VIP, PACAP, and Related Peptides From Gene to Therapy, Volume 1070
, by Vaudry, Hubert; Laburthe, Marc
- ISBN: 9781573315500 | 1573315508
- Cover: Paperback
- Copyright: 8/7/2006
This volume provides an overview on the biochemistry, physiology, and pharmacology of vasoactive intestinal polypeptide (VIP), pituitary adenylate cyclase-activating polypeptide (PACAP), and related peptides.VIP and PACAP are undoubtedly among the most fascinating neuropeptides ever identified. They belong to the largest family of regulatory peptides, which comprises several other prominent neuroendocrine peptides including secretin (the first peptide hormone that has been identified), glucagon, and growth hormone-releasing hormone. The structural and physiological relationships of these peptides as well as their receptors provide a unique model for investigating the processes of molecular evolution leading to the diversification of multigene families.The primary structures of VIP and PACAP have been remarkably well conserved across vertebrates, suggesting that these peptides must be involved in vital functions throughout the animal kingdom. Indeed, VIP and PACAP appear to be implicated in a large array of physiological processes such as development; growth; endocrine, cardiovascular, respiratory, reproductive and digestive functions; immune responses; and circadian rhythms. There is also clear evidence that VIP and PACAP exert both trophic and antiproliferative effects on normal and tumor cells. The beneficial influence of VIP and PACAP agonists and antagonists in various pathological states including heart failure, ischemia, asthma, impotence, and cancer has motivated the development of novel selective VIP or PACAP ligands that could potentially be used as antihypertensive, neuroprotective, bronchodilatory, vasodilatory, and/or antiproliferative drugs. The occurrence of multiple VIP/PACAP receptor subtypes and splice variants that exhibit tissue-specific expression and possess differential affinity for various ligands generates hopes for the development of new therapeutic agents that could act selectively on the desired target cells.NOTE: Annals volumes are available for sale as individual books or as a journal. For information on institutional journal subscriptions, please visit www.blackwellpublishing.com/nyas.ACADEMY MEMBERS: Please contact the New York Academy of Sciences directly to place your order (www.nyas.org). Members of the New York Academy of Science receive full-text access to the Annals online and discounts on print volumes. Please visit www.nyas.org/membership/main.asp for more information about becoming a member.
Hubert Vaudry is the editor of VIP, PACAP, and Related Peptides: From Gene to Therapy, Volume 1070, published by Wiley. Marc Laburthe is the editor of VIP, PACAP, and Related Peptides: From Gene to Therapy, Volume 1070, published by Wiley.
| Introduction. | |||||
|
xvii | ||||
| Reminiscences of a Life in Science. | |||||
|
xix | ||||
| Treatment of Renal Failure Associated with Multiple Myeloma and Other Diseases By PACAP-38. | |||||
|
1 | (4) | |||
| Clues to VIP Function from Knockout Mice. | |||||
|
5 | (5) | |||
| The Glucagon-Like Peptides: Pleiotropic Regulators of Nutrient Homeostasis. | |||||
|
10 | (17) | |||
| Secretin: A Pleiotrophic Hormone. | |||||
|
27 | (24) | |||
| VIP–PACAP System in Immunity: New Insights for Multitarget Therapy. | |||||
|
51 | (24) | |||
| New Insights into the Central PACAPergic System from the Phenotypes in PACAP- and PACAP Receptor-Knockout Mice. | |||||
|
75 | (15) | |||
| Complexing Receptor Pharmacology: Modulation of Family B G Protein– Coupled Receptor Function By RAMPs. | |||||
