Your search keyword '"Carter NP"' showing total 224 results

1. Array painting: a method for the rapid analysis of aberrant chromosomes using DNA microarrays

Author

Fiegler, H, Gribble, SM, Burford, DC, Carr, P, Prigmore, E, Porter, KM, Clegg, S, Crolla, JA, Dennis, NR, Jacobs, P, and Carter, NP

Subjects

Genetic disorders -- Diagnosis -- Research, DNA sequencers -- Usage, Medical genetics -- Research -- Usage, Health, Diagnosis, Usage, Research

Abstract

Objective: The authors describe a method, termed array painting, which allows the rapid, high resolution analysis of the content and breakpoints of aberrant chromosomes. Methods: Array painting is similar in [...]

Published

2003

2. A second generation human haplotype map of over 3.1 million SNPs

Author

Frazer, KA, Ballinger, DG, Cox, DR, Hinds, DA, Stuve, LL, Gibbs, RA, Belmont, JW, Boudreau, A, Hardenbol, P, Leal, SM, Pasternak, S, Wheeler, DA, Willis, TD, Yu, F, Yang, H, Zeng, C, Gao, Y, Hu, H, Hu, W, Li, C, Lin, W, Liu, S, Pan, H, Tang, X, Wang, J, Wang, W, Yu, J, Zhang, B, Zhang, Q, Zhao, H, Zhou, J, Gabriel, SB, Barry, R, Blumenstiel, B, Camargo, A, Defelice, M, Faggart, M, Goyette, M, Gupta, S, Moore, J, Nguyen, H, Onofrio, RC, Parkin, M, Roy, J, Stahl, E, Winchester, E, Ziaugra, L, Altshuler, D, Shen, Y, Yao, Z, Huang, W, Chu, X, He, Y, Jin, L, Liu, Y, Sun, W, Wang, H, Wang, Y, Xiong, X, Xu, L, Waye, MM, Tsui, SK, Xue, H, Wong, JT, Galver, LM, Fan, JB, Gunderson, K, Murray, SS, Oliphant, AR, Chee, MS, Montpetit, A, Chagnon, F, Ferretti, V, Leboeuf, M, Olivier, JF, Phillips, MS, Roumy, S, Sallée, C, Verner, A, Hudson, TJ, Kwok, PY, Cai, D, Koboldt, DC, Miller, RD, Pawlikowska, L, Taillon-Miller, P, Xiao, M, Tsui, LC, Mak, W, Song, YQ, Tam, PK, Nakamura, Y, Kawaguchi, T, Kitamoto, T, Morizono, T, Nagashima, A, Ohnishi, Y, Sekine, A, Tanaka, T, Tsunoda, T, Deloukas, P, Bird, CP, Delgado, M, Dermitzakis, ET, Gwilliam, R, Hunt, S, Morrison, J, Powell, D, Stranger, BE, Whittaker, P, Bentley, DR, Daly, MJ, de Bakker, PI, Barrett, J, Chretien, YR, Maller, J, McCarroll, S, Patterson, N, Pe'er, I, Price, A, Purcell, S, Richter, DJ, Sabeti, P, Saxena, R, Schaffner, SF, Sham, PC, Varilly, P, Stein, LD, Krishnan, L, Smith, AV, Tello-Ruiz, MK, Thorisson, GA, Chakravarti, A, Chen, PE, Cutler, DJ, Kashuk, CS, Lin, S, Abecasis, GR, Guan, W, Li, Y, Munro, HM, Qin, ZS, Thomas, DJ, McVean, G, Auton, A, Bottolo, L, Cardin, N, Eyheramendy, S, Freeman, C, Marchini, J, Myers, S, Spencer, C, Stephens, M, Donnelly, P, Cardon, LR, Clarke, G, Evans, DM, Morris, AP, Weir, BS, Mullikin, JC, Sherry, ST, Feolo, M, Skol, A, Zhang, H, Matsuda, I, Fukushima, Y, Macer, DR, Suda, E, Rotimi, CN, Adebamowo, CA, Ajayi, I, Aniagwu, T, Marshall, PA, Nkwodimmah, C, Royal, CD, Leppert, MF, Dixon, M, Peiffer, A, Qiu, R, Kent, A, Kato, K, Niikawa, N, Adewole, IF, Knoppers, BM, Foster, MW, Clayton, EW, Watkin, J, Muzny, D, Nazareth, L, Sodergren, E, Weinstock, GM, Yakub, I, Birren, BW, Wilson, RK, Fulton, LL, Rogers, J, Burton, J, Carter, NP, Clee, CM, Griffiths, M, Jones, MC, McLay, K, Plumb, RW, Ross, MT, Sims, SK, Willey, DL, Chen, Z, Han, H, Kang, L, Godbout, M, Wallenburg, JC, L'Archevêque, P, Bellemare, G, Saeki, K, An, D, Fu, H, Li, Q, Wang, Z, Wang, R, Holden, AL, Brooks, LD, McEwen, JE, Guyer, MS, Wang, VO, Peterson, JL, Shi, M, Spiegel, J, Sung, LM, Zacharia, LF, Collins, FS, Kennedy, K, Jamieson, R, and Stewart, J

Subjects

Male, Recombination, Genetic, Genetics, Linkage disequilibrium, education.field_of_study, Multidisciplinary, Homozygote, Racial Groups, Haplotype, Population, Single-nucleotide polymorphism, Tag SNP, Biology, Polymorphism, Single Nucleotide, Linkage Disequilibrium, Article, Haplotypes, Humans, Female, Selection, Genetic, International HapMap Project, education, Imputation (genetics), Genetic association

Abstract

We describe the Phase II HapMap, which characterizes over 3.1 million human single nucleotide polymorphisms (SNPs) genotyped in 270 individuals from four geographically diverse populations and includes 25-35% of common SNP variation in the populations surveyed. The map is estimated to capture untyped common variation with an average maximum r 2 of between 0.9 and 0.96 depending on population. We demonstrate that the current generation of commercial genome-wide genotyping products captures common Phase II SNPs with an average maximum r 2 of up to 0.8 in African and up to 0.95 in non-African populations, and that potential gains in power in association studies can be obtained through imputation. These data also reveal novel aspects of the structure of linkage disequilibrium. We show that 10-30% of pairs of individuals within a population share at least one region of extended genetic identity arising from recent ancestry and that up to 1% of all common variants are untaggable, primarily because they lie within recombination hotspots. We show that recombination rates vary systematically around genes and between genes of different function. Finally, we demonstrate increased differentiation at non-synonymous, compared to synonymous, SNPs, resulting from systematic differences in the strength or efficacy of natural selection between populations. ©2007 Nature Publishing Group., link_to_OA_fulltext

Published

2016

3. The DNA sequence of the human X chromosome

Author

ROSS MT, GRAFHAM DV, COFFEY AJ, SCHERER S, MCLAY K, MUZNY D, PLATZER M, HOWELL GR, BURROWS C, BIRD CP, FRANKISH A, LOVELL FL, HOWE KL, ASHURST JL, FULTON RS, SUDBRAK R, WEN G, JONES MC, HURLES ME, ANDREWS TD, SCOTT CE, SEARLE S, RAMSER J, WHITTAKER A, DEADMAN R, CARTER NP, HUNT SE, CHEN R, CREE A, GUNARATNE P, HAVLAK P, HODGSON A, METZKER ML, RICHARDS S, SCOTT G, STEFFEN D, SODERGREN E, WHEELER DA, WORLEY KC, AINSCOUGH R, AMBROSE KD, ANSARI LARI MA, ARADHYA S, ASHWELL RI, BABBAGE AK, BAGGULEY CL, BANERJEE R, BARKER GE, BARLOW KF, BARRETT IP, BATES KN, BEARE DM, BEASLEY H, BEASLEY O, BECK A, BETHEL G, BLECHSCHMIDT K, BRADY N, BRAY ALLEN S, BRIDGEMAN AM, BROWN AJ, BROWN MJ, BONNIN D, BRUFORD EA, BUHAY C, BURCH P, BURFORD D, BURGESS J, BURRILL W, BURTON J, BYE JM, CARDER C, CARREL L, CHAKO J, CHAPMAN JC, CHAVEZ D, CHEN E, CH EN G, CHEN Y, CHEN Z, CHINAULT C, CICCODICOLA A, CLARK SY, CLARKE G, CLEE CM, CLEGG S, CLERC BLANKENBURG K, CLIFFORD K, COBLEY V, COLE CG, CONQUER JS, CORBY N, CONNOR RE, DAVID R, DAVIES J, DAVIS C, DAVIS J, DELGADO O, DESHAZO D, DHAMI P, DING Y, DINH H, DODSWORTH S, DRAPER H, DUGAN ROCHA S, DUNHAM A, DUNN M, DURBIN KJ, DUTTA I, EADES T, ELLWOOD M, EMERY COHEN A, ERRINGTON H, EVANS KL, FAULKNER L, FRANCIS F, FRANKLAND J, FRASER AE, GALGOCZY P, GILBERT J, GILL R, GLOCKNER G, GREGORY SG, GRIBBLE S, GRIFFITHS C, GROCOCK R, GU Y, GWILLIAM R, HAMILTON C, HART EA, HAWES A, HEATH PD, HEITMANN K, HENNIG S, HERNANDEZ J, HINZMANN B, HO S, HOFFS M, HOWDEN PJ, HUCKLE EJ, HUME J, HUNT PJ, HUNT AR, ISHERWOOD J, JACOB L, JOHNSON D, JONES S, DE JONG PJ, JOSEPH SS, KEENAN S, KELLY S, KERSHAW JK, KHAN Z, KIOSCHIS P, KLAGES S, KNIGHTS AJ, KOSIURA A, KOVAR SMITH C, LAIRD GK, LANGFORD C, LAWLOR S, LEVERSHA M, LEWIS L, LIU W, LLOYD C, LLOYD DM, LOULSEGED H, LOVELAND JE, LOVELL JD, LOZADO R, LU J, LYNE R, MA J, MAHESHWARI M, MATTHEWS LH, MCDOWALL J, MCLAREN S, MCMURRAY A, MEIDL P, MEITINGER T, MILNE S, MINER G, MISTRY SL, MORGAN M, MORRIS S, MULLER I, M.U.L.L.I.K.I.N. . ., BALLABIO, ANDREA, Ross, Mt, Grafham, Dv, Coffey, Aj, Scherer, S, Mclay, K, Muzny, D, Platzer, M, Howell, Gr, Burrows, C, Bird, Cp, Frankish, A, Lovell, Fl, Howe, Kl, Ashurst, Jl, Fulton, R, Sudbrak, R, Wen, G, Jones, Mc, Hurles, Me, Andrews, Td, Scott, Ce, Searle, S, Ramser, J, Whittaker, A, Deadman, R, Carter, Np, Hunt, Se, Chen, R, Cree, A, Gunaratne, P, Havlak, P, Hodgson, A, Metzker, Ml, Richards, S, Scott, G, Steffen, D, Sodergren, E, Wheeler, Da, Worley, Kc, Ainscough, R, Ambrose, Kd, ANSARI LARI, Ma, Aradhya, S, Ashwell, Ri, Babbage, Ak, Bagguley, Cl, Ballabio, Andrea, Banerjee, R, Barker, Ge, Barlow, Kf, Barrett, Ip, Bates, Kn, Beare, Dm, Beasley, H, Beasley, O, Beck, A, Bethel, G, Blechschmidt, K, Brady, N, BRAY ALLEN, S, Bridgeman, Am, Brown, Aj, Brown, Mj, Bonnin, D, Bruford, Ea, Buhay, C, Burch, P, Burford, D, Burgess, J, Burrill, W, Burton, J, Bye, Jm, Carder, C, Carrel, L, Chako, J, Chapman, Jc, Chavez, D, Chen, E, CH EN, G, Chen, Y, Chen, Z, Chinault, C, Ciccodicola, A, Clark, Sy, Clarke, G, Clee, Cm, Clegg, S, CLERC BLANKENBURG, K, Clifford, K, Cobley, V, Cole, Cg, Conquer, J, Corby, N, Connor, Re, David, R, Davies, J, Davis, C, Davis, J, Delgado, O, Deshazo, D, Dhami, P, Ding, Y, Dinh, H, Dodsworth, S, Draper, H, DUGAN ROCHA, S, Dunham, A, Dunn, M, Durbin, Kj, Dutta, I, Eades, T, Ellwood, M, EMERY COHEN, A, Errington, H, Evans, Kl, Faulkner, L, Francis, F, Frankland, J, Fraser, Ae, Galgoczy, P, Gilbert, J, Gill, R, Glockner, G, Gregory, Sg, Gribble, S, Griffiths, C, Grocock, R, Gu, Y, Gwilliam, R, Hamilton, C, Hart, Ea, Hawes, A, Heath, Pd, Heitmann, K, Hennig, S, Hernandez, J, Hinzmann, B, Ho, S, Hoffs, M, Howden, Pj, Huckle, Ej, Hume, J, Hunt, Pj, Hunt, Ar, Isherwood, J, Jacob, L, Johnson, D, Jones, S, DE JONG, Pj, Joseph, S, Keenan, S, Kelly, S, Kershaw, Jk, Khan, Z, Kioschis, P, Klages, S, Knights, Aj, Kosiura, A, KOVAR SMITH, C, Laird, Gk, Langford, C, Lawlor, S, Leversha, M, Lewis, L, Liu, W, Lloyd, C, Lloyd, Dm, Loulseged, H, Loveland, Je, Lovell, Jd, Lozado, R, Lu, J, Lyne, R, Ma, J, Maheshwari, M, Matthews, Lh, Mcdowall, J, Mclaren, S, Mcmurray, A, Meidl, P, Meitinger, T, Milne, S, Miner, G, Mistry, Sl, Morgan, M, Morris, S, Muller, I, and M. U. L. L. I. K. I. N. ., .

