• Produktbild: Stress Proteins
  • Produktbild: Stress Proteins
Band 136

Stress Proteins

Fr. 359.00

inkl. gesetzl. MwSt., Versandkostenfrei


Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

23.10.2012

Herausgeber

David S. Latchman

Verlag

Springer Berlin

Seitenzahl

422

Maße (L/B/H)

23.5/15.5/2.5 cm

Gewicht

674 g

Auflage

Softcover reprint of the original 1st ed. 1999

Sprache

Englisch

ISBN

978-3-642-63519-9

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

23.10.2012

Herausgeber

David S. Latchman

Verlag

Springer Berlin

Seitenzahl

422

Maße (L/B/H)

23.5/15.5/2.5 cm

Gewicht

674 g

Auflage

Softcover reprint of the original 1st ed. 1999

Sprache

Englisch

ISBN

978-3-642-63519-9

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: GPSR Kontakt

Noch keine Bewertungen vorhanden

Verfassen Sie die erste Bewertung zu diesem Artikel

Helfen Sie anderen Kundinnen und Kunden durch Ihre Meinung.

Kundinnen und Kunden meinen

Bewertungen (0)

  • Produktbild: Stress Proteins
  • Produktbild: Stress Proteins
  • 1 Stress Proteins: An Overview.- A. Introduction.- B. The Stress Proteins.- C. Functions of Stress Proteins.- D. Hsp Expression and Regulation.- E. Stress Proteins and Protection.- F. Stress Proteins and Human Disease.- G. Conclusion.- 2 The Hsp90 Chaperone Family.- A. General Aspects.- B. The Early Protein Folding Complex.- C. Hsp90-Containing Multimolecular Complexes.- I. The Steroid Receptor-Associated Hsp90-Containing Intermediate Folding Complex.- II. The Steroid Receptor-Associated Hsp90-Containing Mature Folding Complex.- D. Individual Chaperone and Co-chaperone Proteins Found in Hsp90 Complexes.- I. Hsp70.- II. p48Hip.- III. p60Hop.- IV. p23.- V. Immunophilins.- VI. Other TPR-Containing Proteins.- VII. p50Cdc37.- E. Refolding of Denatured Proteins.- F. Benzoquinone Ansamycins and Nucleotide Binding to Hsp90.- G. Hsp90 Client Proteins.- I. Transcription Factors.- 1. Steroid Receptors.- 2. Aryl Hydrocarbon Receptor.- 3. Mutated p53.- 4. Heat Shock Factor.- II. Protein Kinases.- 1. Tyrosine Kinases.- a) The Src Family Kinases.- b) Weel Kinase.- c) Sevenless Tyrosine Kinase.- d) Receptor Tyrosine Kinases — pl85erbB2.- 2. Serine/Threonine Kinases.- a) Raf-1 Kinase.- b) Casein Kinase II.- c) Heme-Regulated eIF-2? Kinase (HRI).- d) Cdk4/Cdk6.- III. Other Proteins.- 1. Cytoskeletal Proteins.- 2. Calmodulin.- 3. ss?-Subunits of Trimeric GTP-Binding Proteins.- 4. Proteasome.- 5. Hepadnavirus Reverse Transcriptase.- 6. Tumor Necrosis Factor Receptor and Retinoblastoma Protein.- H. Hsp90 and Drug Development.- I. Conclusion.- References.- 3 Heat Shock Protein 70.- A. Introduction.- B. Expression and Function of hsp70.- I. Hsp70, Transient Thermotolerance and Permanent Heat Resistance.- II. Hsp70 and Apoptosis.- III. Hsp70 Protects Cells from Oxidative Stress.- IV. Hsp70 Protects Cells from X-Ray Damage.- V. Hsp70 as Molecular Chaperone.- C. Regulation of hsp70.- I. Heat Shock Transcription Factor (HSF), the Transcriptional Regulator of hsp70.- II Signal Transduction Leading to Modulation of hsp70 Levels.- III. Negative Regulatory Effect of ERK1 on hsp70 Gene Expression.- IV. Mutational Analysis of HSF-1 Phosphorylation by ERK1 Protein Kinase.- V. Modulation of HSF-1 by Other Protein Kinases.- VI. Implication of HSF-1 Regulation by Functionally Opposing Signaling Cascades.- VII. Regulation of Heat Shock Response: Possible Involvement of Ku Autoantigen.- References.- 4 Mitochondrial Molecular Chaperones hsp60 and mhsp70: Are Their Roles Restricted to Mitochondria?.- A. Introduction.- B. Structure and function.- I. Studies with Purified Proteins.- 1. Hsp70/DnaK.- 2. Hsp60/GroEL.- II. In Vivo and Mitochondrial Systems.- C. Are hsp60 and mhsp70 Restricted to Mitochondria?.- I. Subcellular Localization: The Unexplained Findings.- II. Consideration of Possible Artifacts.