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Proteasome – Directed Novel Myeloma Therapies

Description
Multiple myeloma (MM) affected 14,400 new individuals in the United States in 2001, with 50,000 total patients, and remains incurable despite conventional and high dose therapies. In order to overcome resistance to current therapies and improve patient outcome, novel biologically-based treatment approaches are needed which target mechanisms whereby MM cells grow and survive in the BM. Our preliminary in vitro studies show that proteasome inhibitor PS-341 mediates apoptosis of resistant MM cells, inhibits binding of MM cells to bone marrow (BM) stromal cells, and inhibits growth and survival cytokines in the BM milieu. This agent also decreases tumor cell growth and prolongs survival in a murine model, and phase II clinical trials demonstrate remarkable clinical activity, even complete responses, in patients with refractory relapsed disease. In this context, we propose to define the molecular mechanism whereby these agents mediate anti-MM activity, as well as mechanisms conferring resistance to these novel agents. To achieve this goal, we will define the role of the ubiquitin-proteasome pathway in MM pathogenesis and therapy (Specific Aim 1); define the molecular sequelae of proteasome inhibitor treatment in MM cells in vitro (Specific Aim 2); evaluate XBP-1 as a target of proteasome inhibitor therapy (Specific Aim 3); and evaluate response and resistance mechanisms to proteasome inhibitors in vivo using animal models and in derived clinical trials (Specific Aim 4). These studies will not only provide for improved use of currently available proteasome inhibitors, but will provide the framework for development of more potent and less toxic targeted therapies.

Specific Aims

To define the role of the ubiquitin-proteasome pathway in MM pathogenesis and therapy
To define the molecular sequelae of proteasome inhibition in MM cells in vitro
To evaluate XBP-1 as a target of proteasome inhibitor therapy
To evaluate response and resistance to proteasome inhibitors in vivo in animal models and in derived clinical trials

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SPOREs Myeloma Projects Proteasome – Directed Novel Myeloma Therapies Description Multiple myeloma (MM) affected 14,400 new individuals in the United States in 2001, with 50,000 total patients, and remains incurable despite conventional and high dose therapies. In order to overcome resistance to current therapies and improve patient outcome, novel biologically-based treatment approaches are needed which target mechanisms whereby MM cells grow and survive in the BM. Our preliminary in vitro studies show that proteasome inhibitor PS-341 mediates apoptosis of resistant MM cells, inhibits binding of MM cells to bone marrow (BM) stromal cells, and inhibits growth and survival cytokines in the BM milieu. This agent also decreases tumor cell growth and prolongs survival in a murine model, and phase II clinical trials demonstrate remarkable clinical activity, even complete responses, in patients with refractory relapsed disease. In this context, we propose to define the molecular mechanism whereby these agents mediate anti-MM activity, as well as mechanisms conferring resistance to these novel agents. To achieve this goal, we will define the role of the ubiquitin-proteasome pathway in MM pathogenesis and therapy (Specific Aim 1); define the molecular sequelae of proteasome inhibitor treatment in MM cells in vitro (Specific Aim 2); evaluate XBP-1 as a target of proteasome inhibitor therapy (Specific Aim 3); and evaluate response and resistance mechanisms to proteasome inhibitors in vivo using animal models and in derived clinical trials (Specific Aim 4). These studies will not only provide for improved use of currently available proteasome inhibitors, but will provide the framework for development of more potent and less toxic targeted therapies. Specific Aims To define the role of the ubiquitin-proteasome pathway in MM pathogenesis and therapy To define the molecular sequelae of proteasome inhibition in MM cells in vitro To evaluate XBP-1 as a target of proteasome inhibitor therapy To evaluate response and resistance to proteasome inhibitors in vivo in animal models and in derived clinical trials back	Breast Gastrointestinal Cancers Lung Myeloma Projects Cores Ovarian Prostate Renal Skin
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