Your search keyword '"Nicole M. Ferraro"' showing total 10 results

1. Identification of rare and common regulatory variants in pluripotent cells using population-scale transcriptomics

Author

Nicole M. Ferraro, Erin N. Smith, Ivan Carcamo-Orive, Chunli Zhao, Joshua W. Knowles, Diane B. Zastrow, Bogdan Mirauta, Dara Vakili, Oliver Stegle, Danilo Horta, David Jakubosky, Laure Fresard, Matteo D’Antonio, Kelly A. Frazer, Daniel D Seaton, Stephen B. Montgomery, Craig Smail, Devon Bonner, Xin Li, Helena Kilpinen, Marc Jan Bonder, Matthew T. Wheeler, Na Cai, and Michael J. Gloudemans

Subjects

Somatic cell, HipSci Consortium, Arabidopsis, Gene Expression, Regenerative Medicine, Medical and Health Sciences, Transcriptome, 0302 clinical medicine, 2.1 Biological and endogenous factors, Stem Cell Research - Induced Pluripotent Stem Cell - Non-Human, Aetiology, Induced pluripotent stem cell, 0303 health sciences, education.field_of_study, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Stem Cells, Single Nucleotide, Biological Sciences, DNA methylation, iPSCORE consortium, Sequence Analysis, Cell type, Cerebellar Ataxia, 1.1 Normal biological development and functioning, Population, Quantitative Trait Loci, Induced Pluripotent Stem Cells, Computational biology, PhLiPS consortium, Quantitative trait locus, Biology, Article, Cell Line, 03 medical and health sciences, Rare Diseases, Underpinning research, Genetics, Humans, Polymorphism, Stem Cell Research - Embryonic - Human, education, Gene, Bardet-Biedl Syndrome, 030304 developmental biology, Nucleic Acid, Whole Genome Sequencing, Stem Cell Research - Induced Pluripotent Stem Cell, Human Genome, Proteins, Genetic Variation, Undiagnosed Diseases Network, DNA Methylation, Stem Cell Research, RNA, Calcium Channels, Generic health relevance, Regulatory Sequences, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Induced pluripotent stem cells (iPSCs) are an established cellular system to study the impact of genetic variants in derived cell types and developmental contexts. However, in their pluripotent state, the disease impact of genetic variants is less well known. Here, we integrate data from 1,367 human iPSC lines to comprehensively map common and rare regulatory variants in human pluripotent cells. Using this population-scale resource, we report hundreds of new colocalization events for human traits specific to iPSCs, and find increased power to identify rare regulatory variants compared with somatic tissues. Finally, we demonstrate how iPSCs enable the identification of causal genes for rare diseases.

Published

2021

2. Nonsense-mediated decay is highly stable across individuals and tissues

Author

Manuel A. Rivas, Craig Smail, Stephen B. Montgomery, Daniel Nachun, Nicole M. Ferraro, Tiffany Eulalio, and Nicole A. Teran

Subjects

In silico, Nonsense-mediated decay, Computational biology, Biology, Genome, Article, 03 medical and health sciences, 0302 clinical medicine, Text mining, Gene Frequency, Genotype-Tissue Expression, Genetics, Humans, RNA, Messenger, Allele frequency, Genetics (clinical), 030304 developmental biology, 0303 health sciences, business.industry, Genetic Diseases, Inborn, RNA, Genetic Variation, Nonsense Mediated mRNA Decay, Minor allele frequency, Gene Expression Regulation, Codon, Nonsense, Allelic Imbalance, Mutation, business, 030217 neurology & neurosurgery

Abstract

Precise interpretation of the effects of protein-truncating variants (PTVs) is important for accurate determination of variant impact. Current methods for assessing the ability of PTVs to induce nonsense-mediated decay (NMD) focus primarily on the position of the variant in the transcript. We used RNA-sequencing of the Genotype Tissue Expression v8 cohort to compute the efficiency of NMD using allelic imbalance for 2,320 rare (genome aggregation database minor allele frequency in silico that utilizing peripheral tissues or cell lines provides accurate prediction of NMD for PTVs.

