R01AI189605
Project Grant
Overview
Grant Description
Transcriptional and post-transcriptional regulation of human TREG identity and function - Abstract
Regulatory T cells (TREGs) are essential for maintaining immune homeostasis by preventing excessive inflammation and autoimmune disease.
TREG stability is governed by the lineage-defining transcription factor FOXP3.
However, exposure to chronic inflammation or repeated T cell receptor stimulation can cause TREGs to destabilize, resulting in loss of FOXP3 expression and suppressive function.
The gene regulatory networks controlling TREG identity and function remain incompletely understood, especially in human T cells.
To address this, we conducted CRISPR nuclease screening for trans-regulatory factors that control the maintenance and suppression of FOXP3 expression in human TREGs.
Our screen highlighted SATB1, SRF, IRF4, and YBX1 as top regulators for further investigation.
This proposal aims to define the multi-level regulatory networks governing TREG stability.
Aim 1 focuses on the transcriptional regulation of FOXP3 by elucidating how key transcription factors (TFs) modulate FOXP3 expression and TREG stability.
We will define the functional roles of key TFs by mapping their binding sites and assessing their effects on chromatin accessibility.
We will employ base editing of key cis-regulatory elements (CREs) that modulate FOXP3 expression to identify critical DNA regions and provide a high-resolution map of TF-CRE interactions in TREGs.
Aim 2 investigates post-transcriptional regulation of FOXP3, focusing on YBX1, an RNA-binding protein we identified as a novel regulator of FOXP3 expression.
Our preliminary data indicate that YBX1 knockout in human TREGs enhances FOXP3 levels and prevents TREG destabilization under inflammatory conditions.
We have also uncovered YBX1-bound transcripts as well as identified pathways regulated by YBX1.
We will further characterize broad cellular pathways regulated by YBX1 and assess direct FOXP3 regulation by systematic mutagenesis of YBX1 binding targets in key TREG transcripts.
We will perform in vitro and in vivo functional assessments in both aims to test the impacts of modulating key regulatory elements and their targets on TREG lineage stability and function.
Together, these studies will provide a comprehensive map of FOXP3 regulation at transcriptional and post-transcriptional levels, and identify strategies to modulate key elements to enhance TREG suppressive function and resistance to destabilization.
Our findings will provide fundamental insights into TREG biology and inform the development of more effective TREG-based immunotherapies for autoimmune diseases, transplantation, and inflammatory disorders.
Regulatory T cells (TREGs) are essential for maintaining immune homeostasis by preventing excessive inflammation and autoimmune disease.
TREG stability is governed by the lineage-defining transcription factor FOXP3.
However, exposure to chronic inflammation or repeated T cell receptor stimulation can cause TREGs to destabilize, resulting in loss of FOXP3 expression and suppressive function.
The gene regulatory networks controlling TREG identity and function remain incompletely understood, especially in human T cells.
To address this, we conducted CRISPR nuclease screening for trans-regulatory factors that control the maintenance and suppression of FOXP3 expression in human TREGs.
Our screen highlighted SATB1, SRF, IRF4, and YBX1 as top regulators for further investigation.
This proposal aims to define the multi-level regulatory networks governing TREG stability.
Aim 1 focuses on the transcriptional regulation of FOXP3 by elucidating how key transcription factors (TFs) modulate FOXP3 expression and TREG stability.
We will define the functional roles of key TFs by mapping their binding sites and assessing their effects on chromatin accessibility.
We will employ base editing of key cis-regulatory elements (CREs) that modulate FOXP3 expression to identify critical DNA regions and provide a high-resolution map of TF-CRE interactions in TREGs.
Aim 2 investigates post-transcriptional regulation of FOXP3, focusing on YBX1, an RNA-binding protein we identified as a novel regulator of FOXP3 expression.
Our preliminary data indicate that YBX1 knockout in human TREGs enhances FOXP3 levels and prevents TREG destabilization under inflammatory conditions.
We have also uncovered YBX1-bound transcripts as well as identified pathways regulated by YBX1.
We will further characterize broad cellular pathways regulated by YBX1 and assess direct FOXP3 regulation by systematic mutagenesis of YBX1 binding targets in key TREG transcripts.
