R01AI196453
Project Grant
Overview
Grant Description
Complement convertase imaging techniques for optimization of complement therapeutic amelioration of antibody mediated rejection - Project summary/abstract
Therapeutic strategies to halt antibody-mediated rejection (AMR) following lung transplantation are lacking, due in large part to the complex pathophysiology of the immune process and the multi-faceted approach that must be taken to establish a defined diagnosis.
It is becoming increasingly clear that AMR has many endotypes, with donor-specific antibodies mediating a host of complement dependent and independent functions.
Thus, the development of strategies to stratify patients based upon endotype has the potential to revolutionize the treatment of AMR.
Pre-clinically, fluorescence imaging has been used to investigate a wide array of diseases and disorders.
In transplantation, the focus has primarily been T cell-mediated rejection, detecting leukocyte trafficking to the graft via phagocyte-specific approaches or fluorogenic probes for inflammatory signatures, such as cathepsin B.
In our own previous work, we developed a fluorogenic probe specific to granzyme B and reported its utility in monitoring therapeutic intervention in a murine model of myocarditis, a surrogate for cardiac transplant rejection.
As such, there is a great unmet need to develop agents capable of non-invasively diagnosing or monitoring AMR.
To this end, we have developed novel fluorogenic probes adept at detecting complement activation in real time, via the examination of complement convertase activity, as opposed to deposition products such as C4d, which persist for weeks at the site of deposition and can only be confirmed by invasive biopsy procedures.
Thus, the goals of this proposal are to develop non- or minimally invasive techniques to image ongoing complement activation in vivo.
To accomplish this, we will use murine models of transplant rejection in concert with an assortment of complement inhibitors that act at different points in the complement activation pathway to characterize the extent to which these probes can determine complement activation.
We will concomitantly examine their efficacy in a novel porcine ex-vivo perfusion system in which human complement activation can be modeled to investigate the potential clinical applicability in the setting of lung transplantation.
To accomplish these goals, we propose the following specific aims: Aim 1: Examination of the extent to which fluorogenic convertase imaging can characterize AMR endotype, and Aim 2: Investigation of the translatability of convertase imaging to the stratification of AMR patients.
On the completion of these studies, we will have validated a cadre of novel protease activatable complement specific imaging agents for use in the examination of AMR.
We will have further dissected the significance of complement pathway specific proteins in mediating and modulating AMR.
By using rodent analogues of clinically available FDA complement inhibitors, should our studies prove efficacious, our results could be rapidly translated.
Therapeutic strategies to halt antibody-mediated rejection (AMR) following lung transplantation are lacking, due in large part to the complex pathophysiology of the immune process and the multi-faceted approach that must be taken to establish a defined diagnosis.
It is becoming increasingly clear that AMR has many endotypes, with donor-specific antibodies mediating a host of complement dependent and independent functions.
Thus, the development of strategies to stratify patients based upon endotype has the potential to revolutionize the treatment of AMR.
Pre-clinically, fluorescence imaging has been used to investigate a wide array of diseases and disorders.
In transplantation, the focus has primarily been T cell-mediated rejection, detecting leukocyte trafficking to the graft via phagocyte-specific approaches or fluorogenic probes for inflammatory signatures, such as cathepsin B.
In our own previous work, we developed a fluorogenic probe specific to granzyme B and reported its utility in monitoring therapeutic intervention in a murine model of myocarditis, a surrogate for cardiac transplant rejection.
As such, there is a great unmet need to develop agents capable of non-invasively diagnosing or monitoring AMR.
To this end, we have developed novel fluorogenic probes adept at detecting complement activation in real time, via the examination of complement convertase activity, as opposed to deposition products such as C4d, which persist for weeks at the site of deposition and can only be confirmed by invasive biopsy procedures.
Thus, the goals of this proposal are to develop non- or minimally invasive techniques to image ongoing complement activation in vivo.
To accomplish this, we will use murine models of transplant rejection in concert with an assortment of complement inhibitors that act at different points in the complement activation pathway to characterize the extent to which these probes can determine complement activation.
We will concomitantly examine their efficacy in a novel porcine ex-vivo perfusion system in which human complement activation can be modeled to investigate the potential clinical applicability in the setting of lung transplantation.
To accomplish these goals, we propose the following specific aims: Aim 1: Examination of the extent to which fluorogenic convertase imaging can characterize AMR endotype, and Aim 2: Investigation of the translatability of convertase imaging to the stratification of AMR patients.
On the completion of these studies, we will have validated a cadre of novel protease activatable complement specific imaging agents for use in the examination of AMR.
We will have further dissected the significance of complement pathway specific proteins in mediating and modulating AMR.
By using rodent analogues of clinically available FDA complement inhibitors, should our studies prove efficacious, our results could be rapidly translated.
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
Chicago,
Illinois
606113015
United States
Geographic Scope
Single Zip Code
Related Opportunity
Northwestern University was awarded
Convertase Imaging for Complement Therapeutic Optimization in AMR
Project Grant R01AI196453
worth $3,267,712
from the National Institute of Allergy and Infectious Diseases in April 2026 with work to be completed primarily in Chicago Illinois 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 4/6/26
Period of Performance
4/1/26
Start Date
3/31/30
End Date
Funding Split
$3.3M
Federal Obligation
$0.0
Non-Federal Obligation
$3.3M
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
R01AI196453
SAI Number
R01AI196453-164772659
Award ID URI
SAI UNAVAILABLE
Awardee Classifications
Private 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
KG76WYENL5K1
Awardee CAGE
01725
Performance District
IL-05
Senators
Richard Durbin
Tammy Duckworth
Tammy Duckworth
Modified: 4/6/26