Published

2021

3. The GTEx Consortium atlas of genetic regulatory effects across human tissues

Author

Deborah C. Mash, Kevin S. Smith, Lappalainen T, Jeffrey A. Thomas, Rajinder Kaul, Paul Flicek, Maghboeba Mosavel, Yuxin Zou, Barbara E. Stranger, Brandon L. Pierce, Yanyu Liang, Andrew R. Hamel, Lihua Jiang, Marcus Hunter, Jimmie B. Vaught, Hae Kyung Im, John M. Rouhana, François Aguet, Ferran Reverter, Jason Bridge, Farzana Jasmine, Scott D. Jewell, William F. Leinweber, Gad Getz, Jonah Einson, Kevin Myer, SE Castel, Barbara E. Engelhardt, Stephen B. Montgomery, Brunilda Balliu, Gary Walters, Helen M. Moore, Daniel Nachun, Zerbino, Lori E. Brigham, Gao Wang, Farhad Hormozdiari, Pejman Mohammadi, Kasper D. Hansen, Nicole A. Teran, Fred A. Wright, Bryan Gillard, Sarah Kim-Hellmuth, CC Powell, Susan E. Koester, Wucher, Aaron Graubert, Duyen T. Nguyen, Shin Lin, Mike Moser, John A. Stamatoyannopoulos, Liqun Qi, Princy Parsana, Peter Hickey, Latarsha J. Carithers, Saboor Shad, Eric R. Gamazon, Jennifer A. Doherty, Stephen J. Trevanion, Kane Hadley, Kate R. Rosenbloom, Anita H. Undale, Robert E. Handsaker, Debra Bradbury, Shankara Anand, Meng Wang, David E. Tabor, Karna Robinson, S. Gabriel, Esti Yeger-Lotem, Kimberly Ramsey, Mary Barcus, Daniel G. MacArthur, Yuan He, Nancy Roche, Alvaro N. Barbeira, Ayellet V. Segrè, Dan Sheppard, Souvik Das, AR Little, Nathan S. Abell, Xiaoquan Wen, Elise D. Flynn, Nicole M. Ferraro, Hua Tang, Jared L. Nedzel, Jessica Wheeler, Abhi Rao, Meier, Thomas Juettemann, Sandra Linder, Bruce A. Roe, Daniel J. Cotter, David A. Davis, Christopher Johns, Lin Chen, Seva Kashin, Muhammad G. Kibriya, Ana Viñuela, Ellen Todres, Ashis Saha, Matthew Stephens, Chiara Sabatti, Manolis Kellis, Laura A. Siminoff, Phillip Branton, Xiao Li, Michael Snyder, Kathryn Demanelis, Gen Li, Barbara A. Foster, Leslie H. Sobin, Simona Volpi, Magali Ruffier, Christopher D. Brown, Ping Guan, Benjamin J. Strober, Alexis Battle, Michael J. Gloudemans, Silva Kasela, Manuel Muñoz-Aguirre, Ellen Karasik, OM deGoede, Roderic Guigó, Michael Washington, Alisa McDonald, Andrew A. Brown, Meritxell Oliva, Kieron Taylor, Nancy J. Cox, Daniel C. Rohrer, Paul J. Hoffman, Gene Kopen, Qin Li, Andrew D Skol, Rodrigo Bonazzola, Tiffany Eulalio, Mark H. Johnson, Laure Fresard, Lindsay F. Rizzardi, Abhiram Rao, T Krubit, W. J. Kent, Alan Kwong, Anna M. Smith, Pedro G. Ferreira, HM Gardiner, Andrew P. Feinberg, Rick Hasz, Lei Hou, Marta Melé, Andrew B. Nobel, Katherine H. Huang, Laura Barker, Maximilian Haeussler, Kristin G. Ardlie, Concepcion R. Nierras, Christopher Lee, Joshua M. Akey, Eskin E, Jeffrey McLean, Donald F. Conrad, Jin Billy Li, YoSon Park, Serghei Mangul, Emmanouil T. Dermitzakis, Brian Jo, D Garrido-Martin, and Barcelona Supercomputing Center

Subjects

Informàtica::Aplicacions de la informàtica::Bioinformàtica [Àrees temàtiques de la UPC], 0303 health sciences, Linkage disequilibrium, Multidisciplinary, Genotype-Tissue Expression (GTEx), Atlas (topology), Human tissues, Cancer susceptibility, Diseases, Genome-wide association study, RNA-Seq, Computational biology, Biology, Expressió gènica, Human genetics, 03 medical and health sciences, Tissues, 0302 clinical medicine, Allelic heterogeneity, Gene expression, Genètica, 030217 neurology & neurosurgery, 030304 developmental biology, Teixits (Histologia)

