Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma

Lauren G. Aoude; Antonia L. Pritchard; Carla Daniela Robles-Espinoza; Karin Wadt; Mark Harland; Jiyeon Choi; Michael Gartside; Victor Quesada; Peter A. Johansson; Jane M. Palmer; Andrew J. Ramsay; Xijun Zhang; Kristine Jones; Judith Symmons; Elizabeth A. Holland; Helen Schmid; Vanessa Bonazzi; Susan Woods; Ken Dutton-Regester; Mitchell S. Stark; Helen Snowden; Remco van Doom; Grant W. Montgomery; Nicholas G. Martin; Thomas M. Keane; Carlos Lopez-Otin; Anne-Marie Gerdes; Hakan Olsson; Christian Ingvar; Ake Borg; Nelleke A. Gruis; Jeffrey M. Trent; Goran Jonsson; D. Timothy Bishop; Graham J. Mann; Julia A. Newton-Bishop; Kevin M. Brown; David J. Adams; Nicholas K. Hayward

doi:10.1093/jnci/dju408

Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma

Lauren G. Aoude
, Antonia L. Pritchard
, Carla Daniela Robles-Espinoza
, Karin Wadt
, Mark Harland
, Jiyeon Choi
, Michael Gartside
, Victor Quesada
, Peter A. Johansson
, Jane M. Palmer
, Andrew J. Ramsay
, Xijun Zhang
, Kristine Jones
, Judith Symmons
, Elizabeth A. Holland
, Helen Schmid
, Vanessa Bonazzi
, Susan Woods
, Ken Dutton-Regester
, Mitchell S. Stark

Helen Snowden, Remco van Doom, Grant W. Montgomery, Nicholas G. Martin, Thomas M. Keane, Carlos Lopez-Otin, Anne-Marie Gerdes, Hakan Olsson, Christian Ingvar, Ake Borg, Nelleke A. Gruis, Jeffrey M. Trent, Goran Jonsson, D. Timothy Bishop, Graham J. Mann, Julia A. Newton-Bishop, Kevin M. Brown, David J. Adams, Nicholas K. Hayward

Division of Biomedical Sciences

Producción científica: Article › revisión exhaustiva

157 Citas (Scopus)

Resumen

Background:
The shelterin complex protects chromosomal ends by regulating how the telomerase complex interacts with telomeres. Following the recent finding in familial melanoma of inactivating germline mutations in POT1, encoding a member of the shelterin complex, we searched for mutations in the other five components of the shelterin complex in melanoma families.
Methods:
Next-generation sequencing techniques were used to screen 510 melanoma families (with unknown genetic etiology) and control cohorts for mutations in shelterin complex encoding genes: ACD, TERF2IP, TERF1, TERF2, and TINF2. Maximum likelihood and LOD [logarithm (base 10) of odds] analyses were used. Mutation clustering was assessed with χ2 and Fisher’s exact tests. P values under .05 were considered statistically significant (one-tailed with Yates’ correction).
Results:
Six families had mutations in ACD and four families carried TERF2IP variants, which included nonsense mutations in both genes (p.Q320X and p.R364X, respectively) and point mutations that cosegregated with melanoma. Of five distinct mutations in ACD, four clustered in the POT1 binding domain, including p.Q320X. This clustering of novel mutations in the POT1 binding domain of ACD was statistically higher (P = .005) in melanoma probands compared with population control individuals (n = 6785), as were all novel and rare variants in both ACD (P = .040) and TERF2IP (P = .022). Families carrying ACD and TERF2IP mutations were also enriched with other cancer types, suggesting that these variants also predispose to a broader spectrum of cancers than just melanoma. Novel mutations were also observed in TERF1, TERF2, and TINF2, but these were not convincingly associated with melanoma.
Conclusions:
Our findings add to the growing support for telomere dysregulation as a key process associated with melanoma susceptibility.

Idioma original	English
Número de páginas	7
Publicación	JNCI: Journal of the National Cancer Institute
Volumen	107
N.º	2
Fecha en línea anticipada	13 dic 2014
DOI	https://doi.org/10.1093/jnci/dju408
Estado	Published - 1 feb 2015

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10.1093/jnci/dju408

Antonia Pritchard
- antonia.pritcharduhi.acuk
- Division of Biomedical Sciences - Reader in Genetics and Immunology
- Melanoma Research Group
Persona: Academic - Research and Teaching or Research only

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Aoude, L. G., Pritchard, A. L., Robles-Espinoza, C. D., Wadt, K., Harland, M., Choi, J., Gartside, M., Quesada, V., Johansson, P. A., Palmer, J. M., Ramsay, A. J., Zhang, X., Jones, K., Symmons, J., Holland, E. A., Schmid, H., Bonazzi, V., Woods, S., Dutton-Regester, K., ... Hayward, N. K. (2015). Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma. JNCI: Journal of the National Cancer Institute, 107(2). https://doi.org/10.1093/jnci/dju408

