, RJ Loss of Werner syndrome protein function promotes aberrant mitotic recombination. Genes and Development 2001;15:933–8.CrossRef

Lee, JW, Harrigan, J, Opresko, PL, Bohr, VA. Pathways and functions of the Werner syndrome protein. Mechanisms of Ageing and Development 2005;126:79–86.CrossRef

Mohaghegh, P, Karow, JK, Brosh, JR, Bohr, VA, Hickson, ID. The Bloom's and Werner's syndrome proteins are DNA structure-specific helicases. Nucleic Acids Research 2001;29:2843–9.CrossRef

Constantinou, A, Tarsounas, M, Karow, JK, et al. Werner's syndrome protein (WRN) migrates Holliday junctions and co-localizes with RPA upon replication arrest. EMBO Reports 2000;1:80–4.CrossRef

Sharma, S, Otterlei, M, Sommers, JA, et al. WRN helicase and FEN-1 form a complex upon replication arrest and together process branch migrating DNA structures associated with the replication fork. Molecular Biology of the Cell 2004;15:734–50.CrossRef

Lee, JW, Kusumoto, R, Doherty, KM, et al. Modulation of Werner syndrome protein function by a single mutation in the conserved RecQ domain. Journal of Biological Chemistry 2005;280:39 627–36.CrossRef Google Scholar PubMed

von Kobbe, C, Thoma, NH, Czyzewski, BK, Pavletich, NP, Bohr, VA. Werner syndrome protein contains three structure-specific DNA binding domains. Journal of Biological Chemistry 2003;278:52 997–3006.CrossRef Google Scholar PubMed

Rodriguez-Lopez, AM, Whitby, MC, Borer, CM, Bachler, MA, Cox, LS. Correction of proliferation and drug sensitivity defects in the progeroid Werner's Syndrome by Holliday junction resolution. Rejuvenation Research 2007;10:27–40.CrossRef

Rodriguez-Lopez, AM, Jackson, DA, Iborra, F, Cox, LS. Asymmetry of DNA replication fork progression in Werner's syndrome. Aging Cell 2002;1:30–9.CrossRef

Li, X, Heyer, WD. Homologous recombination in DNA repair and DNA damage tolerance. Cell Research 2008;18:99–113.CrossRef

Wu, L, Hickson, ID. The Bloom's syndrome helicase suppresses crossing over during homologous recombination. Nature 2003;426:870–4.CrossRef

Svoboda, DL, Vos, JM. Differential replication of a single, UV-induced lesion in the leading or lagging strand by a human cell extract: fork uncoupling or gap formation. Proceedings of the National Academy of Sciences USA 1995;92:11 975–9.

Heller, RC, Marians, KJ. Replisome assembly and the direct restart of stalled replication forks. Nature Reviews Molecular and Cellular Biology 2006;7:932–43.CrossRef

Courcelle, J, Donaldson, JR, Chow, KH, Courcelle, CT. DNA damage-induced replication fork regression and processing in Escherichia coli. Science 2003;299:1064–7.CrossRef

Sogo, JM, Lopes, M, Foiani, M. Fork reversal and ssDNA accumulation at stalled replication forks owing to checkpoint defects. Science 2002;297:599–602.CrossRef

Machwe, A, Xiao, L, Lloyd, RG, Bolt, E, Orren, DK. Replication fork regression in vitro by the Werner syndrome protein (WRN): holliday junction formation, the effect of leading arm structure and a potential role for WRN exonuclease activity. Nucleic Acids Research 2007;35:5729–47.CrossRef

Sidorova, JM, Kehrli, K, Mao, F, Monnat, R Distinct functions of human RECQ helicases WRN and BLM in replication fork recovery and progression after hydroxyurea-induced stalling. DNA Repair (Amsterdam) 2012;12:128–39.CrossRef

Pichierri, P, Nicolai, S, Cignolo, L, Bignami, M, Franchitto, A. The RAD9-RAD1-HUS1 (9.1.1) complex interacts with WRN and is crucial to regulate its response to replication fork stalling. Oncogene 2012;31:2809–23.CrossRef

Jiao, R, Harrigan, JA, Shevelev, I, et al. The Werner syndrome protein is required for recruitment of chromatin assembly factor 1 following DNA damage. Oncogene 2007;26:2311–22.

Turaga, RV, Massip, L, Chavez, A, Johnson, FB, Lebel, M. Werner syndrome protein prevents DNA breaks upon chromatin structure alteration. Aging Cell 2007;6:471–81.CrossRef

Vaziri, H, Dessain, SK, Ng, EE, et al. hSIR2(SIRT1) functions as an NAD-dependent p53 deacetylase. Cell 2001;107:149–59.CrossRef

Wang, C, Chen, L, Hou, X, et al. Interactions between E2F1 and SirT1 regulate apoptotic response to DNA damage. Nature Cell Biology 2006;8:1025–31.CrossRef

Jeong, J, Juhn, K, Lee, H, et al. SIRT1 promotes DNA repair activity and deacetylation of Ku70. Experimental Molecular Medicine 2007;39:8–13.CrossRef

Yuan, Z, Zhang, X, Sengupta, N, Lane, WS, Seto, E. SIRT1 regulates the function of the Nijmegen breakage syndrome protein. Molecular Cell 2007;27:149–62.CrossRef

Oberdoerffer, P, Michan, S, McVay, M, et al. SIRT1 redistribution on chromatin promotes genomic stability but alters gene expression during aging. Cell 2008;135:907–18.CrossRef

Li, K, Casta, A, Wang, R, et al. Regulation of WRN protein cellular localization and enzymatic activities by SIRT1-mediated deacetylation. Journal of Biological Chemistry 2008;283:7590–8.CrossRef Google Scholar PubMed