Published

2005

4. Large-scale discovery of novel genetic causes of developmental disorders

Author

Fitzgerald, TW, Gerety, SS, Jones, WD, van Kogelenberg, M, King, DA, McRae, J, Morley, KI, Parthiban, V, Al-Turki, S, Ambridge, K, Barrett, DM, Bayzetinova, T, Clayton, S, Coomber, EL, Gribble, S, Jones, P, Krishnappa, N, Mason, LE, Middleton, A, Miller, R, Prigmore, E, Rajan, D, Sifrim, A, Tivey, AR, Ahmed, M, Akawi, N, Andrews, R, Anjum, U, Archer, H, Armstrong, R, Balasubramanian, M, Banerjee, R, Baralle, D, Batstone, P, Baty, D, Bennett, C, Berg, J, Bernhard, B, Bevan, AP, Blair, E, Blyth, M, Bohanna, D, Bourdon, L, Bourn, D, Brady, A, Bragin, E, Brewer, C, Brueton, L, Brunstrom, K, Bumpstead, SJ, Bunyan, DJ, Burn, J, Burton, J, Canham, N, Castle, B, Chandler, K, Clasper, S, Clayton-Smith, J, Cole, T, Collins, A, Collinson, MN, Connell, F, Cooper, N, Cox, H, Cresswell, L, Cross, G, Crow, Y, D'Alessandro, M, Dabir, T, Davidson, R, Davies, S, Dean, J, Deshpande, C, Devlin, G, Dixit, A, Dominiczak, A, Donnelly, C, Donnelly, D, Douglas, A, Duncan, A, Eason, J, Edkins, S, Ellard, S, Ellis, P, Elmslie, F, Evans, K, Everest, S, Fendick, T, Fisher, R, Flinter, F, Foulds, N, Fryer, A, Fu, B, Gardiner, C, Gaunt, L, Ghali, N, Gibbons, R, Pereira, SLG, Goodship, J, Goudie, D, Gray, E, Greene, P, Greenhalgh, L, Harrison, L, Hawkins, R, Hellens, S, Henderson, A, Hobson, E, Holden, S, Holder, S, Hollingsworth, G, Homfray, T, Humphreys, M, Hurst, J, Ingram, S, Irving, M, Jarvis, J, Jenkins, L, Johnson, D, Jones, D, Jones, E, Josifova, D, Joss, S, Kaemba, B, Kazembe, S, Kerr, B, Kini, U, Kinning, E, Kirby, G, Kirk, C, Kivuva, E, Kraus, A, Kumar, D, Lachlan, K, Lam, W, Lampe, A, Langman, C, Lees, M, Lim, D, Lowther, G, Lynch, SA, Magee, A, Maher, E, Mansour, S, Marks, K, Martin, K, Maye, U, McCann, E, McConnell, V, McEntagart, M, McGowan, R, McKay, K, McKee, S, McMullan, DJ, McNerlan, S, Mehta, S, Metcalfe, K, Miles, E, Mohammed, S, Montgomery, T, Moore, D, Morgan, S, Morris, A, Morton, J, Mugalaasi, H, Murday, V, Nevitt, L, Newbury-Ecob, R, Norman, A, O'Shea, R, Ogilvie, C, Park, S, Parker, MJ, Patel, C, Paterson, J, Payne, S, Phipps, J, Pilz, DT, Porteous, D, Pratt, N, Prescott, K, Price, S, Pridham, A, Procter, A, Purnell, H, Ragge, N, Rankin, J, Raymond, L, Rice, D, Robert, L, Roberts, E, Roberts, G, Roberts, J, Roberts, P, Ross, A, Rosser, E, Saggar, A, Samant, S, Sandford, R, Sarkar, A, Schweier, S, Scott, C, Scott, R, Selby, A, Seller, A, Sequeira, C, Shannon, N, Shanrif, S, Shaw-Smith, C, Shearing, E, Shears, D, Simonic, I, Simpkin, D, Singzon, R, Skitt, Z, Smith, A, Smith, B, Smith, K, Smithson, S, Sneddon, L, Splitt, M, Squires, M, Stewart, F, Stewart, H, Suri, M, Sutton, V, Swaminathan, GJ, Sweeney, E, Tatton-Brown, K, Taylor, C, Taylor, R, Tein, M, Temple, IK, Thomson, J, Tolmie, J, Torokwa, A, Treacy, B, Turner, C, Turnpenny, P, Tysoe, C, Vandersteen, A, Vasudevan, P, Vogt, J, Wakeling, E, Walker, D, Waters, J, Weber, A, Wellesley, D, Whiteford, M, Widaa, S, Wilcox, S, Williams, D, Williams, N, Woods, G, Wragg, C, Wright, M, Yang, F, Yau, M, Carter, NP, Parker, M, Firth, HV, FitzPatrick, DR, Wright, CF, Barrett, JC, Hurles, ME, Fitzgerald, TW, Gerety, SS, Jones, WD, van Kogelenberg, M, King, DA, McRae, J, Morley, KI, Parthiban, V, Al-Turki, S, Ambridge, K, Barrett, DM, Bayzetinova, T, Clayton, S, Coomber, EL, Gribble, S, Jones, P, Krishnappa, N, Mason, LE, Middleton, A, Miller, R, Prigmore, E, Rajan, D, Sifrim, A, Tivey, AR, Ahmed, M, Akawi, N, Andrews, R, Anjum, U, Archer, H, Armstrong, R, Balasubramanian, M, Banerjee, R, Baralle, D, Batstone, P, Baty, D, Bennett, C, Berg, J, Bernhard, B, Bevan, AP, Blair, E, Blyth, M, Bohanna, D, Bourdon, L, Bourn, D, Brady, A, Bragin, E, Brewer, C, Brueton, L, Brunstrom, K, Bumpstead, SJ, Bunyan, DJ, Burn, J, Burton, J, Canham, N, Castle, B, Chandler, K, Clasper, S, Clayton-Smith, J, Cole, T, Collins, A, Collinson, MN, Connell, F, Cooper, N, Cox, H, Cresswell, L, Cross, G, Crow, Y, D'Alessandro, M, Dabir, T, Davidson, R, Davies, S, Dean, J, Deshpande, C, Devlin, G, Dixit, A, Dominiczak, A, Donnelly, C, Donnelly, D, Douglas, A, Duncan, A, Eason, J, Edkins, S, Ellard, S, Ellis, P, Elmslie, F, Evans, K, Everest, S, Fendick, T, Fisher, R, Flinter, F, Foulds, N, Fryer, A, Fu, B, Gardiner, C, Gaunt, L, Ghali, N, Gibbons, R, Pereira, SLG, Goodship, J, Goudie, D, Gray, E, Greene, P, Greenhalgh, L, Harrison, L, Hawkins, R, Hellens, S, Henderson, A, Hobson, E, Holden, S, Holder, S, Hollingsworth, G, Homfray, T, Humphreys, M, Hurst, J, Ingram, S, Irving, M, Jarvis, J, Jenkins, L, Johnson, D, Jones, D, Jones, E, Josifova, D, Joss, S, Kaemba, B, Kazembe, S, Kerr, B, Kini, U, Kinning, E, Kirby, G, Kirk, C, Kivuva, E, Kraus, A, Kumar, D, Lachlan, K, Lam, W, Lampe, A, Langman, C, Lees, M, Lim, D, Lowther, G, Lynch, SA, Magee, A, Maher, E, Mansour, S, Marks, K, Martin, K, Maye, U, McCann, E, McConnell, V, McEntagart, M, McGowan, R, McKay, K, McKee, S, McMullan, DJ, McNerlan, S, Mehta, S, Metcalfe, K, Miles, E, Mohammed, S, Montgomery, T, Moore, D, Morgan, S, Morris, A, Morton, J, Mugalaasi, H, Murday, V, Nevitt, L, Newbury-Ecob, R, Norman, A, O'Shea, R, Ogilvie, C, Park, S, Parker, MJ, Patel, C, Paterson, J, Payne, S, Phipps, J, Pilz, DT, Porteous, D, Pratt, N, Prescott, K, Price, S, Pridham, A, Procter, A, Purnell, H, Ragge, N, Rankin, J, Raymond, L, Rice, D, Robert, L, Roberts, E, Roberts, G, Roberts, J, Roberts, P, Ross, A, Rosser, E, Saggar, A, Samant, S, Sandford, R, Sarkar, A, Schweier, S, Scott, C, Scott, R, Selby, A, Seller, A, Sequeira, C, Shannon, N, Shanrif, S, Shaw-Smith, C, Shearing, E, Shears, D, Simonic, I, Simpkin, D, Singzon, R, Skitt, Z, Smith, A, Smith, B, Smith, K, Smithson, S, Sneddon, L, Splitt, M, Squires, M, Stewart, F, Stewart, H, Suri, M, Sutton, V, Swaminathan, GJ, Sweeney, E, Tatton-Brown, K, Taylor, C, Taylor, R, Tein, M, Temple, IK, Thomson, J, Tolmie, J, Torokwa, A, Treacy, B, Turner, C, Turnpenny, P, Tysoe, C, Vandersteen, A, Vasudevan, P, Vogt, J, Wakeling, E, Walker, D, Waters, J, Weber, A, Wellesley, D, Whiteford, M, Widaa, S, Wilcox, S, Williams, D, Williams, N, Woods, G, Wragg, C, Wright, M, Yang, F, Yau, M, Carter, NP, Parker, M, Firth, HV, FitzPatrick, DR, Wright, CF, Barrett, JC, and Hurles, ME

Abstract

Despite three decades of successful, predominantly phenotype-driven discovery of the genetic causes of monogenic disorders, up to half of children with severe developmental disorders of probable genetic origin remain without a genetic diagnosis. Particularly challenging are those disorders rare enough to have eluded recognition as a discrete clinical entity, those with highly variable clinical manifestations, and those that are difficult to distinguish from other, very similar, disorders. Here we demonstrate the power of using an unbiased genotype-driven approach to identify subsets of patients with similar disorders. By studying 1,133 children with severe, undiagnosed developmental disorders, and their parents, using a combination of exome sequencing and array-based detection of chromosomal rearrangements, we discovered 12 novel genes associated with developmental disorders. These newly implicated genes increase by 10% (from 28% to 31%) the proportion of children that could be diagnosed. Clustering of missense mutations in six of these newly implicated genes suggests that normal development is being perturbed by an activating or dominant-negative mechanism. Our findings demonstrate the value of adopting a comprehensive strategy, both genome-wide and nationwide, to elucidate the underlying causes of rare genetic disorders.

Published

2015

5. Genome-wide detection and characterization of positive selection in human populations

Author

Sabeti, PC, Varilly, P, Fry, B, Lohmueller, J, Hostetter, E, Cotsapas, C, Xie, X, Byrne, EH, McCarroll, SA, Gaudet, R, Schaffner, SF, Lander, ES, Frazer, KA, Ballinger, DG, Cox, DR, Hinds, DA, Stuve, LL, Gibbs, RA, Belmont, JW, Boudreau, A, Hardenbol, P, Leal, SM, Pasternak, S, Wheeler, DA, Willis, TD, Yu, F, Yang, H, Zeng, C, Gao, Y, Hu, H, Hu, W, Li, C, Lin, W, Liu, S, Pan, H, Tang, X, Wang, J, Wang, W, Yu, J, Zhang, B, Zhang, Q, Zhao, H, Zhou, J, Gabriel, SB, Barry, R, Blumenstiel, B, Camargo, A, Defelice, M, Faggart, M, Goyette, M, Gupta, S, Moore, J, Nguyen, H, Onofrio, RC, Parkin, M, Roy, J, Stahl, E, Winchester, E, Ziaugra, L, Altshuler, D, Shen, Y, Yao, Z, Huang, W, Chu, X, He, Y, Jin, L, Liu, Y, Sun, W, Wang, H, Wang, Y, Xiong, X, Xu, L, Waye, MM, Tsui, SK, Xue, H, Wong, JT, Galver, LM, Fan, JB, Gunderson, K, Murray, SS, Oliphant, AR, Chee, MS, Montpetit, A, Chagnon, F, Ferretti, V, Leboeuf, M, Olivier, JF, Phillips, MS, Roumy, S, Sallée, C, Verner, A, Hudson, TJ, Kwok, PY, Cai, D, Koboldt, DC, Miller, RD, Pawlikowska, L, Taillon-Miller, P, Xiao, M, Tsui, LC, Mak, W, Song, YQ, Tam, PK, Nakamura, Y, Kawaguchi, T, Kitamoto, T, Morizono, T, Nagashima, A, Ohnishi, Y, Sekine, A, Tanaka, T, Tsunoda, T, Deloukas, P, Bird, CP, Delgado, M, Dermitzakis, ET, Gwilliam, R, Hunt, S, Morrison, J, Powell, D, Stranger, BE, Whittaker, P, Bentley, DR, Daly, MJ, de Bakker, PI, Barrett, J, Chretien, YR, Maller, J, McCarroll, S, Patterson, N, Pe'er, I, Price, A, Purcell, S, Richter, DJ, Sabeti, P, Saxena, R, Sham, PC, Stein, LD, Krishnan, L, Smith, AV, Tello-Ruiz, MK, Thorisson, GA, Chakravarti, A, Chen, PE, Cutler, DJ, Kashuk, CS, Lin, S, Abecasis, GR, Guan, W, Li, Y, Munro, HM, Qin, ZS, Thomas, DJ, McVean, G, Auton, A, Bottolo, L, Cardin, N, Eyheramendy, S, Freeman, C, Marchini, J, Myers, S, Spencer, C, Stephens, M, Donnelly, P, Cardon, LR, Clarke, G, Evans, DM, Morris, AP, Weir, BS, Johnson, TA, Mullikin, JC, Sherry, ST, Feolo, M, Skol, A, Zhang, H, Matsuda, I, Fukushima, Y, Macer, DR, Suda, E, Rotimi, CN, Adebamowo, CA, Ajayi, I, Aniagwu, T, Marshall, PA, Nkwodimmah, C, Royal, CD, Leppert, MF, Dixon, M, Peiffer, A, Qiu, R, Kent, A, Kato, K, Niikawa, N, Adewole, IF, Knoppers, BM, Foster, MW, Clayton, EW, Watkin, J, Muzny, D, Nazareth, L, Sodergren, E, Weinstock, GM, Yakub, I, Birren, BW, Wilson, RK, Fulton, LL, Rogers, J, Burton, J, Carter, NP, Clee, CM, Griffiths, M, Jones, MC, McLay, K, Plumb, RW, Ross, MT, Sims, SK, Willey, DL, Chen, Z, Han, H, Kang, L, Godbout, M, Wallenburg, JC, L'Archevêque, P, Bellemare, G, Saeki, K, An, D, Fu, H, Li, Q, Wang, Z, Wang, R, Holden, AL, Brooks, LD, McEwen, JE, Guyer, MS, Wang, VO, Peterson, JL, Shi, M, Spiegel, J, Sung, LM, Zacharia, LF, Collins, FS, Kennedy, K, Jamieson, R, and Stewart, J

Subjects

Models, Molecular, Population, Single-nucleotide polymorphism, Human genetic variation, Biology, Polymorphism, Single Nucleotide, Article, Antiporters, Gene Frequency, Humans, International HapMap Project, Selection, Genetic, education, Selection (genetic algorithm), Genetics, education.field_of_study, Multidisciplinary, Natural selection, Geography, Edar Receptor, Genome, Human, Haplotype, Regional Index: Eurasia, Protein Structure, Tertiary, Europe, Genetics, Population, Haplotypes, Human genome

Abstract

With the advent of dense maps of human genetic variation, it is now possible to detect positive natural selection across the human genome. Here we report an analysis of over 3 million polymorphisms from the International HapMap Project Phase 2 (HapMap2). We used 'long-range haplotype' methods, which were developed to identify alleles segregating in a population that have undergone recent selection, and we also developed new methods that are based on cross-population comparisons to discover alleles that have swept to near-fixation within a population. The analysis reveals more than 300 strong candidate regions. Focusing on the strongest 22 regions, we develop a heuristic for scrutinizing these regions to identify candidate targets of selection. In a complementary analysis, we identify 26 non-synonymous, coding, single nucleotide polymorphisms showing regional evidence of positive selection. Examination of these candidates highlights three cases in which two genes in a common biological process have apparently undergone positive selection in the same population:LARGE and DMD, both related to infection by the Lassa virus, in West Africa;SLC24A5 and SLC45A2, both involved in skin pigmentation, in Europe; and EDAR and EDA2R, both involved in development of hair follicles, in Asia. ©2007 Nature Publishing Group., link_to_OA_fulltext

