UM1HG012010
Cooperative Agreement
Overview
Grant Description
Comprehensive Characterization of Variants Underlying Heart and Blood Diseases with CRISPR Base Editing - Project Summary
How genomic variation influences cellular function is a fundamental problem with tremendous importance for human disease. While it has traditionally been difficult to study the effects of specific sequence variants in an experimentally controlled manner, precise genome editing technologies such as CRISPR base editing enable "writing" of trait-associated variants to cells to unravel their function.
In this proposal, we will perform multi-modal genome editing-based functional characterization of a total of 72,000 genomic variants associated with cardiovascular diseases (CVDs) and hematological traits. CVD and blood traits are uniquely suited to functional dissection because cardiovascular (coronary artery disease, high blood pressure, dyslipidemia) and blood traits have among the best-powered multi-ethnic GWAS of any traits, and a substantial component of trait variability can be captured in cellular assays that can be scaled to perform high-throughput screening.
We have assembled an interdisciplinary team of world-class experts to provide a generalizable pipeline to unravel the functional impact of CVD and blood trait variants by integrating: (1) rich and ancestry-diverse human genetic discoveries, (2) broadly targetable CRISPR base editors and efficient delivery to primary human cells, (3) high-content assays to profile phenotypes at the levels of chromatin, gene expression, and cellular function, and (4) computational methods to design, interpret, visualize, and share experimental results.
In Aim 1, we will employ a robust, three-tiered variant prioritization scheme that incorporates evidence for disease association from large, multi-ethnic GWAS as well as probability of causality to nominate variants for functional assessment. Through this scheme, we will select variants associated with red blood cell and neutrophil traits, coronary artery disease, blood pressure, and HDL and LDL cholesterol that span a range of allelic frequencies and likely causality to test in high-throughput cellular assays.
In Aim 2, we will perform systematic cellular phenotype-based screens using base editors to install candidate variants as well as CRISPR epigenetic inhibition and activation to explore variant-containing regulatory elements. We will use eight established, scalable cellular phenotypic readouts, each of which will enable us to assess which of 12,000 variants and variant-centered elements alter CVD and blood trait-associated cellular phenotypes. We will additionally employ a high-throughput, genome-integrated chromatin accessibility assay to assess which variants alter chromatin accessibility in trait-relevant cell lines. We will follow up with targeted single-cell RNA-seq of 5,600 variants in primary cells from donors of different sex and ethnicity.
In Aim 3, we will produce a catalog of validated variants and their association with phenotypes for each of the proposed screens. We will collaborate with other IGVF groups to utilize these data to optimize models that predict functional variants, regulatory elements, and disease-causing biological mechanisms, ultimately leading to a more complete understanding of the genetic underpinnings of cardiovascular and blood disease risk.
How genomic variation influences cellular function is a fundamental problem with tremendous importance for human disease. While it has traditionally been difficult to study the effects of specific sequence variants in an experimentally controlled manner, precise genome editing technologies such as CRISPR base editing enable "writing" of trait-associated variants to cells to unravel their function.
In this proposal, we will perform multi-modal genome editing-based functional characterization of a total of 72,000 genomic variants associated with cardiovascular diseases (CVDs) and hematological traits. CVD and blood traits are uniquely suited to functional dissection because cardiovascular (coronary artery disease, high blood pressure, dyslipidemia) and blood traits have among the best-powered multi-ethnic GWAS of any traits, and a substantial component of trait variability can be captured in cellular assays that can be scaled to perform high-throughput screening.
We have assembled an interdisciplinary team of world-class experts to provide a generalizable pipeline to unravel the functional impact of CVD and blood trait variants by integrating: (1) rich and ancestry-diverse human genetic discoveries, (2) broadly targetable CRISPR base editors and efficient delivery to primary human cells, (3) high-content assays to profile phenotypes at the levels of chromatin, gene expression, and cellular function, and (4) computational methods to design, interpret, visualize, and share experimental results.
In Aim 1, we will employ a robust, three-tiered variant prioritization scheme that incorporates evidence for disease association from large, multi-ethnic GWAS as well as probability of causality to nominate variants for functional assessment. Through this scheme, we will select variants associated with red blood cell and neutrophil traits, coronary artery disease, blood pressure, and HDL and LDL cholesterol that span a range of allelic frequencies and likely causality to test in high-throughput cellular assays.
In Aim 2, we will perform systematic cellular phenotype-based screens using base editors to install candidate variants as well as CRISPR epigenetic inhibition and activation to explore variant-containing regulatory elements. We will use eight established, scalable cellular phenotypic readouts, each of which will enable us to assess which of 12,000 variants and variant-centered elements alter CVD and blood trait-associated cellular phenotypes. We will additionally employ a high-throughput, genome-integrated chromatin accessibility assay to assess which variants alter chromatin accessibility in trait-relevant cell lines. We will follow up with targeted single-cell RNA-seq of 5,600 variants in primary cells from donors of different sex and ethnicity.
