U01CA265709
Cooperative Agreement
Overview
Grant Description
Personalization and failure testing of dual switch gene drives in lung cancer - project summary
Different patients with non-small-cell lung cancers (NSCLC) can harbor mutations that result in constitutively activated versions of tyrosine kinases (e.g. EGFR, RET, ALK, ROS1, TRK) that can be precisely targeted with inhibitors. However, tyrosine kinase inhibitors are vulnerable to existing, known and unknown, drug resistance mechanisms found in tumors. This results in a game of molecular "whack-a-mole" whereby, resistance evolution appears, the mechanism is isolated, drugs are administered to combat that drug resistance, and then resistance re-emerges until no effective therapies remain.
This process of reverse engineering drug resistance has been a losing battle with a high cost for patients. A promising approach to combat the challenge of resistance evolution is to design and test cell therapies that can sense the therapeutic environment and respond through synthetic biology circuits to reproducibly control evolutionary trajectories.
We propose a synthetic biological technology with proof-of-concept function in mammalian cells that we term "dual-switch selection drives". These drives use inducible drug resistance to create a cell therapy that can engineer a tumor's evolution in situ. The first switch senses the presence of a dimerizer molecule to create reversible drug resistance. Using the mathematical rules of biophysics and evolution, our cell therapy calculates a response to small molecules and produces a tunable amount of cellular fitness that competes with pre-existing drug resistance variants in a tumor.
A second switch with a suicide gene payload hitchhikes on this evolution guided cell therapy until the selection drive cells comprise the majority of the tumor. Then, at the flip of a second switch, a locally diffusible toxin is produced that kills all cells--gene drive or pre-existing resistance mutants of any molecular origin--through a bystander effect.
This technology works with the existing standard of care drugs in NSCLC to produce localized combination therapy that can eradicate pre-existing resistance regardless of the molecular mechanism. Therefore, instead of responding to and combating evolution, we use forward engineering of cell therapies to direct evolution.
In Aim 1, we will use nonintuitive insights from stochastic models of the evolutionary stability of our designs to propose further optimized selection drives. Aim 2 expands our forward engineering approach by pushing our model-driven design of safety and efficacy towards the spatial, cellular, and microenvironmental heterogeneity present in NSCLC. Aim 3 proposes to move evolutionary proof-of-concept experiments into primary human organoids from NSCLC patients with activating mutations in EGFR.
Beyond practical testing of a technology, we will also "build to understand" the basic cancer biology of resistance evolution.
Different patients with non-small-cell lung cancers (NSCLC) can harbor mutations that result in constitutively activated versions of tyrosine kinases (e.g. EGFR, RET, ALK, ROS1, TRK) that can be precisely targeted with inhibitors. However, tyrosine kinase inhibitors are vulnerable to existing, known and unknown, drug resistance mechanisms found in tumors. This results in a game of molecular "whack-a-mole" whereby, resistance evolution appears, the mechanism is isolated, drugs are administered to combat that drug resistance, and then resistance re-emerges until no effective therapies remain.
This process of reverse engineering drug resistance has been a losing battle with a high cost for patients. A promising approach to combat the challenge of resistance evolution is to design and test cell therapies that can sense the therapeutic environment and respond through synthetic biology circuits to reproducibly control evolutionary trajectories.
We propose a synthetic biological technology with proof-of-concept function in mammalian cells that we term "dual-switch selection drives". These drives use inducible drug resistance to create a cell therapy that can engineer a tumor's evolution in situ. The first switch senses the presence of a dimerizer molecule to create reversible drug resistance. Using the mathematical rules of biophysics and evolution, our cell therapy calculates a response to small molecules and produces a tunable amount of cellular fitness that competes with pre-existing drug resistance variants in a tumor.
A second switch with a suicide gene payload hitchhikes on this evolution guided cell therapy until the selection drive cells comprise the majority of the tumor. Then, at the flip of a second switch, a locally diffusible toxin is produced that kills all cells--gene drive or pre-existing resistance mutants of any molecular origin--through a bystander effect.
This technology works with the existing standard of care drugs in NSCLC to produce localized combination therapy that can eradicate pre-existing resistance regardless of the molecular mechanism. Therefore, instead of responding to and combating evolution, we use forward engineering of cell therapies to direct evolution.
