Heat Shock Proteins and Cytoprotection Atp-Deprived Mammalian Cells
| Main Authors: | , |
|---|---|
| Format: | eBook |
| Language: | English |
| Published: |
New York, NY
Springer US
1997, 1997
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| Edition: | 1st ed. 1997 |
| Series: | Molecular Biology Intelligence Unit
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| Subjects: | |
| Online Access: | |
| Collection: | Springer Book Archives -2004 - Collection details see MPG.ReNa |
Table of Contents:
- 4.2. Ischemia-Induced HSP Synthesis in the Heart
- 4.3. Stress Protein Expression in Post-Ischemic Brain
- 4.4. Ischemia-Induced Stress Protein Synthesis in Other Normal Tissues and Tumor Cells
- 4.5. Possible Mechanisms of HSP Accumulation After ATP Depletion
- Concluding Remarks
- 5. Heat Shock Proteins and Cardioresistance to Ischemia
- 5.1. Heat Shock-Induced Cardioresistance to Ischemia/Reperfusion Injury
- 5.2. The Role of Myocardial HSPs in Ischemie Preconditioning
- 5.3. The Cardioresistance Induced by Other Stimuli Can Also Be Associated with HSPs
- 5.4. Evidence for the Involvement of HSP70 in Cardioprotection
- 5.5. Are Other Stress Proteins Cardioprotective?
- Concluding Remarks
- 6. Involvement of Heat Shock Proteins in Protection of Various Normal and Tumor Cells from Ischemic Insult
- 6.1. HSPsand Ischemic Tolerance in the Brain
- 6.2. Ischemic Tolerance in the Kidney
- 6.3. HSPs and Protection from Ischemia of Other Organs and Tissues
- 6.4.
- Concluding Remarks
- 7. What Are the Mechanisms of Heat Shock Protein-Mediated Cytoprotection Under ATP Deprivation?
- 7.1. Two Paradigms of Cell Tolerance to ATP Deprivation: Reduced Injury During the Stress and the Improved Post-Stress Recovery
- 7.2. Chaperoning Under ATP Depletion as a Special Function of HSP70
- 7.3. How Other Stress Proteins Might Maintain the Viability of ATP-Deprived Cells
- 7.4. How Do HSPs Protect Cells against Necrosis during ATP Depletion?
- 8. Mechanisms of Heat Shock Protein-Mediated Protection from Ischemia-Induced Apoptosis
- 8.1. HSPs and Triggering of Apoptosis in Ischemic Cells
- 8.2. HSPs and Transduction of the Apoptotic Signal
- 8.3. HSPs and the Execution of Apoptosis
- 9. Conclusions and Perspectives
- 9.1. Adaptation to Energy Starvation on The Molecular Level
- 9.2. Heat Shock Proteins and Ischemia: Significance for Medicine
- Concluding Remarks
- 1. Heat Shock Proteins and the Regulation of Heat Shock Gene Expression in Eukaryotes
- 1.1. The Family of Stress Proteins and Molecular Chaperones
- 1.2. The Regulation of Heat Shock Gene Expression in Eukaryotes
- Concluding Remarks
- 2. ATP Homeostasis, Ionic Balance and Cell Viability
- 2.1. ATP Homeostasis in Mammalian Cells
- 2.2. Cell Viability and ATP Depletion
- 2.3. Significance of Ionic Imbalance for the Death of ATP-Depleted Cells
- 2.4. Mitochondrial Dysfunction and Damage During Ischemia
- Concluding Remarks
- 3. “Proteotoxicity” of ATP Depletion: Disruption of the Cytoskeleton, Protein Aggregation and Involvement of Molecular Chaperones
- 3.1. The Cytoskeleton Under ATP Deprivation
- 3.2. Protein Aggregation in Energy-Deprived Cells
- 3.3. How Do Heat Shock Proteins Respond to ATP Depletion?
- Concluding Remarks
- 4. ATP Depletion as Inducer of Heat Shock Protein Expression
- 4.1. Anoxia and Mitochondrial Inhibitors Activate HSP Gene Expression