Published

2007

6. Genome-wide screening using automated fluorescent genotyping to detect cryptic cytogenetic abnormalities in children with idiopathic syndromic mental retardation

Author

Borck, G., Rio, M, Sanlaville, D., Redon, Roland, Molinari, F., Bacq, D, Raoul, O, Cormier-Daire, V., Lyonnet, S., Amiel, J., Le Merrer, M., de Blois, M. C., Prieur, M., Vekemans, M., Carter, NP, Munnich, A., Colleaux, Laurence, Handicaps génétiques de l'enfant (Inserm U393), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM), Service de Génétique Médicale [CHU Necker], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-CHU Necker - Enfants Malades [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP), and Assistance publique - Hôpitaux de Paris (AP-HP) (APHP)-CHU Necker - Enfants Malades [AP-HP]

Subjects

Chromosome Aberrations, MESH: Humans, MESH: Genetic Testing, Genotype, Nucleic Acid Hybridization, MESH: Microscopy, Fluorescence, Telomere, MESH: Intellectual Disability, MESH: Nucleic Acid Hybridization, MESH: Genotype, [SDV.GEN.GH]Life Sciences [q-bio]/Genetics/Human genetics, Microscopy, Fluorescence, MESH: Child, Intellectual Disability, MESH: Chromosome Aberrations, Humans, MESH: In Situ Hybridization, Fluorescence, MESH: Microsatellite Repeats, Genetic Testing, MESH: Telomere, Child, In Situ Hybridization, Fluorescence, Microsatellite Repeats

Abstract

International audience; Mental retardation (MR) is the most common developmental disability, affecting approximately 2% of the population. The causes of MR are diverse and poorly understood, but chromosomal rearrangements account for 4-28% of cases, and duplications/deletions smaller than 5 Mb are known to cause syndromic MR. We have previously developed a strategy based on automated fluorescent microsatellite genotyping to test for telomere integrity. This strategy detected about 10% of cryptic subtelomeric rearrangements in patients with idiopathic syndromic MR. Because telomere screening is a first step toward the goal of analyzing the entire genome for chromosomal rearrangements in MR, we have extended our strategy to 400 markers evenly distributed along the chromosomes to detect interstitial anomalies. Among 97 individuals tested, three anomalies were found: two deletions (one in three siblings) and one parental disomy. These results emphasize the value of a genome-wide microsatellite scan for the detection of interstitial aberrations and demonstrate that automated genotyping is a sensitive method that not only detects small interstitial rearrangements and their parental origin but also provides a unique opportunity to detect uniparental disomies. This study will hopefully contribute to the delineation of new contiguous gene syndromes and the identification of new imprinted regions.

Published

2004

7. Genome Sequencing and Analysis of the Tasmanian Devil and Its Transmissible Cancer

Author

Murchison, EP, Schulz-Trieglaff, OB, Ning, Z, Alexandrov, LB, Bauer, MJ, Fu, B, Hims, M, Ding, Z, Ivakhno, S, Stewart, C, Ng, BL, Wong, W, Aken, B, White, S, Alsop, A, Becq, J, Bignell, GR, Cheetham, RK, Cheng, W, Connor, TR, Cox, AJ, Feng, Z-P, Gu, Y, Grocock, RJ, Harris, SR, Khrebtukova, I, Kingsbury, Z, Kowarsky, M, Kreiss, A, Luo, S, Marshall, J, McBride, DJ, Murray, L, Pearse, A-M, Raine, K, Rasolonjatovo, I, Shaw, R, Tedder, P, Tregidgo, C, Vilella, AJ, Wedge, DC, Woods, GM, Gormley, N, Humphray, S, Schroth, G, Smith, G, Hall, K, Searle, SMJ, Carter, NP, Papenfuss, AT, Futreal, PA, Campbell, PJ, Yang, F, Bentley, DR, Evers, DJ, Stratton, MR, Murchison, EP, Schulz-Trieglaff, OB, Ning, Z, Alexandrov, LB, Bauer, MJ, Fu, B, Hims, M, Ding, Z, Ivakhno, S, Stewart, C, Ng, BL, Wong, W, Aken, B, White, S, Alsop, A, Becq, J, Bignell, GR, Cheetham, RK, Cheng, W, Connor, TR, Cox, AJ, Feng, Z-P, Gu, Y, Grocock, RJ, Harris, SR, Khrebtukova, I, Kingsbury, Z, Kowarsky, M, Kreiss, A, Luo, S, Marshall, J, McBride, DJ, Murray, L, Pearse, A-M, Raine, K, Rasolonjatovo, I, Shaw, R, Tedder, P, Tregidgo, C, Vilella, AJ, Wedge, DC, Woods, GM, Gormley, N, Humphray, S, Schroth, G, Smith, G, Hall, K, Searle, SMJ, Carter, NP, Papenfuss, AT, Futreal, PA, Campbell, PJ, Yang, F, Bentley, DR, Evers, DJ, and Stratton, MR

Abstract

The Tasmanian devil (Sarcophilus harrisii), the largest marsupial carnivore, is endangered due to a transmissible facial cancer spread by direct transfer of living cancer cells through biting. Here we describe the sequencing, assembly, and annotation of the Tasmanian devil genome and whole-genome sequences for two geographically distant subclones of the cancer. Genomic analysis suggests that the cancer first arose from a female Tasmanian devil and that the clone has subsequently genetically diverged during its spread across Tasmania. The devil cancer genome contains more than 17,000 somatic base substitution mutations and bears the imprint of a distinct mutational process. Genotyping of somatic mutations in 104 geographically and temporally distributed Tasmanian devil tumors reveals the pattern of evolution and spread of this parasitic clonal lineage, with evidence of a selective sweep in one geographical area and persistence of parallel lineages in other populations.

Published

2012

8. Genome-wide association study of CNVs in 16,000 cases of eight common diseases and 3,000 shared controls

Author

Craddock, N, Hurles, ME, Cardin, N, Pearson, RD, Plagnol, V, Robson, S, Vukcevic, D, Barnes, C, Conrad, DF, Giannoulatou, E, Holmes, C, Marchini, JL, Stirrups, K, Tobin, MD, Wain, LV, Yau, C, Aerts, J, Ahmad, T, Andrews, TD, Arbury, H, Attwood, A, Auton, A, Ball, SG, Balmforth, AJ, Barrett, JC, Barroso, I, Barton, A, Bennett, AJ, Bhaskar, S, Blaszczyk, K, Bowes, J, Brand, OJ, Braund, PS, Bredin, F, Breen, G, Brown, MJ, Bruce, IN, Bull, J, Burren, OS, Burton, J, Byrnes, J, Caesar, S, Clee, CM, Coffey, AJ, Connell, JMC, Cooper, JD, Dominiczak, AF, Downes, K, Drummond, HE, Dudakia, D, Dunham, A, Ebbs, B, Eccles, D, Edkins, S, Edwards, C, Elliot, A, Emery, P, Evans, DM, Evans, G, Eyre, S, Farmer, A, Ferrier, IN, Feuk, L, Fitzgerald, T, Flynn, E, Forbes, A, Forty, L, Franklyn, JA, Freathy, RM, Gibbs, P, Gilbert, P, Gokumen, O, Gordon-Smith, K, Gray, E, Green, E, Groves, CJ, Grozeva, D, Gwilliam, R, Hall, A, Hammond, N, Hardy, M, Harrison, P, Hassanali, N, Hebaishi, H, Hines, S, Hinks, A, Hitman, GA, Hocking, L, Howard, E, Howard, P, Howson, JMM, Hughes, D, Hunt, S, Isaacs, JD, Jain, M, Jewell, DP, Johnson, T, Jolley, JD, Jones, IR, Jones, LA, Kirov, G, Langford, CF, Lango-Allen, H, Lathrop, GM, Lee, J, Lee, KL, Lees, C, Lewis, K, Lindgren, CM, Maisuria-Armer, M, Maller, J, Mansfield, J, Martin, P, Massey, DCO, McArdle, WL, McGuffin, P, McLay, KE, Mentzer, A, Mimmack, ML, Morgan, AE, Morris, AP, Mowat, C, Myers, S, Newman, W, Nimmo, ER, O'Donovan, MC, Onipinla, A, Onyiah, I, Ovington, NR, Owen, MJ, Palin, K, Parnell, K, Pernet, D, Perry, JRB, Phillips, A, Pinto, D, Prescott, NJ, Prokopenko, I, Quail, MA, Rafelt, S, Rayner, NW, Redon, R, Reid, DM, Renwick, A, Ring, SM, Robertson, N, Russell, E, St Clair, D, Sambrook, JG, Sanderson, JD, Schuilenburg, H, Scott, CE, Scott, R, Seal, S, Shaw-Hawkins, S, Shields, BM, Simmonds, MJ, Smyth, DJ, Somaskantharajah, E, Spanova, K, Steer, S, Stephens, J, Stevens, HE, Stone, MA, Su, Z, Symmons, DPM, Thompson, JR, Thomson, W, Travers, ME, Turnbull, C, Valsesia, A, Walker, M, Walker, NM, Wallace, C, Warren-Perry, M, Watkins, NA, Webster, J, Weedon, MN, Wilson, AG, Woodburn, M, Wordsworth, BP, Young, AH, Zeggini, E, Carter, NP, Frayling, TM, Lee, C, McVean, G, Munroe, PB, Palotie, A, Sawcer, SJ, Scherer, SW, Strachan, DP, Tyler-Smith, C, Brown, MA, Burton, PR, Caulfield, MJ, Compston, A, Farrall, M, Gough, SCL, Hall, AS, Hattersley, AT, Hill, AVS, Mathew, CG, Pembrey, M, Satsangi, J, Stratton, MR, Worthington, J, Deloukas, P, Duncanson, A, Kwiatkowski, DP, McCarthy, MI, Ouwehand, WH, Parkes, M, Rahman, N, Todd, JA, Samani, NJ, Donnelly, P, Craddock, N, Hurles, ME, Cardin, N, Pearson, RD, Plagnol, V, Robson, S, Vukcevic, D, Barnes, C, Conrad, DF, Giannoulatou, E, Holmes, C, Marchini, JL, Stirrups, K, Tobin, MD, Wain, LV, Yau, C, Aerts, J, Ahmad, T, Andrews, TD, Arbury, H, Attwood, A, Auton, A, Ball, SG, Balmforth, AJ, Barrett, JC, Barroso, I, Barton, A, Bennett, AJ, Bhaskar, S, Blaszczyk, K, Bowes, J, Brand, OJ, Braund, PS, Bredin, F, Breen, G, Brown, MJ, Bruce, IN, Bull, J, Burren, OS, Burton, J, Byrnes, J, Caesar, S, Clee, CM, Coffey, AJ, Connell, JMC, Cooper, JD, Dominiczak, AF, Downes, K, Drummond, HE, Dudakia, D, Dunham, A, Ebbs, B, Eccles, D, Edkins, S, Edwards, C, Elliot, A, Emery, P, Evans, DM, Evans, G, Eyre, S, Farmer, A, Ferrier, IN, Feuk, L, Fitzgerald, T, Flynn, E, Forbes, A, Forty, L, Franklyn, JA, Freathy, RM, Gibbs, P, Gilbert, P, Gokumen, O, Gordon-Smith, K, Gray, E, Green, E, Groves, CJ, Grozeva, D, Gwilliam, R, Hall, A, Hammond, N, Hardy, M, Harrison, P, Hassanali, N, Hebaishi, H, Hines, S, Hinks, A, Hitman, GA, Hocking, L, Howard, E, Howard, P, Howson, JMM, Hughes, D, Hunt, S, Isaacs, JD, Jain, M, Jewell, DP, Johnson, T, Jolley, JD, Jones, IR, Jones, LA, Kirov, G, Langford, CF, Lango-Allen, H, Lathrop, GM, Lee, J, Lee, KL, Lees, C, Lewis, K, Lindgren, CM, Maisuria-Armer, M, Maller, J, Mansfield, J, Martin, P, Massey, DCO, McArdle, WL, McGuffin, P, McLay, KE, Mentzer, A, Mimmack, ML, Morgan, AE, Morris, AP, Mowat, C, Myers, S, Newman, W, Nimmo, ER, O'Donovan, MC, Onipinla, A, Onyiah, I, Ovington, NR, Owen, MJ, Palin, K, Parnell, K, Pernet, D, Perry, JRB, Phillips, A, Pinto, D, Prescott, NJ, Prokopenko, I, Quail, MA, Rafelt, S, Rayner, NW, Redon, R, Reid, DM, Renwick, A, Ring, SM, Robertson, N, Russell, E, St Clair, D, Sambrook, JG, Sanderson, JD, Schuilenburg, H, Scott, CE, Scott, R, Seal, S, Shaw-Hawkins, S, Shields, BM, Simmonds, MJ, Smyth, DJ, Somaskantharajah, E, Spanova, K, Steer, S, Stephens, J, Stevens, HE, Stone, MA, Su, Z, Symmons, DPM, Thompson, JR, Thomson, W, Travers, ME, Turnbull, C, Valsesia, A, Walker, M, Walker, NM, Wallace, C, Warren-Perry, M, Watkins, NA, Webster, J, Weedon, MN, Wilson, AG, Woodburn, M, Wordsworth, BP, Young, AH, Zeggini, E, Carter, NP, Frayling, TM, Lee, C, McVean, G, Munroe, PB, Palotie, A, Sawcer, SJ, Scherer, SW, Strachan, DP, Tyler-Smith, C, Brown, MA, Burton, PR, Caulfield, MJ, Compston, A, Farrall, M, Gough, SCL, Hall, AS, Hattersley, AT, Hill, AVS, Mathew, CG, Pembrey, M, Satsangi, J, Stratton, MR, Worthington, J, Deloukas, P, Duncanson, A, Kwiatkowski, DP, McCarthy, MI, Ouwehand, WH, Parkes, M, Rahman, N, Todd, JA, Samani, NJ, and Donnelly, P

Abstract

Copy number variants (CNVs) account for a major proportion of human genetic polymorphism and have been predicted to have an important role in genetic susceptibility to common disease. To address this we undertook a large, direct genome-wide study of association between CNVs and eight common human diseases. Using a purpose-designed array we typed approximately 19,000 individuals into distinct copy-number classes at 3,432 polymorphic CNVs, including an estimated approximately 50% of all common CNVs larger than 500 base pairs. We identified several biological artefacts that lead to false-positive associations, including systematic CNV differences between DNAs derived from blood and cell lines. Association testing and follow-up replication analyses confirmed three loci where CNVs were associated with disease-IRGM for Crohn's disease, HLA for Crohn's disease, rheumatoid arthritis and type 1 diabetes, and TSPAN8 for type 2 diabetes-although in each case the locus had previously been identified in single nucleotide polymorphism (SNP)-based studies, reflecting our observation that most common CNVs that are well-typed on our array are well tagged by SNPs and so have been indirectly explored through SNP studies. We conclude that common CNVs that can be typed on existing platforms are unlikely to contribute greatly to the genetic basis of common human diseases.