Abstract

The Genotype-Tissue Expression (GTEx) project dissects how genetic variation affects gene expression and splicing. Some human genetic variants affect the amount of RNA produced and the splicing of gene transcripts, crucial steps in development and maintaining a healthy individual. However, some of these changes only occur in a small number of tissues within the body. The Genotype-Tissue Expression (GTEx) project has been expanded over time, and, looking at the final data in version 8, Aguet et al. present a deep characterization of genetic associations and gene expression and splicing in 838 individuals over 49 tissues (see the Perspective by Wilson). This large study was able to characterize the details underlying many aspects of gene expression and provides a resource with which to better understand the fundamental molecular mechanisms of how genetic variants affect gene regulation and complex traits in humans. Science, this issue p. 1318; see also p. 1298 The Genotype-Tissue Expression (GTEx) project was established to characterize genetic effects on the transcriptome across human tissues and to link these regulatory mechanisms to trait and disease associations. Here, we present analyses of the version 8 data, examining 15,201 RNA-sequencing samples from 49 tissues of 838 postmortem donors. We comprehensively characterize genetic associations for gene expression and splicing in cis and trans, showing that regulatory associations are found for almost all genes, and describe the underlying molecular mechanisms and their contribution to allelic heterogeneity and pleiotropy of complex traits. Leveraging the large diversity of tissues, we provide insights into the tissue specificity of genetic effects and show that cell type composition is a key factor in understanding gene regulatory mechanisms in human tissues. We thank the donors and their families for their generous gifts of organ donation for transplantation and tissue donations for the GTEx research project; the Genomics Platform at the Broad Institute for data generation; J. Struewing for support and leadership of the GTEx project; M. Khan and C. Stolte for the illustrations in Fig. 1; and R. Do, D. Jordan, and M. Verbanck for providing GWAS pleiotropy scores. Funding: This work was supported by the Common Fund of the Office of the Director, U.S. National Institutes of Health, and by NCI, NHGRI, NHLBI, NIDA, NIMH, NIA, NIAID, and NINDS through NIH contracts HHSN261200800001E (Leidos Prime contract with NCI: A.M.S., D.E.T., N.V.R., J.A.M., L.S., M.E.B., L.Q., T.K., D.B., K.R., and A.U.), 10XS170 (NDRI: W.F.L., J.A.T., G.K., A.M., S.S., R.H., G.Wa., M.J., M.Wa., L.E.B., C.J., J.W., B.R., M.Hu., K.M., L.A.S., H.M.G., M.Mo., and L.K.B.), 10XS171 (Roswell Park Cancer Institute: B.A.F., M.T.M., E.K., B.M.G., K.D.R., and J.B.), 10X172 (Science Care Inc.), 12ST1039 (IDOX), 10ST1035 (Van Andel Institute: S.D.J., D.C.R., and D.R.V.), HHSN268201000029C (Broad Institute: F.A., G.G., K.G.A., A.V.S., X.Li., E.T., S.G., A.G., S.A., K.H.H., D.T.N., K.H., S.R.M., and J.L.N.), 5U41HG009494 (F.A., G.G., and K.G.A.), and through NIH grants R01 DA006227-17 (University of Miami Brain Bank: D.C.M. and D.A.D.), Supplement to University of Miami grant DA006227 (D.C.M. and D.A.D.), R01 MH090941 (University of Geneva), R01 MH090951 and R01 MH090937 (University of Chicago), R01 MH090936 (University of North Carolina–Chapel Hill), R01MH101814 (M.M.-A., V.W., S.B.M., R.G., E.T.D., D.G.-M., and A.V.), U01HG007593 (S.B.M.), R01MH101822 (C.D.B.), U01HG007598 (M.O. and B.E.S.), U01MH104393 (A.P.F.), extension H002371 to 5U41HG002371 (W.J.K.), as well as other funding sources: R01MH106842 (T.L., P.M., E.F., and P.J.H.), R01HL142028 (T.L., Si.Ka., and P.J.H.), R01GM122924 (T.L. and S.E.C.), R01MH107666 (H.K.I.), P30DK020595 (H.K.I.), UM1HG008901 (T.L.), R01GM124486 (T.L.), R01HG010067 (Y.Pa.), R01HG002585 (G.Wa. and M.St.), Gordon and Betty Moore Foundation GBMF 4559 (G.Wa. and M.St.), 1K99HG009916-01 (S.E.C.), R01HG006855 (Se.Ka. and R.E.H.), BIO2015-70777-P, Ministerio de Economia y Competitividad and FEDER funds (M.M.-A., V.W., R.G., and D.G.-M.), la Caixa Foundation ID 100010434 under agreement LCF/BQ/SO15/52260001 (D.G.-M.), NIH CTSA grant UL1TR002550-01 (P.M.), Marie-Skłodowska Curie fellowship H2020 Grant 706636 (S.K.-H.), R35HG010718 (E.R.G.), FPU15/03635, Ministerio de Educación, Cultura y Deporte (M.M.-A.),R01MH109905, 1R01HG010480 (A.Ba.), Searle Scholar Program (A.Ba.), R01HG008150 (S.B.M.), 5T32HG000044-22, NHGRI Institutional Training Grant in Genome Science (N.R.G.), EU IMI program (UE7-DIRECT-115317-1) (E.T.D. and A.V.), FNS funded project RNA1 (31003A_149984) (E.T.D. and A.V.), DK110919 (F.H.), F32HG009987 (F.H.), Massachusetts Lions Eye Research Fund Grant (A.R.H.), Wellcome grant WT108749/Z/15/Z (P.F.), and European Molecular Biology Laboratory (P.F. and D.Z.). Peer Reviewed "Article signat per 1 autors/es del BSC membres del THE GTEX CONSORTIUM: Marta Mele Messeguer"

Published

2020

4. Evaluating the Genomic Parameters Governing rAAV-Mediated Homologous Recombination

Author

Laura P. Spector, Stephen B. Montgomery, Nathan S. Abell, Nicole M. Ferraro, Matthew Tiffany, and Mark A. Kay