|
90 | (15) | |||
| The Three-Dimensional Structure of the N-Terminal Domain of Corticotropin-Releasing Factor Receptors: Sushi Domains and the B1 Family of G Protein–Coupled Receptors. | |||||
|
105 | (15) | |||
| Hedgehog Signaling: New Targets for GPCRs Coupled to cAMP and Protein Kinase A. | |||||
|
120 | (9) | |||
| Effect of VIP on TLR2 and TLR4 Expression in Lymph Node Immune Cells During TNBS-Induced Colitis. | |||||
|
129 | (6) | |||
| Immunocytochemical Distribution of VIP and PACAP in the Rat Brain Stem: Implications for REM Sleep Physiology. | |||||
|
135 | (8) | |||
| Microiontophoretically Applied PACAP Blocks Excitatory Effects of Kainic Acid in Vivo. | |||||
|
143 | (6) | |||
| Search for the Optimal Monosodium Glutamate Treatment Schedule to Study the Neuroprotective Effects of PACAP in the Retina. | |||||
|
149 | (7) | |||
| Can PACAP-38 Modulate Immune and Endocrine Responses During Lipopolysaccharide (LPS)-Induced Acute Inflammation? | |||||
|
156 | (5) | |||
| The Glucagon–Miniglucagon Interplay: A New Level in the Metabolic Regulation. | |||||
|
161 | (6) | |||
| Effects of VIP and VIP–DAP on Proliferation and Lipid Peroxidation Metabolism in Human KB Cells. | |||||
|
167 | (6) | |||
| The Delayed Rectifier Channel Current IK Plays a Key Role in the Control of Programmed Cell Death By PACAP and Ethanol in Cerebellar Granule Neurons. | |||||
|
173 | (7) | |||
| Spatial Approximation between the C-Terminus of VIP and the N-Terminal Ectodomain of the VPAC I Receptor. | |||||
|
180 | (5) | |||
| PACAP and VIP Promote Initiation of Electrophysiological Activity in Differentiating Embryonic Stem Cells. | |||||
|
185 | (5) | |||
| Vasoactive Intestinal Peptide Generates CD4+CD25+ Regulatory T Cells in vivo: Therapeutic Applications in Autoimmunity and Transplantation. | |||||
|
190 | (6) | |||
| Endogenous Release of Secretin From the Hypothalamus. | |||||
|
196 | (5) | |||
| Expression of PACAP Receptors in the Frog Brain during Development. | |||||
|
201 | (4) | |||
| The Human VPAC1 Receptor: Identification of the N-terminal Ectodomain as a Major VIP-Binding Site By Photoaffinity Labeling and 3D Modeling. | |||||
|
205 | (5) | |||
| VPAC2 Receptor Activation Mediates VIP Enhancement of Population Spikes in the CA1 Area of the Hippocampus. | |||||
|
210 | (5) | |||
| Expression and GTP Sensitivity of Peptide Histidine Isoleucine High-Affinity-Binding Sites in Rat. | |||||
|
215 | (5) | |||
| PACAP, VIP, and PHI: Effects on AC-, PLC-, and PLD-Driven Signaling Systems in the Primary Glial Cell Cultures. | |||||
|
220 | (6) | |||
| Vasoactive Intestinal Polypeptide Induces Regulatory Dendritic Cells That Prevent Acute Graft Versus Host Disease and Leukemia Relapse after Bone Marrow Transplantation. | |||||
|
226 | (7) | |||
| Vasoactive Intestinal Peptide: The Dendritic Cell —> Regulatory T Cell Axis. | |||||
|
233 | (6) | |||
| VIP and PACAP Receptor Pharmacology: A Comparison of Intracellular Signaling Pathways. | |||||
|
239 | (4) | |||
| Molecular Approximation between Residue 10 of Secretin and Its Receptor Demonstrated By Photoaffinity Labeling. | |||||
|
243 | (5) | |||
| Use of Photoaffinity Labeling to Understand the Molecular Basis of Ligand Binding to the Secretin Receptor. | |||||
|
248 | (17) | |||
| PACAP and Ceramides Exert Opposite Effects on Migration, Neurite Outgrowth, and Cytoskeleton Remodeling. | |||||
|
265 | (6) | |||
| The Effects of PACAP and VIP on the in Vitro Melatonin Secretion from the Embryonic Chicken Pineal Gland. | |||||
|
271 | (5) | |||
| VIP Prevents Experimental Multiple Sclerosis By Downregulating Both Inflammatory and Autoimmune Components of the Disease. | |||||