Published

2010

9. Breaking the waves: improved detection of copy number variation from microarray-based comparative genomic hybridization.

Author

Marioni, JC, Thorne, NP, Valsesia, A, Fitzgerald, T, Redon, R, Fiegler, H, Andrews, TD, Stranger, BE, Lynch, AG, Dermitzakis, ET, Carter, NP, Tavaré, S, Hurles, ME, Marioni, JC, Thorne, NP, Valsesia, A, Fitzgerald, T, Redon, R, Fiegler, H, Andrews, TD, Stranger, BE, Lynch, AG, Dermitzakis, ET, Carter, NP, Tavaré, S, and Hurles, ME

Abstract

BACKGROUND: Large-scale high throughput studies using microarray technology have established that copy number variation (CNV) throughout the genome is more frequent than previously thought. Such variation is known to play an important role in the presence and development of phenotypes such as HIV-1 infection and Alzheimer's disease. However, methods for analyzing the complex data produced and identifying regions of CNV are still being refined. RESULTS: We describe the presence of a genome-wide technical artifact, spatial autocorrelation or 'wave', which occurs in a large dataset used to determine the location of CNV across the genome. By removing this artifact we are able to obtain both a more biologically meaningful clustering of the data and an increase in the number of CNVs identified by current calling methods without a major increase in the number of false positives detected. Moreover, removing this artifact is critical for the development of a novel model-based CNV calling algorithm - CNVmix - that uses cross-sample information to identify regions of the genome where CNVs occur. For regions of CNV that are identified by both CNVmix and current methods, we demonstrate that CNVmix is better able to categorize samples into groups that represent copy number gains or losses. CONCLUSION: Removing artifactual 'waves' (which appear to be a general feature of array comparative genomic hybridization (aCGH) datasets) and using cross-sample information when identifying CNVs enables more biological information to be extracted from aCGH experiments designed to investigate copy number variation in normal individuals.

Published

2007

10. Definition of the zebrafish genome using flow cytometry and cytogenetic mapping

Author

Freeman, JL, Adeniyi, A, Banerjee, R, Dallaire, S, Maguire, SF, Chi, J, Ng, BL, Zepeda, C, Scott, CE, Humphray, S, Rogers, J, Zhou, Y, Zon, LI, Carter, NP, Yang, F, Lee, C, Freeman, JL, Adeniyi, A, Banerjee, R, Dallaire, S, Maguire, SF, Chi, J, Ng, BL, Zepeda, C, Scott, CE, Humphray, S, Rogers, J, Zhou, Y, Zon, LI, Carter, NP, Yang, F, and Lee, C

Abstract

BACKGROUND: The zebrafish (Danio rerio) is an important vertebrate model organism system for biomedical research. The syntenic conservation between the zebrafish and human genome allows one to investigate the function of human genes using the zebrafish model. To facilitate analysis of the zebrafish genome, genetic maps have been constructed and sequence annotation of a reference zebrafish genome is ongoing. However, the duplicative nature of teleost genomes, including the zebrafish, complicates accurate assembly and annotation of a representative genome sequence. Cytogenetic approaches provide "anchors" that can be integrated with accumulating genomic data. RESULTS: Here, we cytogenetically define the zebrafish genome by first estimating the size of each linkage group (LG) chromosome using flow cytometry, followed by the cytogenetic mapping of 575 bacterial artificial chromosome (BAC) clones onto metaphase chromosomes. Of the 575 BAC clones, 544 clones localized to apparently unique chromosomal locations. 93.8% of these clones were assigned to a specific LG chromosome location using fluorescence in situ hybridization (FISH) and compared to the LG chromosome assignment reported in the zebrafish genome databases. Thirty-one BAC clones localized to multiple chromosomal locations in several different hybridization patterns. From these data, a refined second generation probe panel for each LG chromosome was also constructed. CONCLUSION: The chromosomal mapping of the 575 large-insert DNA clones allows for these clones to be integrated into existing zebrafish mapping data. An accurately annotated zebrafish reference genome serves as a valuable resource for investigating the molecular basis of human diseases using zebrafish mutant models.

Published

2007

11. Localization of the gene (LAMA4) to chromosome 6q21 and isolation of a partial cDNA encoding a variant laminin A chain

Author

M.A. Leversha, Pope Fm, Carter Np, L. Al-Imara, Allan J. Richards, and J. C. Lloyd

Subjects

DNA, Complementary, Molecular Sequence Data, Gene mapping, Laminin, Complementary DNA, Consensus Sequence, Genetics, medicine, Humans, Amino Acid Sequence, Gene, DNA Primers, biology, medicine.diagnostic_test, Base Sequence, Molecular Structure, DNA–DNA hybridization, Nucleic acid sequence, Chromosome Mapping, Genetic Variation, Molecular biology, genomic DNA, biology.protein, Chromosomes, Human, Pair 6, Fluorescence in situ hybridization

Abstract

Laminin is a basement membrane glycoprotein composed of three nonidentical chains, A, B1, and B2. Variant chains such as merosin and S-laminin have been found in different tissues. We have isolated a cDNA encoding a novel laminin A variant that hybridizes to a 6.45-kb mRNA. Using amplification of genomic DNA and flow-sorted chromosomes we have assigned the gene (LAMA4) for this new laminin A variant to chromosome 6. Fluorescence in situ hybridization of a YAC clone further localized the gene to 6q21.

Published

1994

12. Chromosome translocations and fusion genes in breast cancer.

Author

Howarth, KD, primary, Batty, EM, additional, Beavis, JC, additional, Blood, KA, additional, Newman, S, additional, Ng, B, additional, Pole, JC, additional, Chua, Y, additional, Ichimura, K, additional, Collins, VP, additional, Project, CG, additional, Chin, S, additional, Caldas, C, additional, Carter, NP, additional, and Edwards, PA, additional

Published

2009

13. Molecular Genetics of human Ferrochelatase in Erythropoietic Protoporphyria

Author

Sarkany, RP, primary, Whitcombe, DM, additional, Carter, NP, additional, Albertson, DG, additional, and Cox, TM, additional

Published

1991

14. Hypocarbia and eye sugery

Author

Yate Bh, Bourne Ma, and Carter Np

Subjects

Anesthesiology and Pain Medicine, business.industry, Anesthesia, Humans, Medicine, Cataract Extraction, Carbon Dioxide, business, Aged

Published

1988

15. Self-Leadership 101: Steering Your Thoughts for Better Performance.

Author

Neck C and Carter K NP

Subjects

Humans, Leadership

Published

2023

16. Chromosomal breaks at FRA18C: association with reduced DOK6 expression, altered oncogenic signaling and increased gastric cancer survival.

Author

Leong SH, Lwin KM, Lee SS, Ng WH, Ng KM, Tan SY, Ng BL, Carter NP, Tang C, and Lian Kon O

Abstract

Chromosomal rearrangements are common in cancer. More than 50% occur in common fragile sites and disrupt tumor suppressors. However, such rearrangements are not known in gastric cancer. Here we report recurrent 18q2 breakpoints in 6 of 17 gastric cancer cell lines. The rearranged chromosome 18, t(9;18), in MKN7 cells was flow sorted and identified by reverse chromosome painting. High-resolution tiling array hybridization mapped breakpoints to DOK6 (docking protein 6) intron 4 in FRA18C (18q22.2) and an intergenic region in 9q22.2. The same rearrangement was detected by FISH in 22% of 99 primary gastric cancers. Intron 4 truncation was associated with reduced DOK6 transcription. Analysis of The Cancer Genome Atlas stomach adenocarcinoma cohort showed significant correlation of DOK6 expression with histological and molecular phenotypes. Multiple oncogenic signaling pathways (gastrin-CREB, NGF-neurotrophin, PDGF, EGFR, ERK, ERBB4, FGFR1, RAS, VEGFR2 and RAF/MAP kinase) known to be active in aggressive gastric cancers were strikingly diminished in gastric cancers with low DOK6 expression. Median survival of patients with low DOK6 -expressing tumors was 2100 days compared with 533 days in patients with high DOK6 -expressing tumors (log-rank P  = 0.0027). The level of DOK6 expression in tumors predicted patient survival independent of TNM stage. These findings point to new functions of human DOK6 as an adaptor that interacts with diverse molecular components of signaling pathways. Our data suggest that DOK6 expression is an integrated biomarker of multiple oncogenic signals in gastric cancer and identify FRA18C as a new cancer-associated fragile site., Competing Interests: The authors declare no competing financial interests.

Published

2017

17. Genetic diagnosis of developmental disorders in the DDD study: a scalable analysis of genome-wide research data.

Author

Wright CF, Fitzgerald TW, Jones WD, Clayton S, McRae JF, van Kogelenberg M, King DA, Ambridge K, Barrett DM, Bayzetinova T, Bevan AP, Bragin E, Chatzimichali EA, Gribble S, Jones P, Krishnappa N, Mason LE, Miller R, Morley KI, Parthiban V, Prigmore E, Rajan D, Sifrim A, Swaminathan GJ, Tivey AR, Middleton A, Parker M, Carter NP, Barrett JC, Hurles ME, FitzPatrick DR, and Firth HV

Subjects

Adolescent, Child, Child, Preschool, Developmental Disabilities genetics, Female, Genetic Variation genetics, Genome-Wide Association Study methods, Heterozygote, Humans, Incidental Findings, Infant, Infant, Newborn, Information Dissemination, Male, Phenotype, Specimen Handling, Developmental Disabilities diagnosis, Genome, Human genetics

Abstract

Background: Human genome sequencing has transformed our understanding of genomic variation and its relevance to health and disease, and is now starting to enter clinical practice for the diagnosis of rare diseases. The question of whether and how some categories of genomic findings should be shared with individual research participants is currently a topic of international debate, and development of robust analytical workflows to identify and communicate clinically relevant variants is paramount., Methods: The Deciphering Developmental Disorders (DDD) study has developed a UK-wide patient recruitment network involving over 180 clinicians across all 24 regional genetics services, and has performed genome-wide microarray and whole exome sequencing on children with undiagnosed developmental disorders and their parents. After data analysis, pertinent genomic variants were returned to individual research participants via their local clinical genetics team., Findings: Around 80,000 genomic variants were identified from exome sequencing and microarray analysis in each individual, of which on average 400 were rare and predicted to be protein altering. By focusing only on de novo and segregating variants in known developmental disorder genes, we achieved a diagnostic yield of 27% among 1133 previously investigated yet undiagnosed children with developmental disorders, whilst minimising incidental findings. In families with developmentally normal parents, whole exome sequencing of the child and both parents resulted in a 10-fold reduction in the number of potential causal variants that needed clinical evaluation compared to sequencing only the child. Most diagnostic variants identified in known genes were novel and not present in current databases of known disease variation., Interpretation: Implementation of a robust translational genomics workflow is achievable within a large-scale rare disease research study to allow feedback of potentially diagnostic findings to clinicians and research participants. Systematic recording of relevant clinical data, curation of a gene-phenotype knowledge base, and development of clinical decision support software are needed in addition to automated exclusion of almost all variants, which is crucial for scalable prioritisation and review of possible diagnostic variants. However, the resource requirements of development and maintenance of a clinical reporting system within a research setting are substantial., Funding: Health Innovation Challenge Fund, a parallel funding partnership between the Wellcome Trust and the UK Department of Health., (Copyright © 2015 Wright et al. Open Access article distributed under the terms of CC BY. Published by Elsevier Ltd. All rights reserved.)

Published

2015

18. The zebrafish reference genome sequence and its relationship to the human genome.

Author

Howe K, Clark MD, Torroja CF, Torrance J, Berthelot C, Muffato M, Collins JE, Humphray S, McLaren K, Matthews L, McLaren S, Sealy I, Caccamo M, Churcher C, Scott C, Barrett JC, Koch R, Rauch GJ, White S, Chow W, Kilian B, Quintais LT, Guerra-Assunção JA, Zhou Y, Gu Y, Yen J, Vogel JH, Eyre T, Redmond S, Banerjee R, Chi J, Fu B, Langley E, Maguire SF, Laird GK, Lloyd D, Kenyon E, Donaldson S, Sehra H, Almeida-King J, Loveland J, Trevanion S, Jones M, Quail M, Willey D, Hunt A, Burton J, Sims S, McLay K, Plumb B, Davis J, Clee C, Oliver K, Clark R, Riddle C, Elliot D, Threadgold G, Harden G, Ware D, Begum S, Mortimore B, Kerry G, Heath P, Phillimore B, Tracey A, Corby N, Dunn M, Johnson C, Wood J, Clark S, Pelan S, Griffiths G, Smith M, Glithero R, Howden P, Barker N, Lloyd C, Stevens C, Harley J, Holt K, Panagiotidis G, Lovell J, Beasley H, Henderson C, Gordon D, Auger K, Wright D, Collins J, Raisen C, Dyer L, Leung K, Robertson L, Ambridge K, Leongamornlert D, McGuire S, Gilderthorp R, Griffiths C, Manthravadi D, Nichol S, Barker G, Whitehead S, Kay M, Brown J, Murnane C, Gray E, Humphries M, Sycamore N, Barker D, Saunders D, Wallis J, Babbage A, Hammond S, Mashreghi-Mohammadi M, Barr L, Martin S, Wray P, Ellington A, Matthews N, Ellwood M, Woodmansey R, Clark G, Cooper J, Tromans A, Grafham D, Skuce C, Pandian R, Andrews R, Harrison E, Kimberley A, Garnett J, Fosker N, Hall R, Garner P, Kelly D, Bird C, Palmer S, Gehring I, Berger A, Dooley CM, Ersan-Ürün Z, Eser C, Geiger H, Geisler M, Karotki L, Kirn A, Konantz J, Konantz M, Oberländer M, Rudolph-Geiger S, Teucke M, Lanz C, Raddatz G, Osoegawa K, Zhu B, Rapp A, Widaa S, Langford C, Yang F, Schuster SC, Carter NP, Harrow J, Ning Z, Herrero J, Searle SM, Enright A, Geisler R, Plasterk RH, Lee C, Westerfield M, de Jong PJ, Zon LI, Postlethwait JH, Nüsslein-Volhard C, Hubbard TJ, Roest Crollius H, Rogers J, and Stemple DL

Subjects

Animals, Chromosomes genetics, Evolution, Molecular, Female, Genes genetics, Genome, Human genetics, Genomics, Humans, Male, Meiosis genetics, Molecular Sequence Annotation, Pseudogenes genetics, Reference Standards, Sex Determination Processes genetics, Zebrafish Proteins genetics, Conserved Sequence genetics, Genome genetics, Zebrafish genetics

Abstract

Zebrafish have become a popular organism for the study of vertebrate gene function. The virtually transparent embryos of this species, and the ability to accelerate genetic studies by gene knockdown or overexpression, have led to the widespread use of zebrafish in the detailed investigation of vertebrate gene function and increasingly, the study of human genetic disease. However, for effective modelling of human genetic disease it is important to understand the extent to which zebrafish genes and gene structures are related to orthologous human genes. To examine this, we generated a high-quality sequence assembly of the zebrafish genome, made up of an overlapping set of completely sequenced large-insert clones that were ordered and oriented using a high-resolution high-density meiotic map. Detailed automatic and manual annotation provides evidence of more than 26,000 protein-coding genes, the largest gene set of any vertebrate so far sequenced. Comparison to the human reference genome shows that approximately 70% of human genes have at least one obvious zebrafish orthologue. In addition, the high quality of this genome assembly provides a clearer understanding of key genomic features such as a unique repeat content, a scarcity of pseudogenes, an enrichment of zebrafish-specific genes on chromosome 4 and chromosomal regions that influence sex determination.