Subjects

Transgene, Population, Genetic Vectors, Computational biology, Biology, 03 medical and health sciences, 0302 clinical medicine, Genome editing, Transcription (biology), Drug Discovery, Genetics, Humans, Transgenes, Enhancer, education, Homologous Recombination, Molecular Biology, Gene, 030304 developmental biology, Pharmacology, 0303 health sciences, education.field_of_study, Gene Transfer Techniques, Dependovirus, Chromatin, 030220 oncology & carcinogenesis, Gene Targeting, Molecular Medicine, Original Article, Homologous recombination, K562 Cells

Abstract

Recombinant adeno-associated virus (rAAV) vectors have the unique ability to promote targeted integration of transgenes via homologous recombination at specified genomic sites, reaching frequencies of 0.1%–1%. We studied genomic parameters that influence targeting efficiencies on a large scale. To do this, we generated more than 1,000 engineered, doxycycline-inducible target sites in the human HAP1 cell line and infected this polyclonal population with a library of AAV-DJ targeting vectors, with each carrying a unique barcode. The heterogeneity of barcode integration at each target site provided an assessment of targeting efficiency at that locus. We compared targeting efficiency with and without target site transcription for identical chromosomal positions. Targeting efficiency was enhanced by target site transcription, while chromatin accessibility was associated with an increased likelihood of targeting. ChromHMM chromatin states characterizing transcription and enhancers in wild-type K562 cells were also associated with increased AAV-HR efficiency with and without target site transcription, respectively. Furthermore, the amenability of a site to targeting was influenced by the endogenous transcriptional level of intersecting genes. These results define important parameters that may not only assist in designing optimal targeting vectors for genome editing, but also provide new insights into the mechanism of AAV-mediated homologous recombination.

Published

2020

5. A vast resource of allelic expression data spanning human tissues

Author

Nancy J. Cox, Sayantan Das, Abhi Rao, Pejman Mohammadi, Alan Kwong, Brandon L. Pierce, Yanyu Liang, Yuxin Zou, Anna M. Smith, Matthew Stephens, Chiara Sabatti, Yuan He, Kasper D. Hansen, Lei Hou, Meritxell Oliva, W. James Kent, Stacey Gabriel, Andrew R. Hame, Tanya Krubit, Gary Walters, Lori E. Brigham, Gao Wang, Kevin S. Smith, Michael J. Gloudemans, Barbara E. Engelhardt, Yongjin Park, Nicole A. Teran, David A. Davis, Thomas Juettemann, Kimberley Ramsey, Fred A. Wright, Lin Chen, Valentin Wucher, Benjamin J. Strober, Duyen T. Nguyen, Eleazar Eskin, Kane Hadley, Deborah C. Mash, Michael Snyder, Sarah Kim-Hellmuth, Laura A. Siminoff, Maghboeba Mosavel, Shin Lin, Richard Hasz, Daniel C. Rohrer, Latarsha J. Carithers, Kevin Myer, Rajinder Kaul, Andrew D. Skol, Bryan Gillard, Dana R. Valley, Philip A. Branton, Stephane E. Castel, Robert E. Handsaker, Debra Bradbury, Meng Wang, Mary Barcus, Xiaoquan Wen, Hua Tang, Daniel J. Cotter, Lihua Jiang, Jason Bridge, Ashis Saha, Gen Li, Susan E. Koester, Qin Li, Mark H. Johnson, Barbara E. Stranger, Jimmie B. Vaught, Hae Kyung Im, Paul Flicek, Marcus Hunter, François Aguet, Elise D. Flynn, Sandra Linder, Nancy Roche, Daniel R. Zerbino, Xiao Li, Barbara A. Foster, Stephen B. Montgomery, Daniel Nachun, Serghei Mangul, Emmanouil T. Dermitzakis, Brian Jo, Simona Volpi, Farzana Jasmine, Scott D. Jewell, Jonah Einson, Tuuli Lappalainen, Farhad Hormozdiari, John M. Rouhana, Ana Viñuela, Daniel G. MacArthur, William F. Leinweber, Gad Getz, Peter Hickey, Eric R. Gamazon, Brunilda Balliu, Jennifer A. Doherty, Christopher D. Brown, Roderic Guigó, Gene Kopen, Rodrigo Bonazzola, Pedro G. Ferreira, Andrew P. Feinberg, Shankara Anand, Helen M. Moore, Paul J. Hoffman, Heather M. Gardiner, Ping Guan, Ferran Reverter, Jin Billy Li, Tiffany Eulalio, Joseph Wheeler, Alvaro N. Barbeira, Jared L. Nedzel, Seva Kashin, Laure Fresard, Lindsay F. Rizzardi, Abhiram Rao, Muhammad G. Kibriya, David Tabor, Leslie H. Sobin, A. Roger Little, Stephen J. Trevanion, Nicole M. Ferraro, Kate R. Rosenbloom, John A. Stamatoyannopoulos, Liqun Qi, Princy Parsana, Ayellet V. Segrè, Dan Sheppard, Nathan S. Abell, Kathryn Demanelis, Manolis Kellis, Silva Kasela, Xin Li, Conner C. Powell, YoSon Park, Michael Washington, Magali Ruffier, Saboor Shad, Christopher Johns, Jeffrey A. Thomas, Andrew Brown, Alisa McDonald, Karna Robinson, Esti Yeger-Lotem, Manuel Muñoz-Aguirre, Kieron Taylor, Marta Melé, Diego Garrido-Martín, Brian Roe, Michael T. Moser, Andrew B. Nobel, Alexis Battle, Maximilian Haeussler, Concepcion R. Nierras, Ellen Karasik, Sam Meier, Anita H. Undale, Ellen Todres, Aaron Graubert, Joshua M. Akey, Jeffrey McLean, Donald F. Conrad, Olivia M. De Goede, Katherine H. Huang, Laura Barker, Kristin G. Ardlie, and Christopher Lee

