RM1GM149403
Project Grant
Overview
Grant Description
Experimental cellular approaches to genotype-environment interaction - project summary
We propose to perform a novel study in the field of cellular epidemiology, that has been made possible by the recent revolution in induced pluripotent stem cell (iPSC) technology. It is well known that there are many cell-specific functions and behaviors that have been missed by the limitations of having to rely on easily obtainable cells, such as blood cells or lymphoblastoid cell lines, for epidemiological studies of disease causation, risk factors, and biomarker identification.
Advances in iPSC technologies now allow us to consider non-invasive large-scale deep cellular phenotyping efforts on disease-appropriate cell types in human subjects. Robust derivation of iPSC lines and their differentiation into organ-specific cell types is possible from blood cells. An important benefit of iPSC-derived cells is that observed biological variation primarily represents genetic influences, since most of the epigenetic memory of the historical organismal environment is lost.
Our proposed study involves an innovative experimental approach to human genotype×environment interaction (GEI). While GEI is thought to exist widely, it is relatively poorly studied in humans due to environmental heterogeneity and the difficulty of controlling environmental exposures. Our iPSC-based cellular approach allows us to rigorously test for GEI experimentally by examining cellular phenotypic variation before and after a controlled environmental challenge.
Our study will be the first and largest study to model human GEI in two different iPSC-derived cell types. First, we will determine if the expected neurotoxic effect of snake venom in neural stem cells (NSCs) is genetically driven, and secondly, whether the suspected differential response of alveolar epithelial type 2 cells (AT2s) to environmental pollutant exposure has a genetic basis.
This project will leverage a major existing human resource, the Mexican American Family Study (MAFS). We will use existing cryo-preserved iPSC lines from 400 MAFS participants for the generation of well-characterized NSCs and AT2s. We propose a novel experimental and efficient pedigree-based approach for studying the genetic basis of cellular response to environmental stress (i.e., GEI), which has previously been difficult to assess.
Our aims are:
1) Assess genetic basis of NSC response to snake venom;
2) Assess genetic basis of AT2 response to benzo[a]pyrene pollution;
3) Examine the genetic basis of environmental disruption of cellular transcriptional coherence/homeostasis; and
4) Identify pleiotropic effects of cellular stress resilience on human organismal phenotypes relevant to health.
This project will employ a novel experimental and efficient pedigree-based approach for studying human GEI, which has previously been difficult to assess. It also will help establish the feasibility of epidemiological scale utilization of iPSC technology to attack biomedical problems. Finally, we expect that the proposed project will rigorously establish the cellular basis of GEI influencing complex phenotypes of relevance to human health.
We propose to perform a novel study in the field of cellular epidemiology, that has been made possible by the recent revolution in induced pluripotent stem cell (iPSC) technology. It is well known that there are many cell-specific functions and behaviors that have been missed by the limitations of having to rely on easily obtainable cells, such as blood cells or lymphoblastoid cell lines, for epidemiological studies of disease causation, risk factors, and biomarker identification.
Advances in iPSC technologies now allow us to consider non-invasive large-scale deep cellular phenotyping efforts on disease-appropriate cell types in human subjects. Robust derivation of iPSC lines and their differentiation into organ-specific cell types is possible from blood cells. An important benefit of iPSC-derived cells is that observed biological variation primarily represents genetic influences, since most of the epigenetic memory of the historical organismal environment is lost.
Our proposed study involves an innovative experimental approach to human genotype×environment interaction (GEI). While GEI is thought to exist widely, it is relatively poorly studied in humans due to environmental heterogeneity and the difficulty of controlling environmental exposures. Our iPSC-based cellular approach allows us to rigorously test for GEI experimentally by examining cellular phenotypic variation before and after a controlled environmental challenge.
Our study will be the first and largest study to model human GEI in two different iPSC-derived cell types. First, we will determine if the expected neurotoxic effect of snake venom in neural stem cells (NSCs) is genetically driven, and secondly, whether the suspected differential response of alveolar epithelial type 2 cells (AT2s) to environmental pollutant exposure has a genetic basis.
