Book contents
- Frontmatter
- Contents
- Editor, Associate Editors, Artistic Consultant, and Contributors
- Preface
- PART I CONTEXT
- 1 The Endothelium in History
- 2 Introductory Essay: Evolution, Comparative Biology, and Development
- 3 Evolution of Cardiovascular Systems and Their Endothelial Linings
- 4 The Evolution and Comparative Biology of Vascular Development and the Endothelium
- 5 Fish Endothelium
- 6 Hagfish: A Model for Early Endothelium
- 7 The Unusual Cardiovascular System of the Hemoglobinless Antarctic Icefish
- 8 The Fish Endocardium: A Review on the Teleost Heart
- 9 Skin Breathing in Amphibians
- 10 Avian Endothelium
- 11 Spontaneous Cardiovascular and Endothelial Disorders in Dogs and Cats
- 12 Giraffe Cardiovascular Adaptations to Gravity
- 13 Energy Turnover and Oxygen Transport in the Smallest Mammal: The Etruscan Shrew
- 14 Molecular Phylogeny
- 15 Darwinian Medicine: What Evolutionary Medicine Offers to Endothelium Researchers
- 16 The Ancestral Biomedical Environment
- 17 Putting Up Resistance: Maternal–Fetal Conflict over the Control of Uteroplacental Blood Flow
- 18 Xenopus as a Model to Study Endothelial Development and Modulation
- 19 Vascular Development in Zebrafish
- 20 Endothelial Cell Differentiation and Vascular Development in Mammals
- 21 Fate Mapping
- 22 Pancreas and Liver: Mutual Signaling during Vascularized Tissue Formation
- 23 Pulmonary Vascular Development
- 24 Shall I Compare the Endothelium to a Summer's Day: The Role of Metaphor in Communicating Science
- 25 The Membrane Metaphor: Urban Design and the Endothelium
- 26 Computer Metaphors for the Endothelium
- PART II ENDOTHELIAL CELL AS INPUT-OUTPUT DEVICE
- PART III VASCULAR BED/ORGAN STRUCTURE AND FUNCTION IN HEALTH AND DISEASE
- PART IV DIAGNOSIS AND TREATMENT
- PART V CHALLENGES AND OPPORTUNITIES
- Index
- Plate section
7 - The Unusual Cardiovascular System of the Hemoglobinless Antarctic Icefish
from PART I - CONTEXT
Published online by Cambridge University Press: 04 May 2010
- Frontmatter
- Contents
- Editor, Associate Editors, Artistic Consultant, and Contributors
- Preface
- PART I CONTEXT
- 1 The Endothelium in History
- 2 Introductory Essay: Evolution, Comparative Biology, and Development
- 3 Evolution of Cardiovascular Systems and Their Endothelial Linings
- 4 The Evolution and Comparative Biology of Vascular Development and the Endothelium
- 5 Fish Endothelium
- 6 Hagfish: A Model for Early Endothelium
- 7 The Unusual Cardiovascular System of the Hemoglobinless Antarctic Icefish
- 8 The Fish Endocardium: A Review on the Teleost Heart
- 9 Skin Breathing in Amphibians
- 10 Avian Endothelium
- 11 Spontaneous Cardiovascular and Endothelial Disorders in Dogs and Cats
- 12 Giraffe Cardiovascular Adaptations to Gravity
- 13 Energy Turnover and Oxygen Transport in the Smallest Mammal: The Etruscan Shrew
- 14 Molecular Phylogeny
- 15 Darwinian Medicine: What Evolutionary Medicine Offers to Endothelium Researchers
- 16 The Ancestral Biomedical Environment
- 17 Putting Up Resistance: Maternal–Fetal Conflict over the Control of Uteroplacental Blood Flow
- 18 Xenopus as a Model to Study Endothelial Development and Modulation
- 19 Vascular Development in Zebrafish
- 20 Endothelial Cell Differentiation and Vascular Development in Mammals
- 21 Fate Mapping
- 22 Pancreas and Liver: Mutual Signaling during Vascularized Tissue Formation
- 23 Pulmonary Vascular Development
- 24 Shall I Compare the Endothelium to a Summer's Day: The Role of Metaphor in Communicating Science
- 25 The Membrane Metaphor: Urban Design and the Endothelium
- 26 Computer Metaphors for the Endothelium
- PART II ENDOTHELIAL CELL AS INPUT-OUTPUT DEVICE
- PART III VASCULAR BED/ORGAN STRUCTURE AND FUNCTION IN HEALTH AND DISEASE
- PART IV DIAGNOSIS AND TREATMENT
- PART V CHALLENGES AND OPPORTUNITIES
- Index
- Plate section
Summary
The possession of erythrocytes containing hemoglobin has long been regarded as a sine qua non of the vertebrate condition. Imagine the surprise of zoologists when they read J. T. Ruud's Nature article on icefishes, “Vertebrates without erythrocytes and blood pigment” (1). Ruud himself was skeptical when he heard about the blodlaus-fisk (i.e., lacking hemoglobin-bearing erythrocytes) that whalers reported to inhabit the waters of South Georgia in the Antarctic. He explained:
I first heard about these “bloodless fish” on a visit to South Georgia in 1929; but no specimens were forthcoming, and I did not take them seriously. I was reminded about their existence, however, when Mr. D. Runstad, biologist of the Norvegia Expedition (1927–28), presented me with some photographs of a “white crocodile fish” caught by him at Bouvet Island, mentioning the fact that its blood was colourless (1).
When, years later (1953), he captured several specimens of the “white crocodile fish” Chaenocephalus aceratus (family Channichthyidae, suborder Notothenioidei; Figure 7.1) at South Georgia, Ruud measured the hematological parameters of its blood (1). He reported that fresh blood is nearly transparent, contains leukocytes at <1% by volume, is iron poor, and lacks erythrocytes and hemoglobin. Ruud also determined that the oxygen (O2)-carrying capacity of C. aceratus blood is ∼10% that of two red-blooded Antarctic fishes that belong to a closely related family (Nototheniidae, Notothenioidei). In all other respects, hematopoiesis in icefishes appears normal and yields the full complement of teleost nonerythroid blood cell lineages: heterophils, granulocytes, lymphocytes, and thrombocytes (2).
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- Endothelial Biomedicine , pp. 74 - 78Publisher: Cambridge University PressPrint publication year: 2007
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