Your search keyword '"Svenson U"' showing total 25 results

1. Association between telomere length and risk of cancer and non-neoplastic diseases: A Mendelian randomization study

Author

Collaboration, Telomeres Mendelian Randomization, Haycock, P, Burgess, S, Nounu, A, Zheng, J, Okoli, G, Bowden, J, Wade, K, Timpson, N, Evans, D, Willeit, P, Aviv, A, Gaunt, T, Hemani, G, Mangino, M, Ellis, H, Kurian, K, Pooley, K, Eeles, R, Lee, J, Fang, S, Chen, W, Law, M, Bowdler, L, Iles, M, Yang, Q, Worrall, B, Markus, H, Hung, R, Amos, C, Spurdle, A, Thompson, D, O'Mara, T, Wolpin, B, Amundadottir, L, Stolzenberg-Solomon, R, Trichopoulou, A, Onland-Moret, N, Lund, E, Duell, E, Canzian, F, Severi, G, Overvad, K, Gunter, M, Tumino, R, Svenson, U, van Rij, A, Baas, A, Bown, M, Samani, N, van t'Hof, F, Tromp, G, Jones, G, Kuivaniemi, H, Elmore, J, Johansson, M, Mckay, J, Scelo, G, Carreras-Torres, R, Gaborieau, V, Brennan, P, Bracci, P, Neale, R, Olson, S, Gallinger, S, Li, D, Petersen, G, Risch, H, Klein, A, Han, J, Abnet, C, Freedman, N, Taylor, P, Maris, J, Aben, K, Kiemeney, L, Vermeulen, S, Wiencke, J, Walsh, K, Wrensch, M, Rice, T, Turnbull, C, Litchfield, K, Paternoster, L, Standl, M, Abecasis, G, SanGiovanni, J, Li, Y, Mijatovic, V, Sapkota, Y, Low, S, Zondervan, K, Montgomery, G, Nyholt, D, van Heel, D, Hunt, K, Arking, D, Ashar, F, Sotoodehnia, N, Woo, D, Rosand, J, Comeau, M, Brown, W, Silverman, E, Hokanson, J, Cho, M, Hui, J, Ferreira, M, Thompson, P, Morrison, A, Felix, J, Smith, N, Christiano, A, Petukhova, L, Betz, R, Fan, X, Zhang, X, Zhu, C, Langefeld, C, Thompson, S, Wang, F, Lin, X, Schwartz, D, Fingerlin, T, Rotter, J, Cotch, M, Jensen, R, Munz, M, Dommisch, H, Schaefer, A, Han, F, Ollila, H, Hillary, R, Albagha, O, Ralston, S, Zeng, C, Zheng, W, Shu, X, Reis, A, Uebe, S, Hüffmeier, U, Kawamura, Y, Otowa, T, Sasaki, T, Hibberd, M, Davila, S, Xie, G, Siminovitch, K, Bei, J, Zeng, Y, Försti, A, Chen, B, Landi, S, Franke, A, Fischer, A, Ellinghaus, D, Flores, C, Noth, I, Ma, S, Foo, J, Liu, J, Kim, J, Cox, D, Delattre, O, Mirabeau, O, Skibola, C, Tang, C, Garcia-Barcelo, M, Chang, K, Su, W, Chang, Y, Martin, N, Gordon, S, Wade, T, Lee, C, Kubo, M, Cha, P, Nakamura, Y, Levy, D, Kimura, M, Hwang, S, Hunt, S, Spector, T, Soranzo, N, Manichaikul, A, Barr, R, Kahali, B, Speliotes, E, Yerges-Armstrong, L, Cheng, C, Jonas, J, Wong, T, Fogh, I, Lin, K, Powell, J, Rice, K, Relton, C, Martin, R, Davey Smith, G, Erasmus MC other, Epidemiology, and Pediatrics

Subjects

0301 basic medicine, Adult, Male, Cancer Research, Single-nucleotide polymorphism, Genome-wide association study, Disease, Bioinformatics, Polymorphism, Single Nucleotide, Risk Assessment, Article, 03 medical and health sciences, Telomere Homeostasis, SDG 3 - Good Health and Well-being, Neoplasms, Mendelian randomization, Journal Article, medicine, Humans, Genetic Predisposition to Disease, Càncer, Germ-Line Mutation, Aged, Cancer, Aged, 80 and over, business.industry, Nucleotides, Odds ratio, Mendelian Randomization Analysis, Middle Aged, Telomere, medicine.disease, Nucleòtids, 030104 developmental biology, Stem cell division, Oncology, Cardiovascular Diseases, Urological cancers Radboud Institute for Health Sciences [Radboudumc 15], Female, ICEP, business, Genome-Wide Association Study, Bristol Population Health Science Institute

Abstract

Importance The causal direction and magnitude of the association between telomere length and incidence of cancer and non-neoplastic diseases is uncertain owing to the susceptibility of observational studies to confounding and reverse causation. Objective To conduct a Mendelian randomization study, using germline genetic variants as instrumental variables, to appraise the causal relevance of telomere length for risk of cancer and non-neoplastic diseases. Data Sources Genomewide association studies (GWAS) published up to January 15, 2015. Study Selection GWAS of noncommunicable diseases that assayed germline genetic variation and did not select cohort or control participants on the basis of preexisting diseases. Of 163 GWAS of noncommunicable diseases identified, summary data from 103 were available. Data Extraction and Synthesis Summary association statistics for single nucleotide polymorphisms (SNPs) that are strongly associated with telomere length in the general population. Main Outcomes and Measures Odds ratios (ORs) and 95%confidence intervals (CIs) for disease per standard deviation (SD) higher telomere length due to germline genetic variation. Results Summary data were available for 35 cancers and 48 non-neoplastic diseases, corresponding to 420 081 cases (median cases, 2526 per disease) and 1 093 105 controls (median, 6789 per disease). Increased telomere length due to germline genetic variation was generally associated with increased risk for site-specific cancers. The strongest associations (ORs [95%CIs] per 1-SD change in genetically increased telomere length) were observed for glioma, 5.27 (3.15-8.81); serous low-malignant-potential ovarian cancer, 4.35 (2.39-7.94); lung adenocarcinoma, 3.19 (2.40-4.22); neuroblastoma, 2.98 (1.92-4.62); bladder cancer, 2.19 (1.32-3.66); melanoma, 1.87 (1.55-2.26); testicular cancer, 1.76 (1.02-3.04); kidney cancer, 1.55 (1.08-2.23); and endometrial cancer, 1.31 (1.07-1.61). Associations were stronger for rarer cancers and at tissue sites with lower rates of stem cell division. There was generally little evidence of association between genetically increased telomere length and risk of psychiatric, autoimmune, inflammatory, diabetic, and other non-neoplastic diseases, except for coronary heart disease (OR, 0.78 [95%CI, 0.67-0.90]), abdominal aortic aneurysm (OR, 0.63 [95%CI, 0.49-0.81]), celiac disease (OR, 0.42 [95%CI, 0.28-0.61]) and interstitial lung disease (OR, 0.09 [95%CI, 0.05-0.15]). Conclusions and Relevance It is likely that longer telomeres increase risk for several cancers but reduce risk for some non-neoplastic diseases, including cardiovascular diseases.

Published

2017

2. Association between telomere length and risk of cancer and non-neoplastic diseases a mendelian randomization study

Author

Haycock, PC, Burgess, S, Nounu, A, Zheng, J, Okoli, GN, Bowden, J, Wade, KH, Timpson, NJ, Evans, DM, Willeit, P, Aviv, A, Gaunt, TR, Hemani, G, Mangino, M, Ellis, HP, Kurian, KM, Pooley, KA, Eeles, RA, Lee, JE, Fang, S, Chen, WV, Law, MH, Bowdler, LM, Iles, MM, Yang, Q, Worrall, BB, Markus, HS, Hung, RJ, Amos, CI, Spurdle, AB, Thompson, DJ, O'Mara, TA, Wolpin, B, Amundadottir, L, Stolzenberg-Solomon, R, Trichopoulou, A, Onland-Moret, NC, Lund, E, Duell, EJ, Canzian, F, Severi, G, Overvad, K, Gunter, MJ, Tumino, R, Svenson, U, Van Rij, A, Baas, AF, Bown, MJ, Samani, NJ, Van t'Hof, FNG, Tromp, G, Jones, GT, Kuivaniemi, H, Elmore, JR, Johansson, M, Mckay, J, Scelo, G, Carreras-Torres, R, Gaborieau, V, Brennan, P, Bracci, PM, Neale, RE, Olson, SH, Gallinger, S, Li, D, Petersen, GM, Risch, HA, Klein, AP, Han, J, Abnet, CC, Freedman, ND, Taylor, PR, Maris, JM, Aben, KK, Kiemeney, LA, Vermeulen, SH, Wiencke, JK, and Walsh, KM