- III. Possible Extramitochondrial Functions.- IV. Proposed Transport Mechanisms.- D. Hsp60 in Drug Resistance and Disease.- E. Future Prospects.- References.- 5 Role of Hsp27 and Related Proteins.- A. Introduction.- B. sHsp Genes and Control of Their Expression.- I. The Family of SHsp and the Structure of the Genes Encoding These Proteins.- II. Regulation of the Expression of sHsp Genes by Heat Shock.- III. Regulation of the Constitutive and Hormone-Dependent Expression of sHsp Genes.- IV. Tissue-Specific sHsp Expression During Development and in Adult Organisms.- V. Specific sHsp Expression During Early Differentiation.- VI. Pathological sHsp Expression and Associated Diseases.- C. Biochemical Properties of sHsp.- I. Structural Organization of sHsp.- II. Quaternary Structure of sHsp.- III. Phosphorylation of sHsp.- IV. Cellular Localization of sHsp.- D. Functions of sHsp.- I. sHsp Expression Induces Thermotolerance and Protects Cytoskeletal Architecture.- II. sHsp Act as Protein Chaperones.- III. sHsp Protection Against TNF and Oxidative Stress Inducers.- IV. sHsp Expression Protects Against Apoptosis.- 1. sHsp Interfere with In Vitro-Mediated Apoptosis.- 2. sHsp as Essential Anti-apoptotic Proteins During Early Cell Differentiation.- 3. Molecular Mechanisms Underlying the Anti-apoptotic Function of sHsp.- E. Conclusions.- References.- 6 Ubiquitin and the Stress Response.- A. Introduction.- B. The Ubiquitin-Proteasome Pathway.- C. The Ubiquitin Pathway and the Stress Response.- I. Stress Proteins in the Ubiquitin Pathway.- 1. Ubiquitin.- 2. Ubiquitin-Conjugating Enzymes.- 3. Other Pathway Components.- II. Ubiquitin Conjugation in Stressed Cells.- III. Ubiquitin-Mediated Degradation in Stressed Cells.- IV. The Ubiquitin Pathway and Induction of the Stress Response.- V. Involvement of Molecular Chaperones in Ubiquitin-Dependent Degradation.- D. Outstanding Questions.- References.- 7 Regulation of Heat Shock Genes by Cytokines.- A. Introduction.- B. Cytokines.- C. Transcription Factors Activated by the IL-6 Receptor Family.- I. C/EBPs.- II. STATs.- D. Role of Interleukin-6 Family of Cytokines in Regulating Hsps.- E. Role of IFN-? in Regulating Hsp Expression.- F. Elevation of C/EBPs and STATs and Hsps Expression During Inflammatory Pathological States.- G. Role of IL-6 and Hsps in SLE.- H. Conclusion.- References.- 8 Regulation of Heat Shock Genes by Ischemia.- A. Introduction.- B. Patterns of Heat Shock Gene Expression After Global and Focal Ischemia.- I. Gene Expression and Neuronal Vulnerability After Global Ischemia.- II. Gene Expression After Focal Ischemia.- III. Cryptic hsp72 Expression After Ischemia.- C. Regulation of the Postischemic Heat Shock Response.- I. Injury Thresholds and the Stress Response.- 1. Thresholds for Expression of hsp72 and Other Ischemia-Inducible Genes.- 2. Temperature Effects on hsp72 Expression After Global Ischemia.- II. Heat Shock Factor Activation After Global Ischemia.- III. Heat Shock Regulation After Anoxia/Aglycemia in Hippocampal Slices.- 1. Hsp72 Induction After In Vitro Anoxia/Aglycemia.- 2. Pharmacological Manipulation of hsp72 Expression.- D. Summary and Conclusions.- References.- 9 Regulation of Heat Shock Transcription Factors by Hypoxia or Ischemia/Reperfusion in the Heart and Brain.- A. Introduction.- B. Regulation of Heat Shock Gene Transcription.- I. Family of Heat Shock Factors.- II. Regulation of DNA-Binding Activity of HSF1.- C. Damage by Ischemia and Reperfusion.- I. Ischemia.- II. Reperfusion.- D. Regulation of Hsps by Ischemia/Reperfusion in the Brain and Heart.- I. Induction of Hsps by Ischemia/Reperfusion in the Brain.- II. Induction of Hsps by Ischemia/Reperfusion in the Heart.- E. Regulation of HSF Activation by Hypoxia or Ischemia/Reperfusion.- I. HSF Activation by Hypoxia.- II. HSF Activation by Ischemia in the Brain.