Kahyo, T, Mostoslavsky, R, Goto, M, Setou, M. Sirtuin-mediated deacetylation pathway stabilizes Werner syndrome protein. FEBS Letters 2008;582:2479–83.CrossRef

Uhl, M, Csernok, A, Aydin, S, et al. Role of SIRT1 in homologous recombination. DNA Repair (Amsterdam) 2010;9:383–93.CrossRef

Michishita, E, McCord, RA, Berber, E, et al. SIRT6 is a histone H3 lysine 9 deacetylase that modulates telomeric chromatin. Nature 2008;452:492–6.CrossRef

Salk, D. Werner's syndrome: a review of recent research with an analysis of connective tissue metabolism, growth control of cultured cells, and chromosomal aberrations. Human Genetics 1982;62:1–5.CrossRef

Goto, M, Miller, RW, Ishikawa, Y, Sugano, H. Excess of rare cancers in Werner syndrome (adult progeria). Cancer Epidemiology, Biomarkers and Prevention 1996;5:239–46.

Ishikawa, Y, Sugano, H, Matsumoto, T, et al. Unusual features of thyroid carcinomas in Japanese patients with Werner syndrome and possible genotype-phenotype relations to cell type and race. Cancer 1999;85:1345–52.3.0.CO;2-#>CrossRef

Nagy, R, Sweet, K, Eng, C. Highly penetrant hereditary cancer syndromes. Oncogene 2004;23:6445–70.CrossRef

Rajagopalan, H, Nowak, MA, Vogelstein, B, Lengauer, C. The significance of unstable chromosomes in colorectal cancer. Nature Reviews Cancer 2003;3:695–701.CrossRef

Vogelstein, B, Kinzler, KW. Cancer genes and the pathways they control. Nature Medicine 2004;10:789–99.CrossRef

Hickson, ID. RecQ helicases: caretakers of the genome. Nature Reviews Cancer 2003;3:169–78.CrossRef

van Brabant, AJ, Stan, R, Ellis, NA. DNA helicases, genomic instability, and human genetic disease. Annual Review of Genomics and Human Genetics 2000;1:409–59.CrossRef

Haupt, S, Berger, M, Goldberg, Z, Haupt, Y. Apoptosis – the p53 network. Journal of Cell Science 2003;116:4077–85.CrossRef Google Scholar PubMed

Hofseth, LJ, Hussain, SP, Harris, CC. p53: 25 years after its discovery. Trends in Pharmacological Sciences 2004;25:177–81.CrossRef

Levine, AJ. p53, the cellular gatekeeper for growth and division. Cell 1997;88:323–31.CrossRef

Spillare, EA, Robles, AI, Wang, XW, et al. p53-mediated apoptosis is attenuated in Werner syndrome cells. Genes and Development 1999;13:1355–60.CrossRef

Blander, G, Kipnis, J, Leal, JF, et al. Physical and functional interaction between p53 and the Werner's syndrome protein. Journal of Biological Chemistry 1999;274:29463–9.CrossRef Google Scholar PubMed

Spillare, EA, Wang, XW, , KC, et al. Redundancy of DNA helicases in p53-mediated apoptosis. Oncogene 2006;25:2119–23.CrossRef

Brosh, RM, Karmakar, P, Sommers, JA, et al. p53 Modulates the exonuclease activity of Werner syndrome protein. Journal of Biological Chemistry 2001;276:35 093–102.CrossRef Google Scholar PubMed

Yang, Q, Zhang, R, Wang, XW, et al. The processing of Holliday junctions by BLM and WRN helicases is regulated by p53. Journal of Biological Chemistry 2002;277:31 980–7.CrossRef Google Scholar PubMed

Sengupta, S, Harris, CC. p53: traffic cop at the crossroads of DNA repair and recombination. Nature Reviews Molecular and Cellular Biology 2005;6:44–55.CrossRef

Grandori, C, Wu, KJ, Fernandez, P, et al. Werner syndrome protein limits MYC-induced cellular senescence. Genes and Development 2003;17:1569–74.CrossRef

Kawabe, T, Tsuyama, N, Kitao, S, et al. Differential regulation of human RecQ family helicases in cell transformation and cell cycle. Oncogene 2000;19:4764–72.CrossRef

Shiratori, M, Sakamoto, S, Suzuki, N, et al. Detection by epitope-defined monoclonal antibodies of Werner DNA helicases in the nucleoplasm and their upregulation by cell transformation and immortalization. Journal of Cell Biology 1999;144:1–9.CrossRef Google Scholar PubMed

Opresko, PL, Calvo, JP, von KC, . Role for the Werner syndrome protein in the promotion of tumor cell growth. Mechanisms of Ageing and Development 2007;128:423–36.CrossRef

Arai, A, Chano, T, Futami, K, et al. RECQL1 and WRN proteins are potential therapeutic targets in head and neck squamous cell carcinoma. Cancer Research 2011;71:4598–607.CrossRef

Aggarwal, M, Sommers, JA, Shoemaker, RH, Brosh, RM Inhibition of helicase activity by a small molecule impairs Werner syndrome helicase (WRN) function in the cellular response to DNA damage or replication stress. Proceedings of the National Academy of Sciences USA 2011;108:1525–30.CrossRef

Agrelo, R, Cheng, WH, Setien, F, et al. Epigenetic inactivation of the premature aging Werner syndrome gene in human cancer. Proceedings of the National Academy of Sciences USA 2006;103:8822–7.CrossRef

Masuda, K, Banno, K, Yanokura, M, et al. Association of epigenetic inactivation of the WRN gene with anticancer drug sensitivity in cervical cancer cells. Oncology Reports 2012;28:1146–52.CrossRef

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35 - Werner syndrome: association of premature aging and cancer predisposition

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