Your search keyword '"Vives, Laura"' showing total 59 results

51. Discovery and genotyping of structural variation from long-read haploid genome sequence data

Author

Huddleston, John, Chaisson, Mark J.P., Steinberg, Karyn Meltz, Warren, Wes, Hoekzema, Kendra, Gordon, David, Graves-Lindsay, Tina A., Munson, Katherine M., Kronenberg, Zev N., Vives, Laura, Peluso, Paul, Boitano, Matthew, Chin, Chen-Shin, Korlach, Jonas, Wilson, Richard K., and Eichler, Evan E.

Abstract

In an effort to more fully understand the full spectrum of human genetic variation, we generated deep single-molecule, real-time (SMRT) sequencing data from two haploid human genomes. By using an assembly-based approach (SMRT-SV), we systematically assessed each genome independently for structural variants (SVs) and indels resolving the sequence structure of 461,553 genetic variants from 2 bp to 28 kbp in length. We find that >89% of these variants have been missed as part of analysis of the 1000 Genomes Project even after adjusting for more common variants (MAF > 1%). We estimate that this theoretical human diploid differs by as much as ∼16 Mbp with respect to the human reference, with long-read sequencing data providing a fivefold increase in sensitivity for genetic variants ranging in size from 7 bp to 1 kbp compared with short-read sequence data. Although a large fraction of genetic variants were not detected by short-read approaches, once the alternate allele is sequence-resolved, we show that 61% of SVs can be genotyped in short-read sequence data sets with high accuracy. Uncoupling discovery from genotyping thus allows for the majority of this missed common variation to be genotyped in the human population. Interestingly, when we repeat SV detection on a pseudodiploid genome constructed in silico by merging the two haploids, we find that ∼59% of the heterozygous SVs are no longer detected by SMRT-SV. These results indicate that haploid resolution of long-read sequencing data will significantly increase sensitivity of SV detection.

Published

2017

52. Detection of structural variants and indels within exome data

Author

Karakoc, Emre, primary, Alkan, Can, additional, O'Roak, Brian J, additional, Dennis, Megan Y, additional, Vives, Laura, additional, Mark, Kenneth, additional, Rieder, Mark J, additional, Nickerson, Debbie A, additional, and Eichler, Evan E, additional

Published

2011

53. Relative Burden of Large CNVs on a Range of Neurodevelopmental Phenotypes

Author

Girirajan, Santhosh, primary, Brkanac, Zoran, additional, Coe, Bradley P., additional, Baker, Carl, additional, Vives, Laura, additional, Vu, Tiffany H., additional, Shafer, Neil, additional, Bernier, Raphael, additional, Ferrero, Giovanni B., additional, Silengo, Margherita, additional, Warren, Stephen T., additional, Moreno, Carlos S., additional, Fichera, Marco, additional, Romano, Corrado, additional, Raskind, Wendy H., additional, and Eichler, Evan E., additional

Published

2011

54. Exome sequencing in sporadic autism spectrum disorders identifies severe de novo mutations

Author

O'Roak, Brian J, primary, Deriziotis, Pelagia, additional, Lee, Choli, additional, Vives, Laura, additional, Schwartz, Jerrod J, additional, Girirajan, Santhosh, additional, Karakoc, Emre, additional, MacKenzie, Alexandra P, additional, Ng, Sarah B, additional, Baker, Carl, additional, Rieder, Mark J, additional, Nickerson, Deborah A, additional, Bernier, Raphael, additional, Fisher, Simon E, additional, Shendure, Jay, additional, and Eichler, Evan E, additional

Published

2011

55. A large and complex structural polymorphism at 16p12.1 underlies microdeletion disease risk

Author

Antonacci, Francesca, primary, Kidd, Jeffrey M, additional, Marques-Bonet, Tomas, additional, Teague, Brian, additional, Ventura, Mario, additional, Girirajan, Santhosh, additional, Alkan, Can, additional, Campbell, Catarina D, additional, Vives, Laura, additional, Malig, Maika, additional, Rosenfeld, Jill A, additional, Ballif, Blake C, additional, Shaffer, Lisa G, additional, Graves, Tina A, additional, Wilson, Richard K, additional, Schwartz, David C, additional, and Eichler, Evan E, additional