Subjects

animal structures, Future studies, lcsh:QH426-470, Short Report, Gene Expression, Genomics, Computational biology, Biology, eQTL, Polymorphism, Single Nucleotide, ASE, Regulatory variation, 03 medical and health sciences, 0302 clinical medicine, Resource (project management), Humans, SNP, Allele, lcsh:QH301-705.5, Alleles, Allele specific, 030304 developmental biology, 0303 health sciences, Allelic expression, Genome, Human, Sequence Analysis, RNA, Haplotype, Functional genomics, Human genetics, lcsh:Genetics, Haplotypes, lcsh:Biology (General), Expression data, Expression quantitative trait loci, GTEx, 030217 neurology & neurosurgery

Abstract

Allele expression (AE) analysis robustly measures cis-regulatory effects. Here, we present and demonstrate the utility of a vast AE resource generated from the GTEx v8 release, containing 15,253 samples spanning 54 human tissues for a total of 431 million measurements of AE at the SNP level and 153 million measurements at the haplotype level. In addition, we develop an extension of our tool phASER that allows effect sizes of cis-regulatory variants to be estimated using haplotype-level AE data. This AE resource is the largest to date, and we are able to make haplotype-level data publicly available. We anticipate that the availability of this resource will enable future studies of regulatory variation across human tissues.

Published

2020

6. Long non-coding RNA gene regulation and trait associations across human tissues

Author

Sarah Kim-Hellmuth, Xiaoquan Wen, Tuuli Lappalainen, Stephane E. Castel, Benjamin J. Strober, Ira M. Hall, François Aguet, Thomas Quertermous, Youngmin Park, Alexis Battle, de Goede Om, Hae Kyung Im, Nicole M. Ferraro, Karla Kirkegaard, Kristin G. Ardlie, Abhiram Rao, Alexandra J. Scott, Christopher D. Brown, Stephen B. Montgomery, Daniel Nachun, and Alvaro N. Barbeira

Subjects

Regulation of gene expression, 0303 health sciences, Cell type, Transcriptional activity, RNA, Computational biology, Biology, Long non-coding RNA, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, Trait, Gene, 030304 developmental biology

Abstract

Long non-coding RNA (lncRNA) genes are known to have diverse impacts on gene regulation. However, it is still a major challenge to distinguish functional lncRNAs from those that are byproducts of surrounding transcriptional activity. To systematically identify hallmarks of biological function, we used the GTEx v8 data to profile the expression, regulation, network relationships and trait associations of lncRNA genes across 49 tissues encompassing 87 distinct traits. In addition to revealing widespread differences in regulatory patterns between lncRNA and protein-coding genes, we identified novel disease-associated lncRNAs, such asC6orf3for psoriasis andLINC01475/RP11-129J12.1for ulcerative colitis. This work provides a comprehensive resource to interrogate lncRNA genes of interest and annotate cell type and human trait relevance.One Sentence SummarylncRNA genes have distinctive regulatory patterns and unique trait associations compared to protein-coding genes.

Published

2019

7. Transcriptomic signatures across human tissues identify functional rare genetic variation

Author

Christopher D. Brown, Austin T. Hilliard, Adolfo Correa, Nicole M. Ferraro, Maja Bucan, Alvaro N. Barbeira, Kristin G. Ardlie, Stephane E. Castel, Shweta Ramdas, Michael C. Bassik, Margot Brandt, Joe R. Davis, Stephen B. Montgomery, Nathan S. Abell, Jonah Einson, Tuuli Lappalainen, Alexis Battle, François Aguet, Alexandra J. Scott, Gaelen T. Hess, Ira M. Hall, Hae Kyung Im, Pejman Mohammadi, Themistocles L. Assimes, Aradhana, Gina M. Peloso, Pradeep Natarajan, Emily Greenwald, Benjamin J. Strober, Rachel L. Kember, Emily K. Tsang, Bence Kotis, Seyedeh M. Zekavat, YoSon Park, Marcello Ziosi, Xin Li, and Craig Smail