|
276 | (6) | |||
| C-Type Natriuretic Peptide Is Specifically Augmented By Pituitary Adenylate Cyclase-Activating Polypeptide in Rat Astrocytes. | |||||
|
282 | (4) | |||
| Aromatase Gene Expression and Regulation in the Female Rat Pituitary. | |||||
|
286 | (7) | |||
| PACAP Inhibits Oxidative Stress-Induced Activation of MAP Kinase-Dependent Apoptotic Pathway in Cultured Cardiomyocytes. | |||||
|
293 | (5) | |||
| Modulation of Pituitary Adenylate Cyclase-Activating Polypeptide (PACAP) Expression in Explant-Cultured Guinea Pig Cardiac Neurons. | |||||
|
298 | (5) | |||
| VIP: An Agent with License to Kill Infective Parasites. | |||||
|
303 | (6) | |||
| PACAP Stimulates the Release of the Secretogranin II-Derived Peptide EM66 from Chromaffin Cells. | |||||
|
309 | (4) | |||
| New Nonradioactive Technique for Vasoactive Intestinal Peptide-Receptor-Ligand-Binding Studies. | |||||
|
313 | (4) | |||
| Calcium Influx through Channels Other than Voltage-Dependent Calcium Channels Is Critical to the Pituitary Adenylate Cyclase-Activating Polypeptide-Induced Increase in Excitability in Guinea Pig Cardiac Neurons. | |||||
|
317 | (5) | |||
| Mechanisms and Modulation of Pituitary Adenylate Cyclase-Activating Protein-Induced Calcium Mobilization in Human Neutrophils. | |||||
|
322 | (8) | |||
| PACAP Enhances Mouse Urinary Bladder Contractility and Is Upregulated in Micturition Reflex Pathways after Cystitis. | |||||
|
330 | (7) | |||
| Protective Role for Plasmid DNA-Mediated VIP Gene Transfer in Non-Obese Diabetic Mice. | |||||
|
337 | (5) | |||
| Inhibition of Self-Renewal and Induction of Neural Differentiation By PACAP in Neural Progenito: Cells. | |||||
|
342 | (6) | |||
| Presence of PACAP and VIP in Embryonic Chicken Brain. | |||||
|
348 | (6) | |||
| Short-Term Fasting Differentially Alters PACAP and VIP Levels in the Brains of Rat and Chicken. | |||||
|
354 | (5) | |||
| VIP Decreases TLR4 Expression Induced By LPS and TNF-α Treatment in Human Synovial Fibroblasts. | |||||
|
359 | (6) | |||
| Effects of Systemic PACAP Treatment in Monosodium Glutamate-Induced Behavioral Changes and Retinal Degeneration. | |||||
|
365 | (6) | |||
| Localization of Small Heterodimer Partner (SHP) and Secretin in Mouse Duodenal Cells. | |||||
|
371 | (5) | |||
| Differential Mechanisms for PACAP and GnRH cAMP Induction Contribute to Cross-talk between both Hormones in the Gonadotrope LßT2 Cell Line. | |||||
|
376 | (4) | |||
| Identification of Proteins Regulated By PACAP in PC12 Cells By 2D Gel Electrophoresis Coupled to Mass Spectrometry. | |||||
|
380 | (8) | |||
| Identification of Repressor Element 1 in Secretin/PACAP/VIP Genes. | |||||
|
388 | (5) | |||
| Retinoic Acid-Induced Human Secretin Gene Expression in Neuronal Cells Is Mediated By Cyclin-Dependent Kinase 1. | |||||
|
393 | (6) | |||
| Neuroendocrine Tumors Express PAC1 Receptors. | |||||
|
399 | (6) | |||
| PAC1 Receptor: Emerging Target for Septic Shock Therapy. | |||||
|
405 | (6) | |||
| PACAP Stimulates Biosynthesis and Release of Endozepines from Rat Astrocytes. | |||||
|
411 | (6) | |||
| Effects of Pituitary Adenylate Cyclase-Activating Polypeptide and Vasoactive Intestinal Polypeptide on Food Intake and Locomotor Activity in the Goldfish, Carassius auratus. | |||||
|
417 | (5) | |||
| Functional Splice Variants of the Type II G Protein—Coupled Receptor (VPAC2) for Vasoactive Intestinal Peptide in Mouse and Human Lymphocytes. | |||||
|
422 | (5) | |||
| Comparative Anatomy of PACAP-Immunoreactive Structures in the Ventral Nerve Cord Ganglia of Lumbricid Oligochaetes. | |||||
|
427 | (4) | |||