Published

2013

19. Massively parallel sequencing reveals the complex structure of an irradiated human chromosome on a mouse background in the Tc1 model of Down syndrome.

Author

Gribble SM, Wiseman FK, Clayton S, Prigmore E, Langley E, Yang F, Maguire S, Fu B, Rajan D, Sheppard O, Scott C, Hauser H, Stephens PJ, Stebbings LA, Ng BL, Fitzgerald T, Quail MA, Banerjee R, Rothkamm K, Tybulewicz VL, Fisher EM, and Carter NP

Subjects

Animals, Chromosomes, Human, Pair 21, Comparative Genomic Hybridization, Disease Models, Animal, Gamma Rays adverse effects, Gene Dosage, Humans, In Situ Hybridization, Fluorescence, Male, Mice, Oligonucleotide Array Sequence Analysis, Recombination, Genetic, Trisomy, Chromosomes, Human radiation effects, Down Syndrome genetics, High-Throughput Nucleotide Sequencing

Abstract

Down syndrome (DS) is caused by trisomy of chromosome 21 (Hsa21) and presents a complex phenotype that arises from abnormal dosage of genes on this chromosome. However, the individual dosage-sensitive genes underlying each phenotype remain largely unknown. To help dissect genotype--phenotype correlations in this complex syndrome, the first fully transchromosomic mouse model, the Tc1 mouse, which carries a copy of human chromosome 21 was produced in 2005. The Tc1 strain is trisomic for the majority of genes that cause phenotypes associated with DS, and this freely available mouse strain has become used widely to study DS, the effects of gene dosage abnormalities, and the effect on the basic biology of cells when a mouse carries a freely segregating human chromosome. Tc1 mice were created by a process that included irradiation microcell-mediated chromosome transfer of Hsa21 into recipient mouse embryonic stem cells. Here, the combination of next generation sequencing, array-CGH and fluorescence in situ hybridization technologies has enabled us to identify unsuspected rearrangements of Hsa21 in this mouse model; revealing one deletion, six duplications and more than 25 de novo structural rearrangements. Our study is not only essential for informing functional studies of the Tc1 mouse but also (1) presents for the first time a detailed sequence analysis of the effects of gamma radiation on an entire human chromosome, which gives some mechanistic insight into the effects of radiation damage on DNA, and (2) overcomes specific technical difficulties of assaying a human chromosome on a mouse background where highly conserved sequences may confound the analysis. Sequence data generated in this study is deposited in the ENA database, Study Accession number: ERP000439.

Published

2013

20. Genetic basis of Y-linked hearing impairment.

Author

Wang Q, Xue Y, Zhang Y, Long Q, Asan, Yang F, Turner DJ, Fitzgerald T, Ng BL, Zhao Y, Chen Y, Liu Q, Yang W, Han D, Quail MA, Swerdlow H, Burton J, Fahey C, Ning Z, Hurles ME, Carter NP, Yang H, and Tyler-Smith C

Subjects

Female, Gene Rearrangement genetics, Humans, Male, Pedigree, Chromosomes, Human, Y genetics, Genes, Y-Linked genetics, Hearing Loss genetics

Abstract

A single Mendelian trait has been mapped to the human Y chromosome: Y-linked hearing impairment. The molecular basis of this disorder is unknown. Here, we report the detailed characterization of the DFNY1 Y chromosome and its comparison with a closely related Y chromosome from an unaffected branch of the family. The DFNY1 chromosome carries a complex rearrangement, including duplication of several noncontiguous segments of the Y chromosome and insertion of ∼160 kb of DNA from chromosome 1, in the pericentric region of Yp. This segment of chromosome 1 is derived entirely from within a known hearing impairment locus, DFNA49. We suggest that a third copy of one or more genes from the shared segment of chromosome 1 might be responsible for the hearing-loss phenotype., (Copyright © 2013 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2013

21. DECIPHER: web-based, community resource for clinical interpretation of rare variants in developmental disorders.

Author

Swaminathan GJ, Bragin E, Chatzimichali EA, Corpas M, Bevan AP, Wright CF, Carter NP, Hurles ME, and Firth HV

Subjects

Computational Biology, Genetic Predisposition to Disease, Genetic Variation, Genome, Human, Humans, Information Dissemination, Mutation, Phenotype, Polymorphism, Single Nucleotide, DNA Copy Number Variations, Databases, Nucleic Acid, Developmental Disabilities genetics, Genetic Diseases, Inborn genetics, Internet

Abstract

Patients with developmental disorders often harbour sub-microscopic deletions or duplications that lead to a disruption of normal gene expression or perturbation in the copy number of dosage-sensitive genes. Clinical interpretation for such patients in isolation is hindered by the rarity and novelty of such disorders. The DECIPHER project (https://decipher.sanger.ac.uk) was established in 2004 as an accessible online repository of genomic and associated phenotypic data with the primary goal of aiding the clinical interpretation of rare copy-number variants (CNVs). DECIPHER integrates information from a variety of bioinformatics resources and uses visualization tools to identify potential disease genes within a CNV. A two-tier access system permits clinicians and clinical scientists to maintain confidential linked anonymous records of phenotypes and CNVs for their patients that, with informed consent, can subsequently be shared with the wider clinical genetics and research communities. Advances in next-generation sequencing technologies are making it practical and affordable to sequence the whole exome/genome of patients who display features suggestive of a genetic disorder. This approach enables the identification of smaller intragenic mutations including single-nucleotide variants that are not accessible even with high-resolution genomic array analysis. This article briefly summarizes the current status and achievements of the DECIPHER project and looks ahead to the opportunities and challenges of jointly analysing structural and sequence variation in the human genome.

Published

2012

22. Diagnostic interpretation of array data using public databases and internet sources.

Author

de Leeuw N, Dijkhuizen T, Hehir-Kwa JY, Carter NP, Feuk L, Firth HV, Kuhn RM, Ledbetter DH, Martin CL, van Ravenswaaij-Arts CM, Scherer SW, Shams S, Van Vooren S, Sijmons R, Swertz M, and Hastings R

Subjects

Genetic Variation, Genome, Human, Humans, Oligonucleotide Array Sequence Analysis, Polymorphism, Single Nucleotide, Search Engine, DNA Copy Number Variations, Databases, Genetic, Diagnostic Tests, Routine, Internet, Software

Abstract

The range of commercially available array platforms and analysis software packages is expanding and their utility is improving, making reliable detection of copy-number variants (CNVs) relatively straightforward. Reliable interpretation of CNV data, however, is often difficult and requires expertise. With our knowledge of the human genome growing rapidly, applications for array testing continuously broadening, and the resolution of CNV detection increasing, this leads to great complexity in interpreting what can be daunting data. Correct CNV interpretation and optimal use of the genotype information provided by single-nucleotide polymorphism probes on an array depends largely on knowledge present in various resources. In addition to the availability of host laboratories' own datasets and national registries, there are several public databases and Internet resources with genotype and phenotype information that can be used for array data interpretation. With so many resources now available, it is important to know which are fit-for-purpose in a diagnostic setting. We summarize the characteristics of the most commonly used Internet databases and resources, and propose a general data interpretation strategy that can be used for comparative hybridization, comparative intensity, and genotype-based array data., Competing Interests: Statement: The authors declare no conflict of interest.

Published

2012

23. Genome sequencing and analysis of the Tasmanian devil and its transmissible cancer.

Author

Murchison EP, Schulz-Trieglaff OB, Ning Z, Alexandrov LB, Bauer MJ, Fu B, Hims M, Ding Z, Ivakhno S, Stewart C, Ng BL, Wong W, Aken B, White S, Alsop A, Becq J, Bignell GR, Cheetham RK, Cheng W, Connor TR, Cox AJ, Feng ZP, Gu Y, Grocock RJ, Harris SR, Khrebtukova I, Kingsbury Z, Kowarsky M, Kreiss A, Luo S, Marshall J, McBride DJ, Murray L, Pearse AM, Raine K, Rasolonjatovo I, Shaw R, Tedder P, Tregidgo C, Vilella AJ, Wedge DC, Woods GM, Gormley N, Humphray S, Schroth G, Smith G, Hall K, Searle SM, Carter NP, Papenfuss AT, Futreal PA, Campbell PJ, Yang F, Bentley DR, Evers DJ, and Stratton MR

Subjects

Animals, Clonal Evolution, Endangered Species, Facial Neoplasms epidemiology, Facial Neoplasms genetics, Facial Neoplasms pathology, Female, Genome-Wide Association Study, Male, Molecular Sequence Data, Tasmania epidemiology, Facial Neoplasms veterinary, Genomic Instability, Marsupialia genetics, Mutation

Abstract

The Tasmanian devil (Sarcophilus harrisii), the largest marsupial carnivore, is endangered due to a transmissible facial cancer spread by direct transfer of living cancer cells through biting. Here we describe the sequencing, assembly, and annotation of the Tasmanian devil genome and whole-genome sequences for two geographically distant subclones of the cancer. Genomic analysis suggests that the cancer first arose from a female Tasmanian devil and that the clone has subsequently genetically diverged during its spread across Tasmania. The devil cancer genome contains more than 17,000 somatic base substitution mutations and bears the imprint of a distinct mutational process. Genotyping of somatic mutations in 104 geographically and temporally distributed Tasmanian devil tumors reveals the pattern of evolution and spread of this parasitic clonal lineage, with evidence of a selective sweep in one geographical area and persistence of parallel lineages in other populations., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

24. An atypical facial appearance and growth pattern in a child with Cornelia de Lange Syndrome: an intragenic deletion predicting loss of the N-terminal region of NIPBL.

Author

Murray JE, Walayat M, Gillett P, Sharkey FH, Rajan D, Carter NP, and FitzPatrick DR

Subjects

Cell Cycle Proteins, Child, Preschool, DNA Mutational Analysis, Facies, Humans, Male, Microcephaly genetics, Mutation, Sequence Deletion, De Lange Syndrome diagnosis, De Lange Syndrome genetics, Proteins genetics

Abstract

Cornelia de Lange Syndrome (CdLS) is a multisystem disorder with a live birth prevalence of approximately one per 15 000. Clinical diagnosis is based on a characteristic facies – low frontal hair line, short nose, triangular nasal tip, crescent shaped mouth, upturned nose, and arched eyebrows – characteristic limb defects and a distinctive pattern of growth and development. Approximately half of all classical cases of CdLS have heterozygous loss of-function mutations in the gene encoding NIPBL, a component of the cohesion-loading apparatus (Dorsett and Krantz, 2009). Herein we describe a patient with a rare intragenic deletion of NIPBL who has typical microcephaly and developmental problems but atypical growth pattern and facial features.

Published

2012

25. Maternally inherited partial monosomy 9p (pter → p24.1) and partial trisomy 20p (pter → p12.1) characterized by microarray comparative genomic hybridization.

Author

Freitas ÉL, Gribble SM, Simioni M, Vieira TP, Silva-Grecco RL, Balarin MA, Prigmore E, Krepischi-Santos AC, Rosenberg C, Szuhai K, van Haeringen A, Carter NP, and Gil-da-Silva-Lopes VL

Subjects

Abnormal Karyotype, Adolescent, Child, Preschool, Chromosome Deletion, Chromosome Mapping, Chromosomes, Human, Pair 20 genetics, Chromosomes, Human, Pair 9 genetics, Comparative Genomic Hybridization methods, DNA Copy Number Variations, Developmental Disabilities genetics, Developmental Disabilities pathology, Forkhead Transcription Factors genetics, Genome, Human, Guanine Nucleotide Exchange Factors genetics, Humans, In Situ Hybridization, Fluorescence, Intellectual Disability genetics, Intellectual Disability pathology, Male, Metaphase, Physical Examination, Trisomy diagnosis, Trisomy pathology, Inheritance Patterns, Trisomy genetics

Abstract

We report on a 17-year-old patient with midline defects, ocular hypertelorism, neuropsychomotor development delay, neonatal macrosomy, and dental anomalies. DNA copy number investigations using a Whole Genome TilePath array consisting, of 30K BAC/PAC clones showed a 6.36 Mb deletion in the 9p24.1-p24.3 region and a 14.83 Mb duplication in the 20p12.1-p13 region, which derived from a maternal balanced t(9;20)(p24.1;p12.1) as shown by FISH studies. Monosomy 9p is a well-delineated chromosomal syndrome with characteristic clinical features, while chromosome 20p duplication is a rare genetic condition. Only a handful of cases of monosomy 9/trisomy 20 have been previously described. In this report, we compare the phenotype of our patient with those already reported in the literature, and discuss the role of DMRT, DOCK8, FOXD4, VLDLR, RSPO4, AVP, RASSF2, PROKR2, BMP2, MKKS, and JAG1, all genes mapping to the deleted and duplicated regions., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2011

26. FoSTeS, MMBIR and NAHR at the human proximal Xp region and the mechanisms of human Xq isochromosome formation.

Author

Koumbaris G, Hatzisevastou-Loukidou H, Alexandrou A, Ioannides M, Christodoulou C, Fitzgerald T, Rajan D, Clayton S, Kitsiou-Tzeli S, Vermeesch JR, Skordis N, Antoniou P, Kurg A, Georgiou I, Carter NP, and Patsalis PC

Subjects

Base Sequence, Chromosome Breakage, Comparative Genomic Hybridization, Humans, Models, Genetic, Molecular Sequence Data, Nucleic Acid Conformation, Polymorphism, Genetic, Recombination, Genetic, Sequence Alignment, Tandem Repeat Sequences genetics, Chromosomes, Human, X genetics, DNA Replication genetics, Isochromosomes genetics

Abstract

The recently described DNA replication-based mechanisms of fork stalling and template switching (FoSTeS) and microhomology-mediated break-induced replication (MMBIR) were previously shown to catalyze complex exonic, genic and genomic rearrangements. By analyzing a large number of isochromosomes of the long arm of chromosome X (i(Xq)), using whole-genome tiling path array comparative genomic hybridization (aCGH), ultra-high resolution targeted aCGH and sequencing, we provide evidence that the FoSTeS and MMBIR mechanisms can generate large-scale gross chromosomal rearrangements leading to the deletion and duplication of entire chromosome arms, thus suggesting an important role for DNA replication-based mechanisms in both the development of genomic disorders and cancer. Furthermore, we elucidate the mechanisms of dicentric i(Xq) (idic(Xq)) formation and show that most idic(Xq) chromosomes result from non-allelic homologous recombination between palindromic low copy repeats and highly homologous palindromic LINE elements. We also show that non-recurrent-breakpoint idic(Xq) chromosomes have microhomology-associated breakpoint junctions and are likely catalyzed by microhomology-mediated replication-dependent recombination mechanisms such as FoSTeS and MMBIR. Finally, we stress the role of the proximal Xp region as a chromosomal rearrangement hotspot.