Published

2010

56. Genome-wide tracking of unmethylated DNA Alu repeats in normal and cancer cells

Author

Rodriguez, Jairo, primary, Vives, Laura, additional, Jordà, Mireia, additional, Morales, Cristina, additional, Muñoz, Mar, additional, Vendrell, Elisenda, additional, and Peinado, Miguel A., additional

Published

2007

57. Detection of structural variants and indels within exome data.

Author

Karakoc, Emre, Alkan, Can, O'Roak, Brian J, Dennis, Megan Y, Vives, Laura, Mark, Kenneth, Rieder, Mark J, Nickerson, Debbie A, and Eichler, Evan E

Subjects

GENOMICS, NUCLEOTIDE sequence, ALGORITHMS, GENETIC polymorphisms, GENE mapping, GENETIC techniques

Abstract

We report an algorithm to detect structural variation and indels from 1 base pair (bp) to 1 Mbp within exome sequence data sets. Splitread uses one end-anchored placements to cluster the mappings of subsequences of unanchored ends to identify the size, content and location of variants with high specificity and sensitivity. The algorithm discovers indels, structural variants, de novo events and copy number-polymorphic processed pseudogenes missed by other methods. [ABSTRACT FROM AUTHOR]

Published

2012

58. Exome sequencing in sporadic autism spectrum disorders identifies severe de novo mutations.

Author

O'Roak, Brian J, Deriziotis, Pelagia, Lee, Choli, Vives, Laura, Schwartz, Jerrod J, Girirajan, Santhosh, Karakoc, Emre, MacKenzie, Alexandra P, Ng, Sarah B, Baker, Carl, Rieder, Mark J, Nickerson, Deborah A, Bernier, Raphael, Fisher, Simon E, Shendure, Jay, and Eichler, Evan E

Subjects

AUTISM spectrum disorders, EXONS (Genetics)

Abstract

A correction to the article "Exome sequencing in sporadic autism spectrum disorders identifies severe de novo mutations," by Choli Lee and colleagues that was published in the 2011 issue is presented.