Abstract

Copyright 2017 American Medical Association. All rights reserved. IMPORTANCE: The causal direction and magnitude of the association between telomere length and incidence of cancer and non-neoplastic diseases is uncertain owing to the susceptibility of observational studies to confounding and reverse causation. OBJECTIVE: To conduct a Mendelian randomization study, using germline genetic variants as instrumental variables, to appraise the causal relevance of telomere length for risk of cancer and non-neoplastic diseases. DATA SOURCES: Genomewide association studies (GWAS) published up to January 15, 2015. STUDY SELECTION: GWAS of noncommunicable diseases that assayed germline genetic variation and did not select cohort or control participants on the basis of preexisting diseases. Of 163 GWAS of noncommunicable diseases identified, summary data from 103 were available. DATA EXTRACTION AND SYNTHESIS: Summary association statistics for single nucleotide polymorphisms (SNPs) that are strongly associated with telomere length in the general population. MAIN OUTCOMES AND MEASURES: Odds ratios (ORs) and 95% confidence intervals (CIs) for disease per standard deviation (SD) higher telomere length due to germline genetic variation. RESULTS: Summary data were available for 35 cancers and 48 non-neoplastic diseases, corresponding to 420 081 cases (median cases, 2526 per disease) and 1 093 105 controls (median, 6789 per disease). Increased telomere length due to germline genetic variation was generally associated with increased risk for site-specific cancers. The strongest associations (ORs [95% CIs] per 1-SD change in genetically increased telomere length) were observed for glioma, 5.27 (3.15-8.81); serous low-malignant-potential ovarian cancer, 4.35 (2.39-7.94); lung adenocarcinoma, 3.19 (2.40-4.22); neuroblastoma, 2.98 (1.92-4.62); bladder cancer, 2.19 (1.32-3.66); melanoma, 1.87 (1.55-2.26); testicular cancer, 1.76 (1.02-3.04); kidney cancer, 1.55 (1.08-2.23); and endometrial cancer, 1.31 (1.07-1.61). Associations were stronger for rarer cancers and at tissue sites with lower rates of stem cell division. There was generally little evidence of association between genetically increased telomere length and risk of psychiatric, autoimmune, inflammatory, diabetic, and other non-neoplastic diseases, except for coronary heart disease (OR, 0.78 [95% CI, 0.67-0.90]), abdominal aortic aneurysm (OR, 0.63 [95% CI, 0.49-0.81]), celiac disease (OR, 0.42 [95% CI, 0.28-0.61]) and interstitial lung disease (OR, 0.09 [95% CI, 0.05-0.15]). CONCLUSIONS AND RELEVANCE: It is likely that longer telomeres increase risk for several cancers but reduce risk for some non-neoplastic diseases, including cardiovascular diseases.

Published

2017

3. Telomere length was similar in school-age children with bronchopulmonary dysplasia and allergic asthma

Author

Henckel, E, primary, Svenson, U, additional, Nordlund, B, additional, Berggren Broström, E, additional, Hedlin, G, additional, Degerman, S, additional, and Bohlin, K, additional

Published

2018

4. Association Between Telomere Length and Risk of Cancer and Non-Neoplastic Diseases: A Mendelian Randomization Study

Author

Haycock, P.C., Burgess, S., Nounu, A., Zheng, J., Okoli, G.N., Bowden, J., Wade, K.H., Timpson, N.J., Evans, D.M., Willeit, P., Aviv, A., Gaunt, T.R., Hemani, G., Mangino, M., Ellis, H.P., Kurian, K.M., Pooley, K.A., Eeles, R.A., Lee, J.E., Fang, S., Chen, W.V., Law, M.H., Bowdler, L.M., Iles, M.M., Yang, Q., Worrall, B.B., Markus, H.S., Hung, R.J., Amos, C.I., Spurdle, A.B., Thompson, D.J., O'Mara, T.A., Wolpin, B., Amundadottir, L., Stolzenberg-Solomon, R., Trichopoulou, A., Onland-Moret, N.C., Lund, E., Duell, E.J., Canzian, F., Severi, G., Overvad, K., Gunter, M.J., Tumino, R., Svenson, U., Rij, A. van, Baas, A.F., Bown, M.J., Samani, N.J., t'Hof, F.N.G. van, Tromp, G., Jones, G.T., Kuivaniemi, H., Elmore, J.R., Johansson, M., McKay, J., Scelo, G., Carreras-Torres, R., Gaborieau, V., Brennan, P., Bracci, P.M., Neale, R.E., Olson, S.H., Gallinger, S., Li, D., Petersen, G.M., Risch, H.A., Klein, A.P., Han, J., Abnet, C.C., Freedman, N.D., Taylor, P.R., Maris, J.M., Aben, K.K.H., Kiemeney, L.A., Vermeulen, S.H., Wiencke, J.K., Walsh, K.M., Wrensch, M., Rice, T., Turnbull, C., Litchfield, K., Paternoster, L., Standl, M., Abecasis, G.R., SanGiovanni, J.P., Li, Y., Mijatovic, V., Sapkota, Y., Low, S.K., Zondervan, K.T., Montgomery, G.W., Nyholt, D.R., Heel, D.A. van, Hunt, K., Arking, D.E., Ashar, F.N., Sotoodehnia, N., Woo, D., et al., Haycock, P.C., Burgess, S., Nounu, A., Zheng, J., Okoli, G.N., Bowden, J., Wade, K.H., Timpson, N.J., Evans, D.M., Willeit, P., Aviv, A., Gaunt, T.R., Hemani, G., Mangino, M., Ellis, H.P., Kurian, K.M., Pooley, K.A., Eeles, R.A., Lee, J.E., Fang, S., Chen, W.V., Law, M.H., Bowdler, L.M., Iles, M.M., Yang, Q., Worrall, B.B., Markus, H.S., Hung, R.J., Amos, C.I., Spurdle, A.B., Thompson, D.J., O'Mara, T.A., Wolpin, B., Amundadottir, L., Stolzenberg-Solomon, R., Trichopoulou, A., Onland-Moret, N.C., Lund, E., Duell, E.J., Canzian, F., Severi, G., Overvad, K., Gunter, M.J., Tumino, R., Svenson, U., Rij, A. van, Baas, A.F., Bown, M.J., Samani, N.J., t'Hof, F.N.G. van, Tromp, G., Jones, G.T., Kuivaniemi, H., Elmore, J.R., Johansson, M., McKay, J., Scelo, G., Carreras-Torres, R., Gaborieau, V., Brennan, P., Bracci, P.M., Neale, R.E., Olson, S.H., Gallinger, S., Li, D., Petersen, G.M., Risch, H.A., Klein, A.P., Han, J., Abnet, C.C., Freedman, N.D., Taylor, P.R., Maris, J.M., Aben, K.K.H., Kiemeney, L.A., Vermeulen, S.H., Wiencke, J.K., Walsh, K.M., Wrensch, M., Rice, T., Turnbull, C., Litchfield, K., Paternoster, L., Standl, M., Abecasis, G.R., SanGiovanni, J.P., Li, Y., Mijatovic, V., Sapkota, Y., Low, S.K., Zondervan, K.T., Montgomery, G.W., Nyholt, D.R., Heel, D.A. van, Hunt, K., Arking, D.E., Ashar, F.N., Sotoodehnia, N., Woo, D., and et al.

Abstract

Contains fulltext : 174181.pdf (publisher's version ) (Closed access), Importance: The causal direction and magnitude of the association between telomere length and incidence of cancer and non-neoplastic diseases is uncertain owing to the susceptibility of observational studies to confounding and reverse causation. Objective: To conduct a Mendelian randomization study, using germline genetic variants as instrumental variables, to appraise the causal relevance of telomere length for risk of cancer and non-neoplastic diseases. Data Sources: Genomewide association studies (GWAS) published up to January 15, 2015. Study Selection: GWAS of noncommunicable diseases that assayed germline genetic variation and did not select cohort or control participants on the basis of preexisting diseases. Of 163 GWAS of noncommunicable diseases identified, summary data from 103 were available. Data Extraction and Synthesis: Summary association statistics for single nucleotide polymorphisms (SNPs) that are strongly associated with telomere length in the general population. Main Outcomes and Measures: Odds ratios (ORs) and 95% confidence intervals (CIs) for disease per standard deviation (SD) higher telomere length due to germline genetic variation. Results: Summary data were available for 35 cancers and 48 non-neoplastic diseases, corresponding to 420081 cases (median cases, 2526 per disease) and 1093105 controls (median, 6789 per disease). Increased telomere length due to germline genetic variation was generally associated with increased risk for site-specific cancers. The strongest associations (ORs [95% CIs] per 1-SD change in genetically increased telomere length) were observed for glioma, 5.27 (3.15-8.81); serous low-malignant-potential ovarian cancer, 4.35 (2.39-7.94); lung adenocarcinoma, 3.19 (2.40-4.22); neuroblastoma, 2.98 (1.92-4.62); bladder cancer, 2.19 (1.32-3.66); melanoma, 1.87 (1.55-2.26); testicular cancer, 1.76 (1.02-3.04); kidney cancer, 1.55 (1.08-2.23); and endometrial cancer, 1.31 (1.07-1.61). Associations were stronger for rarer cance