Published

2011

27. Comprehensive assessment of array-based platforms and calling algorithms for detection of copy number variants.

Author

Pinto D, Darvishi K, Shi X, Rajan D, Rigler D, Fitzgerald T, Lionel AC, Thiruvahindrapuram B, Macdonald JR, Mills R, Prasad A, Noonan K, Gribble S, Prigmore E, Donahoe PK, Smith RS, Park JH, Hurles ME, Carter NP, Lee C, Scherer SW, and Feuk L

Subjects

Algorithms, Databases, Genetic, Genetic Association Studies, Genome, Genotype, Reproducibility of Results, Software, Comparative Genomic Hybridization methods, DNA Copy Number Variations, Oligonucleotide Array Sequence Analysis methods, Polymorphism, Single Nucleotide

Abstract

We have systematically compared copy number variant (CNV) detection on eleven microarrays to evaluate data quality and CNV calling, reproducibility, concordance across array platforms and laboratory sites, breakpoint accuracy and analysis tool variability. Different analytic tools applied to the same raw data typically yield CNV calls with <50% concordance. Moreover, reproducibility in replicate experiments is <70% for most platforms. Nevertheless, these findings should not preclude detection of large CNVs for clinical diagnostic purposes because large CNVs with poor reproducibility are found primarily in complex genomic regions and would typically be removed by standard clinical data curation. The striking differences between CNV calls from different platforms and analytic tools highlight the importance of careful assessment of experimental design in discovery and association studies and of strict data curation and filtering in diagnostics. The CNV resource presented here allows independent data evaluation and provides a means to benchmark new algorithms.

Published

2011

28. aCGH.Spline--an R package for aCGH dye bias normalization.

Author

Fitzgerald TW, Larcombe LD, Le Scouarnec S, Clayton S, Rajan D, Carter NP, and Redon R

Subjects

Carbocyanines chemistry, DNA Copy Number Variations, Comparative Genomic Hybridization methods, Fluorescent Dyes chemistry, Software

Abstract

Motivation: The careful normalization of array-based comparative genomic hybridization (aCGH) data is of critical importance for the accurate detection of copy number changes. The difference in labelling affinity between the two fluorophores used in aCGH-usually Cy5 and Cy3-can be observed as a bias within the intensity distributions. If left unchecked, this bias is likely to skew data interpretation during downstream analysis and lead to an increased number of false discoveries., Results: In this study, we have developed aCGH.Spline, a natural cubic spline interpolation method followed by linear interpolation of outlier values, which is able to remove a large portion of the dye bias from large aCGH datasets in a quick and efficient manner., Conclusions: We have shown that removing this bias and reducing the experimental noise has a strong positive impact on the ability to detect accurately both copy number variation (CNV) and copy number alterations (CNA).

Published

2011

29. Fetal-specific DNA methylation ratio permits noninvasive prenatal diagnosis of trisomy 21.

Author

Papageorgiou EA, Karagrigoriou A, Tsaliki E, Velissariou V, Carter NP, and Patsalis PC

Subjects

Base Sequence, Case-Control Studies, DNA blood, DNA genetics, DNA Primers genetics, Discriminant Analysis, Female, Humans, Immunoprecipitation methods, Male, Polymerase Chain Reaction methods, Predictive Value of Tests, Pregnancy, Reference Values, DNA Methylation genetics, Down Syndrome diagnosis, Down Syndrome genetics, Fetus metabolism, Prenatal Diagnosis methods

Abstract

The trials performed worldwide toward noninvasive prenatal diagnosis (NIPD) of Down's syndrome (or trisomy 21) have shown the commercial and medical potential of NIPD compared to the currently used invasive prenatal diagnostic procedures. Extensive investigation of methylation differences between the mother and the fetus has led to the identification of differentially methylated regions (DMRs). In this study, we present a strategy using the methylated DNA immunoprecipitation (MeDiP) methodology in combination with real-time quantitative PCR (qPCR) to achieve fetal chromosome dosage assessment, which can be performed noninvasively through the analysis of fetal-specific DMRs. We achieved noninvasive prenatal detection of trisomy 21 by determining the methylation ratio of normal and trisomy 21 cases for each tested fetal-specific DMR present in maternal peripheral blood, followed by further statistical analysis. The application of this fetal-specific methylation ratio approach provided correct diagnosis of 14 trisomy 21 and 26 normal cases.

Published

2011

30. High incidence of recurrent copy number variants in patients with isolated and syndromic Müllerian aplasia.

Author

Nik-Zainal S, Strick R, Storer M, Huang N, Rad R, Willatt L, Fitzgerald T, Martin V, Sandford R, Carter NP, Janecke AR, Renner SP, Oppelt PG, Oppelt P, Schulze C, Brucker S, Hurles M, Beckmann MW, Strissel PL, and Shaw-Smith C

Subjects

Adolescent, Adult, Cohort Studies, Female, Genetic Testing, Humans, Incidence, Kidney abnormalities, Mullerian Ducts abnormalities, Somites abnormalities, Spine abnormalities, Syndrome, Uterus abnormalities, Vagina abnormalities, Young Adult, 46, XX Disorders of Sex Development epidemiology, 46, XX Disorders of Sex Development genetics, Abnormalities, Multiple epidemiology, Abnormalities, Multiple genetics, Chromosome Deletion, Congenital Abnormalities epidemiology, Congenital Abnormalities genetics, DNA Copy Number Variations

Abstract

Background: Congenital malformations involving the Müllerian ducts are observed in around 5% of infertile women. Complete aplasia of the uterus, cervix, and upper vagina, also termed Müllerian aplasia or Mayer-Rokitansky-Kuster-Hauser (MRKH) syndrome, occurs with an incidence of around 1 in 4500 female births, and occurs in both isolated and syndromic forms. Previous reports have suggested that a proportion of cases, especially syndromic cases, are caused by variation in copy number at different genomic loci., Methods: In order to obtain an overview of the contribution of copy number variation to both isolated and syndromic forms of Müllerian aplasia, copy number assays were performed in a series of 63 cases, of which 25 were syndromic and 38 isolated., Results: A high incidence (9/63, 14%) of recurrent copy number variants in this cohort is reported here. These comprised four cases of microdeletion at 16p11.2, an autism susceptibility locus not previously associated with Müllerian aplasia, four cases of microdeletion at 17q12, and one case of a distal 22q11.2 microdeletion. Microdeletions at 16p11.2 and 17q12 were found in 4/38 (10.5%) cases with isolated Müllerian aplasia, and at 16p11.2, 17q12 and 22q11.2 (distal) in 5/25 cases (20%) with syndromic Müllerian aplasia., Conclusion: The finding of microdeletion at 16p11.2 in 2/38 (5%) of isolated and 2/25 (8%) of syndromic cases suggests a significant contribution of this copy number variant alone to the pathogenesis of Müllerian aplasia. Overall, the high incidence of recurrent copy number variants in all forms of Müllerian aplasia has implications for the understanding of the aetiopathogenesis of the condition, and for genetic counselling in families affected by it.

Published

2011

31. Massive genomic rearrangement acquired in a single catastrophic event during cancer development.

Author

Stephens PJ, Greenman CD, Fu B, Yang F, Bignell GR, Mudie LJ, Pleasance ED, Lau KW, Beare D, Stebbings LA, McLaren S, Lin ML, McBride DJ, Varela I, Nik-Zainal S, Leroy C, Jia M, Menzies A, Butler AP, Teague JW, Quail MA, Burton J, Swerdlow H, Carter NP, Morsberger LA, Iacobuzio-Donahue C, Follows GA, Green AR, Flanagan AM, Stratton MR, Futreal PA, and Campbell PJ

Subjects

Bone Neoplasms genetics, Cell Line, Tumor, Chromosome Painting, Female, Gene Rearrangement, Humans, Leukemia, Lymphocytic, Chronic, B-Cell genetics, Middle Aged, Chromosome Aberrations, Neoplasms genetics, Neoplasms pathology

Abstract

Cancer is driven by somatically acquired point mutations and chromosomal rearrangements, conventionally thought to accumulate gradually over time. Using next-generation sequencing, we characterize a phenomenon, which we term chromothripsis, whereby tens to hundreds of genomic rearrangements occur in a one-off cellular crisis. Rearrangements involving one or a few chromosomes crisscross back and forth across involved regions, generating frequent oscillations between two copy number states. These genomic hallmarks are highly improbable if rearrangements accumulate over time and instead imply that nearly all occur during a single cellular catastrophe. The stamp of chromothripsis can be seen in at least 2%-3% of all cancers, across many subtypes, and is present in ∼25% of bone cancers. We find that one, or indeed more than one, cancer-causing lesion can emerge out of the genomic crisis. This phenomenon has important implications for the origins of genomic remodeling and temporal emergence of cancer., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

32. Differential DNA methylation as a tool for noninvasive prenatal diagnosis (NIPD) of X chromosome aneuploidies.

Author

Della Ragione F, Mastrovito P, Campanile C, Conti A, Papageorgiou EA, Hultén MA, Patsalis PC, Carter NP, and D'Esposito M

Subjects

Biomarkers blood, DNA analysis, Female, Fetus metabolism, Fetus physiology, Humans, Male, Placenta physiology, Pregnancy blood, Tumor Suppressor Proteins blood, Tumor Suppressor Proteins genetics, Turner Syndrome blood, Turner Syndrome genetics, Aneuploidy, Chromosomes, Human, X genetics, DNA Methylation, Prenatal Diagnosis methods

Abstract

The demographic tendency in industrial countries to delay childbearing, coupled with the maternal age effect in common chromosomal aneuploidies and the risk to the fetus of invasive prenatal diagnosis, are potent drivers for the development of strategies for noninvasive prenatal diagnosis. One breakthrough has been the discovery of differentially methylated cell-free fetal DNA in the maternal circulation. We describe novel bisulfite conversion- and methylation-sensitive enzyme digestion DNA methylation-related approaches that we used to diagnose Turner syndrome from first trimester samples. We used an X-linked marker, EF3, and an autosomal marker, RASSF1A, to discriminate between placental and maternal blood cell DNA using real-time methylation-specific PCR after bisulfite conversion and real-time PCR after methylation-sensitive restriction digestion. By normalizing EF3 amplifications versus RASSF1A outputs, we were able to calculate sex chromosome/autosome ratios in chorionic villus samples, thus permitting us to correctly diagnose Turner syndrome. The identification of this new marker coupled with the strategy outlined here may be instrumental in the development of an efficient, noninvasive method of diagnosis of sex chromosome aneuploidies in plasma samples.

Published

2010

33. Distinct effects of allelic NFIX mutations on nonsense-mediated mRNA decay engender either a Sotos-like or a Marshall-Smith syndrome.

Author

Malan V, Rajan D, Thomas S, Shaw AC, Louis Dit Picard H, Layet V, Till M, van Haeringen A, Mortier G, Nampoothiri S, Puseljić S, Legeai-Mallet L, Carter NP, Vekemans M, Munnich A, Hennekam RC, Colleaux L, and Cormier-Daire V

Subjects

Adolescent, Adult, Base Sequence, Child, Chromosomes, Human, Pair 19 genetics, Comparative Genomic Hybridization, DNA Mutational Analysis, Female, Gene Expression Regulation, Genetic Testing, Humans, In Situ Hybridization, Male, Molecular Sequence Data, NFI Transcription Factors metabolism, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Syndrome, Abnormalities, Multiple genetics, Alleles, Codon, Nonsense genetics, Mutation genetics, NFI Transcription Factors genetics, RNA Stability genetics

Abstract

By using a combination of array comparative genomic hybridization and a candidate gene approach, we identified nuclear factor I/X (NFIX) deletions or nonsense mutation in three sporadic cases of a Sotos-like overgrowth syndrome with advanced bone age, macrocephaly, developmental delay, scoliosis, and unusual facies. Unlike the aforementioned human syndrome, Nfix-deficient mice are unable to gain weight and die in the first 3 postnatal weeks, while they also present with a spinal deformation and decreased bone mineralization. These features prompted us to consider NFIX as a candidate gene for Marshall-Smith syndrome (MSS), a severe malformation syndrome characterized by failure to thrive, respiratory insufficiency, accelerated osseous maturation, kyphoscoliosis, osteopenia, and unusual facies. Distinct frameshift and splice NFIX mutations that escaped nonsense-mediated mRNA decay (NMD) were identified in nine MSS subjects. NFIX belongs to the Nuclear factor one (NFI) family of transcription factors, but its specific function is presently unknown. We demonstrate that NFIX is normally expressed prenatally during human brain development and skeletogenesis. These findings demonstrate that allelic NFIX mutations trigger distinct phenotypes, depending specifically on their impact on NMD.

Published

2010

34. Laser excitation power and the flow cytometric resolution of complex karyotypes.

Author

Ng BL and Carter NP

Subjects

Cell Line, Tumor, Cells, Cultured, Humans, Flow Cytometry methods, Karyotyping, Lasers

Abstract

The analytical resolution of individual chromosome peaks in the flow karyotype of cell lines is dependent on sample preparation and the detection sensitivity of the flow cytometer. We have investigated the effect of laser power on the resolution of chromosome peaks in cell lines with complex karyotypes. Chromosomes were prepared from a human gastric cancer cell line and a cell line from a patient with an abnormal phenotype using a modified polyamine isolation buffer. The stained chromosome suspensions were analyzed on a MoFlo sorter (Beckman Coulter) equipped with two water-cooled lasers (Coherent). A bivariate flow karyotype was obtained from each of the cell lines at various laser power settings and compared to a karyotype generated using laser power settings of 300 mW. The best separation of chromosome peaks was obtained with laser powers of 300 mW. This study demonstrates the requirement for high-laser powers for the accurate detection and purification of chromosomes, particularly from complex karyotypes, using a conventional flow cytometer., (Copyright 2010 International Society for Advancement of Cytometry.)

Published

2010

35. Consensus statement: chromosomal microarray is a first-tier clinical diagnostic test for individuals with developmental disabilities or congenital anomalies.