We will perform in vitro and in vivo functional assessments in both aims to test the impacts of modulating key regulatory elements and their targets on TREG lineage stability and function.
Together, these studies will provide a comprehensive map of FOXP3 regulation at transcriptional and post-transcriptional levels, and identify strategies to modulate key elements to enhance TREG suppressive function and resistance to destabilization.
Our findings will provide fundamental insights into TREG biology and inform the development of more effective TREG-based immunotherapies for autoimmune diseases, transplantation, and inflammatory disorders.
Awardee
Funding Goals
<P>THE GOALS ARE:</P><UL><LI>TO FOSTER FUNDAMENTAL CREATIVE DISCOVERIES, INNOVATIVE RESEARCH STRATEGIES, AND THEIR APPLICATIONS AS A BASIS FOR ULTIMATELY PROTECTING AND IMPROVING HEALTH;</LI><LI>TO DEVELOP, MAINTAIN, AND RENEW SCIENTIFIC HUMAN AND PHYSICAL RESOURCES THAT WILL ENSURE THE NATION'S CAPABILITY TO PREVENT DISEASE;</LI><LI>TO EXPAND THE KNOWLEDGE BASE IN MEDICAL AND ASSOCIATED SCIENCES IN ORDER TO ENHANCE THE NATION'S ECONOMIC WELL-BEING AND ENSURE A CONTINUED HIGH RETURN ON THE PUBLIC INVESTMENT IN RESEARCH; AND</LI><LI>TO EXEMPLIFY AND PROMOTE THE HIGHEST LEVEL OF SCIENTIFIC INTEGRITY, PUBLIC ACCOUNTABILITY, AND SOCIAL RESPONSIBILITY IN THE CONDUCT OF SCIENCE.</LI></UL><P>IN REALIZING THESE GOALS, THE NIH PROVIDES LEADERSHIP AND DIRECTION TO PROGRAMS DESIGNED TO IMPROVE THE HEALTH OF THE NATION BY CONDUCTING AND SUPPORTING RESEARCH:</P><UL><LI>IN THE CAUSES, DIAGNOSIS, PREVENTION, AND CURE OF HUMAN DISEASES;</LI><LI>IN THE PROCESSES OF HUMAN GROWTH AND DEVELOPMENT;</LI><LI>IN THE BIOLOGICAL EFFECTS OF ENVIRONMENTAL CONTAMINANTS;</LI><LI>IN THE UNDERSTANDING OF MENTAL, ADDICTIVE AND PHYSICAL DISORDERS; AND</LI><LI>IN DIRECTING PROGRAMS FOR THE COLLECTION, DISSEMINATION, AND EXCHANGE OF INFORMATION IN MEDICINE AND HEALTH, INCLUDING THE DEVELOPMENT AND SUPPORT OF MEDICAL LIBRARIES AND THE TRAINING OF MEDICAL LIBRARIANS AND OTHER HEALTH INFORMATION SPECIALISTS.</LI></UL>
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
San Francisco,
California
941582261
United States
Geographic Scope
Single Zip Code
Related Opportunity
J.David Gladstone Institutes was awarded
Human Treg Identity Function Regulation Enhanced Immune Homeostasis
Project Grant R01AI189605
worth $3,601,712
from the National Institute of Allergy and Infectious Diseases in February 2026 with work to be completed primarily in San Francisco California United States.
The grant
has a duration of 4 years and
was awarded through assistance program 93.855 Allergy and Infectious Diseases Research.
The Project Grant was awarded through grant opportunity NIH Research Project Grant (Parent R01 Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 3/5/26
Period of Performance
2/6/26
Start Date
1/31/30
End Date
Funding Split
$3.6M
Federal Obligation
$0.0
Non-Federal Obligation
$3.6M
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
R01AI189605
SAI Number
R01AI189605-3378926968
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Nonprofit With 501(c)(3) IRS Status (Other Than An Institution Of Higher Education)
Awarding Office
75NM00 NIH National Institute of Allergy and Infectious Diseases
Funding Office
75NM00 NIH National Institute of Allergy and Infectious Diseases
Awardee UEI
KH6NJ6ND8737
Awardee CAGE
3HSQ5
Performance District
CA-11
Senators
Dianne Feinstein
Alejandro Padilla
Alejandro Padilla
Modified: 3/5/26