Published

2017

5. Association between telomere length and risk of cancer and non-neoplastic diseases a mendelian randomization study

Author

Haycock, P. (Philip), Burgess, S. (Stephen), Nounu, A. (Aayah), Zheng, J. (Jie), Okoli, G.N. (George N.), Bowden, J., Wade, K.H. (Kaitlin Hazel), Timpson, N.J. (Nicholas J.), Evans, D.M. (David M.), Willeit, P. (Peter), Aviv, A. (Abraham), Gaunt, T.R. (Tom), Hemani, G., Mangino, M. (Massimo), Ellis, H.P. (Hayley Patricia), Kurian, K.M. (Kathreena M.), Pooley, K.A. (Karen A.), Eeles, R. (Rosalind), Lee, J.E. (Jeffrey E.), Fang, S. (Shenying), Chen, W.V. (Wei V.), Law, M.H. (Matthew H.), Bowdler, L.M. (Lisa M.), Iles, M.M. (Mark M.), Yang, Q. (Qiong Fang), Worrall, B.B. (Bradford B.), Markus, H.S. (Hugh), Hung, R.J. (Rayjean J.), Amos, W., Spurdle, A.B. (Amanda), Thompson, D. (Deborah), O'Mara, T.A. (Tracy A.), Wolpin, B. (Brian), Amundadottir, L. (Laufey), Stolzenberg-Solomon, R. (Rachael), Trichopoulou, A. (Antonia), Onland-Moret, N.C. (Charlotte), Lund, E. (Eiliv), Duell, E.J. (Eric), Canzian, F. (Federico), Severi, G. (Gianluca), Overvad, K. (Kim), Gunter, M.J. (Marc J.), Tumino, R. (Rosario), Svenson, U. (Ulrika), Rij, A.M. (Andre) van, Baas, A.F. (Annette), Bown, N., Samani, N.J. (Nilesh), Van t'Hof, F.N.G. (Femke N.G.), Tromp, G. (Gerard), Jones, G.T. (Gregory T.), Kuivaniemi, H. (Helena), Elmore, J.R. (James R.), Johansson, M. (Mattias), Mckay, J. (James), Scelo, G. (Ghislaine), Carreras-Torres, R. (Robert), Gaborieau, V. (Valerie), Brennan, P. (Paul), Bracci, P.M. (Paige M.), Neale, R.E. (Rachel E.), Olson, S.H. (Sara H.), Gallinger, S. (Steve), Li, D. (Donghui), Olson, S.H. (Sara), Risch, H. (Harvey), Klein, A.P. (Alison P.), Han, J., Abnet, C.C. (Christian C.), Freedman, N.D. (Neal D.), Taylor, P.R. (Phil R.), Maris, J.M. (John), Aben, K.K.H. (Katja), Kiemeney, L.A.L.M. (Bart), Vermeulen, S.H.H.M. (Sita), Wiencke, J.K. (John K.), Walsh, K.M. (Kyle M.), Wrensch, M. (Margaret), Rice, T. (Terri), Turnbull, C. (Clare), Litchfield, K. (Kevin), Paternoster, L. (Lavinia), Standl, M. (Marie), Abecasis, G.R. (Gonçalo), SanGiovanni, J.P. (John Paul), Li, Y. (Yong), Mijatovic, V. (Vladan), Sapkota, Y. (Yadav), Low, S.-K. (Siew-Kee), Zondervan, K.T. (Krina), Montgomery, G.W. (Grant W.), Nyholt, D.R. (Dale), Heel, D.A. (David) van, Hunt, K. (Karen), Arking, D.E. (Dan), Ashar, F.N. (Foram N.), Sotoodehnia, N. (Nona), Woo, D. (Daniel), Rosand, J. (Jonathan), Comeau, M.E. (Mary E.), Brown, W.M. (W. Mark), Silverman, E. (Edwin), Hokanson, J.E. (John E.), Cho, M.H. (Michael), Hui, J. (Jennie), Ferreira, M.A. (Manuel A.), Thompson, P.J. (Philip J.), Morrison, A.C. (Alanna), Felix, J.F. (Janine F.), Smith, N.L. (Nicholas L.), Christiano, A.M. (Angela), Petukhova, L. (Lynn), Betz, R.C. (Regina), Fan, X. (Xing), Zhang, X. (Xuejun), Zhu, C. (Caihong), Langefeld, C.D. (Carl), Thompson, S.D. (Susan D.), Wang, F. (Feijie), Lin, X. (Xu), Schwartz, D.A. (David A.), Fingerlin, T.E. (Tasha E.), Rotter, J.I. (Jerome I.), Cotch, M.F. (Mary Frances), Jensen, R.A. (Richard A.), Munz, M. (Matthias), Dommisch, H. (Henrik), Schaefer, A. (Antje), Han, F. (Fang), Ollila, H.M., Hillary, R.P. (Ryan P.), Albagha, O.M.E. (Omar M.), Ralston, S.H. (Stuart), Zeng, C. (Chenjie), Zheng, W. (Wei), Shu, X.-O. (Xiao-Ou), Reis, A. (André), Uebe, S. (Steffen), Hüffmeier, U. (Ulrike), Kawamura, Y. (Yoshiya), Otowa, T. (Takeshi), Sasaki, T. (Tsukasa), Hibberd, M.L. (Martin), Davila, S. (Sonia), Xie, G. (Gang), Siminovitch, K.A. (Katherine), Bei, J.-X. (Jin-Xin), Zeng, Y.X., Försti, A. (Asta), Chen, B. (Bowang), Landi, S. (Stefano), Franke, A. (Andre), Fischer, A. (Annegret), Ellinghaus, D. (David), Flores, C. (Carlos), Noth, I. (Imre), Ma, S.-F. (Shwu-Fan), Foo, J.-N. (Jia-Nee), Liu, J. (Jianjun), Kim, J.-W. (Jong-Won), Cox, D.G. (David), Delattre, O. (Olivier), Mirabeau, O. (Olivier), Skibola, C.F. (Christine F.), Tang, C.S. (Clara S.), Garcia-Barcelo, M., Chang, K.-P. (Kai-Ping), Su, W.-H. (Wen-Hui), Chang, Y.-S. (Yu-Sun), Martin, N.G. (Nicholas G.), Gordon, S.D. (Scott D.), Wade, T.D. (Tracey D.), Lee, C. (Chaeyoung), Kubo, M. (Michiaki), Cha, P.-C. (Pei-Chieng), Nakamura, Y. (Yusuke), Levy, D. (Daniel), Kimura, M. (Masayuki), Hwang, S.-J. (Shih-Jen), Hunt, S.C. (Steven), Spector, T.D. (Timothy), Soranzo, N. (Nicole), Manichaikul, A.W. (Ani W.), Barr, R.G. (Graham), Kahali, B. (Bratati), Speliotes, E.K. (Elizabeth), Yerges-Armstrong, L.M. (Laura), Cheng, C-Y. (Ching-Yu), Jonas, J.B. (Jost B.), Wong, T.Y. (Tien Yin), Fogh, I. (Isabella), Lin, K. (Kuang), Powell, J. (John), Rice, K. (Kenneth), Relton, C.L. (Caroline), Martin, R.M. (Richard M.), Smith, A.V. (Davey), Haycock, P. (Philip), Burgess, S. (Stephen), Nounu, A. (Aayah), Zheng, J. (Jie), Okoli, G.N. (George N.), Bowden, J., Wade, K.H. (Kaitlin Hazel), Timpson, N.J. (Nicholas J.), Evans, D.M. (David M.), Willeit, P. (Peter), Aviv, A. (Abraham), Gaunt, T.R. (Tom), Hemani, G., Mangino, M. (Massimo), Ellis, H.P. (Hayley Patricia), Kurian, K.M. (Kathreena M.), Pooley, K.A. (Karen A.), Eeles, R. (Rosalind), Lee, J.E. (Jeffrey E.), Fang, S. (Shenying), Chen, W.V. (Wei V.), Law, M.H. (Matthew H.), Bowdler, L.M. (Lisa M.), Iles, M.M. (Mark M.), Yang, Q. (Qiong Fang), Worrall, B.B. (Bradford B.), Markus, H.S. (Hugh), Hung, R.J. (Rayjean J.), Amos, W., Spurdle, A.B. (Amanda), Thompson, D. (Deborah), O'Mara, T.A. (Tracy A.), Wolpin, B. (Brian), Amundadottir, L. (Laufey), Stolzenberg-Solomon, R. (Rachael), Trichopoulou, A. (Antonia), Onland-Moret, N.C. (Charlotte), Lund, E. (Eiliv), Duell, E.J. (Eric), Canzian, F. (Federico), Severi, G. (Gianluca), Overvad, K. (Kim), Gunter, M.J. (Marc J.), Tumino, R. (Rosario), Svenson, U. (Ulrika), Rij, A.M. (Andre) van, Baas, A.F. (Annette), Bown, N., Samani, N.J. (Nilesh), Van t'Hof, F.N.G. (Femke N.G.), Tromp, G. (Gerard), Jones, G.T. (Gregory T.), Kuivaniemi, H. (Helena), Elmore, J.R. (James R.), Johansson, M. (Mattias), Mckay, J. (James), Scelo, G. (Ghislaine), Carreras-Torres, R. (Robert), Gaborieau, V. (Valerie), Brennan, P. (Paul), Bracci, P.M. (Paige M.), Neale, R.E. (Rachel E.), Olson, S.H. (Sara H.), Gallinger, S. (Steve), Li, D. (Donghui), Olson, S.H. (Sara), Risch, H. (Harvey), Klein, A.P. (Alison P.), Han, J., Abnet, C.C. (Christian C.), Freedman, N.D. (Neal D.), Taylor, P.R. (Phil R.), Maris, J.M. (John), Aben, K.K.H. (Katja), Kiemeney, L.A.L.M. (Bart), Vermeulen, S.H.H.M. (Sita), Wiencke, J.K. (John K.), Walsh, K.M. (Kyle M.), Wrensch, M. (Margaret), Rice, T. (Terri), Turnbull, C. (Clare), Litchfield, K. (Kevin), Paternoster, L. (Lavinia), Standl, M. (Marie), Abecasis, G.R. (Gonçalo), SanGiovanni, J.P. (John Paul), Li, Y. (Yong), Mijatovic, V. (Vladan), Sapkota, Y. (Yadav), Low, S.-K. (Siew-Kee), Zondervan, K.T. (Krina), Montgomery, G.W. (Grant W.), Nyholt, D.R. (Dale), Heel, D.A. (David) van, Hunt, K. (Karen), Arking, D.E. (Dan), Ashar, F.N. (Foram N.), Sotoodehnia, N. (Nona), Woo, D. (Daniel), Rosand, J. (Jonathan), Comeau, M.E. (Mary E.), Brown, W.M. (W. Mark), Silverman, E. (Edwin), Hokanson, J.E. (John E.), Cho, M.H. (Michael), Hui, J. (Jennie), Ferreira, M.A. (Manuel A.), Thompson, P.J. (Philip J.), Morrison, A.C. (Alanna), Felix, J.F. (Janine F.), Smith, N.L. (Nicholas L.), Christiano, A.M. (Angela), Petukhova, L. (Lynn), Betz, R.C. (Regina), Fan, X. (Xing), Zhang, X. (Xuejun), Zhu, C. (Caihong), Langefeld, C.D. (Carl), Thompson, S.D. (Susan D.), Wang, F. (Feijie), Lin, X. (Xu), Schwartz, D.A. (David A.), Fingerlin, T.E. (Tasha E.), Rotter, J.I. (Jerome I.), Cotch, M.F. (Mary Frances), Jensen, R.A. (Richard A.), Munz, M. (Matthias), Dommisch, H. (Henrik), Schaefer, A. (Antje), Han, F. (Fang), Ollila, H.M., Hillary, R.P. (Ryan P.), Albagha, O.M.E. (Omar M.), Ralston, S.H. (Stuart), Zeng, C. (Chenjie), Zheng, W. (Wei), Shu, X.-O. (Xiao-Ou), Reis, A. (André), Uebe, S. (Steffen), Hüffmeier, U. (Ulrike), Kawamura, Y. (Yoshiya), Otowa, T. (Takeshi), Sasaki, T. (Tsukasa), Hibberd, M.L. (Martin), Davila, S. (Sonia), Xie, G. (Gang), Siminovitch, K.A. (Katherine), Bei, J.-X. (Jin-Xin), Zeng, Y.X., Försti, A. (Asta), Chen, B. (Bowang), Landi, S. (Stefano), Franke, A. (Andre), Fischer, A. (Annegret), Ellinghaus, D. (David), Flores, C. (Carlos), Noth, I. (Imre), Ma, S.-F. (Shwu-Fan), Foo, J.-N. (Jia-Nee), Liu, J. (Jianjun), Kim, J.-W. (Jong-Won), Cox, D.G. (David), Delattre, O. (Olivier), Mirabeau, O. (Olivier), Skibola, C.F. (Christine F.), Tang, C.S. (Clara S.), Garcia-Barcelo, M., Chang, K.-P. (Kai-Ping), Su, W.-H. (Wen-Hui), Chang, Y.-S. (Yu-Sun), Martin, N.G. (Nicholas G.), Gordon, S.D. (Scott D.), Wade, T.D. (Tracey D.), Lee, C. (Chaeyoung), Kubo, M. (Michiaki), Cha, P.-C. (Pei-Chieng), Nakamura, Y. (Yusuke), Levy, D. (Daniel), Kimura, M. (Masayuki), Hwang, S.-J. (Shih-Jen), Hunt, S.C. (Steven), Spector, T.D. (Timothy), Soranzo, N. (Nicole), Manichaikul, A.W. (Ani W.), Barr, R.G. (Graham), Kahali, B. (Bratati), Speliotes, E.K. (Elizabeth), Yerges-Armstrong, L.M. (Laura), Cheng, C-Y. (Ching-Yu), Jonas, J.B. (Jost B.), Wong, T.Y. (Tien Yin), Fogh, I. (Isabella), Lin, K. (Kuang), Powell, J. (John), Rice, K. (Kenneth), Relton, C.L. (Caroline), Martin, R.M. (Richard M.), and Smith, A.V. (Davey)