- III. HSF Activation by Ischemia/Reperfusion in the Heart.- IV. HSF Activation by Ischemia/Reperfusion in Other Tissues.- F. Ischemic Tolerance by Hsps in the Brain and Heart.- I. Ischemic Tolerance by Hsps in the Brain.- II. Myocardial Protection Against Ischemia by Hsps.- G. Mechanisms of HSF Activation by Hypoxia or Ischemia/Reperfusion.- I. Specific Activation of HSF1 by Hypoxia or Ischemia/Reperfusion.- II. Signals for the Activation of HSF1 by Hypoxia or Ischemia/Reperfusion.- 1. ATP Depletion.- 2. Reactive Oxygen Species.- 3. Arachidonic Acid and Its Metabolites.- 4. Decreased Intracellular pH.- H. Clinical Application and Future Perspective.- References.- 10 Autoregulation of the Heat Shock Response.- A. Introduction.- B. Regulation of the Heat Shock Response in Eukaryotes.- I. Overview.- II. Biochemical Study of Autoregulation in Higher Eukaryotes.- III. Genetic Evidence for Autoregulation of the Heat Shock Response in Yeast and Drosophila.- C. Regulation of the Heat Shock Response in Prokaryotes.- I. Overview.- II. Genetic Evidence for Autoregulation of the E. coli Heat Shock Response.- III. Biochemical Studies on Autoregulation of the E. coli Heat Shock Response.- D. Common Features of the Prokaryotic and Eukaryotic Heat Shock Response.- References.- 11 The Cellular Stress Gene Response in Brain.- A. Introduction.- B. Response of the Brain to Physiologically Relevant Temperature Increase.- I. Differential Induction of Heat Shock mRNA in Different Cell Types of the Hyperthermic Brain.- II. Intracellular Targeting of Neural Heat Shock mRNAs.- III. Cell Type Differences in Neural Heat Shock Proteins.- IV. Expression of Heat Shock Proteins in the Developing Brain.- V. Activation of Neural Heat Shock Transcription Factor HSF1.- VI. In Vivo Transcription Rate of Heat Shock Genes in the Brain.- VII. Neuroprotective Effect of Heat Shock Protein in the Retina.- VIII. Conclusions.- C. Cellular Stress Gene Response to Focal Cerebral Ischemia.- I. Hsp70 and Delineation of the Penumbra.- II. Hsp32 (HO-1) Spreading Depression Mediated Induction in Microglia.- III. Hsp27 Spreading Depression Mediated Induction in Astrocytes.- IV. Glucose Transporters/grp75/grp78: HIF Mediated Induction.- V. Conclusions.- D. Cellular Stress Gene Response to Subarachnoid Hemorrhage.- I. Clinical Syndrome of Subarachnoid Hemorrhage and the Role of HO.- II. Induction of HO-1 Following Experimental Subarachnoid Hemorrhage.- III. Induction of HO-1 Following Subarachnoid Injections of Hemoglobin and Protoporphyrins.- IV. Model for Metabolism of Herne by Microglia, Neurons and Meningeal Cells Following Subarachnoid Hemorrhage.- References.- 12 Heat Stress Proteins and Their Relationship to Myocardial Protection.- A. Introduction.- B. Heat Stress and the Stress Response.- C. Are Stress Proteins Protective?.- D. Evidence for the Ability of Stress Proteins To Protect the Cell.- I. Thermotolerance.- II. Cross-tolerance.- III. Stress Proteins and the Heart.- IV. Heat Stress and Myocardial Protection.- V. Heat Stress Proteins and Ischaemic Preconditioning.- VI. Heat Stress and Protection Against Non-ischaemic Injury.- VII. Mechanisms of Cardiac Protection by Elevated Temperature.- E. Conclusions.- References.- 13 Heat Shock Proteins in Inflammation and Immunity.- A. Introduction: Multiple Roles of Heat Shock Proteins in Inflammation and Immunity.- B. Role of Hsp Localization in the Induction of an Immune Response.- C. Hsp and Cell Adhesion in the Initiation of Inflammation.- D. Non-specific Immunity: Cells and Mediators Involved in the Induction of a Heat Shock/Stress Response.- I. Monocytes-Macrophages.- 1. Reactive Oxygen Species.- 2. Lipid Mediators of Inflammation.- 3. Cytokines.- 4. Nuclear Factor ?B (NF-?B).- II. Granulocytic Phagocytes.- 1. Polymorphonuclear Leukocytes (PMN).- 2. Eosinophils.- E. Cellular Immunity.- I. T Cells.- II. ?? T Cells.