MASSACHUSETTS GENERAL HOSPITAL, THE
Many bacterial pathogens utilize toxins to cause serious disease. For instance, anthrax lethal toxin (LeTx) is one of the primary virulence factors that Bacillus anthracis utilizes to subvert the host immune system and induce cell death, resulting in a rapid onset of death that is often untreatable with modern medicine, as demonstrated by the 45 percent case-fatality rate among patients with inhalation anthrax during the 2001 attacks. There is an urgent need for a better understanding of the mechanism of anthrax LeTx and corresponding drugs to inhibit these processes. I propose to identify host cellular factors required for toxin entry and toxin-induced cell death using a LeTx macrophage viability model and the complementary approaches of chemical genetics and RNAi. I will conduct a chemical high-throughput screen in macrophages to identify small molecule inhibitors of LeTx-induced cell death. I will prioritize inhibitors according to their potency and activities in secondary assays designed to determine what host pathways or events are inhibited, such as those involved in toxin cell entry or toxicity once the toxin enters the cell. Small molecules with known host targets will be further evaluated using RNAi and structurally different compounds that target the same protein. Alternatively, the best compounds with no known target will be applied to affinity chromatography to identify their host targets, which will help determine their mechanisms of action. We have successfully conducted pilot chemical and RNAi HTS assays that have identified promising leads, indicating that larger screens will likely succeed. The long-term goal of this application is to gain insight into the general biology of toxin translocation and toxicity mechanisms, and the specific biology of anthrax toxin. Accomplishing the proposed aims will illuminate the molecular basis of LeTx entry and toxicity in macrophages and yield small molecules that will serve both as tools to probe LeTx biology as well as proof-of-concept leads for the development of novel therapeutics. This research may lead to new paradigms in host-targeted therapeutics that circumvent the growing problem of antibiotic resistance of important infectious diseases. PUBLIC HEALTH RELEVANCE: Many bacterial pathogens produce toxins that cause serious disease including cholera, tetanus, botulism, diphtheria, and anthrax and often share key steps in cell entry and cell death processes that rely on host proteins. I propose to use an anthrax lethal toxin-induced cell death model to identify host proteins and pathways co-opted by toxins. This work will illuminate the molecular mechanisms underlying resultant pathology and may provide clues for how to combat toxin-related diseases.
| AWARD OVERVIEW |
| Award Number |
1F32AI084323-01 |
Funding Agency |
Department of Health and Human Services |
| Total Award Amount |
$102,208 |
Project Location - City |
Boston |
| Award Date |
07/17/2009 |
Project Location - State |
MA |
| Project Status |
Completed |
Project Location - Zip |
02114-0000
|
| Jobs Reported |
0.97 |
Congressional District |
09 |
| Project Location - Country |
US |
|
|
Recipient Information
(Grants)
| Recipient Information (Grants) |
|
Recipient Name
|
MASSACHUSETTS GENERAL HOSPITAL, THE |
| Recipient DUNS Number |
073130411
|
| Recipient Address |
55 FRUIT ST |
| Recipient City |
BOSTON |
| Recipient State |
Massachusetts |
| Recipient Zip |
02114-2621 |
| Recipient Congressional District |
09 |
| Recipient Country |
USA |
Required to Report Top 5
Highly Compensated Officials |
No |
Projects and Jobs Information
| Projects and Jobs Information |
| Project Title |
Identifying Host-Factors Required for Toxin Entry and Toxicity |
| Project Status |
Completed |
| Final Project Report Submitted |
Yes |
| Project Activities Description |
General Medical and Surgical Hospitals |
| Quarterly Activities/Project Description |
We have now completed a high-throughput small molecule screen for inhibitors of anthrax lethal toxin (LeTx)-induced macrophage cell death. We selected approximately 150 of these small molecule hits to retest and found that approximately 75% of them retested. We sorted these compounds into upstream (entry of toxin) or downstream (effect of toxin once inside cell) inhibitors using several secondary assays. One of these assays uses a fusion protein containing the N-terminus of lethal factor and the active component of diphtheria toxin (LFn-DTA), which enters macrophages through the same protective antigen (PA)-dependent mechanism as LF, but kills the cells using a different mechanism. This allows the decoupling of toxin entry from toxin mechanism of killing. Another assay we utilized involved incubating cells with edema factor (EF) and PA and assaying for the entry of EF (an adenylate cyclase) into cells by quantifying cellular cAMP levels. We are currently in the process of testing the