Abstract

IMPORTANCE: The causal direction and magnitude of the association between telomere length and incidence of cancer and non-neoplastic diseases is uncertain owing to the susceptibility of observational studies to confounding and reverse causation. OBJECTIVE: To conduct a Mendelian randomization study, using germline genetic variants as instrumental variables, to appraise the causal relevance of telomere length for risk of cancer and non-neoplastic diseases. DATA SOURCES: Genomewide association studies (GWAS) published up to January 15, 2015. STUDY SELECTION: GWAS of noncommunicable diseases that assayed germline genetic variation and did not select cohort or control participants on the basis of preexisting diseases. Of 163 GWAS of noncommunicable diseases identified, summary data from 103 were available. DATA EXTRACTION AND SYNTHESIS: Summary association statistics for single nucleotide polymorphisms (SNPs) that are strongly associated with telomere length in the general population. MAIN OUTCOMES AND MEASURES: Odds ratios (ORs) and 95% confidence intervals (CIs) for disease per standard deviation (SD) higher telomere length due to germline genetic variation. RESULTS: Summary data were available for 35 cancers and 48 non-neoplastic diseases, corresponding to 420 081 cases (median cases, 2526 per disease) and 1 093 105 controls (median, 6789 per disease). Increased telomere length due to germline genetic variation was generally associated with increased risk for site-specific cancers. The strongest associations (ORs [95% CIs] per 1-SD change in genetically increased telomere length) were observed for glioma, 5.27 (3.15-8.81); serous low-malignant-potential ovarian cancer, 4.35 (2.39-7.94); lung adenocarcinoma, 3.19 (2.40-4.22); neuroblastoma, 2.98 (1.92-4.62); bladder cancer, 2.19 (1.32-3.66); melanoma, 1.87 (1.55-2.26); testicular cancer, 1.76 (1.02-3.04); kidney cancer, 1.55 (1.08-2.23); and endometrial cancer, 1.31 (1.07-1.61). Associations were stronger for rarer ca

Published

2017

6. Reproducibility of telomere length assessment: an international collaborative study

Author

Cooper, Rachel, Martin-Ruiz, CM, Baird, D, Roger, L, Boukamp, P, Krunic, D, Cawthon, R, Dokter, MM, van, der Harst P, Bekaert, S, de, Meyer T, Roos, G, Svenson, U, Codd, V, Samani, NJ, McGlynn, L, Shiels, PG, Pooley, KA, Dunning, AM, Cooper, R, Wong, A, Kingston, A, and von, Zglinicki T

Abstract

Background: Telomere length is a putative biomarker of ageing, morbidity and mortality. Its application is hampered by lack of widely applicable reference ranges and uncertainty regarding the present limits of measurement reproducibility within and between laboratories. Methods: We instigated an international collaborative study of telomere length assessment: 10 different laboratories, employing 3 different techniques [Southern blotting, single telomere length analysis (STELA) and real-time quantitative PCR (qPCR)] performed two rounds of fully blinded measurements on 10 human DNA samples per round to enable unbiased assessment of intra- and inter-batch variation between laboratories and techniques. Results: Absolute results from different laboratories differed widely and could thus not be compared directly, but rankings of relative telomere lengths were highly correlated (correlation coefficients of 0.63–0.99). Intra-technique correlations were similar for Southern blotting and qPCR and were stronger than inter-technique ones. However, inter-laboratory coefficients of variation (CVs) averaged about 10% for Southern blotting and STELA and more than 20% for qPCR. This difference was compensated for by a higher dynamic range for the qPCR method as shown by equal variance after z-scoring. Technical variation per laboratory, measured as median of intra- and inter-batch CVs, ranged from 1.4% to 9.5%, with differences between laboratories only marginally significant ( P = 0.06). Gel-based and PCR-based techniques were not different in accuracy. Conclusions: Intra- and inter-laboratory technical variation severely limits the usefulness of data pooling and excludes sharing of reference ranges between laboratories. We propose to establish a common set of physical telomere length standards to improve comparability of telomere length estimates between laboratories.