@article{a7e7f9358ad8426bb9203c1421330a5c,

title = "Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma",

abstract = " Background: The shelterin complex protects chromosomal ends by regulating how the telomerase complex interacts with telomeres. Following the recent finding in familial melanoma of inactivating germline mutations in POT1, encoding a member of the shelterin complex, we searched for mutations in the other five components of the shelterin complex in melanoma families. Methods: Next-generation sequencing techniques were used to screen 510 melanoma families (with unknown genetic etiology) and control cohorts for mutations in shelterin complex encoding genes: ACD, TERF2IP, TERF1, TERF2, and TINF2. Maximum likelihood and LOD [logarithm (base 10) of odds] analyses were used. Mutation clustering was assessed with χ2 and Fisher{\textquoteright}s exact tests. P values under .05 were considered statistically significant (one-tailed with Yates{\textquoteright} correction). Results: Six families had mutations in ACD and four families carried TERF2IP variants, which included nonsense mutations in both genes (p.Q320X and p.R364X, respectively) and point mutations that cosegregated with melanoma. Of five distinct mutations in ACD, four clustered in the POT1 binding domain, including p.Q320X. This clustering of novel mutations in the POT1 binding domain of ACD was statistically higher (P = .005) in melanoma probands compared with population control individuals (n = 6785), as were all novel and rare variants in both ACD (P = .040) and TERF2IP (P = .022). Families carrying ACD and TERF2IP mutations were also enriched with other cancer types, suggesting that these variants also predispose to a broader spectrum of cancers than just melanoma. Novel mutations were also observed in TERF1, TERF2, and TINF2, but these were not convincingly associated with melanoma. Conclusions: Our findings add to the growing support for telomere dysregulation as a key process associated with melanoma susceptibility. ",

author = "Aoude, \{Lauren G.\} and Pritchard, \{Antonia L.\} and Robles-Espinoza, \{Carla Daniela\} and Karin Wadt and Mark Harland and Jiyeon Choi and Michael Gartside and Victor Quesada and Johansson, \{Peter A.\} and Palmer, \{Jane M.\} and Ramsay, \{Andrew J.\} and Xijun Zhang and Kristine Jones and Judith Symmons and Holland, \{Elizabeth A.\} and Helen Schmid and Vanessa Bonazzi and Susan Woods and Ken Dutton-Regester and Stark, \{Mitchell S.\} and Helen Snowden and \{van Doom\}, Remco and Montgomery, \{Grant W.\} and Martin, \{Nicholas G.\} and Keane, \{Thomas M.\} and Carlos Lopez-Otin and Anne-Marie Gerdes and Hakan Olsson and Christian Ingvar and Ake Borg and Gruis, \{Nelleke A.\} and Trent, \{Jeffrey M.\} and Goran Jonsson and Bishop, \{D. Timothy\} and Mann, \{Graham J.\} and Newton-Bishop, \{Julia A.\} and Brown, \{Kevin M.\} and Adams, \{David J.\} and Hayward, \{Nicholas K.\}",

note = "Copyright {\textcopyright} Oxford University Press",

year = "2015",

month = feb,

day = "1",

doi = "10.1093/jnci/dju408",

language = "English",

volume = "107",

journal = "JNCI: Journal of the National Cancer Institute",

issn = "0027-8874",

publisher = "Oxford University Press",

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Aoude, LG, Pritchard, AL, Robles-Espinoza, CD, Wadt, K, Harland, M, Choi, J, Gartside, M, Quesada, V, Johansson, PA, Palmer, JM, Ramsay, AJ, Zhang, X, Jones, K, Symmons, J, Holland, EA, Schmid, H, Bonazzi, V, Woods, S, Dutton-Regester, K, Stark, MS, Snowden, H, van Doom, R, Montgomery, GW, Martin, NG, Keane, TM, Lopez-Otin, C, Gerdes, A-M, Olsson, H, Ingvar, C, Borg, A, Gruis, NA, Trent, JM, Jonsson, G, Bishop, DT, Mann, GJ, Newton-Bishop, JA, Brown, KM, Adams, DJ & Hayward, NK 2015, 'Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma', JNCI: Journal of the National Cancer Institute, vol. 107, n.º 2. https://doi.org/10.1093/jnci/dju408

TY - JOUR

T1 - Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma

AU - Aoude, Lauren G.

AU - Pritchard, Antonia L.

AU - Robles-Espinoza, Carla Daniela

AU - Wadt, Karin

AU - Harland, Mark

AU - Choi, Jiyeon

AU - Gartside, Michael

AU - Quesada, Victor

AU - Johansson, Peter A.

