"From ions to life–minerals: there is a bio–inspired growth pathway paved by enzymes! From Buchner’s discovery of cell–free fermentation and enzymology to modern day biochemistry – there are still many more paths to explore! This volume is an excellent training manual for such expeditions." ( Coordination Chemistry Reviews, July 2009)

HISTORICAL DEVELOPMENT AND PERSPECTIVES OF THE SERIES.

PREFACE TO VOLUME 4.

CONTRIBUTORS TO VOLUME 4.

TITLES OF VOLUMES 1–44 IN THE METAL IONS IN BIOLOGICAL SYSTEMS SERIES.

CONTENTS OF VOLUMES IN THE METAL IONS IN LIFE SCIENCES SERIES.

(1) Crystals and Life. An Introduction (Arthur Veis).

Abstract.

1. Introduction.

2. Global Effects.

3. Minerals within Living Systems.

4. Concluding Remarks.

Acknowledgments.

Abbreviations.

References.

(2) What Genes and Genomes Tell Us about Calcium Carbonate Biomineralization (Fred H. Wilt and Christopher E. Killian).

Abstract.

1. Introduction.

2. One Gene–One Protein Approaches.

3. Many Genes–One Structure Approaches.

4. General Conclusions.

Acknowledgments.

Abbreviations.

References.

(3) The Role of Enzymes in Biomineralization Processes (Ingrid M. Weiss and Frédéric Marin).

Abstract.

1. Introduction.

2. From Ions to Minerals: A Pathway Paved by Enzymes.

3. The “Evolution” of Solids: A Complex Network of Regulation.

4. Mimicking Nature: How Far Can the Design of Biomineralization Enzymes Take Us?

5. Conclusions.

Acknowledgments.

Abbreviations.

References. 

(4) Metal–Bacteria Interactions at Both the Planktonic Cell and Biofilm Levels (Ryan C. Hunter and Terry J. Beveridge).

Abstract.

1. Introduction.

2. Planktonic Bacterial Cells.

3. Metal–Microbe Interactions.

4. Microbial Biofilm Communities.

5. Biofilm Microenvironments and Their Impact on Geochemical Interactions.

6. Concluding Remarks.

Acknowledgments.

Abbreviations and Definitions.

References.

(5) Biomineralization of Calcium Carbonate. The Interplay with Biosubstrates (Amir Berman).

Abstract.

1. Introduction.

2. Control in Biological Mineralization.

3. Recent Perspectives on Mineralization Strategies.

4. CaCO3 Growth in Confinement.

5. Crystal Assembly.

6. In Vitro Studies of CaCO3 Mineralization.

7. Calcium Carbonate Nucleation and Growth on Artificial Substrates.

8. Summary and Outlook.

Acknowledgments.

Abbreviations.

References.

(6) Sulfate–Containing Biominerals (Fabienne Bosselmann and Matthias Epple).

Abstract.

1. Sulfate–Containing Biominerals: An Overview.

2. Gypsum and Bassanite (Calcium Sulfates).

3. Celestite (Strontium Sulfate).

4. Barite (Barium Sulfate).

5. Jarosite (Potassium Iron Hydroxide Sulfate).

6. Concluding Remarks.

Acknowledgments.

References.

7 OXALATE BIOMINERALS.

(7) Oxalate Biominerals (Enrique J. Baran and Paula V. Monje).

Abstract.

1. Introduction.

2. Metallic Oxalates: Physico–Chemical and Structural Properties.

3. Calcium Oxalates in Plants.

4. Calcium Oxalates in Other Forms of Life.

5. Other Oxalate Biominerals.

6. Pathological Oxalates.

7. Oxalates in the Environment.

8. Oxalate Degrading Systems.

9. Conclusions and Perspectives.

Acknowledgments.

Abbreviations.

References.

8 MOLECULAR PROC.

(8) Molecular Processes of Biosilicification in Diatoms (Aubrey K. Davis and Mark Hildebrand).

Abstract.

1. Introduction.

2. Silicon Transport.

3. Silica Structure Formation.

4. Regulation of Structure Formation.

5. Manipulation of Diatom Silica Structure.

6. Concluding Remarks and Future Directions.

Acknowledgments.

Abbreviations.

References.

(9) Heavy Metals in the Jaws of Invertebrates (Helga C. Lichtenegger, Henrik Birkedal, and J. Herbert Waite).

Abstract.

1. Introduction.

2. Iron Biomineralization in Chitons and Limpets.

3. Copper and Zinc in Marine Worm Jaws.

4. Zinc and Manganese in Arthropods.

5. Heavy Metals and Jaw Mechanics.

6. General Conclusions.

Acknowledgment.

Abbreviations and Definitions.

References.

(10) Ferritin. Biomineralization of Iron (Elizabeth C. Theil, Xiaofeng S. Liu, and Manolis Matzapetakis).