- III. Hsp, NK Cells and Cancer Immunity.- F. The Paradigm of Asthma.- G. Conclusions and Perspectives.- References.- 14 Heat Shock Proteins in Embryonic Development.- A. Introduction.- B. Specific Expression of Hsps During Drosophila Development.- C. Essential Roles of Hsps During Development.- I. Mammalian Small Hsp: A “Checkpoint” Between Proliferation, Differentiation and Cell Death.- II. Hsp90 and the Control of Muscle Cell Differentiation Through the Regulation of Myogenic Transcription Factors.- III. Hsp70-2: A Specialized Chaperone Essential for Meiosis.- D. Mechanisms Regulating the Expression of Hsps During Differentiation and Development.- E. In Search of Additional Developmental Chaperones.- F. The Place of Hsps in Aging.- G. Conclusion.- References.- 15 Heat Shock Proteins in Rheumatoid Arthritis.- A. Introduction.- B. Autoimmune Arthritis and Immunity to Bacterial Antigens.- C. Hsp60 Is the Critical Antigen in Rat Adjuvant Arthritis.- D. Nasal Tolerance to hsp Peptides Suppresses Antigen and Non-Antigen Induced Arthritis.- E. Conserved hsp60 Epitopes Induce Arthritis Suppressive T Cells.- F. Suppression in Arthritis Models Is Specific for Heat Shock Proteins.- G. Immune Mediated Diseases.- H. Rheumatoid Arthritis as a Model Autoimmune Disease.- I. Hsps in Autoimmune and Other Inflammatory Diseases.- J. Hsps in Human Arthritic Diseases.- K. Hsp60 T Cell Responses in RA and JRA Are Associated with Suppressive Cytokine Production.- L. Mechanisms by Which hsps Produce Protection in Autoimmune Arthritis.- M. Lessons for the Development of Specific Immunotherapy in Autoimmunity.- N. Conclusion.- References.- 16 Heat Shock Protein 60 and Type I Diabetes.- A. Introduction.- B. Hsp60 and Autoimmune Diseases.- C. Hsp60 Reactivity and the NOD Mouse Model of Type I Diabetes.- D. Cell Types Required for Diabetogenesis in Patients.- E. Islet Cell Antibody Responses.- F. Autoreactive T Cell Responses.- G. T Cell Clones of Unknown Antigen Specificity.- H. Evidence from Suppression of Specific T Cell Responses in NOD Mice.- I. Concluding Remarks.- References.- 17 Heat Shock Proteins and Multiple Sclerosis.- A. Introduction.- B. Hsp Expression in Inflammatory, Demyelinating Diseases of the Brain.- I. Hsp Expression in Glial Cells.- II. Experimental Allergic Encephalomyelitis.- III. Multiple Sclerosis.- C. Immune Response to Hsps.- I. Experimental Allergic Encephalomyelitis.- II. Multiple Sclerosis.- D. Other Roles of Hsps in MS.- E. Conclusions and Future Work.- References.- 18 Heat Shock Proteins in Atherosclerosis.- A. Introduction.- B. Pathogenesis of Primary Atherosclerotic Lesions.- C. Arterial Hsp Expression After Vascular Injury and During Development of Atherosclerotic Lesions.- D. Association of Hsps with Specific Stages of Atherosclerotic Lesion Development.- I. Hsps in Hypertension, a Risk Factor for Atherosclerosis.- II. Immunological Responses to Hsps in Primary Plaque Development.- 1. T-Lymphocyte Activation by Hsp60 in Atherosclerotic Vessels.- 2. Do Anti-Hsp60 Antibodies Contribute to Necrotic Core Formation?.- 3. Biphasic Effects of Hsp Expression in Organ Transplantation: Tissue Preservation Versus Graft Arteriosclerosis.- III. Hsps in the Mature Atherosclerotic Plaque.- 1. Induction of Hsp Expression by oxLDL.- 2. The Stress Response and Plaque Cell Survival Versus Necrosis.- E. Future Directions.- References.- 19 Heat Shock Protein-Peptide Interaction: Basis for a New Generation of Vaccines Against Cancers and Intracellular Infections.- A. Introduction.- B. Hsps Chaperone Antigenic Peptides.- C. Unique Advantages of Hsp-Peptide Vaccines.- D. Use of Hsp-Peptide Complexes as Cancer Vaccines.- E. Protective Human Cancer Antigens: Unique to Each Individual Cancer or Shared Between Cancers?.- F. Hsp-Peptide Complexes as Vaccines Against Intracellular Infectious Agents.- References.