Subjects

Multifactorial Inheritance, Multidisciplinary, Genome, Human, Alternative splicing, Genetic Variation, Computational biology, Biology, Phenotype, Genome, Article, Transcriptome, Organ Specificity, Genetic variation, Humans, Human genome, Function (biology)

Abstract

© 2020 American Association for the Advancement of Science. All rights reserved. INTRODUCTION: The human genome contains tens of thousands of rare (minor allele frequency 800 genomes matched with transcriptomes across 49 tissues, we were able to study RVs that underlie extreme changes in the transcriptome. To capture the diversity of these extreme changes, we developed and integrated approaches to identify expression, allele-specific expression, and alternative splicing outliers, and characterized the RV landscape underlying each outlier signal. We demonstrate that personal genome interpretation and RV discovery is enhanced by using these signals. This approach provides a new means to integrate a richer set of functional RVs into models of genetic burden, improve disease gene identification, and enable the delivery of precision genomics.

Published

2019

8. Systematic assessment of regulatory effects of human disease variants in pluripotent cells

Author

Kelly A. Frazer, Oliver Stegle, David Jakubosky, Michael J. Gloudemans, Daniel D Seaton, Bogdan Mirauta, Craig Smail, Danilo Horta, Stephen B. Montgomery, Nicole M. Ferraro, Marc Jan Bonder, Matteo D’Antonio, Smith En, Na Cai, Ivan Carcamo-Orive, Laure Fresard, and Xin Li

Subjects

Exon, Polyadenylation, Gene expression, Genome-wide association study, Computational biology, Disease, Biology, Quantitative trait locus, Induced pluripotent stem cell, Gene

Abstract

Identifying regulatory genetic effects in pluripotent cells provides important insights into disease variants with potentially transient or developmental origins. Combining existing and newly-generated data, we established a population-scale resource of 1,367 induced pluripotent stem cell lines derived from 948 unique donors, with matched RNA-sequencing (RNA-seq) and genetic information. The sample size of our study allowed us to significantly expand our knowledge of quantitative trait loci (QTL) in pluripotent human cells and their broad trait and disease relevance. We identified cis-QTL for conventional gene expression levels but also transcript-ratio, exon expression levels, alternative-splicing and alternative polyadenylation usage, cumulatively yielding cis regulatory effects for 18,556 genes. We assessed the effects of rare variants identified from whole-genome sequencing data, by relating these to gene expression outliers, observing an enrichment for rare, deleterious variants in iPSCs with outlying expression profiles, which exceeds previous observations in differentiated tissues. Finally, we assessed distal QTL on a genome-wide scale, identifying 193 trans-eQTL, linked to 191 trans-eGenes (FDR By linking our regulatory map of rare and common QTL to comprehensive GWAS data, we identified high-confidence colocalization events for 4,336 individual GWAS loci, which includes physical traits such as height and coronary artery disease. In addition, we identify rare variant associations for metabolic rate and trans-eQTL linked to both cancer and height. Collectively, our data greatly expand the regulatory landscape in human pluripotent cells, and catalogues trait-associated variants that have potential developmental or transient contexts.