Published

2014

7. A SPALEED structural study of lead adsorption on stepped copper surfaces Cu(211) and Cu(511)

Author

Hofmann, F., primary, Svenson, U., additional, and Toennies, J.Peter, additional

Published

1997

8. Association Between Telomere Length and Risk of Cancer and Non-Neoplastic Diseases: A Mendelian Randomization Study.

Author

Haycock PC, Burgess S, Nounu A, Zheng J, Okoli GN, Bowden J, Wade KH, Timpson NJ, Evans DM, Willeit P, Aviv A, Gaunt TR, Hemani G, Mangino M, Ellis HP, Kurian KM, Pooley KA, Eeles RA, Lee JE, Fang S, Chen WV, Law MH, Bowdler LM, Iles MM, Yang Q, Worrall BB, Markus HS, Hung RJ, Amos CI, Spurdle AB, Thompson DJ, O'Mara TA, Wolpin B, Amundadottir L, Stolzenberg-Solomon R, Trichopoulou A, Onland-Moret NC, Lund E, Duell EJ, Canzian F, Severi G, Overvad K, Gunter MJ, Tumino R, Svenson U, van Rij A, Baas AF, Bown MJ, Samani NJ, van t'Hof FNG, Tromp G, Jones GT, Kuivaniemi H, Elmore JR, Johansson M, Mckay J, Scelo G, Carreras-Torres R, Gaborieau V, Brennan P, Bracci PM, Neale RE, Olson SH, Gallinger S, Li D, Petersen GM, Risch HA, Klein AP, Han J, Abnet CC, Freedman ND, Taylor PR, Maris JM, Aben KK, Kiemeney LA, Vermeulen SH, Wiencke JK, Walsh KM, Wrensch M, Rice T, Turnbull C, Litchfield K, Paternoster L, Standl M, Abecasis GR, SanGiovanni JP, Li Y, Mijatovic V, Sapkota Y, Low SK, Zondervan KT, Montgomery GW, Nyholt DR, van Heel DA, Hunt K, Arking DE, Ashar FN, Sotoodehnia N, Woo D, Rosand J, Comeau ME, Brown WM, Silverman EK, Hokanson JE, Cho MH, Hui J, Ferreira MA, Thompson PJ, Morrison AC, Felix JF, Smith NL, Christiano AM, Petukhova L, Betz RC, Fan X, Zhang X, Zhu C, Langefeld CD, Thompson SD, Wang F, Lin X, Schwartz DA, Fingerlin T, Rotter JI, Cotch MF, Jensen RA, Munz M, Dommisch H, Schaefer AS, Han F, Ollila HM, Hillary RP, Albagha O, Ralston SH, Zeng C, Zheng W, Shu XO, Reis A, Uebe S, Hüffmeier U, Kawamura Y, Otowa T, Sasaki T, Hibberd ML, Davila S, Xie G, Siminovitch K, Bei JX, Zeng YX, Försti A, Chen B, Landi S, Franke A, Fischer A, Ellinghaus D, Flores C, Noth I, Ma SF, Foo JN, Liu J, Kim JW, Cox DG, Delattre O, Mirabeau O, Skibola CF, Tang CS, Garcia-Barcelo M, Chang KP, Su WH, Chang YS, Martin NG, Gordon S, Wade TD, Lee C, Kubo M, Cha PC, Nakamura Y, Levy D, Kimura M, Hwang SJ, Hunt S, Spector T, Soranzo N, Manichaikul AW, Barr RG, Kahali B, Speliotes E, Yerges-Armstrong LM, Cheng CY, Jonas JB, Wong TY, Fogh I, Lin K, Powell JF, Rice K, Relton CL, Martin RM, and Davey Smith G

Subjects

Adult, Aged, Aged, 80 and over, Cardiovascular Diseases genetics, Female, Genome-Wide Association Study, Germ-Line Mutation, Humans, Male, Middle Aged, Polymorphism, Single Nucleotide, Risk Assessment methods, Telomere genetics, Genetic Predisposition to Disease genetics, Mendelian Randomization Analysis methods, Neoplasms genetics, Telomere Homeostasis genetics

Abstract

Importance: The causal direction and magnitude of the association between telomere length and incidence of cancer and non-neoplastic diseases is uncertain owing to the susceptibility of observational studies to confounding and reverse causation., Objective: To conduct a Mendelian randomization study, using germline genetic variants as instrumental variables, to appraise the causal relevance of telomere length for risk of cancer and non-neoplastic diseases., Data Sources: Genomewide association studies (GWAS) published up to January 15, 2015., Study Selection: GWAS of noncommunicable diseases that assayed germline genetic variation and did not select cohort or control participants on the basis of preexisting diseases. Of 163 GWAS of noncommunicable diseases identified, summary data from 103 were available., Data Extraction and Synthesis: Summary association statistics for single nucleotide polymorphisms (SNPs) that are strongly associated with telomere length in the general population., Main Outcomes and Measures: Odds ratios (ORs) and 95% confidence intervals (CIs) for disease per standard deviation (SD) higher telomere length due to germline genetic variation., Results: Summary data were available for 35 cancers and 48 non-neoplastic diseases, corresponding to 420 081 cases (median cases, 2526 per disease) and 1 093 105 controls (median, 6789 per disease). Increased telomere length due to germline genetic variation was generally associated with increased risk for site-specific cancers. The strongest associations (ORs [95% CIs] per 1-SD change in genetically increased telomere length) were observed for glioma, 5.27 (3.15-8.81); serous low-malignant-potential ovarian cancer, 4.35 (2.39-7.94); lung adenocarcinoma, 3.19 (2.40-4.22); neuroblastoma, 2.98 (1.92-4.62); bladder cancer, 2.19 (1.32-3.66); melanoma, 1.87 (1.55-2.26); testicular cancer, 1.76 (1.02-3.04); kidney cancer, 1.55 (1.08-2.23); and endometrial cancer, 1.31 (1.07-1.61). Associations were stronger for rarer cancers and at tissue sites with lower rates of stem cell division. There was generally little evidence of association between genetically increased telomere length and risk of psychiatric, autoimmune, inflammatory, diabetic, and other non-neoplastic diseases, except for coronary heart disease (OR, 0.78 [95% CI, 0.67-0.90]), abdominal aortic aneurysm (OR, 0.63 [95% CI, 0.49-0.81]), celiac disease (OR, 0.42 [95% CI, 0.28-0.61]) and interstitial lung disease (OR, 0.09 [95% CI, 0.05-0.15])., Conclusions and Relevance: It is likely that longer telomeres increase risk for several cancers but reduce risk for some non-neoplastic diseases, including cardiovascular diseases.

Published

2017

9. Long leukocyte telomere length in prostate cancer patients at diagnosis is associated with poor metastasis-free and cancer-specific survival.

Author

Svenson U, Roos G, and Wikström P

Subjects

Aged, Case-Control Studies, Cohort Studies, Humans, Male, Middle Aged, Neoplasm Metastasis, Prognosis, Prostatic Neoplasms pathology, Risk Factors, Leukocytes ultrastructure, Prostatic Neoplasms blood, Prostatic Neoplasms genetics, Telomere ultrastructure

Abstract

Previous studies have suggested that leukocyte telomere length is associated with risk of developing prostate cancer. Investigations of leukocyte telomere length as a prognostic factor in prostate cancer are, however, lacking. In this study, leukocyte telomere length was investigated both as a risk marker, comparing control subjects and patient risk groups (based on serum levels of prostate-specific antigen, tumor differentiation, and tumor stage), and as a prognostic marker for metastasis-free and cancer-specific survival. Relative telomere length was measured by a well-established quantitative polymerase chain reaction method in 415 consecutively sampled individuals. Statistical evaluation included 162 control subjects without cancer development during follow-up and 110 untreated patients with newly diagnosed localized prostate cancer at the time of blood draw. Leukocyte telomere length did not differ significantly between control subjects and patients, or between patient risk groups. Interestingly, however, and in line with our previous results in breast and kidney cancer patients, relative telomere length at diagnosis was an independent prognostic factor. Patients with long leukocyte telomeres (⩾median) had a significantly worse prostate cancer-specific and metastasis-free survival compared to patients with short telomere length. In contrast, for patients who died of other causes than prostate cancer, long relative telomere length was not coupled to shorter survival time. To our knowledge, these results are novel and give further strength to our hypothesis that leukocyte telomere length might be used as a prognostic marker in malignancy.

Published

2017

10. Telomere length in peripheral leukocytes is associated with immune cell tumor infiltration and prognosis in colorectal cancer patients.

