R35CA253175
Project Grant
Overview
Grant Description
Determinants of Response to Cancer Immunotherapy - Project Summary/Abstract
While immunotherapy is transforming cancer treatment, the majority of patients do not achieve durable responses. We have been studying response and resistance to different immune checkpoint inhibitors and are now poised to propose mechanistic studies aimed at providing an understanding of the immune states and pathways that mediate or inhibit response to immune checkpoint blockade.
Using high-dimensional unbiased single-cell RNA-seq (scRNA-seq), we can identify both canonical and non-canonical immune effectors that can mediate anti-tumor responses. We believe that non-canonical effectors such as cytotoxic CD4 T cells, which we have recently described, are not effectively triggered by our current treatments. Using the same single-cell approaches, we can identify both known and novel cell types in cancer patients that can mediate immune suppression.
In our first objective, we will determine whether combination immunotherapies that include drug(s) targeting specific immunosuppressive cells can enhance the function of these cytotoxic CD4+ T cells. By leveraging neoadjuvant clinical trials where patients receive immunotherapy prior to surgery, we will use single-cell genomics and proteomics to define whether these combinations can 1) target the desired immunosuppressive mechanisms, and 2) enhance canonical and/or non-canonical effectors within the resected tumors. We will also use this approach to determine whether we can map these specific cell states into the circulating compartment.
The second objective is based on a longstanding interest in our group to define the dynamics of antigen-specific responses. Using single-cell T cell receptor sequencing, we can identify expanded T cell clones as well as follow their localization. In addition to understanding how immunotherapy combinations induce and modulate specific T cell clonotypes within the tumor, we can determine how immunotherapies can induce functional plasticity to desired or undesired states.
The third objective builds on our 20-year experience using mouse models to dissect mechanisms underlying response or resistance to immunotherapy. We will determine the functional significance of non-canonical immune effectors using depletion and knock-out strategies. We will also determine how combination immunotherapies can elicit both effective or ineffective anti-tumor immune responses, thereby guiding the design of future clinical trials.
In conclusion, our proposal is based on hypothesis-driven bench-to-bedside and bedside-to-bench mechanistic studies with the goal of advancing cancer immunotherapy. With our deep expertise in this field, experience leading multi-disciplinary teams focused on translational research, and a rich network of basic science and clinical collaborators, we are uniquely positioned to succeed in the research plan outlined in this proposal.
While immunotherapy is transforming cancer treatment, the majority of patients do not achieve durable responses. We have been studying response and resistance to different immune checkpoint inhibitors and are now poised to propose mechanistic studies aimed at providing an understanding of the immune states and pathways that mediate or inhibit response to immune checkpoint blockade.
Using high-dimensional unbiased single-cell RNA-seq (scRNA-seq), we can identify both canonical and non-canonical immune effectors that can mediate anti-tumor responses. We believe that non-canonical effectors such as cytotoxic CD4 T cells, which we have recently described, are not effectively triggered by our current treatments. Using the same single-cell approaches, we can identify both known and novel cell types in cancer patients that can mediate immune suppression.
In our first objective, we will determine whether combination immunotherapies that include drug(s) targeting specific immunosuppressive cells can enhance the function of these cytotoxic CD4+ T cells. By leveraging neoadjuvant clinical trials where patients receive immunotherapy prior to surgery, we will use single-cell genomics and proteomics to define whether these combinations can 1) target the desired immunosuppressive mechanisms, and 2) enhance canonical and/or non-canonical effectors within the resected tumors. We will also use this approach to determine whether we can map these specific cell states into the circulating compartment.
The second objective is based on a longstanding interest in our group to define the dynamics of antigen-specific responses. Using single-cell T cell receptor sequencing, we can identify expanded T cell clones as well as follow their localization. In addition to understanding how immunotherapy combinations induce and modulate specific T cell clonotypes within the tumor, we can determine how immunotherapies can induce functional plasticity to desired or undesired states.
The third objective builds on our 20-year experience using mouse models to dissect mechanisms underlying response or resistance to immunotherapy. We will determine the functional significance of non-canonical immune effectors using depletion and knock-out strategies. We will also determine how combination immunotherapies can elicit both effective or ineffective anti-tumor immune responses, thereby guiding the design of future clinical trials.
In conclusion, our proposal is based on hypothesis-driven bench-to-bedside and bedside-to-bench mechanistic studies with the goal of advancing cancer immunotherapy. With our deep expertise in this field, experience leading multi-disciplinary teams focused on translational research, and a rich network of basic science and clinical collaborators, we are uniquely positioned to succeed in the research plan outlined in this proposal.
Awardee
Funding Goals
TO PROVIDE FUNDAMENTAL INFORMATION ON THE CAUSE AND NATURE OF CANCER IN PEOPLE, WITH THE EXPECTATION THAT THIS WILL RESULT IN BETTER METHODS OF PREVENTION, DETECTION AND DIAGNOSIS, AND TREATMENT OF NEOPLASTIC DISEASES. CANCER BIOLOGY RESEARCH INCLUDES THE FOLLOWING RESEARCH PROGRAMS: CANCER CELL BIOLOGY, CANCER IMMUNOLOGY, HEMATOLOGY AND ETIOLOGY, DNA AND CHROMOSOMAL ABERRATIONS, TUMOR BIOLOGY AND METASTASIS, AND STRUCTURAL BIOLOGY AND MOLECULAR APPLICATIONS.
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Seattle,
Washington
981094433
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 485% from $815,497 to $4,773,463.
Fred Hutchinson Cancer Center was awarded
Cancer Immunotherapy Response Mechanisms: Enhancing Immune Effector Function
Project Grant R35CA253175
worth $4,773,463
from National Cancer Institute in August 2021 with work to be completed primarily in Seattle Washington United States.
The grant
has a duration of 7 years and
was awarded through assistance program 93.396 Cancer Biology Research.
The Project Grant was awarded through grant opportunity NCI Outstanding Investigator Award (R35 Clinical Trial Not Allowed).
Status
(Ongoing)
Last Modified 7/21/25
Period of Performance
8/1/21
Start Date
7/31/28
End Date
Funding Split
$4.8M
Federal Obligation
$0.0
Non-Federal Obligation
$4.8M
Total Obligated
Activity Timeline
Transaction History
Modifications to R35CA253175
Additional Detail
Award ID FAIN
R35CA253175
SAI Number
R35CA253175-422704644
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Nonprofit With 501(c)(3) IRS Status (Other Than An Institution Of Higher Education)
Awarding Office
75NC00 NIH National Cancer Institute
Funding Office
75NC00 NIH National Cancer Institute
Awardee UEI
TJFZLPP6NYL6
Awardee CAGE
50WB4
Performance District
WA-07
Senators
Maria Cantwell
Patty Murray
Patty Murray
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) | $1,899,144 | 100% |
Modified: 7/21/25