Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges

Binghuang Cai; Biao Li; Nikki Kiga; Janita Thusberg; Timothy Bergquist; Yun Ching Chen; Noushin Niknafs; Hannah Carter; Collin Tokheim; Violeta Beleva-Guthrie; Christopher Douville; Rohit Bhattacharya; Hui Ting Grace Yeo; Jean Fan; Sohini Sengupta; Dewey Kim; Melissa Cline; Tychele Turner; Mark Diekhans; Jan Zaucha; Lipika R. Pal; Chen Cao; Chen Hsin Yu; Yizhou Yin; Marco Carraro; Manuel Giollo; Carlo Ferrari; Emanuela Leonardi; Silvio C.E. Tosatto; Jason Bobe; Madeleine Ball; Roger A. Hoskins; Susanna Repo; George Church; Steven E. Brenner; John Moult; Julian Gough; Mario Stanke; Rachel Karchin; Sean D. Mooney

doi:10.1002/humu.23265

Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges

Binghuang Cai, Biao Li, Nikki Kiga, Janita Thusberg, Timothy Bergquist, Yun Ching Chen, Noushin Niknafs, Hannah Carter, Collin Tokheim, Violeta Beleva-Guthrie, Christopher Douville, Rohit Bhattacharya, Hui Ting Grace Yeo, Jean Fan, Sohini Sengupta, Dewey Kim, Melissa Cline, Tychele Turner, Mark Diekhans, Jan ZauchaLipika R. Pal, Chen Cao, Chen Hsin Yu, Yizhou Yin, Marco Carraro, Manuel Giollo, Carlo Ferrari, Emanuela Leonardi, Silvio C.E. Tosatto, Jason Bobe, Madeleine Ball, Roger A. Hoskins, Susanna Repo, George Church, Steven E. Brenner, John Moult, Julian Gough, Mario Stanke, Rachel Karchin, Sean D. Mooney

Whiting School of Engineering

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

The advent of next-generation sequencing has dramatically decreased the cost for whole-genome sequencing and increased the viability for its application in research and clinical care. The Personal Genome Project (PGP) provides unrestricted access to genomes of individuals and their associated phenotypes. This resource enabled the Critical Assessment of Genome Interpretation (CAGI) to create a community challenge to assess the bioinformatics community's ability to predict traits from whole genomes. In the CAGI PGP challenge, researchers were asked to predict whether an individual had a particular trait or profile based on their whole genome. Several approaches were used to assess submissions, including ROC AUC (area under receiver operating characteristic curve), probability rankings, the number of correct predictions, and statistical significance simulations. Overall, we found that prediction of individual traits is difficult, relying on a strong knowledge of trait frequency within the general population, whereas matching genomes to trait profiles relies heavily upon a small number of common traits including ancestry, blood type, and eye color. When a rare genetic disorder is present, profiles can be matched when one or more pathogenic variants are identified. Prediction accuracy has improved substantially over the last 6 years due to improved methodology and a better understanding of features.

Original language	English (US)
Pages (from-to)	1266-1276
Number of pages	11
Journal	Human mutation
Volume	38
Issue number	9
DOIs	https://doi.org/10.1002/humu.23265
State	Published - Sep 2017

Keywords

biomedical informatics
community challenge
critical assessment
genome
genome interpretation
open consent
personal genome project (PGP)
phenotype

ASJC Scopus subject areas

Genetics
Genetics(clinical)

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10.1002/humu.23265

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Cai, B., Li, B., Kiga, N., Thusberg, J., Bergquist, T., Chen, Y. C., Niknafs, N., Carter, H., Tokheim, C., Beleva-Guthrie, V., Douville, C., Bhattacharya, R., Yeo, H. T. G., Fan, J., Sengupta, S., Kim, D., Cline, M., Turner, T., Diekhans, M., ... Mooney, S. D. (2017). Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges. Human mutation, 38(9), 1266-1276. https://doi.org/10.1002/humu.23265

Cai, B, Li, B, Kiga, N, Thusberg, J, Bergquist, T, Chen, YC, Niknafs, N, Carter, H, Tokheim, C, Beleva-Guthrie, V, Douville, C, Bhattacharya, R, Yeo, HTG, Fan, J, Sengupta, S, Kim, D, Cline, M, Turner, T, Diekhans, M, Zaucha, J, Pal, LR, Cao, C, Yu, CH, Yin, Y, Carraro, M, Giollo, M, Ferrari, C, Leonardi, E, Tosatto, SCE, Bobe, J, Ball, M, Hoskins, RA, Repo, S, Church, G, Brenner, SE, Moult, J, Gough, J, Stanke, M, Karchin, R & Mooney, SD 2017, 'Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges', Human mutation, vol. 38, no. 9, pp. 1266-1276. https://doi.org/10.1002/humu.23265