In Aim 3, we will produce a catalog of validated variants and their association with phenotypes for each of the proposed screens. We will collaborate with other IGVF groups to utilize these data to optimize models that predict functional variants, regulatory elements, and disease-causing biological mechanisms, ultimately leading to a more complete understanding of the genetic underpinnings of cardiovascular and blood disease risk.
Awardee
Funding Goals
NHGRI SUPPORTS THE DEVELOPMENT OF RESOURCES AND TECHNOLOGIES THAT WILL ACCELERATE GENOME RESEARCH AND ITS APPLICATION TO HUMAN HEALTH AND GENOMIC MEDICINE. A CRITICAL PART OF THE NHGRI MISSION CONTINUES TO BE THE STUDY OF THE ETHICAL, LEGAL AND SOCIAL IMPLICATIONS (ELSI) OF GENOME RESEARCH. NHGRI ALSO SUPPORTS THE TRAINING AND CAREER DEVELOPMENT OF INVESTIGATORS AND THE DISSEMINATION OF GENOME INFORMATION TO THE PUBLIC AND TO HEALTH PROFESSIONALS. THE SMALL BUSINESS INNOVATION RESEARCH (SBIR) PROGRAM IS USED TO INCREASE PRIVATE SECTOR COMMERCIALIZATION OF INNOVATIONS DERIVED FROM FEDERAL RESEARCH AND DEVELOPMENT, TO INCREASE SMALL BUSINESS PARTICIPATION IN FEDERAL RESEARCH AND DEVELOPMENT, AND TO FOSTER AND ENCOURAGE PARTICIPATION OF SOCIALLY AND ECONOMICALLY DISADVANTAGED SMALL BUSINESS CONCERNS AND WOMEN-OWNED SMALL BUSINESS CONCERNS IN TECHNOLOGICAL INNOVATION. THE SMALL BUSINESS TECHNOLOGY TRANSFER (STTR) PROGRAM IS USED TO FOSTER SCIENTIFIC AND TECHNOLOGICAL INNOVATION THROUGH COOPERATIVE RESEARCH AND DEVELOPMENT CARRIED OUT BETWEEN SMALL BUSINESS CONCERNS AND RESEARCH INSTITUTIONS, TO FOSTER TECHNOLOGY TRANSFER BETWEEN SMALL BUSINESS CONCERNS AND RESEARCH INSTITUTIONS, TO INCREASE PRIVATE SECTOR COMMERCIALIZATION OF INNOVATIONS DERIVED FROM FEDERAL RESEARCH AND DEVELOPMENT, AND TO FOSTER AND ENCOURAGE PARTICIPATION OF SOCIALLY AND ECONOMICALLY DISADVANTAGED SMALL BUSINESS CONCERNS AND WOMEN-OWNED SMALL BUSINESS CONCERNS IN TECHNOLOGICAL INNOVATION.
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Massachusetts
United States
Geographic Scope
State-Wide
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 556% from $1,033,149 to $6,781,035.
The General Hospital Corporation was awarded
Genomic Characterization of Heart & Blood Disease Variants with CRISPR
Cooperative Agreement UM1HG012010
worth $6,781,035
from National Human Genome Research Institute in September 2021 with work to be completed primarily in Massachusetts United States.
The grant
has a duration of 4 years 8 months and
was awarded through assistance program 93.172 Human Genome Research.
The Cooperative Agreement was awarded through grant opportunity Systematic Characterization of Genomic Variation on Genomic Function and Phenotype (UM1 Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 1/21/25
Period of Performance
9/1/21
Start Date
5/31/26
End Date
Funding Split
$6.8M
Federal Obligation
$0.0
Non-Federal Obligation
$6.8M
Total Obligated
Activity Timeline
Subgrant Awards
Disclosed subgrants for UM1HG012010
Transaction History
Modifications to UM1HG012010
Additional Detail
Award ID FAIN
UM1HG012010
SAI Number
UM1HG012010-2904403225
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Nonprofit With 501(c)(3) IRS Status (Other Than An Institution Of Higher Education)
Awarding Office
75N400 NIH NATIONAL HUMAN GENOME RESEARCH INSTITUTE
Funding Office
75N400 NIH NATIONAL HUMAN GENOME RESEARCH INSTITUTE
Awardee UEI
FLJ7DQKLL226
Awardee CAGE
0ULU5
Performance District
MA-90
Senators
Edward Markey
Elizabeth Warren
Elizabeth Warren
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| National Human Genome Research Institute, National Institutes of Health, Health and Human Services (075-0891) | Health research and training | Grants, subsidies, and contributions (41.0) | $3,857,640 | 100% |
Modified: 1/21/25