R01AI177635
Project Grant
Overview
Grant Description
Hijacking Plasmodium Ubiquitin-Proteasome System to Defeat Drug Resistance - Project Summary/Abstract
In 2020, with over 250 million debilitating cases and over half a million deaths, mostly in young children, malaria is a persistent global health crisis. The malaria-causing parasite Plasmodium falciparum (PF) has developed resistance to most antimalarial drugs deployed, including the backbone artemisinins (ARTs). ART and its semi-synthetic analogs are considered essential for malaria treatment.
ARTs are prodrugs that are activated within the parasites to form a reactive radical that covalently attacks proteins, lipids, and other cellular constituents. ART resistance is widespread in Southeast Asia and has been reported in Africa. ART combination therapy (ACT) is a mainstay for treatment of malaria, but its efficacy can be derailed when a two-drug combination becomes de facto monotherapy. Moreover, extended exposure of PF to ACTs induces multidrug tolerance.
We recently showed that inhibitors specific for the PF proteasome (PF20S) kill PF in each stage of its life cycle and synergize with ART, overcoming ART resistance. This proposal builds on our discovery that a covalent hybrid of an ART analogue and a PF20S inhibitor that we call an artezomib (ATZ) can enhance ART action and overcome resistance to each of its components. We have synthesized ATZs that are more potent PF20S inhibitors than their component PF20S inhibitor. They not only kill wild type and ART-resistant (K13 mutant) PF, PF with proteasome mutations that confer resistance to the PF20S inhibitor, but also kill PF that expresses both ART-resistant and PI-resistant mutations.
We propose the following mechanism by which ATZs overcome resistance to the PF20S inhibitor within them: we found that upon activation of ATZ in the parasites, the ART component binds PF proteins, like activated ART itself. The PF ubiquitin proteasome system digests ATZ-bound proteins into oligopeptides, some of which display the PF inhibitor component of the ATZ. We hypothesize that extended contact of ATZ-bearing peptides within the PF20S active site augments the binding of the PF20S inhibitor component of the ATZ, overcoming the decreased binding otherwise conferred by PF20S point mutations. Thus, an ATZ can overcome resistance to each of its components.
In mouse models of malaria, an ATZ drove P. berghei below the limit of detection and suppressed recrudescence of a P. berghei ART-resistant K13 mutant and doing so better than ART.
In Aim 1 of this proposal, we will conduct lead optimization to improve ATZs' potency, selectivity, and ATZs' pharmacokinetic properties. In Aim 2, we will explore ATZs' mechanism of action; attempt to select for ATZ-resistant parasites; determine the frequency and mechanism of resistance, if any; and study antimalarial activity of ATZs in stages of the PF life cycle when ART alone is ineffective. Aim 3 will test the efficacy of ATZs in mice, including humanized mice infected with PF.
In 2020, with over 250 million debilitating cases and over half a million deaths, mostly in young children, malaria is a persistent global health crisis. The malaria-causing parasite Plasmodium falciparum (PF) has developed resistance to most antimalarial drugs deployed, including the backbone artemisinins (ARTs). ART and its semi-synthetic analogs are considered essential for malaria treatment.
ARTs are prodrugs that are activated within the parasites to form a reactive radical that covalently attacks proteins, lipids, and other cellular constituents. ART resistance is widespread in Southeast Asia and has been reported in Africa. ART combination therapy (ACT) is a mainstay for treatment of malaria, but its efficacy can be derailed when a two-drug combination becomes de facto monotherapy. Moreover, extended exposure of PF to ACTs induces multidrug tolerance.
We recently showed that inhibitors specific for the PF proteasome (PF20S) kill PF in each stage of its life cycle and synergize with ART, overcoming ART resistance. This proposal builds on our discovery that a covalent hybrid of an ART analogue and a PF20S inhibitor that we call an artezomib (ATZ) can enhance ART action and overcome resistance to each of its components. We have synthesized ATZs that are more potent PF20S inhibitors than their component PF20S inhibitor. They not only kill wild type and ART-resistant (K13 mutant) PF, PF with proteasome mutations that confer resistance to the PF20S inhibitor, but also kill PF that expresses both ART-resistant and PI-resistant mutations.
We propose the following mechanism by which ATZs overcome resistance to the PF20S inhibitor within them: we found that upon activation of ATZ in the parasites, the ART component binds PF proteins, like activated ART itself. The PF ubiquitin proteasome system digests ATZ-bound proteins into oligopeptides, some of which display the PF inhibitor component of the ATZ. We hypothesize that extended contact of ATZ-bearing peptides within the PF20S active site augments the binding of the PF20S inhibitor component of the ATZ, overcoming the decreased binding otherwise conferred by PF20S point mutations. Thus, an ATZ can overcome resistance to each of its components.
In mouse models of malaria, an ATZ drove P. berghei below the limit of detection and suppressed recrudescence of a P. berghei ART-resistant K13 mutant and doing so better than ART.
In Aim 1 of this proposal, we will conduct lead optimization to improve ATZs' potency, selectivity, and ATZs' pharmacokinetic properties. In Aim 2, we will explore ATZs' mechanism of action; attempt to select for ATZ-resistant parasites; determine the frequency and mechanism of resistance, if any; and study antimalarial activity of ATZs in stages of the PF life cycle when ART alone is ineffective. Aim 3 will test the efficacy of ATZs in mice, including humanized mice infected with PF.
Funding Goals
NOT APPLICABLE
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
New York,
New York
100654805
United States
Geographic Scope
Single Zip Code
Related Opportunity
Analysis Notes
Amendment Since initial award the total obligations have increased 310% from $752,693 to $3,084,139.
Weill Medical College Of Cornell University was awarded
Defeating Malaria Drug Resistance: Enhancing Antimalarial Action with Artezomib
Project Grant R01AI177635
worth $3,084,139
from the National Institute of Allergy and Infectious Diseases in July 2023 with work to be completed primarily in New York New York United States.
The grant
has a duration of 5 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 7/6/26
Period of Performance
7/1/23
Start Date
6/30/28
End Date
Funding Split
$3.1M
Federal Obligation
$0.0
Non-Federal Obligation
$3.1M
Total Obligated
Activity Timeline
Subgrant Awards
Disclosed subgrants for R01AI177635
Transaction History
Modifications to R01AI177635
Additional Detail
Award ID FAIN
R01AI177635
SAI Number
R01AI177635-2571871415
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
YNT8TCJH8FQ8
Awardee CAGE
1UMU6
Performance District
NY-12
Senators
Kirsten Gillibrand
Charles Schumer
Charles Schumer
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| National Institute of Allergy and Infectious Diseases, National Institutes of Health, Health and Human Services (075-0885) | Health research and training | Grants, subsidies, and contributions (41.0) | $752,693 | 100% |
Modified: 7/6/26