| Involvement of the Adenylyl. Cyclase/Protein Kinase A Signaling Pathway in the Stimulatory Effect of PACAP on Frog Adrenocortical Cells. | |||||
|
431 | (5) | |||
| Breast Cancer VPAC1 Receptors. | |||||
|
436 | (4) | |||
| PACAP and Type I PACAP Receptors in Human Prostate Cancer Tissue. | |||||
|
440 | (10) | |||
| Lack of Trimethyltin (TMT)-Induced Elevation of Plasma Corticosterone in PACAP-Deficient Mice. | |||||
|
450 | (7) | |||
| Expression of PACAP Receptor mRNAs By Neuropeptide Y Neurons in the Rat Arcuate Nucleus. | |||||
|
457 | (5) | |||
| Developmental Pattern of VIP Binding Sites in the Human Hypothalamus. | |||||
|
462 | (6) | |||
| Changes in PACAP Levels in the Central Nervous System after Ovariectomy and Castration. | |||||
|
468 | (6) | |||
| Effects of Pituitary Adenylate Cyclase-Activating Polypeptide, Vasoactive Intestinal Polypeptide, and Somatostatin on the Release of Thyrotropin from the Bullfrog Pituitary. | |||||
|
474 | (7) | |||
| The Vasoactive Intestinal Peptide Receptor Turnover in Pulmonary Arteries Indicates an Important Role for VIP it the Rat Lung Circulation. | |||||
|
481 | (3) | |||
| A Splice Variant to PACAP Receptor That Is Involved in Spermatogenesis Is Expressed in Astrocytes. | |||||
|
484 | (7) | |||
| Glucose Activation of the Glucagon Receptor Gene: Functional Dissimilarity with Several Other Glucose Response Elements. | |||||
|
491 | (9) | |||
| NAP, a Peptide Derived from the Activity-Dependent Neuroprotective Protein, Modulates Macrophage Function. | |||||
|
500 | (7) | |||
| Involvement of ERK and CREB Signaling Pathways in the Protective Effect of PACAP in Monosodium Glutamate-Induced Retinal Lesion. | |||||
|
507 | (5) | |||
| Mechanisms of VIP-Induced Neuroprotection against Neonatal Excitotoxicity. | |||||
|
512 | (6) | |||
| Comparative Study of the Effects of PACAP in Young, Aging, and Castrated Males in a Rat Model of Parkinson's Disease. | |||||
|
518 | (7) | |||
| VIP and Tolerance Induction in Autoimmunity. | |||||
|
525 | (6) | |||
| Neuroprotective Effect of PACAP against Kainic Acid-Induced Neurotoxicity in Rat Retina. | |||||
|
531 | (4) | |||
| PACAP Stimulates the Release of Interleukin-6 in Cultured Rat Muller Cells. | |||||
|
535 | (5) | |||
| VIP Protects Th2 Cells By Downregulating Granzyme B Expression. | |||||
|
540 | (5) | |||
| Serotonergic Inhibition of Intense Jumping Behavior in Mice Lacking PACAP (Adcyap1-/-). | |||||
|
545 | (5) | |||
| Pleiotropic Functions of PACAP in the CNS: Neuroprotection and Neurodevelopment. | |||||
|
550 | (11) | |||
| The Prenatal Expression of Secretin Receptor. | |||||
|
561 | (5) | |||
| Cyclic AMP Formation in C6 Glioma Cells: Effect of PACAP and VIP in Early and Late Passages. | |||||
|
566 | (4) | |||
| Protective Effects of PACAP in Excitotoxic Striatal Lesion. | |||||
|
570 | (5) | |||
| Characterization of the New Photoaffinity Probe (Bz2-K24)-VIP. | |||||
|
575 | (6) | |||
| PACAP Receptor (PAC1-R) Expression in Rat and Rhesus Monkey Thymus. | |||||
|
581 | (5) | |||
| Characterization of the PAC1 Variants Expressed in the Mouse Heart. | |||||
|
586 | (5) | |||
| Distribution of PACAP in the Brain of the Cartilaginous Fish Torpedo Marmorwa. | |||||
|
591 | (6) | |||
| Involvement of Protein Kinase C in the PACAP-Induced Differentiation of Neural Stem Cells into Astrocytes. | |||||
|
597 | (5) | |||
| Role of Two Genes Encoding PACAP in Early Brain Development in Zebrafish. | |||||
|
602 | (20) | |||
| A Role for Pituitary Adenylate Cyclase Activating Polypeptide (PACAP) in Detrusor Hyperreflexia after Spinal Cord Injury (SCI). | |||||
|
622 | (7) | |||
| Index of Contributors | 629 |
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