2514394
Project Grant
Overview
Grant Description
Bring-SynBio: Deciphering and directing lactylation epigenetics to control macrophage immune cell phenotype.
Macrophages are immune cells that play critical roles in fighting disease, healing tissues, and maintaining overall health.
Their behavior can shift in ways that either help or harm the body, depending on their environment.
Histone lactylation, in which lactate, a small molecule metabolite produced in the body, changes how genes are turned on or off, may help explain how these cells change roles.
This project will use synthetic biology to create precision tools that can add or remove lactylation marks on DNA-packaging proteins.
These tools will help scientists understand how lactylation affects macrophage behavior and could lead to new ways to control immune responses in diseases like cancer.
Course module development and support of undergraduate researchers will help to grow the biomanufacturing workforce.
This project investigates the functional role of histone lactylation in macrophage polarization.
Lactylation has been linked to macrophage transitions from inflammatory (M1) to anti-inflammatory (M2) phenotypes, particularly within the immunosuppressive tumor microenvironment.
The central hypothesis is that modulating histone lactylation can selectively control macrophage phenotype, independent of external stimuli.
In Phase I, lactylation writers and erasers will be created.
These are enzymes capable of adding or removing lactylation at specific sites on histones.
First, a detailed map of histone lactylation across macrophage polarization states and external stimuli will be established.
Site-specific lactylation tools will be generated by engineering a dCas9-P300 fusion system to promote lactylation at H3K18 near the ARG1 gene and evolved using a yeast-based screening platform for increased lactylation selectivity.
Histone deacetylase complexes using CRISPR-Cas9 strategies to remove lactylation will be designed and implemented, and the impact on macrophage phenotype assessed.
Key milestones for Phase 1 include validation of lactylation writers and erasers with confirmed selectivity over acetylation and demonstration that these tools can meaningfully regulate macrophage phenotype.
In Phase 2, the functional impact of these new lactylation tools in preclinical cancer models will be evaluated.
Studies will employ lactylation readers and writers to quantitate how lactylation influences tumor-associated macrophage repolarization and how these tools can improve outcomes of chimeric antigen receptor macrophages, using both in vitro and in vivo tumor environments.
In total, this project will advance fundamental understanding of macrophage immunometabolism, provide versatile tools for lactylation engineering, and lay the groundwork for durable macrophage-based therapies for cancer and other immune-mediated diseases.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are not planned for this award.
Macrophages are immune cells that play critical roles in fighting disease, healing tissues, and maintaining overall health.
Their behavior can shift in ways that either help or harm the body, depending on their environment.
Histone lactylation, in which lactate, a small molecule metabolite produced in the body, changes how genes are turned on or off, may help explain how these cells change roles.
This project will use synthetic biology to create precision tools that can add or remove lactylation marks on DNA-packaging proteins.
These tools will help scientists understand how lactylation affects macrophage behavior and could lead to new ways to control immune responses in diseases like cancer.
Course module development and support of undergraduate researchers will help to grow the biomanufacturing workforce.
This project investigates the functional role of histone lactylation in macrophage polarization.
Lactylation has been linked to macrophage transitions from inflammatory (M1) to anti-inflammatory (M2) phenotypes, particularly within the immunosuppressive tumor microenvironment.
The central hypothesis is that modulating histone lactylation can selectively control macrophage phenotype, independent of external stimuli.
In Phase I, lactylation writers and erasers will be created.
These are enzymes capable of adding or removing lactylation at specific sites on histones.
First, a detailed map of histone lactylation across macrophage polarization states and external stimuli will be established.
Site-specific lactylation tools will be generated by engineering a dCas9-P300 fusion system to promote lactylation at H3K18 near the ARG1 gene and evolved using a yeast-based screening platform for increased lactylation selectivity.
Histone deacetylase complexes using CRISPR-Cas9 strategies to remove lactylation will be designed and implemented, and the impact on macrophage phenotype assessed.
Key milestones for Phase 1 include validation of lactylation writers and erasers with confirmed selectivity over acetylation and demonstration that these tools can meaningfully regulate macrophage phenotype.
In Phase 2, the functional impact of these new lactylation tools in preclinical cancer models will be evaluated.
Studies will employ lactylation readers and writers to quantitate how lactylation influences tumor-associated macrophage repolarization and how these tools can improve outcomes of chimeric antigen receptor macrophages, using both in vitro and in vivo tumor environments.
In total, this project will advance fundamental understanding of macrophage immunometabolism, provide versatile tools for lactylation engineering, and lay the groundwork for durable macrophage-based therapies for cancer and other immune-mediated diseases.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are not planned for this award.
Awardee
Funding Goals
THE GOAL OF THIS FUNDING OPPORTUNITY, "BIOMEDICAL RESEARCH INITIATIVE FOR NEXT-GEN BIOTECHNOLOGIES - SYNBIO CONTROL", IS IDENTIFIED IN THE LINK: HTTPS://WWW.NSF.GOV/PUBLICATIONS/PUB_SUMM.JSP?ODS_KEY=NSF24603
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Newark,
Delaware
19713-1324
United States
Geographic Scope
Single Zip Code
University Of Delaware was awarded
Project Grant 2514394
worth $300,000
from the Division of Chemical, Bioengineering, Environmental, and Transport System in September 2025 with work to be completed primarily in Newark Delaware United States.
The grant
has a duration of 2 years and
was awarded through assistance program 47.041 Engineering.
The Project Grant was awarded through grant opportunity Biomedical Research Initiative for Next-Gen BioTechnologies - SynBio Control.
Status
(Ongoing)
Last Modified 8/21/25
Period of Performance
9/1/25
Start Date
8/31/27
End Date
Funding Split
$300.0K
Federal Obligation
$0.0
Non-Federal Obligation
$300.0K
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
2514394
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Public/State Controlled Institution Of Higher Education
Awarding Office
490702 DIVISION OF CHEMICAL BIOENGINEERING
Funding Office
490702 DIVISION OF CHEMICAL BIOENGINEERING
Awardee UEI
T72NHKM259N3
Awardee CAGE
015X1
Performance District
DE-00
Senators
Thomas Carper
Christopher Coons
Christopher Coons
Modified: 8/21/25