Author

Miller DT, Adam MP, Aradhya S, Biesecker LG, Brothman AR, Carter NP, Church DM, Crolla JA, Eichler EE, Epstein CJ, Faucett WA, Feuk L, Friedman JM, Hamosh A, Jackson L, Kaminsky EB, Kok K, Krantz ID, Kuhn RM, Lee C, Ostell JM, Rosenberg C, Scherer SW, Spinner NB, Stavropoulos DJ, Tepperberg JH, Thorland EC, Vermeesch JR, Waggoner DJ, Watson MS, Martin CL, and Ledbetter DH

Subjects

Child, Chromosome Banding, Humans, Karyotyping, Chromosome Disorders genetics, Congenital Abnormalities genetics, Developmental Disabilities genetics

Abstract

Chromosomal microarray (CMA) is increasingly utilized for genetic testing of individuals with unexplained developmental delay/intellectual disability (DD/ID), autism spectrum disorders (ASD), or multiple congenital anomalies (MCA). Performing CMA and G-banded karyotyping on every patient substantially increases the total cost of genetic testing. The International Standard Cytogenomic Array (ISCA) Consortium held two international workshops and conducted a literature review of 33 studies, including 21,698 patients tested by CMA. We provide an evidence-based summary of clinical cytogenetic testing comparing CMA to G-banded karyotyping with respect to technical advantages and limitations, diagnostic yield for various types of chromosomal aberrations, and issues that affect test interpretation. CMA offers a much higher diagnostic yield (15%-20%) for genetic testing of individuals with unexplained DD/ID, ASD, or MCA than a G-banded karyotype ( approximately 3%, excluding Down syndrome and other recognizable chromosomal syndromes), primarily because of its higher sensitivity for submicroscopic deletions and duplications. Truly balanced rearrangements and low-level mosaicism are generally not detectable by arrays, but these are relatively infrequent causes of abnormal phenotypes in this population (<1%). Available evidence strongly supports the use of CMA in place of G-banded karyotyping as the first-tier cytogenetic diagnostic test for patients with DD/ID, ASD, or MCA. G-banded karyotype analysis should be reserved for patients with obvious chromosomal syndromes (e.g., Down syndrome), a family history of chromosomal rearrangement, or a history of multiple miscarriages., (Copyright (c) 2010 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2010

36. Discovery of common Asian copy number variants using integrated high-resolution array CGH and massively parallel DNA sequencing.

Author

Park H, Kim JI, Ju YS, Gokcumen O, Mills RE, Kim S, Lee S, Suh D, Hong D, Kang HP, Yoo YJ, Shin JY, Kim HJ, Yavartanoo M, Chang YW, Ha JS, Chong W, Hwang GR, Darvishi K, Kim H, Yang SJ, Yang KS, Kim H, Hurles ME, Scherer SW, Carter NP, Tyler-Smith C, Lee C, and Seo JS

Subjects

Algorithms, Asian People, China, Chromosome Mapping, Computational Biology methods, Databases, Genetic, Gene Dosage, Genome, Human, Humans, Japan, Korea, Mongolia, Genetic Variation, Nucleic Acid Hybridization, Sequence Analysis, DNA methods

Abstract

Copy number variants (CNVs) account for the majority of human genomic diversity in terms of base coverage. Here, we have developed and applied a new method to combine high-resolution array comparative genomic hybridization (CGH) data with whole-genome DNA sequencing data to obtain a comprehensive catalog of common CNVs in Asian individuals. The genomes of 30 individuals from three Asian populations (Korean, Chinese and Japanese) were interrogated with an ultra-high-resolution array CGH platform containing 24 million probes. Whole-genome sequencing data from a reference genome (NA10851, with 28.3x coverage) and two Asian genomes (AK1, with 27.8x coverage and AK2, with 32.0x coverage) were used to transform the relative copy number information obtained from array CGH experiments into absolute copy number values. We discovered 5,177 CNVs, of which 3,547 were putative Asian-specific CNVs. These common CNVs in Asian populations will be a useful resource for subsequent genetic studies in these populations, and the new method of calling absolute CNVs will be essential for applying CNV data to personalized medicine.

Published

2010

37. Genome-wide association study of CNVs in 16,000 cases of eight common diseases and 3,000 shared controls.

Author

Craddock N, Hurles ME, Cardin N, Pearson RD, Plagnol V, Robson S, Vukcevic D, Barnes C, Conrad DF, Giannoulatou E, Holmes C, Marchini JL, Stirrups K, Tobin MD, Wain LV, Yau C, Aerts J, Ahmad T, Andrews TD, Arbury H, Attwood A, Auton A, Ball SG, Balmforth AJ, Barrett JC, Barroso I, Barton A, Bennett AJ, Bhaskar S, Blaszczyk K, Bowes J, Brand OJ, Braund PS, Bredin F, Breen G, Brown MJ, Bruce IN, Bull J, Burren OS, Burton J, Byrnes J, Caesar S, Clee CM, Coffey AJ, Connell JM, Cooper JD, Dominiczak AF, Downes K, Drummond HE, Dudakia D, Dunham A, Ebbs B, Eccles D, Edkins S, Edwards C, Elliot A, Emery P, Evans DM, Evans G, Eyre S, Farmer A, Ferrier IN, Feuk L, Fitzgerald T, Flynn E, Forbes A, Forty L, Franklyn JA, Freathy RM, Gibbs P, Gilbert P, Gokumen O, Gordon-Smith K, Gray E, Green E, Groves CJ, Grozeva D, Gwilliam R, Hall A, Hammond N, Hardy M, Harrison P, Hassanali N, Hebaishi H, Hines S, Hinks A, Hitman GA, Hocking L, Howard E, Howard P, Howson JM, Hughes D, Hunt S, Isaacs JD, Jain M, Jewell DP, Johnson T, Jolley JD, Jones IR, Jones LA, Kirov G, Langford CF, Lango-Allen H, Lathrop GM, Lee J, Lee KL, Lees C, Lewis K, Lindgren CM, Maisuria-Armer M, Maller J, Mansfield J, Martin P, Massey DC, McArdle WL, McGuffin P, McLay KE, Mentzer A, Mimmack ML, Morgan AE, Morris AP, Mowat C, Myers S, Newman W, Nimmo ER, O'Donovan MC, Onipinla A, Onyiah I, Ovington NR, Owen MJ, Palin K, Parnell K, Pernet D, Perry JR, Phillips A, Pinto D, Prescott NJ, Prokopenko I, Quail MA, Rafelt S, Rayner NW, Redon R, Reid DM, Renwick, Ring SM, Robertson N, Russell E, St Clair D, Sambrook JG, Sanderson JD, Schuilenburg H, Scott CE, Scott R, Seal S, Shaw-Hawkins S, Shields BM, Simmonds MJ, Smyth DJ, Somaskantharajah E, Spanova K, Steer S, Stephens J, Stevens HE, Stone MA, Su Z, Symmons DP, Thompson JR, Thomson W, Travers ME, Turnbull C, Valsesia A, Walker M, Walker NM, Wallace C, Warren-Perry M, Watkins NA, Webster J, Weedon MN, Wilson AG, Woodburn M, Wordsworth BP, Young AH, Zeggini E, Carter NP, Frayling TM, Lee C, McVean G, Munroe PB, Palotie A, Sawcer SJ, Scherer SW, Strachan DP, Tyler-Smith C, Brown MA, Burton PR, Caulfield MJ, Compston A, Farrall M, Gough SC, Hall AS, Hattersley AT, Hill AV, Mathew CG, Pembrey M, Satsangi J, Stratton MR, Worthington J, Deloukas P, Duncanson A, Kwiatkowski DP, McCarthy MI, Ouwehand W, Parkes M, Rahman N, Todd JA, Samani NJ, and Donnelly P

Subjects

Arthritis, Rheumatoid genetics, Case-Control Studies, Crohn Disease genetics, Diabetes Mellitus genetics, Gene Frequency genetics, Humans, Nucleic Acid Hybridization, Oligonucleotide Array Sequence Analysis, Pilot Projects, Polymorphism, Single Nucleotide genetics, Quality Control, DNA Copy Number Variations genetics, Disease, Genetic Predisposition to Disease genetics, Genome-Wide Association Study

Abstract

Copy number variants (CNVs) account for a major proportion of human genetic polymorphism and have been predicted to have an important role in genetic susceptibility to common disease. To address this we undertook a large, direct genome-wide study of association between CNVs and eight common human diseases. Using a purpose-designed array we typed approximately 19,000 individuals into distinct copy-number classes at 3,432 polymorphic CNVs, including an estimated approximately 50% of all common CNVs larger than 500 base pairs. We identified several biological artefacts that lead to false-positive associations, including systematic CNV differences between DNAs derived from blood and cell lines. Association testing and follow-up replication analyses confirmed three loci where CNVs were associated with disease-IRGM for Crohn's disease, HLA for Crohn's disease, rheumatoid arthritis and type 1 diabetes, and TSPAN8 for type 2 diabetes-although in each case the locus had previously been identified in single nucleotide polymorphism (SNP)-based studies, reflecting our observation that most common CNVs that are well-typed on our array are well tagged by SNPs and so have been indirectly explored through SNP studies. We conclude that common CNVs that can be typed on existing platforms are unlikely to contribute greatly to the genetic basis of common human diseases.

Published

2010

38. Origins and functional impact of copy number variation in the human genome.

Author

Conrad DF, Pinto D, Redon R, Feuk L, Gokcumen O, Zhang Y, Aerts J, Andrews TD, Barnes C, Campbell P, Fitzgerald T, Hu M, Ihm CH, Kristiansson K, Macarthur DG, Macdonald JR, Onyiah I, Pang AW, Robson S, Stirrups K, Valsesia A, Walter K, Wei J, Tyler-Smith C, Carter NP, Lee C, Scherer SW, and Hurles ME

Subjects

Gene Duplication, Genome-Wide Association Study, Genotype, Haplotypes genetics, Humans, Oligonucleotide Array Sequence Analysis, Polymorphism, Single Nucleotide genetics, Racial Groups genetics, Reproducibility of Results, DNA Copy Number Variations genetics, Genetic Predisposition to Disease genetics, Genome, Human genetics, Mutagenesis genetics

Abstract

Structural variations of DNA greater than 1 kilobase in size account for most bases that vary among human genomes, but are still relatively under-ascertained. Here we use tiling oligonucleotide microarrays, comprising 42 million probes, to generate a comprehensive map of 11,700 copy number variations (CNVs) greater than 443 base pairs, of which most (8,599) have been validated independently. For 4,978 of these CNVs, we generated reference genotypes from 450 individuals of European, African or East Asian ancestry. The predominant mutational mechanisms differ among CNV size classes. Retrotransposition has duplicated and inserted some coding and non-coding DNA segments randomly around the genome. Furthermore, by correlation with known trait-associated single nucleotide polymorphisms (SNPs), we identified 30 loci with CNVs that are candidates for influencing disease susceptibility. Despite this, having assessed the completeness of our map and the patterns of linkage disequilibrium between CNVs and SNPs, we conclude that, for complex traits, the heritability void left by genome-wide association studies will not be accounted for by common CNVs.

Published

2010

39. Confirmed rare copy number variants implicate novel genes in schizophrenia.

Author

Tam GW, van de Lagemaat LN, Redon R, Strathdee KE, Croning MD, Malloy MP, Muir WJ, Pickard BS, Deary IJ, Blackwood DH, Carter NP, and Grant SG

Subjects

Case-Control Studies, Cognition physiology, DNA Mutational Analysis, Genome-Wide Association Study, Humans, Validation Studies as Topic, DNA Copy Number Variations physiology, Genes physiology, Schizophrenia genetics

Abstract

Understanding how cognitive processes including learning, memory, decision making and ideation are encoded by the genome is a key question in biology. Identification of sets of genes underlying human mental disorders is a path towards this objective. Schizophrenia is a common disease with cognitive symptoms, high heritability and complex genetics. We have identified genes involved with schizophrenia by measuring differences in DNA copy number across the entire genome in 91 schizophrenia cases and 92 controls in the Scottish population. Our data reproduce rare and common variants observed in public domain data from >3000 schizophrenia cases, confirming known disease loci as well as identifying novel loci. We found copy number variants in PDE10A (phosphodiesterase 10A), CYFIP1 [cytoplasmic FMR1 (Fragile X mental retardation 1)-interacting protein 1], K(+) channel genes KCNE1 and KCNE2, the Down's syndrome critical region 1 gene RCAN1 (regulator of calcineurin 1), cell-recognition protein CHL1 (cell adhesion molecule with homology with L1CAM), the transcription factor SP4 (specificity protein 4) and histone deacetylase HDAC9, among others (see http://www.genes2cognition.org/SCZ-CNV). Integrating the function of these many genes into a coherent model of schizophrenia and cognition is a major unanswered challenge.

Published

2010

40. The role of DNA copy number variation in schizophrenia.

Author

Tam GW, Redon R, Carter NP, and Grant SG

Subjects

Chromosome Deletion, Chromosomes, Human, Pair 1, Chromosomes, Human, Pair 15, Chromosomes, Human, Pair 2, Genetic Predisposition to Disease, Genome-Wide Association Study, Humans, Mental Disorders etiology, Mental Disorders genetics, Models, Genetic, Neural Pathways metabolism, Schizophrenia etiology, DNA Copy Number Variations, Schizophrenia genetics

Abstract

Schizophrenia is a major psychiatric disease with strong evidence of genetic risk factors. Recent studies based on genome-wide study of copy number variations (CNVs) have detected novel recurrent submicroscopic copy number changes, including recurrent deletions at 1q21.11, 15q11.3, 15q13.3, and the recurrent CNV at the 2p16.3 neurexin 1 locus. These schizophrenia susceptibility CNV loci demonstrate that schizophrenia is, at least in part, genetic in origin and provide the basis for further investigation of mutations associated with the disease. The studies combined have also established the role of rare and-in sporadic cases-de novo variants in schizophrenia. Furthermore, neuronal-related genes and genetic pathways are starting to emerge from the CNV loci associated with schizophrenia. Here, we review the major findings in the recent literature, which begin to unravel the genetic and biological architecture of this complex human neuropsychiatric disorder.

Published

2009

41. Reduced TFAP2A function causes variable optic fissure closure and retinal defects and sensitizes eye development to mutations in other morphogenetic regulators.

Author

Gestri G, Osborne RJ, Wyatt AW, Gerrelli D, Gribble S, Stewart H, Fryer A, Bunyan DJ, Prescott K, Collin JR, Fitzgerald T, Robinson D, Carter NP, Wilson SW, and Ragge NK

Subjects

Adult, Animals, Branchio-Oto-Renal Syndrome genetics, Child, Preschool, Female, Gene Deletion, Humans, Infant, Male, Middle Aged, Morphogenesis genetics, Mutation, Zebrafish, Zebrafish Proteins genetics, Eye embryology, Eye Abnormalities genetics, Retina abnormalities, Transcription Factor AP-2 genetics

Abstract

Mutations in the transcription factor encoding TFAP2A gene underlie branchio-oculo-facial syndrome (BOFS), a rare dominant disorder characterized by distinctive craniofacial, ocular, ectodermal and renal anomalies. To elucidate the range of ocular phenotypes caused by mutations in TFAP2A, we took three approaches. First, we screened a cohort of 37 highly selected individuals with severe ocular anomalies plus variable defects associated with BOFS for mutations or deletions in TFAP2A. We identified one individual with a de novo TFAP2A four amino acid deletion, a second individual with two non-synonymous variations in an alternative splice isoform TFAP2A2, and a sibling-pair with a paternally inherited whole gene deletion with variable phenotypic expression. Second, we determined that TFAP2A is expressed in the lens, neural retina, nasal process, and epithelial lining of the oral cavity and palatal shelves of human and mouse embryos--sites consistent with the phenotype observed in patients with BOFS. Third, we used zebrafish to examine how partial abrogation of the fish ortholog of TFAP2A affects the penetrance and expressivity of ocular phenotypes due to mutations in genes encoding bmp4 or tcf7l1a. In both cases, we observed synthetic, enhanced ocular phenotypes including coloboma and anophthalmia when tfap2a is knocked down in embryos with bmp4 or tcf7l1a mutations. These results reveal that mutations in TFAP2A are associated with a wide range of eye phenotypes and that hypomorphic tfap2a mutations can increase the risk of developmental defects arising from mutations at other loci.

