Chapter
III. Physiological Role of the Nuclear T3 Binding Site
IV. The Possibility of Other Initiating Sites
V. Speculations on Molecular Mechanisms
Chapter 2. In Vitro Studies on Thyroid Hormone Receptors
II. Cell Culture Considerations
III. Effect of Thyroid Hormones in Cultured GH1 Cells
IV. Quantitation of Growth Hormone mRNA and Regulation of Glucocorticoid Action by Thyroid Hormone in GH1 Cells
V. Are There Extranuclear Actions of Thyroid Hormone?
VI. Summary and Conclusions
Chapter 3. Regulation of Gene Expression by Thyroid Hormones
II. Thyroid Hormone "Receptors"
III. Studies on the Nuclear Localization of the Receptors
IV. Hormonal Control of Receptor Levels?
V. Characteristics of the Solubilized Receptors
VI. Chromatin Fractionation Studies
VII. The Receptor as a DNA-Binding Protein
VIII. A Macromolecular Factor Is Required for the Specificity of Hormone Recognition by the Receptor
IX. Biological Activities of Various Thyroid Hormones: The Role of Cellular Metabolism
X. Thyroid Hormones Regulate Specific Messenger RNA Levels
XI. Model for Thyroid Hormone Action
Chapter 4. Direct Identification and Characterization of β-Adrenergic Receptors and Functional Relationship of Adenylyl Cyclase
II. Chemistry of HYP and I-HYP
III. [125I]HYP Binding to β-Adrenergic Receptors
IV. Direct Analysis of Interaction of Agonists and Antagonists with β-Adrenergic Receptors Employing [125I]HYP
V. Determination of Kt and Ka for Inhibition or Activation of Adenylyl Cyclase
VI. Effects of Guanine Nucleotides
VII. Structure-Function Relationships
VIII. Relationship between Receptor Binding, Adenylyl Cyclase Activity, and Biological Effects
IX. Nature of the Functional Relationship of β-Andrenergic Receptors and Adenylyl Cyclase
Chapter 5. Heart β-Andrenoceptors
III. Tissue Uptake of Catecholamines
IV. Affinity of Ligands for Cardiac β-Adrenoceptors
V. Apparent Dissociation of Adenylyl Cyclase Stimulation from Other Myocardial Effects of Adrenergic Ligands
Chapter 6. Regulation of β-Adrenergic Receptors by β-Adrenergic Agonists
II. Methods for Direct Study of β-Adrenergic Receptors
III. Catecholamine Desensitization in the Frog Erythrocyte Model System— In Vivo Studies
IV. In Vitro Desensitization Studies
V. Studies in a Cell-Free System
VI. A Model of Catecholamine Desensitization in the Frog Erythrocyte
Chapter 7. Regulation of β-Adrenergic Function in the Rat Pineal Gland
I. β-Adrenergic Stimulation of Melatonin Synthesis
II. Regulation of Sensitivity to β-Adrenergic Stimulation
Chapter 8. A Model for Peptide Hormone Action Based upon Measurement of Functional Hormone Binding
II. The Functional Binding Procedure
III. Computer Stimulations of H-N Plots for Selected Models of Binding-Response Coupling
V. Kinetics of Functional Binding: Threshold
VI. Cooperativity in Binding and Response
VII. Summary and Conclusions
VIII. Statistical Appendix
Chapter 9. Role of Carbohydrate in the Action of Gonadotropins
II. Carbohydrate Structures of Gonadotropins Revealed by Sequential Degradation with Glycosidases
III. Immunologic Properties of Glycosidase-Treated Derivatives of hCG and PMSG
IV. Mechanism of Gonadotropin Action after Carbohydrate Removal
V. Models of Hormone Action and Role of Cyclic AMP as a Mediator of Steroidogenesis
Chapter 10. Gonadotropin Receptors and Regulation of Interstitial Cell Function in the Testis
II. Gonadotropin Receptors
III. Gonadotropin Binding and Regulation of Leydig Cell Responses
IV. Hormonal Regulation of Gonadotropin Receptors