This project will leverage a major existing human resource, the Mexican American Family Study (MAFS). We will use existing cryo-preserved iPSC lines from 400 MAFS participants for the generation of well-characterized NSCs and AT2s. We propose a novel experimental and efficient pedigree-based approach for studying the genetic basis of cellular response to environmental stress (i.e., GEI), which has previously been difficult to assess.
Our aims are:
1) Assess genetic basis of NSC response to snake venom;
2) Assess genetic basis of AT2 response to benzo[a]pyrene pollution;
3) Examine the genetic basis of environmental disruption of cellular transcriptional coherence/homeostasis; and
4) Identify pleiotropic effects of cellular stress resilience on human organismal phenotypes relevant to health.
This project will employ a novel experimental and efficient pedigree-based approach for studying human GEI, which has previously been difficult to assess. It also will help establish the feasibility of epidemiological scale utilization of iPSC technology to attack biomedical problems. Finally, we expect that the proposed project will rigorously establish the cellular basis of GEI influencing complex phenotypes of relevance to human health.
Funding Goals
THE NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES (NIGMS) SUPPORTS BASIC RESEARCH THAT INCREASES OUR UNDERSTANDING OF BIOLOGICAL PROCESSES AND LAYS THE FOUNDATION FOR ADVANCES IN DISEASE DIAGNOSIS, TREATMENT, AND PREVENTION. NIGMS ALSO SUPPORTS RESEARCH IN SPECIFIC CLINICAL AREAS THAT AFFECT MULTIPLE ORGAN SYSTEMS: ANESTHESIOLOGY AND PERI-OPERATIVE PAIN, CLINICAL PHARMACOLOGY ?COMMON TO MULTIPLE DRUGS AND TREATMENTS, AND INJURY, CRITICAL ILLNESS, SEPSIS, AND WOUND HEALING.? NIGMS-FUNDED SCIENTISTS INVESTIGATE HOW LIVING SYSTEMS WORK AT A RANGE OF LEVELSFROM MOLECULES AND CELLS TO TISSUES AND ORGANSIN RESEARCH ORGANISMS, HUMANS, AND POPULATIONS. ADDITIONALLY, TO ENSURE THE VITALITY AND CONTINUED PRODUCTIVITY OF THE RESEARCH ENTERPRISE, NIGMS PROVIDES LEADERSHIP IN SUPPORTING THE TRAINING OF THE NEXT GENERATION OF SCIENTISTS, ENHANCING THE DIVERSITY OF THE SCIENTIFIC WORKFORCE, AND DEVELOPING RESEARCH CAPACITY THROUGHOUT THE COUNTRY.
Grant Program (CFDA)
Place of Performance
Brownsville,
Texas
785204933
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 201% from $1,617,775 to $4,873,202.
The University Of Texas Rio Grande Valley was awarded
Genotype-Environment Interaction Study Using iPSC Technology
Project Grant RM1GM149403
worth $4,873,202
from the HHS Office of the Assistant Secretary for Financial Resources in September 2023 with work to be completed primarily in Brownsville Texas United States.
The grant
has a duration of 5 years and
was awarded through assistance program 93.859 Biomedical Research and Research Training.
The Project Grant was awarded through grant opportunity Collaborative Program Grant for Multidisciplinary Teams (RM1 - Clinical Trial Optional).
Status
(Ongoing)
Last Modified 8/20/25
Period of Performance
9/7/23
Start Date
8/31/28
End Date
Funding Split
$4.9M
Federal Obligation
$0.0
Non-Federal Obligation
$4.9M
Total Obligated
Activity Timeline
Transaction History
Modifications to RM1GM149403
Additional Detail
Award ID FAIN
RM1GM149403
SAI Number
RM1GM149403-2601175705
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Public/State Controlled Institution Of Higher Education
Awarding Office
75NS00 NIH National Institute of General Medical Sciences
Funding Office
75AM00 ASFR OFFICE OF THE ASSISTANT SECRETARY FOR FINANCIAL RESOURCES
Awardee UEI
L3ATVUT2KNK7
Awardee CAGE
6Y726
Performance District
TX-34
Senators
John Cornyn
Ted Cruz
Ted Cruz
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| National Institute of General Medical Sciences, National Institutes of Health, Health and Human Services (075-0851) | Health research and training | Grants, subsidies, and contributions (41.0) | $1,617,775 | 100% |
Modified: 8/20/25