In Aim 1, we will use nonintuitive insights from stochastic models of the evolutionary stability of our designs to propose further optimized selection drives. Aim 2 expands our forward engineering approach by pushing our model-driven design of safety and efficacy towards the spatial, cellular, and microenvironmental heterogeneity present in NSCLC. Aim 3 proposes to move evolutionary proof-of-concept experiments into primary human organoids from NSCLC patients with activating mutations in EGFR.
Beyond practical testing of a technology, we will also "build to understand" the basic cancer biology of resistance evolution.
Funding Goals
TO DEVELOP THE MEANS TO CURE AS MANY CANCER PATIENTS AS POSSIBLE AND TO CONTROL THE DISEASE IN THOSE PATIENTS WHO ARE NOT CURED. CANCER TREATMENT RESEARCH INCLUDES THE DEVELOPMENT AND EVALUATION OF IMPROVED METHODS OF CANCER TREATMENT THROUGH THE SUPPORT AND PERFORMANCE OF BOTH FUNDAMENTAL AND APPLIED LABORATORY AND CLINICAL RESEARCH. RESEARCH IS SUPPORTED IN THE DISCOVERY, DEVELOPMENT, AND CLINICAL TESTING OF ALL MODES OF THERAPY INCLUDING: SURGERY, RADIOTHERAPY, CHEMOTHERAPY, AND BIOLOGICAL THERAPY INCLUDING MOLECULARLY TARGETED THERAPIES, BOTH INDIVIDUALLY AND IN COMBINATION. IN ADDITION, RESEARCH IS CARRIED OUT IN AREAS OF NUTRITIONAL SUPPORT, STEM CELL AND BONE MARROW TRANSPLANTATION, IMAGE GUIDED THERAPIES AND STUDIES TO REDUCE TOXICITY OF CYTOTOXIC THERAPIES, AND OTHER METHODS OF SUPPORTIVE CARE THAT MAY SUPPLEMENT AND ENHANCE PRIMARY TREATMENT. SMALL BUSINESS INNOVATION RESEARCH (SBIR) PROGRAM: TO EXPAND AND IMPROVE THE SBIR PROGRAM, 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. SMALL BUSINESS TECHNOLOGY TRANSFER (STTR) PROGRAM: TO STIMULATE AND 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
University Park,
Pennsylvania
16802
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 1973% from $125,000 to $2,591,489.
The Pennsylvania State University was awarded
Personalization and Failure Testing of Dual Switch Gene Drives in Lung Cancer
Cooperative Agreement U01CA265709
worth $2,591,489
from National Cancer Institute in September 2021 with work to be completed primarily in University Park Pennsylvania United States.
The grant
has a duration of 5 years and
was awarded through assistance program 93.395 Cancer Treatment Research.
The Cooperative Agreement was awarded through grant opportunity Collaborative Approaches to Engineer Biology for Cancer Applications (U01 Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 9/24/25
Period of Performance
9/10/21
Start Date
8/31/26
End Date
Funding Split
$2.6M
Federal Obligation
$0.0
Non-Federal Obligation
$2.6M
Total Obligated
Activity Timeline
Subgrant Awards
Disclosed subgrants for U01CA265709
Transaction History
Modifications to U01CA265709
Additional Detail
Award ID FAIN
U01CA265709
SAI Number
U01CA265709-1604902485
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Other
Awarding Office
75NC00 NIH National Cancer Institute
Funding Office
75NC00 NIH National Cancer Institute
Awardee UEI
NPM2J7MSCF61
Awardee CAGE
7A720
Performance District
PA-15
Senators
Robert Casey
John Fetterman
John Fetterman
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| National Cancer Institute, National Institutes of Health, Health and Human Services (075-0849) | Health research and training | Grants, subsidies, and contributions (41.0) | $815,037 | 77% |
| National Institute of Biomedical Imaging and Bioengineering, National Institutes of Health, Health and Human Services (075-0898) | Health research and training | Grants, subsidies, and contributions (41.0) | $250,000 | 23% |
Modified: 9/24/25