Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in Health and Disease

doi:10.2174/187231309788166398

. 2009 May 1;3(2):189-196.

doi: 10.2174/187231309788166398.

Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in Health and Disease

Xu Feng¹

Affiliations

PMID: 20161446
PMCID: PMC2790195
DOI: 10.2174/187231309788166398

Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in Health and Disease

Xu Feng. Curr Chem Biol. 2009.

. 2009 May 1;3(2):189-196.

doi: 10.2174/187231309788166398.

Author

Xu Feng¹

Affiliation

¹ Department of Pathology, University of Alabama at Birmingham, Birmingham, AL 35294, USA.

PMID: 20161446
PMCID: PMC2790195
DOI: 10.2174/187231309788166398

Abstract

Bone, a calcified tissue composed of 60% inorganic component (hydroxyapatite), 10% water and 30% organic component (proteins), has three functions: providing mechanical support for locomotion, protecting vital organs, and regulating mineral homeostasis. A lifelong execution of these functions depends on a healthy skeleton, which is maintained by constant bone remodeling in which old bone is removed by the bone-resorbing cell, osteoclasts, and then replaced by new bone formed by the bone-forming cell, osteoblasts. This remodeling process requires a physical interaction of bone with these bone cells. Moreover, numerous cancers including breast and prostate have a high tendency to metastasize to bone, which is in part attributable to the capacity of the tumor cells to attach to bone. The intensive investigation in the past two decades has led to the notion that the cell-bone interaction involves integrins on cell surface and bone matrix proteins. However, the biochemical composition of bone and emerging evidence are inconsistent with this belief. In this review, I will discuss the current understanding of the molecular mechanism underlying the cell-bone interaction. I will also highlight the facts and new findings supporting that the inorganic, rather than the organic, component of bone is likely responsible for cellular attachment.

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Figures

**Fig. (1)**
Osteoclast Differentiation and Function Depend on Attachment on Bone Matrix

**Fig. (2)**
Osteoblast Differentiation and Function in Bone Remodeling

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References

1. Morgan EF, Barnes GL, Einhorn TA. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 3–26.
1. Zhu W, Robey PG, Boskey AL. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 191–240.
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[1] Morgan EF, Barnes GL, Einhorn TA. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 3–26.

[2] Morgan EF, Barnes GL, Einhorn TA. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 3–26.

[3] Zhu W, Robey PG, Boskey AL. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 191–240.

[4] Zhu W, Robey PG, Boskey AL. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 191–240.

[5] Parfitt AM. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 71–92.

[6] Parfitt AM. In: Osteoporosis. Marcus R, Feldman D, Nelson DA, Rosen CJ, editors. Academic Press; San Diego: 2008. pp. 71–92.

[7] Teitelbaum SL. Bone resorption by osteoclasts. Science. 2000;289:1504–1508. - PubMed

[8] Teitelbaum SL. Bone resorption by osteoclasts. Science. 2000;289:1504–1508. - PubMed

[9] Teitelbaum SL, Ross FP. Genetic regulation of osteoclast development and function. Nature Reviews Genetics. 2003;4:638–649. - PubMed

[10] Teitelbaum SL, Ross FP. Genetic regulation of osteoclast development and function. Nature Reviews Genetics. 2003;4:638–649. - PubMed

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Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in Health and Disease

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Chemical and Biochemical Basis of Cell-Bone Matrix Interaction in Health and Disease

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