Cover Image

Inorganic biochemistry of iron metabolism [electronic resource] : from molecular mechanisms to clinical consequences / Robert Crichton ; with the collaboration of Johan Boelart [and others]

Show other versions (1)

Iron is of fundamental importance to the growth, development and well-being of almost all living organisms. Multiple biological systems have evolved for the uptake, utilisation, storage and homeostasis of iron in microbes, plants and mammals. Both iron deficiency and iron overload are found extensiv...

Full description

Saved in:
Bibliographic Details
Online Access: Full Text (via Wiley)
Main Author: Crichton, Robert R.
Other Authors: Boelaert, Johan R.
Format: Electronic eBook
Language:English
Published: Chichester, West Sussex ; New York : Wiley, ©2001.
Edition:2nd ed.
Subjects:
Iron > Metabolism.
Iron proteins.
Iron > Metabolism > Disorders.
Table of Contents:
  • Cover
  • Contents
  • Preface
  • 1 Solution Chemistry of Iron in Biological Media
  • 1.1 Aqueous Solution Chemistry of Iron
  • 1.2 Oxygen Free Radicals
  • 1.3 Iron Hydrolysis
  • A Ubiquitous Phenomenon
  • 1.4 Hydrolysis of Iron(III) in Acid Media
  • Formation of Polynuclear Species
  • 1.5 Formation of Precipitates
  • 1.6 Biomineralization
  • 1.7 References
  • 2 The Importance of Iron for Biological Systems
  • 2.1 Introduction
  • 2.2 Physical Techniques for the Study of Iron in Biological Systems
  • 2.3 Haemoproteins
  • 2.4 Iron-Sulfur Proteins
  • 2.5 Other Iron-containing Proteins
  • 2.6 References
  • 3 Microbial Iron Uptake
  • 3.1 Introduction
  • 3.2 Siderophores
  • 3.3 Ferrous Iron Transport Systems
  • 3.4 Iron Metabolism
  • 3.5 Iron Regulation in Bacteria
  • the Fur Protein
  • 3.6 Acknowledgements
  • 3.7 References
  • 4 Iron Uptake by Plants and Yeast
  • 4.1 Iron Acquisition by Plants
  • 4.2 Plant Ferritins
  • 4.3 Iron Acquisition by Yeast
  • 4.4 Intracellular Iron Metabolism.
  • 4.5 Iron Transport in Other Fungi
  • 4.6 References
  • 5 Cellular Iron Uptake in Mammals
  • 5.1 The Transferrins
  • 5.2 Iron Uptake by Mammalian Cells
  • Uptake of Transferrin-bound Iron
  • 5.3 Iron Uptake by Mammalian Cells
  • Uptake of Non-transferrin Bound Iron
  • 5.4 References
  • 6 Intracellular Iron Storage and Biomineralization
  • 6.1 Intracellular Iron Storage
  • 6.2 Biomineralization
  • 6.3 References
  • 7 Intracellular Iron Metabolism and Cellular Iron Homeostasis
  • 7.1 Intracellular Iron Metabolism
  • 7.2 Metal Ion Homeostasis
  • 7.3 References
  • 8 Iron Absorption in Mammals with Particular Reference to Man
  • 8.1 Iron Metabolism in Man: An Overview
  • 8.2 Sources of Dietary Iron in Man and the Importance of Luminal Factors
  • 8.3 Molecular Mechanisms of Mucosal Iron Absorption
  • 8.4 A Model of Iron Uptake and Regulation of Iron Homeostasis by the Enterocyte
  • 8.5 References
  • 9 Pathophysiology of Iron Deficiency and Iron Overload in Man.
  • 9.1 Introduction: Acquired and Genetic Disorders of Iron Metabolism
  • 9.2 Body Iron Regulation
  • 9.3 Iron Absorption in Disorders of Iron Metabolism
  • 9.4 Iron Deficiency
  • 9.5 Iron Overload
  • 9.6 Conclusion
  • 9.7 References
  • 10 Iron and Oxidative Stress
  • 10.1 Introduction
  • 10.2 Iron and Fenton Chemistry
  • 10.3 Importance of Cytoprotection
  • 10.4 Importance of Cell Type in Response to Oxidative Stress
  • 10.5 Natural Resistance-associated Macrophage Protein (Nramp1)
  • 10.6 Ageing of Cells
  • 10.7 Cell Signalling and Iron
  • 10.8 Apoptosis
  • 10.9 Relationship Between NFKB and NO
  • 10.10 How Does NO and H2O2 Affect the Iron Regulatory Proteins IRP-1 and IRP-2
  • 10.11 Diseases in which Increases in Iron may be Associated with Increased Oxidative Stress in the Cell
  • 10.12 Diseases in which Iron Plays an Important Role
  • 10.13 Neurodegenerative Diseases
  • tidtid62.

Similar Items