Published

2019

9. Population-scale tissue transcriptomics maps long non-coding RNAs to complex disease

Author

Olivia M. de Goede, Daniel C. Nachun, Nicole M. Ferraro, Michael J. Gloudemans, Abhiram S. Rao, Craig Smail, Tiffany Y. Eulalio, François Aguet, Bernard Ng, Jishu Xu, Alvaro N. Barbeira, Stephane E. Castel, Sarah Kim-Hellmuth, YoSon Park, Alexandra J. Scott, Benjamin J. Strober, Christopher D. Brown, Xiaoquan Wen, Ira M. Hall, Alexis Battle, Tuuli Lappalainen, Hae Kyung Im, Kristin G. Ardlie, Sara Mostafavi, Thomas Quertermous, Karla Kirkegaard, Stephen B. Montgomery, Shankara Anand, Stacey Gabriel, Gad A. Getz, Aaron Graubert, Kane Hadley, Robert E. Handsaker, Katherine H. Huang, Xiao Li, Daniel G. MacArthur, Samuel R. Meier, Jared L. Nedzel, Duyen T. Nguyen, Ayellet V. Segrè, Ellen Todres, Brunilda Balliu, Rodrigo Bonazzola, Andrew Brown, Donald F. Conrad, Daniel J. Cotter, Nancy Cox, Sayantan Das, Emmanouil T. Dermitzakis, Jonah Einson, Barbara E. Engelhardt, Eleazar Eskin, Elise D. Flynn, Laure Fresard, Eric R. Gamazon, Diego Garrido-Martín, Nicole R. Gay, Roderic Guigó, Andrew R. Hamel, Yuan He, Paul J. Hoffman, Farhad Hormozdiari, Lei Hou, Brian Jo, Silva Kasela, Seva Kashin, Manolis Kellis, Alan Kwong, Xin Li, Yanyu Liang, Serghei Mangul, Pejman Mohammadi, Manuel Muñoz-Aguirre, Andrew B. Nobel, Meritxell Oliva, Yongjin Park, Princy Parsana, Ferran Reverter, John M. Rouhana, Chiara Sabatti, Ashis Saha, Matthew Stephens, Barbara E. Stranger, Nicole A. Teran, Ana Viñuela, Gao Wang, Fred Wright, Valentin Wucher, Yuxin Zou, Pedro G. Ferreira, Gen Li, Marta Melé, Esti Yeger-Lotem, Debra Bradbury, Tanya Krubit, Jeffrey A. McLean, Liqun Qi, Karna Robinson, Nancy V. Roche, Anna M. Smith, David E. Tabor, Anita Undale, Jason Bridge, Lori E. Brigham, Barbara A. Foster, Bryan M. Gillard, Richard Hasz, Marcus Hunter, Christopher Johns, Mark Johnson, Ellen Karasik, Gene Kopen, William F. Leinweber, Alisa McDonald, Michael T. Moser, Kevin Myer, Kimberley D. Ramsey, Brian Roe, Saboor Shad, Jeffrey A. Thomas, Gary Walters, Michael Washington, Joseph Wheeler, Scott D. Jewell, Daniel C. Rohrer, Dana R. Valley, David A. Davis, Deborah C. Mash, Mary E. Barcus, Philip A. Branton, Leslie Sobin, Laura K. Barker, Heather M. Gardiner, Maghboeba Mosavel, Laura A. Siminoff, Paul Flicek, Maximilian Haeussler, Thomas Juettemann, W. James Kent, Christopher M. Lee, Conner C. Powell, Kate R. Rosenbloom, Magali Ruffier, Dan Sheppard, Kieron Taylor, Stephen J. Trevanion, Daniel R. Zerbino, Nathan S. Abell, Joshua Akey, Lin Chen, Kathryn Demanelis, Jennifer A. Doherty, Andrew P. Feinberg, Kasper D. Hansen, Peter F. Hickey, Farzana Jasmine, Lihua Jiang, Rajinder Kaul, Muhammad G. Kibriya, Jin Billy Li, Qin Li, Shin Lin, Sandra E. Linder, Brandon L. Pierce, Lindsay F. Rizzardi, Andrew D. Skol, Kevin S. Smith, Michael Snyder, John Stamatoyannopoulos, Hua Tang, Meng Wang, Latarsha J. Carithers, Ping Guan, Susan E. Koester, A. Roger Little, Helen M. Moore, Concepcion R. Nierras, Abhi K. Rao, Jimmie B. Vaught, and Simona Volpi

Subjects

Multifactorial Inheritance, Population, Quantitative Trait Loci, Coronary Artery Disease, Disease, Computational biology, Quantitative trait locus, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Transcriptome, 03 medical and health sciences, 0302 clinical medicine, Humans, education, Gene, 030304 developmental biology, 0303 health sciences, education.field_of_study, Gene Expression Profiling, Genetic Variation, Inflammatory Bowel Diseases, Long non-coding RNA, Diabetes Mellitus, Type 1, Diabetes Mellitus, Type 2, Organ Specificity, Expression quantitative trait loci, Trait, RNA, Long Noncoding, 030217 neurology & neurosurgery

Abstract

Long non-coding RNA (lncRNA) genes have well-established and important impacts on molecular and cellular functions. However, among the thousands of lncRNA genes, it is still a major challenge to identify the subset with disease or trait relevance. To systematically characterize these lncRNA genes, we used Genotype Tissue Expression (GTEx) project v8 genetic and multi-tissue transcriptomic data to profile the expression, genetic regulation, cellular contexts, and trait associations of 14,100 lncRNA genes across 49 tissues for 101 distinct complex genetic traits. Using these approaches, we identified 1,432 lncRNA gene-trait associations, 800 of which were not explained by stronger effects of neighboring protein-coding genes. This included associations between lncRNA quantitative trait loci and inflammatory bowel disease, type 1 and type 2 diabetes, and coronary artery disease, as well as rare variant associations to body mass index.