compounds in multiple secondary assays, including PA pore-formation, endosome acidification, LF refolding, LF activity within the cell, proteasome activity, and caspase-1 activation. We have found 2 compounds that act downstream of LeTx cell entry, yet do not inhibit any of the known host processes, including proteasome and caspase-1 activity. We conducted SAR on these compounds to determine if they can be modified such that a linker could be added to attach them to agarose beads without loss of activity. We have successfully synthesized a compound based on one of the original hits, that has a COOH group to attach to a bead and use for target ID. We are currently analyzing proteomic data from a SILAC experiment with this compound. We also identified a compound that appears to inhibit the proteasome pathway, but does not directly inhibit the proteasome. We have biotinylated this compound and are attempting to identify its relevant target to determine mode of action. |
| Jobs Created |
0.97 |
| Description of Jobs Created |
Many bacterial pathogens produce toxins that cause serious disease including cholera, tetanus, botulism, diphtheria, and anthrax. These toxins cause host damage by evolving to hijack host factors and can thus be used to probe the biology of host cellular processes. For example, anthrax lethal toxin (LeTx) co-opts host cell factors to enter and induce macrophage cell death through unknown mechanisms. Studying anthrax LeTx function could provide significant insight into general upstream events necessary for toxin entry (e.g. receptor-mediated endocytosis, lipid-raft biology, chaperonin function), and downstream events induced by toxin activity once inside the host cell (e.g. signaling pathways, inflammasome formation, cell death events). From a pilot high-throughput chemical screen, we identified both upstream and downstream inhibitors of LeTx-induced macrophage cell death, demonstrating that our system has the potential to reveal novel insights into host biological mechanisms. Also, we identified small molecules that are LeTx inhibitors with known mechanisms, allowing the potential to rapidly assess the role of the identified host factors in LeTx biology. I propose to examine host cellular processes required for toxin entry and toxin-induced cell death. I will use an anthrax LeTx model and the complementary approaches of chemical genetics and RNAi. The discovery of protective small molecules, along with the identification of their cellular targets and mechanisms of protection, will lead to a deeper understanding of the biology of toxin trafficking and toxin-induced cell death. Furthermore, this research may lead to new paradigms in host-targeted therapeutics that circumvent the growing problem of antibiotic resistance of important infectious diseases. |
Purchaser Information
(Grants)
| Purchaser Information |
| Contracting Office ID |
Not Reported |
| Contracting Office Name |
Not Available |
| Contracting Office Region |
Not Available |
| TAS Major Program |
75-0900 |
| Award Information |
| Award Date |
07/17/2009 |
| Award Number |
1F32AI084323-01 |
| Order Number |
|
| Award Type |
Grants |
| Funding Agency ID |
75 |
| Funding Agency Name |
Department of Health and Human Services |
| Funding Office Name |
Not Available |
| Awarding Agency ID |
75 |
| Awarding Agency Name |
Department of Health and Human Services |
| Amount of Award |
$102,208 |
| Funds Invoiced/Received |
$102,208 |
| Expenditure Amount |
$102,208 |
| Infrastructure Expenditure Amount |
$0 |
| Infrastructure Purpose and Rationale |
Not Reported |
| Infrastructure Point of Contact Name |
Not Reported |
| Infrastructure Point of Contact Email |
Not Reported |
| Infrastructure Point of Contact Phone |
Not Reported |
| Infrastructure Point of Contact Address |
Not Reported |
| Infrastructure Point of Contact City |
Not Reported |
| Infrastructure Point of Contact State |
Not Reported |
| Infrastructure Point of Contact Zip |
Not Reported |
Product or Service Information
(Grants)
| Product or Service Information |
| Primary Activity Code |
622110 |
| Activity Description |
General Medical and Surgical Hospitals |
| Sub-Awards Information |
| Sub-awards to Organizations |
0 |
| Sub-award Amounts to Organizations |
$0 |
| Sub-Awards to Individuals |
0 |
| Sub-Award Amounts to Individuals |
$0 |
| Number of Sub-awards less than $25,000/award |
0 |
| Amount of Sub-awards less than $25,000/award |
$0 |
| Number of payments to vendors greater than $25,000 |
0 |
| Total Amount of payments to vendors greater than $25,000/award |
$0 |
| Number of payments to vendors less than $25,000/award |
60 |
| Total Amount of payments to vendors less than $25,000/award |
$15,927 |
| Location Information |
| Latitude, Longitude |
42º 21' 44",
-71º 4' 11" |
| Congressional District |
09 |
| Address 1 |
55 Fruit Street |
| Address 2 |
|
| City |
Boston |
| County |
Suffolk |
| State |
MA |
| Zip |
02114-0000 |
|
 |