Author

Svenson U, Öberg Å, Stenling R, Palmqvist R, and Roos G

Subjects

Adult, Aged, Aged, 80 and over, Colorectal Neoplasms immunology, Colorectal Neoplasms mortality, Female, Humans, Kaplan-Meier Estimate, Male, Middle Aged, Prognosis, Proportional Hazards Models, Real-Time Polymerase Chain Reaction, Biomarkers, Tumor genetics, Colorectal Neoplasms pathology, Leukocytes metabolism, Lymphocytes, Tumor-Infiltrating immunology, Telomere metabolism

Abstract

Telomeres are protective structures at the end of chromosomes, essential for chromosomal integrity. A large number of studies have investigated leukocyte telomere length as a possible risk marker for various cancers, colorectal cancer (CRC) included. In contrast, studies investigating leukocyte telomere length in relation to CRC survival are lacking. We previously reported that relative telomere length (RTL) of leukocytes collected at diagnosis predicted survival in patients with breast and kidney cancer. We suggested that these findings might reflect various immunological mechanisms, affected by the presence of a tumor. In the present study, leukocyte RTL was examined in relation to immune cell tumor infiltration and prognosis in 130 patients with CRC diagnosis. RTL was measured with a well-established qPCR method. We found that patients with the highest degree of lymphocyte tumor infiltration had shorter leukocyte RTL. Consistent with our previous findings, short RTL was a favorable prognostic marker in univariate survival analysis. In the current study, RTL did not remain as an independent predictor in multivariate survival analysis, when including metastatic status in the model. However, a non-significant trend towards a similar telomere-associated survival pattern was observed in patients with limited disease. In contrast, for patients who died of other causes than CRC, short RTL was associated with significantly shorter survival time. To our knowledge, this is the first study to investigate an association between leukocyte RTL, immune cell tumor infiltration, and cancer-specific survival in CRC patients. Larger studies are warranted to verify these findings.

Published

2016

11. Reproducibility of telomere length assessment: an international collaborative study.

Author

Martin-Ruiz CM, Baird D, Roger L, Boukamp P, Krunic D, Cawthon R, Dokter MM, van der Harst P, Bekaert S, de Meyer T, Roos G, Svenson U, Codd V, Samani NJ, McGlynn L, Shiels PG, Pooley KA, Dunning AM, Cooper R, Wong A, Kingston A, and von Zglinicki T

Subjects

Biomarkers, Blotting, Southern, Humans, International Cooperation, Real-Time Polymerase Chain Reaction, Reproducibility of Results, Aging genetics, DNA genetics, Telomere genetics

Abstract

Background: Telomere length is a putative biomarker of ageing, morbidity and mortality. Its application is hampered by lack of widely applicable reference ranges and uncertainty regarding the present limits of measurement reproducibility within and between laboratories., Methods: We instigated an international collaborative study of telomere length assessment: 10 different laboratories, employing 3 different techniques [Southern blotting, single telomere length analysis (STELA) and real-time quantitative PCR (qPCR)] performed two rounds of fully blinded measurements on 10 human DNA samples per round to enable unbiased assessment of intra- and inter-batch variation between laboratories and techniques., Results: Absolute results from different laboratories differed widely and could thus not be compared directly, but rankings of relative telomere lengths were highly correlated (correlation coefficients of 0.63-0.99). Intra-technique correlations were similar for Southern blotting and qPCR and were stronger than inter-technique ones. However, inter-laboratory coefficients of variation (CVs) averaged about 10% for Southern blotting and STELA and more than 20% for qPCR. This difference was compensated for by a higher dynamic range for the qPCR method as shown by equal variance after z-scoring. Technical variation per laboratory, measured as median of intra- and inter-batch CVs, ranged from 1.4% to 9.5%, with differences between laboratories only marginally significant (P = 0.06). Gel-based and PCR-based techniques were not different in accuracy., Conclusions: Intra- and inter-laboratory technical variation severely limits the usefulness of data pooling and excludes sharing of reference ranges between laboratories. We propose to establish a common set of physical telomere length standards to improve comparability of telomere length estimates between laboratories., (© The Author 2014. Published by Oxford University Press on behalf of the International Epidemiological Association.)

Published

2015

12. Is Southern blotting necessary to measure telomere length reproducibly? Authors' Response to: Commentary: The reliability of telomere length measurements.

Author

Martin-Ruiz CM, Baird D, Roger L, Boukamp P, Krunic D, Cawthon R, Dokter MM, Van Der Harst P, Bekaert S, De Meyer T, Roos G, Svenson U, Codd V, Samani NJ, Mcglynn L, Shiels PG, Pooley KA, Dunning AM, Cooper R, Wong A, Kingston A, and Von Zglinicki T

Subjects

Humans, Reproducibility of Results, Blotting, Southern, Telomere

Published

2015

13. Reproducibility of telomere length assessment: Authors' Response to Damjan Krstajic and Ljubomir Buturovic.

Author

Martin-Ruiz CM, Baird D, Roger L, Boukamp P, Krunic D, Cawthon R, Dokter MM, Van Der Harst P, Bekaert S, De Meyer T, Roos G, Svenson U, Codd V, Samani NJ, Mcglynn L, Shiels PG, Pooley KA, Dunning AM, Cooper R, Wong A, Kingston A, and Von Zglinicki T

Subjects

Humans, Reproducibility of Results, Telomere

Published

2015

14. Specific genomic aberrations predict survival, but low mutation rate in cancer hot spots, in clear cell renal cell carcinoma.

Author

Köhn L, Svenson U, Ljungberg B, and Roos G

Subjects

Adult, Aged, Aged, 80 and over, Carcinoma, Renal Cell mortality, Carcinoma, Renal Cell pathology, Chromosomes, Human, Pair 14, Chromosomes, Human, Pair 3, Chromosomes, Human, Pair 7, Chromosomes, Human, Pair 9, DNA-Binding Proteins, Female, Gene Expression, Genetic Heterogeneity, Humans, Kidney Neoplasms mortality, Kidney Neoplasms pathology, Male, Middle Aged, Nuclear Proteins genetics, PTEN Phosphohydrolase genetics, Prognosis, Survival Analysis, Telomere Homeostasis, Transcription Factors genetics, Tumor Suppressor Protein p53 genetics, Von Hippel-Lindau Tumor Suppressor Protein genetics, Carcinoma, Renal Cell diagnosis, Carcinoma, Renal Cell genetics, Chromosome Aberrations, Kidney Neoplasms diagnosis, Kidney Neoplasms genetics, Mutation Rate

Abstract

Detailed genetic profiling of clear cell renal cell carcinoma (ccRCC) has revealed genomic regions commonly affected by structural changes and a general genetic heterogeneity. VHL and PBRM1, both located at chromosome 3p, are 2 major genes mutated at high frequency but apart from these aberrations, the mutational landscape in ccRCC is largely undefined. Potential prognostic information given by the genomic changes appears to depend on the particular cohort studied. We analyzed a Swedish ccRCC cohort of 74 patients and found common changes (loss or gain occurring in >20% of the tumors) in 12 chromosomal regions (1p, 3p, 3q, 5q, 6q, 7p, 7q 8p, 9p, 9q, 10q, and 14q). A poor outcome was associated with gain of 7q and losses on 9p, 9q, and 14q. These aberrations were more frequent in metastasized tumors, suggesting alterations of genes important for tumor progression. Sequencing of 48 genes implicated in cancer revealed that only VHL, TP53, and PTEN were mutated at a noticeable frequency (51%, 9%, and 9%, respectively). Shorter relative telomere length (RTL) has been associated with loss of specific chromosomal regions in ccRCC tumors, but we could not verify this finding. However, a significantly lower tumor/nontumor (T/N) RTL ratio was detected for tumors with losses in 4q or 9p. In conclusion, poor outcome in ccRCC was associated with gain of 7q and loss on 9p, 9q, and 14q, whereas the mutation rate overall was low in a screen of cancer-associated genes.

Published

2015

15. Stand up for health--avoiding sedentary behaviour might lengthen your telomeres: secondary outcomes from a physical activity RCT in older people.

Author

Sjögren P, Fisher R, Kallings L, Svenson U, Roos G, and Hellénius ML

Subjects

Aged, Blood Cells ultrastructure, Female, Humans, Male, Overweight physiopathology, Pilot Projects, Prospective Studies, Exercise physiology, Sedentary Behavior, Telomere Homeostasis physiology

Abstract

Background: Telomere length has been associated with a healthy lifestyle and longevity. However, the effect of increased physical activity on telomere length is still unknown. Therefore, the aim was to study the relationship between changes in physical activity level and sedentary behaviour and changes in telomere length., Methods: Telomere length was measured in blood cells 6 months apart in 49, 68-year-old, sedentary, overweight individuals taking part in a randomised controlled physical activity intervention trial. The intervention group received individualised physical activity on prescription. Physical activity was measured with a 7-day diary, questionnaires and a pedometer. Sitting time was measured with the short version of The International Physical Activity Questionnaire., Results: Time spent exercising as well as steps per day increased significantly in the intervention group. Reported sitting time decreased in both groups. No significant associations between changes in steps per day and changes in telomere length were noted. In the intervention group, there was a negative correlation between changes in time spent exercising and changes in telomere length (rho=-0.39, p=0.07). On the other hand, in the intervention group, telomere lengthening was significantly associated with reduced sitting time (rho=-0.68, p=0.02)., Conclusions: Reduced sitting time was associated with telomere lengthening in blood cells in sedentary, overweight 68-year-old individuals participating in a 6-month physical activity intervention trial., (Published by the BMJ Publishing Group Limited. For permission to use (where not already granted under a licence) please go to http://group.bmj.com/group/rights-licensing/permissions.)

