Mineral minimization in nature's alternative teeth

Christopher C. Broomell; Rashda K. Khan; Dana N. Moses; Ali Miserez; Michael G. Pontin; Galen D. Stucky; Frank W. Zok; J. Herbert Waite

doi:10.1098/rsif.2006.0153

Mineral minimization in nature's alternative teeth

Christopher C. Broomell, Rashda K. Khan, Dana N. Moses, Ali Miserez, Michael G. Pontin, Galen D. Stucky, Frank W. Zok, J. Herbert Waite^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

60 Citations (Scopus)

Abstract

Contrary to conventional wisdom, mineralization is not the only strategy evolved for the formation of hard, stiff materials. Indeed, the sclerotized mouthparts of marine invertebrates exhibit Young's modulus and hardness approaching 10 and 1 GPa, respectively, with little to no help from mineralization. Based on biochemical analyses, three of these mouthparts, the jaws of glycerid and nereid polychaetes and a squid beak, reveal a largely organic composition dominated by glycine- and histidine-rich proteins. Despite the well-known metal ion binding by the imidazole side-chain of histidine and the suggestion that this interaction provides mechanical support in nereid jaws, there is at present no universal molecular explanation for the relationship of histidine to mechanical properties in these sclerotized structures.

Original language	English
Pages (from-to)	19-31
Number of pages	13
Journal	Journal of the Royal Society Interface
Volume	4
Issue number	12
DOIs	https://doi.org/10.1098/rsif.2006.0153
Publication status	Published - Feb 22 2007
Externally published	Yes

ASJC Scopus Subject Areas

Biotechnology
Biophysics
Bioengineering
Biomaterials
Biochemistry
Biomedical Engineering

Keywords

Copper
Histidine-rich proteins
Polychaete jaws
Sclerotins
Squid beak
Zinc

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1098/rsif.2006.0153

Cite this

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title = "Mineral minimization in nature's alternative teeth",

abstract = "Contrary to conventional wisdom, mineralization is not the only strategy evolved for the formation of hard, stiff materials. Indeed, the sclerotized mouthparts of marine invertebrates exhibit Young's modulus and hardness approaching 10 and 1 GPa, respectively, with little to no help from mineralization. Based on biochemical analyses, three of these mouthparts, the jaws of glycerid and nereid polychaetes and a squid beak, reveal a largely organic composition dominated by glycine- and histidine-rich proteins. Despite the well-known metal ion binding by the imidazole side-chain of histidine and the suggestion that this interaction provides mechanical support in nereid jaws, there is at present no universal molecular explanation for the relationship of histidine to mechanical properties in these sclerotized structures.",

keywords = "Copper, Histidine-rich proteins, Polychaete jaws, Sclerotins, Squid beak, Zinc",

author = "Broomell, {Christopher C.} and Khan, {Rashda K.} and Moses, {Dana N.} and Ali Miserez and Pontin, {Michael G.} and Stucky, {Galen D.} and Zok, {Frank W.} and Waite, {J. Herbert}",

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AU - Broomell, Christopher C.

AU - Khan, Rashda K.

AU - Moses, Dana N.

AU - Miserez, Ali

AU - Pontin, Michael G.

AU - Stucky, Galen D.

AU - Zok, Frank W.

AU - Waite, J. Herbert

PY - 2007/2/22

Y1 - 2007/2/22

N2 - Contrary to conventional wisdom, mineralization is not the only strategy evolved for the formation of hard, stiff materials. Indeed, the sclerotized mouthparts of marine invertebrates exhibit Young's modulus and hardness approaching 10 and 1 GPa, respectively, with little to no help from mineralization. Based on biochemical analyses, three of these mouthparts, the jaws of glycerid and nereid polychaetes and a squid beak, reveal a largely organic composition dominated by glycine- and histidine-rich proteins. Despite the well-known metal ion binding by the imidazole side-chain of histidine and the suggestion that this interaction provides mechanical support in nereid jaws, there is at present no universal molecular explanation for the relationship of histidine to mechanical properties in these sclerotized structures.

AB - Contrary to conventional wisdom, mineralization is not the only strategy evolved for the formation of hard, stiff materials. Indeed, the sclerotized mouthparts of marine invertebrates exhibit Young's modulus and hardness approaching 10 and 1 GPa, respectively, with little to no help from mineralization. Based on biochemical analyses, three of these mouthparts, the jaws of glycerid and nereid polychaetes and a squid beak, reveal a largely organic composition dominated by glycine- and histidine-rich proteins. Despite the well-known metal ion binding by the imidazole side-chain of histidine and the suggestion that this interaction provides mechanical support in nereid jaws, there is at present no universal molecular explanation for the relationship of histidine to mechanical properties in these sclerotized structures.

KW - Copper

KW - Histidine-rich proteins

KW - Polychaete jaws

KW - Sclerotins

KW - Squid beak

KW - Zinc

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Mineral minimization in nature's alternative teeth

Abstract

ASJC Scopus Subject Areas

Keywords

UN SDGs

Access to Document

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