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title = "Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges",

abstract = "The advent of next-generation sequencing has dramatically decreased the cost for whole-genome sequencing and increased the viability for its application in research and clinical care. The Personal Genome Project (PGP) provides unrestricted access to genomes of individuals and their associated phenotypes. This resource enabled the Critical Assessment of Genome Interpretation (CAGI) to create a community challenge to assess the bioinformatics community's ability to predict traits from whole genomes. In the CAGI PGP challenge, researchers were asked to predict whether an individual had a particular trait or profile based on their whole genome. Several approaches were used to assess submissions, including ROC AUC (area under receiver operating characteristic curve), probability rankings, the number of correct predictions, and statistical significance simulations. Overall, we found that prediction of individual traits is difficult, relying on a strong knowledge of trait frequency within the general population, whereas matching genomes to trait profiles relies heavily upon a small number of common traits including ancestry, blood type, and eye color. When a rare genetic disorder is present, profiles can be matched when one or more pathogenic variants are identified. Prediction accuracy has improved substantially over the last 6 years due to improved methodology and a better understanding of features.",

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author = "Binghuang Cai and Biao Li and Nikki Kiga and Janita Thusberg and Timothy Bergquist and Chen, {Yun Ching} and Noushin Niknafs and Hannah Carter and Collin Tokheim and Violeta Beleva-Guthrie and Christopher Douville and Rohit Bhattacharya and Yeo, {Hui Ting Grace} and Jean Fan and Sohini Sengupta and Dewey Kim and Melissa Cline and Tychele Turner and Mark Diekhans and Jan Zaucha and Pal, {Lipika R.} and Chen Cao and Yu, {Chen Hsin} and Yizhou Yin and Marco Carraro and Manuel Giollo and Carlo Ferrari and Emanuela Leonardi and Tosatto, {Silvio C.E.} and Jason Bobe and Madeleine Ball and Hoskins, {Roger A.} and Susanna Repo and George Church and Brenner, {Steven E.} and John Moult and Julian Gough and Mario Stanke and Rachel Karchin and Mooney, {Sean D.}",

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AU - Cai, Binghuang

AU - Li, Biao

AU - Kiga, Nikki

AU - Thusberg, Janita

AU - Bergquist, Timothy

AU - Chen, Yun Ching

AU - Niknafs, Noushin

AU - Carter, Hannah

AU - Tokheim, Collin

AU - Beleva-Guthrie, Violeta

AU - Douville, Christopher

AU - Bhattacharya, Rohit

AU - Yeo, Hui Ting Grace

AU - Fan, Jean

AU - Sengupta, Sohini

AU - Kim, Dewey

AU - Cline, Melissa

AU - Turner, Tychele

AU - Diekhans, Mark

AU - Zaucha, Jan

AU - Pal, Lipika R.

AU - Cao, Chen

AU - Yu, Chen Hsin

AU - Yin, Yizhou

AU - Carraro, Marco

AU - Giollo, Manuel

AU - Ferrari, Carlo

AU - Leonardi, Emanuela

AU - Tosatto, Silvio C.E.

AU - Bobe, Jason

AU - Ball, Madeleine

AU - Hoskins, Roger A.

AU - Repo, Susanna

AU - Church, George

AU - Brenner, Steven E.

AU - Moult, John

AU - Gough, Julian

AU - Stanke, Mario

AU - Karchin, Rachel

AU - Mooney, Sean D.

PY - 2017/9

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N2 - The advent of next-generation sequencing has dramatically decreased the cost for whole-genome sequencing and increased the viability for its application in research and clinical care. The Personal Genome Project (PGP) provides unrestricted access to genomes of individuals and their associated phenotypes. This resource enabled the Critical Assessment of Genome Interpretation (CAGI) to create a community challenge to assess the bioinformatics community's ability to predict traits from whole genomes. In the CAGI PGP challenge, researchers were asked to predict whether an individual had a particular trait or profile based on their whole genome. Several approaches were used to assess submissions, including ROC AUC (area under receiver operating characteristic curve), probability rankings, the number of correct predictions, and statistical significance simulations. Overall, we found that prediction of individual traits is difficult, relying on a strong knowledge of trait frequency within the general population, whereas matching genomes to trait profiles relies heavily upon a small number of common traits including ancestry, blood type, and eye color. When a rare genetic disorder is present, profiles can be matched when one or more pathogenic variants are identified. Prediction accuracy has improved substantially over the last 6 years due to improved methodology and a better understanding of features.

AB - The advent of next-generation sequencing has dramatically decreased the cost for whole-genome sequencing and increased the viability for its application in research and clinical care. The Personal Genome Project (PGP) provides unrestricted access to genomes of individuals and their associated phenotypes. This resource enabled the Critical Assessment of Genome Interpretation (CAGI) to create a community challenge to assess the bioinformatics community's ability to predict traits from whole genomes. In the CAGI PGP challenge, researchers were asked to predict whether an individual had a particular trait or profile based on their whole genome. Several approaches were used to assess submissions, including ROC AUC (area under receiver operating characteristic curve), probability rankings, the number of correct predictions, and statistical significance simulations. Overall, we found that prediction of individual traits is difficult, relying on a strong knowledge of trait frequency within the general population, whereas matching genomes to trait profiles relies heavily upon a small number of common traits including ancestry, blood type, and eye color. When a rare genetic disorder is present, profiles can be matched when one or more pathogenic variants are identified. Prediction accuracy has improved substantially over the last 6 years due to improved methodology and a better understanding of features.

KW - biomedical informatics

KW - community challenge

KW - critical assessment

KW - genome

KW - genome interpretation

KW - open consent

KW - personal genome project (PGP)

KW - phenotype

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Matching phenotypes to whole genomes: Lessons learned from four iterations of the personal genome project community challenges

Abstract

Keywords

ASJC Scopus subject areas

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