AU - Palmer, Jane M.

AU - Ramsay, Andrew J.

AU - Zhang, Xijun

AU - Jones, Kristine

AU - Symmons, Judith

AU - Holland, Elizabeth A.

AU - Schmid, Helen

AU - Bonazzi, Vanessa

AU - Woods, Susan

AU - Dutton-Regester, Ken

AU - Stark, Mitchell S.

AU - Snowden, Helen

AU - van Doom, Remco

AU - Montgomery, Grant W.

AU - Martin, Nicholas G.

AU - Keane, Thomas M.

AU - Lopez-Otin, Carlos

AU - Gerdes, Anne-Marie

AU - Olsson, Hakan

AU - Ingvar, Christian

AU - Borg, Ake

AU - Gruis, Nelleke A.

AU - Trent, Jeffrey M.

AU - Jonsson, Goran

AU - Bishop, D. Timothy

AU - Mann, Graham J.

AU - Newton-Bishop, Julia A.

AU - Brown, Kevin M.

AU - Adams, David J.

AU - Hayward, Nicholas K.

PY - 2015/2/1

Y1 - 2015/2/1

N2 - Background: The shelterin complex protects chromosomal ends by regulating how the telomerase complex interacts with telomeres. Following the recent finding in familial melanoma of inactivating germline mutations in POT1, encoding a member of the shelterin complex, we searched for mutations in the other five components of the shelterin complex in melanoma families. Methods: Next-generation sequencing techniques were used to screen 510 melanoma families (with unknown genetic etiology) and control cohorts for mutations in shelterin complex encoding genes: ACD, TERF2IP, TERF1, TERF2, and TINF2. Maximum likelihood and LOD [logarithm (base 10) of odds] analyses were used. Mutation clustering was assessed with χ2 and Fisher’s exact tests. P values under .05 were considered statistically significant (one-tailed with Yates’ correction). Results: Six families had mutations in ACD and four families carried TERF2IP variants, which included nonsense mutations in both genes (p.Q320X and p.R364X, respectively) and point mutations that cosegregated with melanoma. Of five distinct mutations in ACD, four clustered in the POT1 binding domain, including p.Q320X. This clustering of novel mutations in the POT1 binding domain of ACD was statistically higher (P = .005) in melanoma probands compared with population control individuals (n = 6785), as were all novel and rare variants in both ACD (P = .040) and TERF2IP (P = .022). Families carrying ACD and TERF2IP mutations were also enriched with other cancer types, suggesting that these variants also predispose to a broader spectrum of cancers than just melanoma. Novel mutations were also observed in TERF1, TERF2, and TINF2, but these were not convincingly associated with melanoma. Conclusions: Our findings add to the growing support for telomere dysregulation as a key process associated with melanoma susceptibility.

AB - Background: The shelterin complex protects chromosomal ends by regulating how the telomerase complex interacts with telomeres. Following the recent finding in familial melanoma of inactivating germline mutations in POT1, encoding a member of the shelterin complex, we searched for mutations in the other five components of the shelterin complex in melanoma families. Methods: Next-generation sequencing techniques were used to screen 510 melanoma families (with unknown genetic etiology) and control cohorts for mutations in shelterin complex encoding genes: ACD, TERF2IP, TERF1, TERF2, and TINF2. Maximum likelihood and LOD [logarithm (base 10) of odds] analyses were used. Mutation clustering was assessed with χ2 and Fisher’s exact tests. P values under .05 were considered statistically significant (one-tailed with Yates’ correction). Results: Six families had mutations in ACD and four families carried TERF2IP variants, which included nonsense mutations in both genes (p.Q320X and p.R364X, respectively) and point mutations that cosegregated with melanoma. Of five distinct mutations in ACD, four clustered in the POT1 binding domain, including p.Q320X. This clustering of novel mutations in the POT1 binding domain of ACD was statistically higher (P = .005) in melanoma probands compared with population control individuals (n = 6785), as were all novel and rare variants in both ACD (P = .040) and TERF2IP (P = .022). Families carrying ACD and TERF2IP mutations were also enriched with other cancer types, suggesting that these variants also predispose to a broader spectrum of cancers than just melanoma. Novel mutations were also observed in TERF1, TERF2, and TINF2, but these were not convincingly associated with melanoma. Conclusions: Our findings add to the growing support for telomere dysregulation as a key process associated with melanoma susceptibility.

U2 - 10.1093/jnci/dju408

DO - 10.1093/jnci/dju408

M3 - Article

SN - 0027-8874

VL - 107

JO - JNCI: Journal of the National Cancer Institute

JF - JNCI: Journal of the National Cancer Institute

IS - 2

ER -

Nonsense Mutations in the Shelterin Complex Genes ACD and TERF2IP in Familial Melanoma

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