Published

2014

16. Short telomere length is associated with NOTCH1/SF3B1/TP53 aberrations and poor outcome in newly diagnosed chronic lymphocytic leukemia patients.

Author

Mansouri L, Grabowski P, Degerman S, Svenson U, Gunnarsson R, Cahill N, Smedby KE, Geisler C, Juliusson G, Roos G, and Rosenquist R

Subjects

Aged, Biomarkers, Tumor metabolism, Disease-Free Survival, Female, Follow-Up Studies, Humans, Male, Middle Aged, Phosphoproteins metabolism, Predictive Value of Tests, RNA Splicing Factors, Receptor, Notch1 metabolism, Retrospective Studies, Ribonucleoprotein, U2 Small Nuclear metabolism, Survival Rate, Telomere metabolism, Tumor Suppressor Protein p53 metabolism, Biomarkers, Tumor genetics, Leukemia, Lymphocytic, Chronic, B-Cell diagnosis, Leukemia, Lymphocytic, Chronic, B-Cell genetics, Leukemia, Lymphocytic, Chronic, B-Cell mortality, Leukemia, Lymphocytic, Chronic, B-Cell therapy, Mutation, Phosphoproteins genetics, Receptor, Notch1 genetics, Ribonucleoprotein, U2 Small Nuclear genetics, Telomere genetics, Tumor Suppressor Protein p53 genetics

Abstract

Most previous studies on telomere length (TL) in chronic lymphocytic leukemia (CLL) are based on referral cohorts including a high proportion of aggressive cases. Here, the impact of TL was analyzed in a population-based cohort of newly diagnosed CLL (n = 265) and in relation to other prognostic markers. Short telomeres were particularly associated with high-risk genetic markers, such as NOTCH1, SF3B1, or TP53 aberrations, and predicted a short time to treatment (TTT) and overall survival (OS) (both P < 0.0001). TL was an independent prognostic factor and subdivided patients with otherwise good-prognostic features (e.g., mutated IGHV genes, favorable cytogenetics) into subgroups with different outcome. Furthermore, in follow-up samples (n = 119) taken 5-8 years after diagnosis, TL correlated well with TL at diagnosis and remained unaffected by treatment. Altogether, these novel data indicate that short TL already at diagnosis is associated with poor outcome in CLL and that TL can be measured at later stages of the disease., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

17. Telomere length in relation to immunological parameters in patients with renal cell carcinoma.

Author

Svenson U, Grönlund E, Söderström I, Sitaram RT, Ljungberg B, and Roos G

Subjects

Biomarkers, Tumor immunology, Carcinoma, Renal Cell immunology, Cytokines blood, Flow Cytometry, Humans, Immunophenotyping, Interleukin-10 blood, Interleukin-7 blood, Interleukin-8 blood, Kidney Neoplasms immunology, T-Lymphocytes, Regulatory metabolism, Biomarkers, Tumor genetics, Carcinoma, Renal Cell genetics, Kidney Neoplasms genetics, Telomere genetics

Abstract

Over the last decade, telomere length (TL) has gained attention as a potential biomarker in cancer disease. We previously reported that long blood TL was associated with a poorer outcome in patients with breast cancer and renal cell carcinoma. Based on these findings, we hypothesized that certain immunological components may have an impact on TL dynamics in cancer patients. One aim of the present study was to investigate a possible association between serum cytokines and TL of peripheral blood cells, tumors and corresponding kidney cortex, in patients with clear cell renal cell carcinoma. For this purpose, a multiplex cytokine assay was used. Correlation analysis revealed significant positive correlations between tumor TL and peripheral levels of three cytokines (IL-7, IL-8 and IL-10). In a parallel patient group with various kidney tumors, TL was investigated in whole blood and in immune cell subsets in relation to peripheral levels of regulatory T cells (Tregs). A significant positive association was found between whole blood TL and Treg levels. However, the strongest correlation was found between Tregs and TL of the T lymphocyte fraction. Thus, patients with higher Treg levels displayed longer T cell telomeres, which might reflect a suppressed immune system with fewer cell divisions and hence less telomere shortening. These results are in line with our earlier observation that long blood TL is an unfavorable prognostic factor for cancer-specific survival. In summary, we here show that immunological components are associated with TL in patients with renal cell carcinoma, providing further insight into the field of telomere biology in cancer.

Published

2013

18. Blood cell telomere length is a dynamic feature.

Author

Svenson U, Nordfjäll K, Baird D, Roger L, Osterman P, Hellenius ML, and Roos G

Subjects

Adult, Aged, Blood Donors, Child, Preschool, Female, Humans, Infant, Male, Middle Aged, Blood Cells metabolism, Telomere metabolism

Abstract

There is a considerable heterogeneity in blood cell telomere length (TL) for individuals of similar age and recent studies have revealed that TL changes by time are dependent on TL at baseline. TL is partly inherited, but results from several studies indicate that e.g. life style and/or environmental factors can affect TL during life. Collectively, these studies imply that blood cell TL might fluctuate during a life time and that the actual TL at a defined time point is the result of potential regulatory mechanism(s) and environmental factors. We analyzed relative TL (RTL) in subsequent blood samples taken six months apart from 50 individuals and found significant associations between RTL changes and RTL at baseline. Individual RTL changes per month were more pronounced than the changes recorded in a previously studied population analyzed after 10 years' follow up. The data argues for an oscillating TL pattern which levels out at longer follow up times. In a separate group of five blood donors, a marked telomere loss was demonstrated within a six month period for one donor where after TL was stabilized. PCR determined RTL changes were verified by Southern blotting and STELA (single telomere elongation length analysis). The STELA demonstrated that for the donor with a marked telomere loss, the heterogeneity of the telomere distribution decreased considerably, with a noteworthy loss of the largest telomeres. In summary, the collected data support the concept that individual blood cell telomere length is a dynamic feature and this will be important to recognize in future studies of human telomere biology.

Published

2011

19. Shortened telomere length is associated with increased risk of cancer: a meta-analysis.

Author

Ma H, Zhou Z, Wei S, Liu Z, Pooley KA, Dunning AM, Svenson U, Roos G, Hosgood HD 3rd, Shen M, and Wei Q

Subjects

Confidence Intervals, Humans, Odds Ratio, Publication Bias, Risk Factors, Genetic Predisposition to Disease, Neoplasms genetics, Telomere metabolism

Abstract

Background: Telomeres play a key role in the maintenance of chromosome integrity and stability, and telomere shortening is involved in initiation and progression of malignancies. A series of epidemiological studies have examined the association between shortened telomeres and risk of cancers, but the findings remain conflicting., Methods: A dataset composed of 11,255 cases and 13,101 controls from 21 publications was included in a meta-analysis to evaluate the association between overall cancer risk or cancer-specific risk and the relative telomere length. Heterogeneity among studies and their publication bias were further assessed by the χ(2)-based Q statistic test and Egger's test, respectively., Results: The results showed that shorter telomeres were significantly associated with cancer risk (OR = 1.35, 95% CI = 1.14-1.60), compared with longer telomeres. In the stratified analysis by tumor type, the association remained significant in subgroups of bladder cancer (OR = 1.84, 95% CI = 1.38-2.44), lung cancer (OR = 2.39, 95% CI = 1.18-4.88), smoking-related cancers (OR = 2.25, 95% CI = 1.83-2.78), cancers in the digestive system (OR = 1.69, 95% CI = 1.53-1.87) and the urogenital system (OR = 1.73, 95% CI = 1.12-2.67). Furthermore, the results also indicated that the association between the relative telomere length and overall cancer risk was statistically significant in studies of Caucasian subjects, Asian subjects, retrospective designs, hospital-based controls and smaller sample sizes. Funnel plot and Egger's test suggested that there was no publication bias in the current meta-analysis (P = 0.532)., Conclusions: The results of this meta-analysis suggest that the presence of shortened telomeres may be a marker for susceptibility to human cancer, but single larger, well-design prospective studies are warranted to confirm these findings.

Published

2011

20. Large-scale parent-child comparison confirms a strong paternal influence on telomere length.

Author

Nordfjäll K, Svenson U, Norrback KF, Adolfsson R, and Roos G

Subjects

Adult, Age Distribution, Aged, Child, Female, Humans, Male, Middle Aged, Mothers, Pedigree, Sex Characteristics, Fathers, Telomere metabolism

Abstract

Telomere length is documented to have a hereditary component, and both paternal and X-linked inheritance have been proposed. We investigated blood cell telomere length in 962 individuals with an age range between 0 and 102 years. Telomere length correlations were analyzed between parent-child pairs in different age groups and between grandparent-grandchild pairs. A highly significant correlation between the father's and the child's telomere length was observed (r=0.454, P<0.001), independent of the sex of the offspring (father-son: r=0.465, P<0.001; father-daughter: r=0.484, P<0.001). For mothers, the correlations were weaker (mother-child: r=0.148, P=0.098; mother-son: r=0.080, P=0.561; mother-daughter: r=0.297, P=0.013). A positive telomere length correlation was also observed for grandparent-grandchild pairs (r=0.272, P=0.013). Our findings indicate that fathers contribute significantly stronger to the telomere length of the offspring compared with mothers (P=0.012), but we cannot exclude a maternal influence on the daughter's telomeres. Interestingly, the father-child correlations diminished with increasing age (P=0.022), suggesting that nonheritable factors have an impact on telomere length dynamics during life.

