Main description:

Various endogenous and environmental challenges of homoiostasis have resulted in the evolution of apparently quite different mechanisms for the same or similar functions in individual representatives of the animal kingdom. One of the prominent achievements of comparative physiology over the last few decades has been the description of regula- tory features common to many studied species beyond the extreme diversity of their morphological forms. Delineation offunctional princi- ples universally applicable to the physiology and biochemistry of living systems became often possible through technical advances in the devel- opment of numerous new techniques, in many cases modified and adopted from other fields of science, but also by approaching certain problems using multifactorial analysis. The advance in technology has facilitated studies of minute functional details of mechanisms, which finally lead to better understanding of generally similar functions, covered by the multiple developments of Nature as a response to an extreme variety of different conditions. Improved understanding of specific mechanisms, however, has presented new problems at the level of system integration.
The importance of the integrative aspect became particularly apparent during an international symposium on 'Mecha- nisms of Systemic Regulation in Lower Vertebrates: Respiration, Circu- lation, Ion Transfer and Metabolism' (organized in 1990 by Norbert Heisler and Johannes Piiper at the Max-Planck-Institut fUr experimen- telle Medizin at Gottingen/Germany).

Contents:

Acid-Base Regulation and Ammonia Elimination.- 1 pH Homeostasis in Terrestrial Vertebrates; Ammonium Ion as a Proton Source.- 1 Introduction.- 2 Renal Glutamine Metabolism.- 3 Catabolism of Protein Generates Bicarbonate.- 4 Disposal of Metabolic Bicarbonate.- 5 Summary.- References.- 2 Renal Transport of Organic Acids and Bases in Non-Mammalian Vertebrates.- 1 Introduction.- 2 Organic Acids (or Anions).- 3 Organic Bases (or Cations).- References.- 3 pH Homeostasis in Terrestrial Vertebrates: A Comparison of Traditional and New Concepts.- 1 Introduction.- 2 Nutrients and Acid-Base Status.- 3 Renal Ammonium and Net Acid Excretion.- 4 Conclusions and Summary.- References.- 4 Ammonia vs Ammonium: Elimination Pathways of Nitrogenous Wastes in Ammoniotelic Fishes.- 1 Introduction.- 2 Production, Ionization and Partial Pressure.- 3 Aqueous Diffusion.- 4 Transfer of Ammonia Across Cell Membranes.- 5 Elimination of Ammonia from the Body Fluids.- 6 Conclusions.- References.- Ion Transfer Processes.- 5 Morphological Basis of Acid-Base and Ionic Regulation in Fish.- 1 Introduction.- 2 Ionic Regulation.- 3 Acid-Base Regulation.- References.- 6 The Roles of Natriuretic Peptide Hormones in Fish Osmoregulation and Hemodynamics.- 1 Introduction.- 2 Biochemistry of Natriuretic Peptide Hormones in Mammals.- 3 Physiology of Natriuretic Peptide Hormones in Mammals.- 4 Physiology of Fish Osmoregulation.- 5 Endocrine Control of Fish Osmoregulation.- 6 Evidence for Role of Natriuretic Peptide Hormones in Fish Osmoregulation.- 7 Conclusions.- References.- 7 Regulation of Ion and Water Transport by Hydrogen Ions in High Resistance Epithelia.- 1 Introduction.- 2 Intracellular pH: A Cross-Talk Signal in Principal Cells.- 3 Regulation of K+ Channel Activity by Intracellular ATP: ADP.- 4 Regulation of K+ Channel Activity by Intracellular Ca2+.- 5 Proton Permeability in Anti-Diuretic-Hormone-Induced Channels.- 6 Cellular Transport Pathways for Na+ Absorption and H+ Secretion.- 7 Conclusions.- References.- 8 Intracellular Signals Controlling Ionic and Acid-Base Regulation in Avian Nasal Gland Cells.- 1 Introduction.- 2 Secretory Mechanism.- 3 Signals for Secretion.- 4 Metabolism and Intracellular pH.- 5 Muscarinic Receptor Characterization.- 6 Proliferation and Differentiation Responses.- 7 Conclusions.- References.- Hypoxia and Metabolic Adaptation.- 9 Interrelationships Between Hypoxia and Thermoregulation in Vertebrates.- 1 Introduction.- 2 Hypoxia and Thermoregulation.- 3 Other Stresses and Thermoregulation.- 4 Conclusions.- References.- 10 Sulfide Tolerance in Marine Invertebrates.- 1 Introduction.- 2 Sediment.- 3 Living System.- 4 Sulfide Tolerance.- 5 Conclusion.- References.