The GWAS community has now identified many thousands of variants that affect complex traits, but there is still a critical gap in our ability to interpret why these variants matter. While some signals affect genes that are directly involved in the relevant disease processes, many other signals likely arise due to indirect trans- regulatory effects on core disease genes and pathways. There has been huge progress in recent years on methods to identify variants that affect cis-regulation of nearby genes, but it remains extremely difficult to measure and interpret how and whether those associated genes may affect disease processes directly or via trans-acting effects on other genes. In this grant we propose to develop new experimental and computational methods to help bridge this critical gap. We have recently developed two complementary experimental techniques that use CRISPR-perturbations to map out the upstream regulators and downstream targets of a gene of interest. We will work on methodological improvements for these methods, and apply them in effector T cells and regulatory T cells to map out gene regulatory networks in these important immune cell types. We will develop new computational methods for inferring gene networks using these data. Finally, we will develop and implement new methods for interpreting autoimmune disease loci in light of the network information. This project will establish new high throughput techniques for elucidating regulatory relationships among genes and for using these to interpret GWAS data.

Public Health Relevance

In the last decade there has been huge progress in identifying the genetic bases of complex diseases. However, it has been much more challenging to interpret the molecular mechanisms through which these genetic variants act to affect disease outcomes. In this project we propose to develop new techniques for studying how disease-associated genes may affect gene regulatory networks in cells, as these are one important step linking genetic variation to disease.

Agency
National Institute of Health (NIH)
Institute
National Human Genome Research Institute (NHGRI)
Type
Research Project (R01)
Project #
2R01HG008140-04
Application #
9998651
Study Section
Genomics, Computational Biology and Technology Study Section (GCAT)
Program Officer
Chadwick, Lisa
Project Start
2016-06-23
Project End
2025-03-31
Budget Start
2020-06-01
Budget End
2021-03-31
Support Year
4
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Stanford University
Department
Genetics
Type
Schools of Medicine
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94305
Boyle, Evan A; Pritchard, Jonathan K; Greenleaf, William J (2018) High-resolution mapping of cancer cell networks using co-functional interactions. Mol Syst Biol 14:e8594
Li, Yang I; Knowles, David A; Humphrey, Jack et al. (2018) Annotation-free quantification of RNA splicing using LeafCutter. Nat Genet 50:151-158
Knowles, David A; Burrows, Courtney K; Blischak, John D et al. (2018) Determining the genetic basis of anthracycline-cardiotoxicity by molecular response QTL mapping in induced cardiomyocytes. Elife 7:
Calderon, Diego; Bhaskar, Anand; Knowles, David A et al. (2017) Inferring Relevant Cell Types for Complex Traits by Using Single-Cell Gene Expression. Am J Hum Genet 101:686-699
Harris, Kelley; Pritchard, Jonathan K (2017) Rapid evolution of the human mutation spectrum. Elife 6:
Harpak, Arbel; Lan, Xun; Gao, Ziyue et al. (2017) Frequent nonallelic gene conversion on the human lineage and its effect on the divergence of gene duplicates. Proc Natl Acad Sci U S A 114:12779-12784
Boyle, Evan A; Li, Yang I; Pritchard, Jonathan K (2017) An Expanded View of Complex Traits: From Polygenic to Omnigenic. Cell 169:1177-1186
Bhaskar, Anand; Javanmard, Adel; Courtade, Thomas A et al. (2017) Novel probabilistic models of spatial genetic ancestry with applications to stratification correction in genome-wide association studies. Bioinformatics 33:879-885