Your search keyword '"Rouette A"' showing total 3 results

1. A robust benchmark for detection of germline large deletions and insertions

Author

Zook, Justin M, Hansen, Nancy F, Olson, Nathan D, Chapman, Lesley, Mullikin, James C, Xiao, Chunlin, Sherry, Stephen, Koren, Sergey, Phillippy, Adam M, Boutros, Paul C, Sahraeian, Sayed Mohammad E, Huang, Vincent, Rouette, Alexandre, Alexander, Noah, Mason, Christopher E, Hajirasouliha, Iman, Ricketts, Camir, Lee, Joyce, Tearle, Rick, Fiddes, Ian T, Barrio, Alvaro Martinez, Wala, Jeremiah, Carroll, Andrew, Ghaffari, Noushin, Rodriguez, Oscar L, Bashir, Ali, Jackman, Shaun, Farrell, John J, Wenger, Aaron M, Alkan, Can, Soylev, Arda, Schatz, Michael C, Garg, Shilpa, Church, George, Marschall, Tobias, Chen, Ken, Fan, Xian, English, Adam C, Rosenfeld, Jeffrey A, Zhou, Weichen, Mills, Ryan E, Sage, Jay M, Davis, Jennifer R, Kaiser, Michael D, Oliver, John S, Catalano, Anthony P, Chaisson, Mark JP, Spies, Noah, Sedlazeck, Fritz J, and Salit, Marc

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Genetics, Human Genome, 1.1 Normal biological development and functioning, Underpinning research, Generic health relevance, Diploidy, Genomic Structural Variation, Germ-Line Mutation, Humans, INDEL Mutation, Molecular Sequence Annotation, Sequence Analysis, DNA

Abstract

New technologies and analysis methods are enabling genomic structural variants (SVs) to be detected with ever-increasing accuracy, resolution and comprehensiveness. To help translate these methods to routine research and clinical practice, we developed a sequence-resolved benchmark set for identification of both false-negative and false-positive germline large insertions and deletions. To create this benchmark for a broadly consented son in a Personal Genome Project trio with broadly available cells and DNA, the Genome in a Bottle Consortium integrated 19 sequence-resolved variant calling methods from diverse technologies. The final benchmark set contains 12,745 isolated, sequence-resolved insertion (7,281) and deletion (5,464) calls ≥50 base pairs (bp). The Tier 1 benchmark regions, for which any extra calls are putative false positives, cover 2.51 Gbp and 5,262 insertions and 4,095 deletions supported by ≥1 diploid assembly. We demonstrate that the benchmark set reliably identifies false negatives and false positives in high-quality SV callsets from short-, linked- and long-read sequencing and optical mapping.

Published

2020

2. Author Correction: A robust benchmark for detection of germline large deletions and insertions

Author

Zook, Justin M, Hansen, Nancy F, Olson, Nathan D, Chapman, Lesley, Mullikin, James C, Xiao, Chunlin, Sherry, Stephen, Koren, Sergey, Phillippy, Adam M, Boutros, Paul C, Sahraeian, Sayed Mohammad E, Huang, Vincent, Rouette, Alexandre, Alexander, Noah, Mason, Christopher E, Hajirasouliha, Iman, Ricketts, Camir, Lee, Joyce, Tearle, Rick, Fiddes, Ian T, Barrio, Alvaro Martinez, Wala, Jeremiah, Carroll, Andrew, Ghaffari, Noushin, Rodriguez, Oscar L, Bashir, Ali, Jackman, Shaun, Farrell, John J, Wenger, Aaron M, Alkan, Can, Soylev, Arda, Schatz, Michael C, Garg, Shilpa, Church, George, Marschall, Tobias, Chen, Ken, Fan, Xian, English, Adam C, Rosenfeld, Jeffrey A, Zhou, Weichen, Mills, Ryan E, Sage, Jay M, Davis, Jennifer R, Kaiser, Michael D, Oliver, John S, Catalano, Anthony P, Chaisson, Mark JP, Spies, Noah, Sedlazeck, Fritz J, and Salit, Marc

Subjects

Control Engineering, Mechatronics and Robotics, Engineering

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

3. A robust benchmark for detection of germline large deletions and insertions

Author

Joyce V. Lee, Paul C. Boutros, Marc L. Salit, Anthony P. Catalano, Nancy F. Hansen, Adam C. English, Rick Tearle, George M. Church, Christopher E. Mason, Oscar L. Rodriguez, Nathan D. Olson, Noushin Ghaffari, Weichen Zhou, Sayed Mohammad Ebrahim Sahraeian, Shaun D. Jackman, Aaron M. Wenger, Shilpa Garg, Lesley M. Chapman, Fritz J. Sedlazeck, Sergey Koren, Michael D. Kaiser, Jeremiah Wala, Jay M. Sage, Jennifer R. Davis, Alexandre Rouette, Jeffrey A. Rosenfeld, Iman Hajirasouliha, Alvaro Martinez Barrio, Chunlin Xiao, Can Alkan, Noah Alexander, Ian T. Fiddes, Tobias Marschall, Michael C. Schatz, James C. Mullikin, Justin M. Zook, John S. Oliver, Stephen T. Sherry, Noah Spies, Ali Bashir, Mark Chaisson, Ryan E. Mills, Vincent Huang, Xian Fan, Adam M. Phillippy, Ken Chen, Andrew Carroll, Arda Soylev, John J. Farrell, Camir Ricketts, and Alkan, Can

Subjects

Sequence analysis, Computer science, Genomic Structural Variation, Biomedical Engineering, Bioengineering, Genomics, Computational biology, Applied Microbiology and Biotechnology, Genome, Article, Set (abstract data type), 03 medical and health sciences, 0302 clinical medicine, INDEL Mutation, False positive paradox, Humans, Germ-Line Mutation, 030304 developmental biology, 0303 health sciences, Molecular Sequence Annotation, Sequence Analysis, DNA, Diploidy, Personal Genome Project, Benchmark (computing), Molecular Medicine, 030217 neurology & neurosurgery, Biotechnology

Abstract

New technologies and analysis methods are enabling genomic structural variants (SVs) to be detected with ever-increasing accuracy, resolution, and comprehensiveness. To help translate these methods to routine research and clinical practice, we developed the first sequence-resolved benchmark set for identification of both false negative and false positive germline large insertions and deletions. To create this benchmark for a broadly consented son in a Personal Genome Project trio with broadly available cells and DNA, the Genome in a Bottle (GIAB) Consortium integrated 19 sequence-resolved variant calling methods from diverse technologies. The final benchmark set contains 12745 isolated, sequence-resolved insertion (7281) and deletion (5464) calls ≥50 base pairs (bp). The Tier 1 benchmark regions, for which any extra calls are putative false positives, cover 2.51 Gbp and 5262 insertions and 4095 deletions supported by ≥1 diploid assembly. We demonstrate the benchmark set reliably identifies false negatives and false positives in high-quality SV callsets from short-, linked-, and long-read sequencing and optical mapping.

Published

2019