Chapter 11. Follitropin Receptors in Rat Testis Tubule Membranes: Characterization, Solubilization, and Study of Factors Affecting Interaction with FSH
II. Preparation of Purified Rat Tubule Membranes
III. Binding of [125I]hFSH to Subcellular Fractions of Rat Tubules
IV. Binding of [125I]hFSH to Rat Tubule Plasma Membranes
V. Effects of Nucleotides on the Binding and Dissociation of [125I]hFSH
VI. Properties of the Follitropin Receptor in Purified Tubule Membranes
VII. Inhibition of FSH Binding to Tubule Membrane Receptor
VIII. Solubilization of Follitropin Receptors in Rat Testes
Chapter 12. Mechanism of Action of FSH in the Male Rat
II. Membrane Receptors for FSH
III. Effects on Cyclic Nucleotide Metabolism
IV. Stimulation of Translation and Transcription
V. Modulation of Androgen Binding Protein Activity
Chapter 13. Physiological Aspects of Appearance and Desensitization of Gonadotropin-Sensitive Adenylyl Cyclase in Ovarian Tissues and Membranes of Rabbits, Rats, and Pigs
II. Desensitization of Adenylyl Cyclase to LH Stimulation in Graafian Follicles
III. Desensitization of Adenylyl Cyclase to LH Stimulation in Corpora Lutea
IV. Desensitization of Adenylyl Cyclase to LH Stimulation in Membrane Particles
Chapter 14. Development and Hormonal Regulation of Gonadotropin Responsiveness in Granulosa Cells of the Mammalian Ovary
II. Changes in Granulosa Cells during Follicular Maturation
III. Induction of the Luteinized State in Vitro in Granulosa Cells Obtained from Immature Small Follicles
IV. Role of Steroid Hormones in Granulosa Cell Luteinization
V. Granulosa Cell Atresia
VI. Intraovarian Inhibitors
Chapter 15. Regulation of Prolactin Receptors by Steroid Hormones and Use of Radioligand Assays in Endocrine Research
I. Introduction: Binding Studies and Radioreceptor Assays
II. Hepatic Receptors for Lactogenic Hormones
III. Prolactin Receptor Induction in the Testes and Prostate Gland
IV. Prolactin Receptor in the Ovaries—A Synergism of Luteotropin Receptor Induction
V. Prolactin Receptor Induction in the Mammary Gland
VI. Prolactin Receptors in the Adrenal Gland and Kidney
VII. Prolactin Receptors in Mammary Carcinomas
Chapter 16. Hormone Regulation of Ovarian Hormone Receptors
Chapter 17. Interactions of TRH, LH-RH, and Somatostatin in the Anterior Pituitary Gland
II. Role of Cyclic AMP in the Action of Hypothalamic Hormones
III. [3H]TRH Binding in Anterior Pituitary Tissue
IV. Modulation of Pituitary TRH Receptors
V. Interactions between TRH and Somatostatin for TSH and PRL Release
VI. Modulation of LH and FSH Responses to LH-RH by Androgens and Estrogens
Chapter 18. Brain Receptors for Neurotransmitters
VI. Glutamate and Aspartate
Chapter 19. The Mechanism of Opiate Agonist and Antagonist Action
II. Biochemical Basis of the Sodium Effect
III. Endogenous Ligands for the Opiate Receptor
IV. The Opiate Receptor in Vivo
Chapter 20. Hormonal Regulation of Cyclic Nucleotide Phosphodiesterases
II. General Considerations
III. Techniques and Applications
IV. Insulin Activation of Cyclic Nucleotide Phosphodiesterase
Chapter 21. Phosphorylation of Membrane Proteins in the Actions of Hormones and Neurotransmitters
II. Evidence for a Role of Membrane Protein Phosphorylation in the Effects of Neurotransmitters
III. Evidence Suggesting a Role for Membrane Phosphorylation in Hormonal Control of Permeability and Transport
IV. Membrane Protein Phosphorylation Serving Other Functions
V. Conclusions and Speculation on Future Research
Receptors and Hormone Action
:Volume III
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