Grants and Contracts Details
Description
Heart disease is a major dose limiting factor of cancer therapy that uses anthracycline as a component
of the protocol. Generation of reactive oxygen species (ROS) has been implicated in the toxicity of a large
number of therapeutic agents including those containing the redox cycling groups. The goal of this study is
to identify novel mechanisms that lead to cardioprotection during cancer treatment. Our studies of animal
and isolated cardiomyocytes indicate that overexpression of the mitochondrial antioxidant enzyme
manganese containing superoxide dismutase (MnSOD) protects the heart against adriamycin (ADR)-induced
cardiac injury. Interestingly, ADR treatment leads to an increase in circulating levels of tumor necrosis factor
alpha (TNF), a pleiotropic cytokine that has also been shown to produce ROS. We also found that ADR-
induced cardiac injury is associated with translocation of p53 to the mitochondria and interaction of p53 with
MnSOD. Based on these novel findings we hypothesize that ADR toxicity is the result of a cascade that
involves ADR producing direct oxidative stress that sequentially leads to TNF production and amplification of
oxidative stress in mitochondria. To test this hypothesis, cardiac tissue and cardiomyocytes isolated from
MnSOD deficient, wild type, and mice overexpressing MnSOD as well as p53 deficient, p53 deficient with
MnSOD deficient, and p53 deficient overexpressing MnSOD mice of the same inbred background will be
used as models. Aims 1 and 2 will test the hypothesis that ADR toxicity is the result of a cascade that
involves ADR and its metabolites producing direct oxidative stress that sequentially leads to TNF production
and amplification of oxidative stress in heart tissues and in cardiomyocytes. Aim 3 will test the hypothesis
that oxidative stress initiated in mitochondria serves as a death signal, which regulates p53 translocation and
its mitochondrial-mediated transcription dependent and independent pathways. Aim 4 will test the
hypothesis that selective modulation of cellular antioxidant status or TNF levels alters ADR-induced cardiac
injury in experimental therapeutic settings. The results from these studies will provide importantinsights for
mechanistic-based pharmacological interventions to reduce cancer therapy-associated cardiac injury.
Because the extensive use of ADR, translation of these findings will not only improve the quality of life but
will also enhance the probability of cancer free survival for a large number of cancer patients.
Status | Finished |
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Effective start/end date | 9/25/08 → 7/31/15 |
Funding
- National Cancer Institute: $1,333,800.00
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