Published

2021

10. A Quantitative Proteome Map of the Human Body

Author

Lihua Jiang, Meng Wang, Shin Lin, Ruiqi Jian, Xiao Li, Joanne Chan, Guanlan Dong, Huaying Fang, Aaron E. Robinson, Michael P. Snyder, François Aguet, Shankara Anand, Kristin G. Ardlie, Stacey Gabriel, Gad Getz, Aaron Graubert, Kane Hadley, Robert E. Handsaker, Katherine H. Huang, Seva Kashin, Daniel G. MacArthur, Samuel R. Meier, Jared L. Nedzel, Duyen Y. Nguyen, Ayellet V. Segrè, Ellen Todres, Brunilda Balliu, Alvaro N. Barbeira, Alexis Battle, Rodrigo Bonazzola, Andrew Brown, Christopher D. Brown, Stephane E. Castel, Don Conrad, Daniel J. Cotter, Nancy Cox, Sayantan Das, Olivia M. de Goede, Emmanouil T. Dermitzakis, Barbara E. Engelhardt, Eleazar Eskin, Tiffany Y. Eulalio, Nicole M. Ferraro, Elise Flynn, Laure Fresard, Eric R. Gamazon, Diego Garrido-Martín, Nicole R. Gay, Roderic Guigó, Andrew R. Hamel, Yuan He, Paul J. Hoffman, Farhad Hormozdiari, Lei Hou, Hae Kyung Im, Brian Jo, Silva Kasela, Manolis Kellis, Sarah Kim-Hellmuth, Alan Kwong, Tuuli Lappalainen, Xin Li, Yanyu Liang, Serghei Mangul, Pejman Mohammadi, Stephen B. Montgomery, Manuel Muñoz-Aguirre, Daniel C. Nachun, Andrew B. Nobel, Meritxell Oliva, YoSon Park, Yongjin Park, Princy Parsana, Ferran Reverter, John M. Rouhana, Chiara Sabatti, Ashis Saha, Andrew D. Skol, Matthew Stephens, Barbara E. Stranger, Benjamin J. Strober, Nicole A. Teran, Ana Viñuela, Gao Wang, Xiaoquan Wen, Fred Wright, Valentin Wucher, Yuxin Zou, Pedro G. Ferreira, Gen Li, Marta Melé, Esti Yeger-Lotem, Mary E. Barcus, Debra Bradbury, Tanya Krubit, Jeffrey A. McLean, Liqun Qi, Karna Robinson, Nancy V. Roche, Anna M. Smith, Leslie Sobin, David E. Tabor, Anita Undale, Jason Bridge, Lori E. Brigham, Barbara A. Foster, Bryan M. Gillard, Richard Hasz, Marcus Hunter, Christopher Johns, Mark Johnson, Ellen Karasik, Gene Kopen, William F. Leinweber, Alisa McDonald, Michael T. Moser, Kevin Myer, Kimberley D. Ramsey, Brian Roe, Saboor Shad, Jeffrey A. Thomas, Gary Walters, Michael Washington, Joseph Wheeler, Scott D. Jewell, Daniel C. Rohrer, Dana R. Valley, David A. Davis, Deborah C. Mash, Philip A. Branton, Laura K. Barker, Heather M. Gardiner, Maghboeba Mosavel, Laura A. Siminoff, Paul Flicek, Maximilian Haeussler, Thomas Juettemann, W. James Kent, Christopher M. Lee, Conner C. Powell, Kate R. Rosenbloom, Magali Ruffier, Dan Sheppard, Kieron Taylor, Stephen J. Trevanion, Daniel R. Zerbino, Nathan S. Abell, Joshua Akey, Lin Chen, Kathryn Demanelis, Jennifer A. Doherty, Andrew P. Feinberg, Kasper D. Hansen, Peter F. Hickey, Farzana Jasmine, Rajinder Kaul, Muhammad G. Kibriya, Jin Billy Li, Qin Li, Sandra E. Linder, Brandon L. Pierce, Lindsay F. Rizzardi, Kevin S. Smith, John Stamatoyannopoulos, Hua Tang, Latarsha J. Carithers, Ping Guan, Susan E. Koester, A. Roger Little, Helen M. Moore, Concepcion R. Nierras, Abhi K. Rao, Jimmie B. Vaught, and Simona Volpi

Subjects

Proteomics, Cell signaling, Proteome, Quantitative proteomics, Gene Expression, Disease, Computational biology, Biology, ENCODE, Article, General Biochemistry, Genetics and Molecular Biology, Transcriptome, 03 medical and health sciences, 0302 clinical medicine, Humans, Secretion, RNA, Messenger, Gene, 030304 developmental biology, 0303 health sciences, Gene Expression Profiling, RNA, Metabolism, Phenotype, Secretory protein, 030217 neurology & neurosurgery

Abstract

Determining protein levels in each tissue and how they compare with RNA levels is important for understanding human biology and disease as well as regulatory processes that control protein levels. We quantified the relative protein levels from 12,627 genes across 32 normal human tissue types prepared by the GTEx project. Known and new tissue specific or enriched proteins (5,499) were identified and compared to transcriptome data. Many ubiquitous transcripts are found to encode highly tissue specific proteins. Discordance in the sites of RNA expression and protein detection also revealed potential sites of synthesis and action of protein signaling molecules. Overall, these results provide an extraordinary resource, and demonstrate that understanding protein levels can provide insights into metabolism, regulation, secretome, and human diseases.SummaryQuantitative proteome study of 32 human tissues and integrated analysis with transcriptome data revealed that understanding protein levels could provide in-depth knowledge to post transcriptional or translational regulations, human metabolism, secretome, and diseases.

Published

2020