Abstract.

1. Introduction.

2. Protein Nanocage Structures.

3. Iron Entry: The Protein Ferroxidase Site.

4. Mineral Precursor Translocation, Nucleation, and Mineralization.

5. Ferritin Demineralization and the Nanocage Gated Pores.

6. Summary and Perspective.

Acknowledgments.

Abbreviations and Definitions.

References.

(11) Magnetism and Molecular Biology of Magnetic Iron Minerals in Bacteria (Richard B. Frankel, Sabrina Schübbe, and Dennis A. Bazylinski).

Abstract.

1. Introduction. Magnetotactic Bacteria.

2. Molecular Biology of Magnetosome Chain Formation.

3. Magnetic Properties of Magnetosomes.

4. Conclusions.

Acknowledgments.

Abbreviations.

References.

(12) Biominerals. Recorders of the Past? (Danielle Fortin, Sean Langley, and Susan Glasauer).

Abstract.

1. Introduction.

2. What Are Biominerals?

3. Biominerals as Biosignatures?

4. Tools to Study Biosignatures.

5. General Conclusions.

Acknowledgments.

Abbreviations.

References.

(13) Dynamics of Biomineralization and Biodemineralization (Lijun Wang and George H. Nancollas).

Abstract.

1. Introduction.

2. Nucleation and Crystal Growth.

3. Dissolution.

4. Conclusion and Future Directions.

Acknowledgments.

Abbreviations and Definitions.

List of Symbols.

References.

(14) Mechanism of Mineralization of Collagen–Based Connective Tissues (Adele L. Boskey).

Abstract.

1. Introduction.

2. Function of Collagen in the Regulation of Vertebrate Biomineralization.

3. Comparative Composition of the Organic Components of Collagenous Mineralized Tissues.

4. Is there a Uniform Theory of Vertebrate Mineralization?

Acknowledgments.

Abbreviations.

References.

(15) Mammalian Enamel Formation (Janet Moradian–Oldak and Michael L. Paine).

Abstract.

1. Introduction.

2. Delineation of the Extracellular Space.

3. Ion Composition and Transport.

4. The Organic Matrix Components.

5. Function of Organic Matrix in Enamel Formation.

6. Matrix Degradation.

7. Conclusions.

Acknowledgments.

Abbreviations.

References.

(16) Mechanical Design of Biomineralized Tissues. Bone and Other Hierarchical Materials (Peter Fratzl).

Abstract.

1. Introduction.

2. Growth, Self–Repair, and Structural Hierarchies.

3. Hierarchical Structure of Bone.

4. Hierarchical Structure of a Silica Sponge Skeleton.

5. Some Structural Elements with Mechanical Function.

6. Conclusions.

Acknowledgments.

References.

(17) Bioinspired Growth of Mineralized Tissue (Darilis Suárez–González and William L. Murphy).

Abstract.

1. Introduction.

2. Natural Development of Bone.

3. Connective Tissue Progenitor Cells.

4. Inductive Soluble Factors.

5. Bone Structural Properties.

6. Scaffold Materials for Bioinspired Mineralized Tissue Fabrication.

7. Summary.

Acknowledgments.

Abbreviations and Definitions.

References.

(18) Polymer–Controlled Biomimetic Mineralization of Novel Inorganic Materials (Helmut Cölfen and Markus Antonietti).

Abstract.

1. Introduction.

2. Different Crystallization Modes and Ways to Modify Crystallization.

3. Polymer–Controlled Crystallization.

4. Conclusion.

5. Current Trends and Outlook to the Future.

Acknowledgments.

Abbreviations.

References.

SUBJECT INDEX.

Mrs. Astrid Sigel, Prof. Helmut Sigel and, c/o Dept. of Chemistry, Inorganic Chemistry, University of Basel, Spitalstrasse 51, CH–4056 Basel, Switzerland  

Professor Roland K. O. Sigel, Institute of Inorganic Chemistry, University of Zurich, Winterthurerstrasse 190, CH–8057 Zurich, Switzerland

Volume 4 focuses on the vibrant research area centering around Biomineralization and its role in Nature and in biomimetic applications. With nearly 2700 references, 14 tables, and more than 140 illustrations, it is an essential resource for scientists working in the wide range from material sciences and inorganic biochemistry all the way through to medicine including the clinic.

In 18 stimulating chapters, written by 36 internationally recognized experts, Biomineralization. From Nature to Application highlights critically the interrelations between crystals and life. The volume covers the role of genes and genomes as well as enzymes on biomineralization processes; carbonate, sulfate, oxalate, and silicate biominerals; heavy metals, ferritin, and magnetotactic bacteria; the formation of bone, dentin, enamel, etc; the dynamics of biomineralization and biodemineralization; the mechanical design and bioinspired growth of mineralized tissues; and polymer–controlled biomimetic mineralizations for diverse applications.