Published

2012

59. Retrotransposons Are the Major Contributors to the Expansion of the Drosophila ananassae Muller F Element.

Author

Leung W, Shaffer CD, Chen EJ, Quisenberry TJ, Ko K, Braverman JM, Giarla TC, Mortimer NT, Reed LK, Smith ST, Robic S, McCartha SR, Perry DR, Prescod LM, Sheppard ZA, Saville KJ, McClish A, Morlock EA, Sochor VR, Stanton B, Veysey-White IC, Revie D, Jimenez LA, Palomino JJ, Patao MD, Patao SM, Himelblau ET, Campbell JD, Hertz AL, McEvilly MF, Wagner AR, Youngblom J, Bedi B, Bettincourt J, Duso E, Her M, Hilton W, House S, Karimi M, Kumimoto K, Lee R, Lopez D, Odisho G, Prasad R, Robbins HL, Sandhu T, Selfridge T, Tsukashima K, Yosif H, Kokan NP, Britt L, Zoellner A, Spana EP, Chlebina BT, Chong I, Friedman H, Mammo DA, Ng CL, Nikam VS, Schwartz NU, Xu TQ, Burg MG, Batten SM, Corbeill LM, Enoch E, Ensign JJ, Franks ME, Haiker B, Ingles JA, Kirkland LD, Lorenz-Guertin JM, Matthews J, Mittig CM, Monsma N, Olson KJ, Perez-Aragon G, Ramic A, Ramirez JR, Scheiber C, Schneider PA, Schultz DE, Simon M, Spencer E, Wernette AC, Wykle ME, Zavala-Arellano E, McDonald MJ, Ostby K, Wendland P, DiAngelo JR, Ceasrine AM, Cox AH, Docherty JEB, Gingras RM, Grieb SM, Pavia MJ, Personius CL, Polak GL, Beach DL, Cerritos HL, Horansky EA, Sharif KA, Moran R, Parrish S, Bickford K, Bland J, Broussard J, Campbell K, Deibel KE, Forka R, Lemke MC, Nelson MB, O'Keeffe C, Ramey SM, Schmidt L, Villegas P, Jones CJ, Christ SL, Mamari S, Rinaldi AS, Stity G, Hark AT, Scheuerman M, Silver Key SC, McRae BD, Haberman AS, Asinof S, Carrington H, Drumm K, Embry T, McGuire R, Miller-Foreman D, Rosen S, Safa N, Schultz D, Segal M, Shevin Y, Svoronos P, Vuong T, Skuse G, Paetkau DW, Bridgman RK, Brown CM, Carroll AR, Gifford FM, Gillespie JB, Herman SE, Holtcamp KL, Host MA, Hussey G, Kramer DM, Lawrence JQ, Martin MM, Niemiec EN, O'Reilly AP, Pahl OA, Quintana G, Rettie EAS, Richardson TL, Rodriguez AE, Rodriguez MO, Schiraldi L, Smith JJ, Sugrue KF, Suriano LJ, Takach KE, Vasquez AM, Velez X, Villafuerte EJ, Vives LT, Zellmer VR, Hauke J, Hauser CR, Barker K, Cannon L, Parsamian P, Parsons S, Wichman Z, Bazinet CW, Johnson DE, Bangura A, Black JA, Chevee V, Einsteen SA, Hilton SK, Kollmer M, Nadendla R, Stamm J, Fafara-Thompson AE, Gygi AM, Ogawa EE, Van Camp M, Kocsisova Z, Leatherman JL, Modahl CM, Rubin MR, Apiz-Saab SS, Arias-Mejias SM, Carrion-Ortiz CF, Claudio-Vazquez PN, Espada-Green DM, Feliciano-Camacho M, Gonzalez-Bonilla KM, Taboas-Arroyo M, Vargas-Franco D, Montañez-Gonzalez R, Perez-Otero J, Rivera-Burgos M, Rivera-Rosario FJ, Eisler HL, Alexander J, Begley SK, Gabbard D, Allen RJ, Aung WY, Barshop WD, Boozalis A, Chu VP, Davis JS, Duggal RN, Franklin R, Gavinski K, Gebreyesus H, Gong HZ, Greenstein RA, Guo AD, Hanson C, Homa KE, Hsu SC, Huang Y, Huo L, Jacobs S, Jia S, Jung KL, Wai-Chee Kong S, Kroll MR, Lee BM, Lee PF, Levine KM, Li AS, Liu C, Liu MM, Lousararian AP, Lowery PB, Mallya AP, Marcus JE, Ng PC, Nguyen HP, Patel R, Precht H, Rastogi S, Sarezky JM, Schefkind A, Schultz MB, Shen D, Skorupa T, Spies NC, Stancu G, Vivian Tsang HM, Turski AL, Venkat R, Waldman LE, Wang K, Wang T, Wei JW, Wu DY, Xiong DD, Yu J, Zhou K, McNeil GP, Fernandez RW, Menzies PG, Gu T, Buhler J, Mardis ER, and Elgin SCR

Subjects

Animals, Base Composition genetics, Base Sequence, Codon genetics, Female, Gene Expression Profiling, Genes, Insect, Histones metabolism, Protein Processing, Post-Translational genetics, Wolbachia genetics, Chromosomes genetics, Drosophila genetics, Retroelements genetics

Abstract

The discordance between genome size and the complexity of eukaryotes can partly be attributed to differences in repeat density. The Muller F element (∼5.2 Mb) is the smallest chromosome in Drosophila melanogaster , but it is substantially larger (>18.7 Mb) in D. ananassae To identify the major contributors to the expansion of the F element and to assess their impact, we improved the genome sequence and annotated the genes in a 1.4-Mb region of the D. ananassae F element, and a 1.7-Mb region from the D element for comparison. We find that transposons (particularly LTR and LINE retrotransposons) are major contributors to this expansion (78.6%), while Wolbachia sequences integrated into the D. ananassae genome are minor contributors (0.02%). Both D. melanogaster and D. ananassae F-element genes exhibit distinct characteristics compared to D-element genes ( e.g. , larger coding spans, larger introns, more coding exons, and lower codon bias), but these differences are exaggerated in D. ananassae Compared to D. melanogaster , the codon bias observed in D. ananassae F-element genes can primarily be attributed to mutational biases instead of selection. The 5' ends of F-element genes in both species are enriched in dimethylation of lysine 4 on histone 3 (H3K4me2), while the coding spans are enriched in H3K9me2. Despite differences in repeat density and gene characteristics, D. ananassae F-element genes show a similar range of expression levels compared to genes in euchromatic domains. This study improves our understanding of how transposons can affect genome size and how genes can function within highly repetitive domains., (Copyright © 2017 Leung et al.)

Published

2017