Published

2010

21. Polymorphisms in telomere-associated genes, breast cancer susceptibility and prognosis.

Author

Varadi V, Brendle A, Brandt A, Johansson R, Enquist K, Henriksson R, Svenson U, Tavelin B, Roos G, Hemminki K, Lenner P, and Försti A

Subjects

Adult, Aged, Aged, 80 and over, Breast Neoplasms pathology, Epidemiologic Methods, Female, Genetic Predisposition to Disease, Genotype, Humans, Middle Aged, Neoplasm Metastasis, Neoplasm Staging, Polymorphism, Single Nucleotide, Prognosis, Telomere-Binding Proteins genetics, Breast Neoplasms genetics, Telomere genetics

Abstract

Telomeres are essential structures for maintaining chromosomal stability and their length has been reported to correlate with cancer risk and clinical outcome. Single nucleotide polymorphisms (SNPs) in genes encoding telomere-associated proteins could affect telomere length and chromosomal stability by influencing gene expression or protein configuration in the telomeres. Here, we report the results of the first association study on genetic variation in telomere-associated genes and their effect on telomere length, breast cancer (BC) susceptibility and prognosis. We genotyped 14 potentially functional and most informative SNPs in nine telomere-associated genes (TERT, TEP1, TERF1, TERF2, TERF2IP, ACD, POT1, TNKS and TNKS2) in 782 incident BC cases and 1559 matched controls. Relative telomere length (RTL) varied statistically significantly between the genotypes of the SNPs rs446977 (TEP1, p=0.04), rs938886 (TEP1, p=0.04) and rs6990097 (TNKS, p=0.04). However, none of them was associated with BC susceptibility and only rs6990097 correlated with regional lymph node metastasis (odds ratio (OR) 1.38, 95% confidence interval (CI) 1.08-1.77). The strongest association with BC susceptibility was observed for rs3785074 (TERF2, OR 0.51, 95% CI 0.31-0.83) and rs10509637 (TNKS2, OR 1.33, 95% CI 1.08-1.62). Haplotype and diplotype analysis confirmed the association of the TNKS2 gene with BC susceptibility. rs3785074 (TERF2) was additionally associated with histologic grade (OR 1.44, 95% CI 1.08-1.92) and negative oestrogen receptor status (OR 2.93, 95% CI 1.13-7.58). None of the SNPs showed a significant correlation with survival of the breast cancer patients. With these results, none of the SNPs represents any valuable prognostic marker for BC.

Published

2009

22. Telomere length as a biological marker in malignancy.

Author

Svenson U and Roos G

Subjects

Animals, Humans, Neoplasms diagnosis, Prognosis, Risk Factors, Biomarkers, Tumor metabolism, Homeostasis, Neoplasms metabolism, Telomere metabolism

Abstract

Telomere maintenance is important for tumor cell growth and survival. Telomere length (TL) is determined by the balance between positive and negative factors impacting telomere homeostasis. In the last decade, TL has emerged as a promising clinical marker for risk and prognosis prediction in patients with malignant disorders. Tumor TL, as well as TL in healthy tissues such as peripheral blood, may carry valuable information for future treatment strategies. Here we discuss the present status of TL as a biological marker in cancer patients.

Published

2009

23. Telomere length in peripheral blood predicts survival in clear cell renal cell carcinoma.

Author

Svenson U, Ljungberg B, and Roos G

Subjects

Adenocarcinoma, Clear Cell blood, Adenocarcinoma, Clear Cell pathology, Adult, Aged, Aged, 80 and over, Female, Humans, Kidney ultrastructure, Kidney Neoplasms blood, Kidney Neoplasms pathology, Male, Middle Aged, Neoplasm Staging, Survival Rate, Adenocarcinoma, Clear Cell genetics, Kidney Neoplasms genetics, Telomere metabolism

Abstract

Telomeres are repetitive structures located at chromosome ends. Previous studies have indicated that blood cell telomeres may serve as a biomarker for cancer risk. In addition, we recently reported that blood telomere length predicted survival in patients with breast cancer. In the present study, we examined whether blood telomere length may act as a predictor for survival in newly diagnosed patients with clear cell renal cell carcinoma. Furthermore, we analyzed telomere length in tumor samples and corresponding kidney cortex. Relative telomere length (RTL) was measured on extracted DNA using real-time PCR. Interestingly, and in line with our previous findings in breast cancer, patients with the longest blood telomeres (fourth quartile) had a significantly worse prognosis compared with patients with shorter blood RTL (P=0.005). A highly significant association was found between long blood telomeres and a poor outcome in patients with nonmetastatic disease (P<0.001), whereas patients with distant metastases had a poor survival regardless of blood RTL (P=0.432). No correlations were found between blood RTL and various clinical variables, such as erythrocyte sedimentation rate, hemoglobin, and thrombocyte count. Multivariate Cox regression analysis verified long blood RTL as an independent negative prognostic marker. In contrast, telomere length in kidney cortex and tumor tissue did not predict survival. In conclusion, our results indicate that blood RTL may predict kidney cancer survival, with implications for future treatment strategies.

Published

2009

24. The individual blood cell telomere attrition rate is telomere length dependent.

Author

Nordfjäll K, Svenson U, Norrback KF, Adolfsson R, Lenner P, and Roos G

Subjects

Adolescent, Adult, Age Factors, Aged, Aged, 80 and over, Blood Cells metabolism, Child, Child, Preschool, Cohort Studies, Female, Humans, Infant, Male, Telomere genetics, Telomere metabolism, Young Adult, Blood Cells chemistry, Telomere chemistry

Abstract

Age-associated telomere shortening is a well documented feature of peripheral blood cells in human population studies, but it is not known to what extent these data can be transferred to the individual level. Telomere length (TL) in two blood samples taken at approximately 10 years interval from 959 individuals was investigated using real-time PCR. TL was also measured in 13 families from a multigenerational cohort. As expected, we found an age-related decline in TL over time (r = -0.164, P<0.001, n = 959). However, approximately one-third of the individuals exhibited a stable or increased TL over a decade. The individual telomere attrition rate was inversely correlated with initial TL at a highly significant level (r = -0.752, P<0.001), indicating that the attrition rate was most pronounced in individuals with long telomeres at baseline. In accordance, the age-associated telomere attrition rate was more prominent in families with members displaying longer telomeres at a young age (r = -0.691, P<0.001). Abnormal blood TL has been reported at diagnosis of various malignancies, but in the present study there was no association between individual telomere attrition rate or prediagnostic TL and later tumor development. The collected data strongly suggest a TL maintenance mechanism acting in vivo, providing protection of short telomeres as previously demonstrated in vitro. Our findings might challenge the hypothesis that individual TL can predict possible life span or later tumor development., Competing Interests: The authors have declared that no competing interests exist.

Published

2009

25. Breast cancer survival is associated with telomere length in peripheral blood cells.

Author

Svenson U, Nordfjäll K, Stegmayr B, Manjer J, Nilsson P, Tavelin B, Henriksson R, Lenner P, and Roos G

Subjects

Age Factors, Aged, Chromosomal Instability, Female, Humans, Middle Aged, Odds Ratio, Prognosis, Proportional Hazards Models, Reverse Transcriptase Polymerase Chain Reaction, Risk, Treatment Outcome, Biomarkers, Tumor metabolism, Breast Neoplasms blood, Breast Neoplasms mortality, Telomere ultrastructure

Abstract

Telomeres are essential for maintaining chromosomal stability. Previous studies have indicated that individuals with shorter blood telomeres may be at higher risk of developing various types of cancer, such as in lung, bladder, and kidney. We have analyzed relative telomere length (RTL) of peripheral blood cells in relation to breast cancer incidence and prognosis. The study included 265 newly diagnosed breast cancer patients and 446 female controls. RTL was measured by real-time PCR, and our results show that the patient group displayed significantly longer telomeres compared with controls (P < 0.001). Age-adjusted odds ratios (OR) for breast cancer risk increased with increasing telomere length, with a maximal OR of 5.17 [95% confidence interval (95% CI), 3.09-8.64] for the quartile with the longest telomeres. Furthermore, RTL carried prognostic information for patients with advanced disease. Node positive (N+) patients with short telomeres (16 mm (median tumor diameter), short telomeres were associated with a significantly better outcome than longer telomeres (P = 0.006). Cox regression analysis showed that long RTL was a significant independent negative prognostic factor (hazards ratio, 2.92; 95% CI, 1.33-6.39; P = 0.007). Our results indicate that blood RTL may serve as a prognostic indicator in breast cancer patients with advanced disease.

Published

2008