Published

2009

42. Separation of the PROX1 gene from upstream conserved elements in a complex inversion/translocation patient with hypoplastic left heart.

Author

Gill HK, Parsons SR, Spalluto C, Davies AF, Knorz VJ, Burlinson CE, Ng BL, Carter NP, Ogilvie CM, Wilson DI, and Roberts RG

Subjects

Base Sequence, Chromosome Breakage, Chromosomes, Human, Pair 3, Humans, Molecular Sequence Data, Sequence Homology, Nucleic Acid, Chromosome Inversion, Chromosomes, Human, Pair 1, Homeodomain Proteins genetics, Hypoplastic Left Heart Syndrome genetics, Translocation, Genetic, Tumor Suppressor Proteins genetics

Abstract

Hypoplastic left heart (HLH) occurs in at least 1 in 10 000 live births but may be more common in utero. Its causes are poorly understood but a number of affected cases are associated with chromosomal abnormalities. We set out to localize the breakpoints in a patient with sporadic HLH and a de novo translocation. Initial studies showed that the apparently simple 1q41;3q27.1 translocation was actually combined with a 4-Mb inversion, also de novo, of material within 1q41. We therefore localized all four breakpoints and found that no known transcription units were disrupted. However we present a case, based on functional considerations, synteny and position of highly conserved non-coding sequence elements, and the heterozygous Prox1(+/-) mouse phenotype (ventricular hypoplasia), for the involvement of dysregulation of the PROX1 gene in the aetiology of HLH in this case. Accordingly, we show that the spatial expression pattern of PROX1 in the developing human heart is consistent with a role in cardiac development. We suggest that dysregulation of PROX1 gene expression due to separation from its conserved upstream elements is likely to have caused the heart defects observed in this patient, and that PROX1 should be considered as a potential candidate gene for other cases of HLH. The relevance of another breakpoint separating the cardiac gene ESRRG from a conserved downstream element is also discussed.

Published

2009

43. Human Y chromosome base-substitution mutation rate measured by direct sequencing in a deep-rooting pedigree.

Author

Xue Y, Wang Q, Long Q, Ng BL, Swerdlow H, Burton J, Skuce C, Taylor R, Abdellah Z, Zhao Y, MacArthur DG, Quail MA, Carter NP, Yang H, and Tyler-Smith C

Subjects

Humans, Male, Pedigree, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Chromosomes, Human, Y, Evolution, Molecular, Point Mutation

Abstract

Understanding the key process of human mutation is important for many aspects of medical genetics and human evolution. In the past, estimates of mutation rates have generally been inferred from phenotypic observations or comparisons of homologous sequences among closely related species. Here, we apply new sequencing technology to measure directly one mutation rate, that of base substitutions on the human Y chromosome. The Y chromosomes of two individuals separated by 13 generations were flow sorted and sequenced by Illumina (Solexa) paired-end sequencing to an average depth of 11x or 20x, respectively. Candidate mutations were further examined by capillary sequencing in cell-line and blood DNA from the donors and additional family members. Twelve mutations were confirmed in approximately 10.15 Mb; eight of these had occurred in vitro and four in vivo. The latter could be placed in different positions on the pedigree and led to a mutation-rate measurement of 3.0 x 10(-8) mutations/nucleotide/generation (95% CI: 8.9 x 10(-9)-7.0 x 10(-8)), consistent with estimates of 2.3 x 10(-8)-6.3 x 10(-8) mutations/nucleotide/generation for the same Y-chromosomal region from published human-chimpanzee comparisons depending on the generation and split times assumed.

Published

2009

44. Prepublication data sharing.

Author

Birney E, Hudson TJ, Green ED, Gunter C, Eddy S, Rogers J, Harris JR, Ehrlich SD, Apweiler R, Austin CP, Berglund L, Bobrow M, Bountra C, Brookes AJ, Cambon-Thomsen A, Carter NP, Chisholm RL, Contreras JL, Cooke RM, Crosby WL, Dewar K, Durbin R, Dyke SO, Ecker JR, El Emam K, Feuk L, Gabriel SB, Gallacher J, Gelbart WM, Granell A, Guarner F, Hubbard T, Jackson SA, Jennings JL, Joly Y, Jones SM, Kaye J, Kennedy KL, Knoppers BM, Kyrpides NC, Lowrance WW, Luo J, MacKay JJ, Martín-Rivera L, McCombie WR, McPherson JD, Miller L, Miller W, Moerman D, Mooser V, Morton CC, Ostell JM, Ouellette BF, Parkhill J, Raina PS, Rawlings C, Scherer SE, Scherer SW, Schofield PN, Sensen CW, Stodden VC, Sussman MR, Tanaka T, Thornton J, Tsunoda T, Valle D, Vuorio EI, Walker NM, Wallace S, Weinstock G, Whitman WB, Worley KC, Wu C, Wu J, and Yu J

Subjects

Cooperative Behavior, Human Genome Project, Humans, Ontario, Research Personnel ethics, Research Personnel standards, Access to Information, Guidelines as Topic, Publishing ethics, Publishing standards, Research standards

Abstract

Rapid release of prepublication data has served the field of genomics well. Attendees at a workshop in Toronto recommend extending the practice to other biological data sets.

Published

2009

45. Genomic and genic deletions of the FOX gene cluster on 16q24.1 and inactivating mutations of FOXF1 cause alveolar capillary dysplasia and other malformations.

Author

Stankiewicz P, Sen P, Bhatt SS, Storer M, Xia Z, Bejjani BA, Ou Z, Wiszniewska J, Driscoll DJ, Maisenbacher MK, Bolivar J, Bauer M, Zackai EH, McDonald-McGinn D, Nowaczyk MM, Murray M, Hustead V, Mascotti K, Schultz R, Hallam L, McRae D, Nicholson AG, Newbury R, Durham-O'Donnell J, Knight G, Kini U, Shaikh TH, Martin V, Tyreman M, Simonic I, Willatt L, Paterson J, Mehta S, Rajan D, Fitzgerald T, Gribble S, Prigmore E, Patel A, Shaffer LG, Carter NP, Cheung SW, Langston C, and Shaw-Smith C

Subjects

Abnormalities, Multiple genetics, Capillaries abnormalities, Child, Preschool, Chromosome Mapping, Doxorubicin analogs & derivatives, Female, Humans, In Situ Hybridization, Fluorescence, Infant, Infant, Newborn, Male, Pulmonary Alveoli blood supply, Pulmonary Veins abnormalities, Bronchopulmonary Dysplasia genetics, Chromosomes, Human, Pair 16 genetics, Forkhead Transcription Factors genetics, Gene Deletion, Gene Silencing, Mutation genetics, Pulmonary Alveoli pathology

Abstract

Alveolar capillary dysplasia with misalignment of pulmonary veins (ACD/MPV) is a rare, neonatally lethal developmental disorder of the lung with defining histologic abnormalities typically associated with multiple congenital anomalies (MCA). Using array CGH analysis, we have identified six overlapping microdeletions encompassing the FOX transcription factor gene cluster in chromosome 16q24.1q24.2 in patients with ACD/MPV and MCA. Subsequently, we have identified four different heterozygous mutations (frameshift, nonsense, and no-stop) in the candidate FOXF1 gene in unrelated patients with sporadic ACD/MPV and MCA. Custom-designed, high-resolution microarray analysis of additional ACD/MPV samples revealed one microdeletion harboring FOXF1 and two distinct microdeletions upstream of FOXF1, implicating a position effect. DNA sequence analysis revealed that in six of nine deletions, both breakpoints occurred in the portions of Alu elements showing eight to 43 base pairs of perfect microhomology, suggesting replication error Microhomology-Mediated Break-Induced Replication (MMBIR)/Fork Stalling and Template Switching (FoSTeS) as a mechanism of their formation. In contrast to the association of point mutations in FOXF1 with bowel malrotation, microdeletions of FOXF1 were associated with hypoplastic left heart syndrome and gastrointestinal atresias, probably due to haploinsufficiency for the neighboring FOXC2 and FOXL1 genes. These differences reveal the phenotypic consequences of gene alterations in cis.

Published

2009

46. Sites of differential DNA methylation between placenta and peripheral blood: molecular markers for noninvasive prenatal diagnosis of aneuploidies.

Author

Papageorgiou EA, Fiegler H, Rakyan V, Beck S, Hulten M, Lamnissou K, Carter NP, and Patsalis PC

Subjects

Chromosomes, Human, Pair 13 genetics, Chromosomes, Human, Pair 18 genetics, Chromosomes, Human, Pair 21 genetics, Chromosomes, Human, X genetics, Chromosomes, Human, Y genetics, CpG Islands, DNA analysis, Epigenesis, Genetic, Female, Gene Expression Profiling, Humans, Immunoprecipitation, Male, Oligonucleotide Array Sequence Analysis, RNA, Messenger genetics, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction, Aneuploidy, Biomarkers blood, DNA genetics, DNA Methylation, Fetus metabolism, Placenta metabolism, Prenatal Diagnosis methods

Abstract

The use of epigenetic differences between maternal whole blood and fetal (placental) DNA is one of the main areas of interest for the development of noninvasive prenatal diagnosis of aneuploidies. However, the lack of detailed chromosome-wide identification of differentially methylated sites has limited the application of this approach. In this study, we describe an analysis of chromosome-wide methylation status using methylation DNA immunoprecipitation coupled with high-resolution tiling oligonucleotide array analysis specific for chromosomes 21, 18, 13, X, and Y using female whole blood and placental DNA. We identified more than 2000 regions of differential methylation between female whole blood and placental DNA on each of the chromosomes tested. A subset of the differentially methylated regions identified was validated by real-time quantitative polymerase chain reaction. Additionally, correlation of these regions with CpG islands, genes, and promoter regions was investigated. Between 56 to 83% of the regions were located within nongenic regions whereas only 1 to 11% of the regions overlapped with CpG islands; of these, up to 65% were found in promoter regions. In summary, we identified a large number of previously unreported fetal epigenetic molecular markers that have the potential to be developed into targets for noninvasive prenatal diagnosis of trisomy 21 and other common aneuploidies. In addition, we demonstrated the effectiveness of the methylation DNA immunoprecipitation approach in the enrichment of hypermethylated fetal DNA.

Published

2009

47. DECIPHER: Database of Chromosomal Imbalance and Phenotype in Humans Using Ensembl Resources.

Author

Firth HV, Richards SM, Bevan AP, Clayton S, Corpas M, Rajan D, Van Vooren S, Moreau Y, Pettett RM, and Carter NP

Subjects

Adult, Child, Child, Preschool, Comparative Genomic Hybridization, Computational Biology, Female, Gene Dosage, Genes, Dominant, Genome, Human, Humans, Internet, Male, Phenotype, Syndrome, Chromosome Aberrations, Databases, Genetic

Abstract

Many patients suffering from developmental disorders harbor submicroscopic deletions or duplications that, by affecting the copy number of dosage-sensitive genes or disrupting normal gene expression, lead to disease. However, many aberrations are novel or extremely rare, making clinical interpretation problematic and genotype-phenotype correlations uncertain. Identification of patients sharing a genomic rearrangement and having phenotypic features in common leads to greater certainty in the pathogenic nature of the rearrangement and enables new syndromes to be defined. To facilitate the analysis of these rare events, we have developed an interactive web-based database called DECIPHER (Database of Chromosomal Imbalance and Phenotype in Humans Using Ensembl Resources) which incorporates a suite of tools designed to aid the interpretation of submicroscopic chromosomal imbalance, inversions, and translocations. DECIPHER catalogs common copy-number changes in normal populations and thus, by exclusion, enables changes that are novel and potentially pathogenic to be identified. DECIPHER enhances genetic counseling by retrieving relevant information from a variety of bioinformatics resources. Known and predicted genes within an aberration are listed in the DECIPHER patient report, and genes of recognized clinical importance are highlighted and prioritized. DECIPHER enables clinical scientists worldwide to maintain records of phenotype and chromosome rearrangement for their patients and, with informed consent, share this information with the wider clinical research community through display in the genome browser Ensembl. By sharing cases worldwide, clusters of rare cases having phenotype and structural rearrangement in common can be identified, leading to the delineation of new syndromes and furthering understanding of gene function.

Published

2009

48. Comparative genomic hybridization: DNA labeling, hybridization and detection.

Author

Redon R, Fitzgerald T, and Carter NP

Subjects

Automation, DNA Probes, Female, Genome, Human genetics, Humans, Male, Quality Control, Reference Standards, Comparative Genomic Hybridization methods, DNA metabolism, Staining and Labeling

Abstract

Array-CGH involves the comparison of a test to a reference genome using a microarray composed of target sequences with known chromosomal coordinates. The test and reference DNA samples are used as templates to generate two probe DNAs labeled with distinct fluorescent dyes. The two probe DNAs are co-hybridized on a microarray in the presence of Cot-1 DNA to suppress unspecific hybridization of repeat sequences. After slide washes and drying, microarray images are acquired on a laser scanner and fluorescent intensities from every target sequence spot on the array are extracted using dedicated computer programs. Intensity ratios are calculated and normalized to enable data interpretation. Although the protocols explained in this chapter correspond primarily to the use of large-insert clone microarrays in either manual or automated fashion, necessary adaptations for hybridization on microarrays comprising shorter target DNA sequences are also briefly described.

Published

2009

49. Comparative genomic hybridization: DNA preparation for microarray fabrication.

Author

Redon R, Rigler D, and Carter NP

Subjects

DNA Primers metabolism, Humans, Oligonucleotides genetics, Polymerase Chain Reaction, Comparative Genomic Hybridization methods, DNA isolation & purification, Oligonucleotide Array Sequence Analysis methods

Abstract

The spatial resolution of microarray-based comparative genomic hybridization (array-CGH) is dependent on the length and density of target DNA sequences covering the chromosomal region of interest. Here we describe the methods developed at the Wellcome Trust Sanger Institute (Cambridge, UK) to construct microarrays comprising large-insert clones available through genome sequencing projects. These methods are applicable to Bacterial and Phage Artificial Chromosomes (BAC and PAC) as well as fosmid and cosmid clones. The protocols are scalable for the construction of microarrays composed of several hundreds up to several ten thousands clones.

Published

2009

50. Comparative genomic hybridization: microarray design and data interpretation.

Author

Redon R and Carter NP

Subjects

Data Interpretation, Statistical, Gene Dosage, Humans, Comparative Genomic Hybridization methods, Oligonucleotide Array Sequence Analysis methods

Abstract

Microarray-based Comparative Genomic Hybridization (array-CGH) has been applied for a decade to screen for submicroscopic DNA gains and losses in tumor and constitutional DNA samples. This method has become increasingly flexible with the integration of new biological resources generated by genome sequencing projects. In this chapter, we describe alternative strategies for whole genome screening and high resolution breakpoint mapping of copy number changes by array-CGH, as well as tools available for accurate analysis of array-CGH experiments. Although most methods listed here have been designed for microarrays comprising large-insert clones, they can be adapted easily to other types of microarray platforms, such as those constructed from printed or synthesized oligonucleotides.

Published

2009