Hostname: page-component-7bb8b95d7b-fmk2r Total loading time: 0 Render date: 2024-09-11T14:21:34.442Z Has data issue: false hasContentIssue false
  • English
  • Français

Studies on Selected Proteins of Bone in Archaeology

Published online by Cambridge University Press:  18 July 2016

Harry Sobel  and
Rainer Berger
Harry Sobel
Affiliation:
Isotope and Archeometry Laboratory, Institute of Geophysics and Planetary Physics University of California, Los Angeles, California 90024 USA
Rainer Berger
Affiliation:
Isotope and Archeometry Laboratory, Institute of Geophysics and Planetary Physics University of California, Los Angeles, California 90024 USA
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

With the advent of AMS radiocarbon dating of very small samples, a much greater opportunity now exists for research into specialized materials. Investigations of the proteins of bone and teeth for archaeological purposes suggest that much more information might be obtained by appropriate study of individual proteins in these tissues. Although present research seems limited to 14C dating, racemization and dietary selection, conditions of the environment during preservation and some of the physiological events during life are likely to be discernible through further studies.

Type
II. 14C in Archaeology
Information
Radiocarbon , Volume 37 , Issue 2 , 1995 , pp. 331 - 335
Copyright
Copyright © the Department of Geosciences, The University of Arizona 

References

Ajie, H. O. (ms.) 1991 Comparison of bone collagen for determination of radiocarbon ages and paleodietary reconstruction. Ph.D. dissertation, University of California, Los Angeles: 140 p.Google Scholar
Ajie, H. O., Hauschka, P. V., Kaplan, I. R. and Sobel, H. 1991 Comparison of bone collagen and osteocalcin for determination of radiocarbon ages and paleodietary reconstruction. Earth and Planetary Science Letters 107(2): 380388.Google Scholar
Berger, R., Fergusson, G. J. and Libby, W. F. 1965 UCLA radiocarbon dates IV. Radiocarbon 7: 336371.Google Scholar
Dallman, R. P. 1990 Iron. In Brown, M. L., ed., Present Knowledge of Nutrition , 6th edition. Washington, D.C., Nutritional Foundation: 241260.Google Scholar
Delmas, P. D., Tracy, R. P., Riggs, B. L. and Mann, K. G. 1984 Identification of the noncollagenous proteins of bovine bone by two dimensional gel electrophoresis. Calcified Tissue Research 36(3): 308316.Google Scholar
Fu, M. X., Wella-Knecht, F. J., Blackledge, A., Lyons, T. J., Thorpe, S. R. and Baynes, J. W. 1994 Glycation, gloxidation and cross-linking of collagen by glucose. Kinetics, mechanisms and inhibition of late stages of the Mailard Reaction. Diabetes 43(5): 676683.CrossRefGoogle Scholar
Gundberg, C. M., Anderson, M., Dickson, I. and Gallop, P. M. 1986 “Glycated” osteocalcin in human and bovine bone. Journal of Biochemical Chemistry 261(1) 1455714561.Google Scholar
Hansen, E. F., Lee, S. N. and Sobel, H. 1992 The effects of relative humidity on some physical properties of modern vellum: Implications for the optimum relative humidity for the display and storage of parchment. Journal of the American Institute for Conservation 31(3): 325342.Google Scholar
Libby, W. F., Berger, R., Mead, J. F., Alexander, G. V. and Ross, J. F. 1964 Replacement rates for human tissue from atmospheric radiocarbon. Science 146(3648): 11701172.Google Scholar
Mimni, M. E., ed., 1988–1989 Collagen V1–5. Boca Raton, Florida, CRC Press.Google Scholar
Noda, M., ed., 1993 Cellular and Molecular Biology of Bone. San Diego, Academic Press: 1567.Google Scholar
Poser, J. W., Esch, F. S., Ling, N. C. and Price, P. A. 1980 Isolation and sequence of the vitamin K-dependent bone protein. Journal of Biological Chemistry 255 (18): 86858691.CrossRefGoogle Scholar
Price, P. A. and Baukol, S. 1981 1,25–dihydroxy vitamin D3 increases serum levels of the vitamin K-dependent bone protein. Biochemical and Biophysical Research Communications 99(3): 928933.Google Scholar
Price, P. A., Poser, J. W. and Ramon, N. 1976 Primary structure of the γ-carboxy glutamic acid-containing protein from bovine bone. Proceedings of the National Academy of Sciences 73(10): 33743375.Google Scholar
Puleo, L. E. and Sobel, H. 1972 Oxygen-modified collagen and its possible pathological significance. Aerospace Medicine 43(4): 429431.Google Scholar
Sobel, H. and Ajie, H. 1992 Modification in amino acids of Dead Sea Scroll parchments. Free-Radical Biology and Medicine 13(6): 701702.Google Scholar
Stadman, E. R. 1993 Oxidation of free amino acids and amino acid residues in proteins by radiolysis and by metal catalyzed reactions. In Annual Reviews of Biochemistry 62: 797821. Palo Alto, California, Annual Reviews Inc. Google Scholar
Termine, J. D. 1993 Bone matrix proteins and the mineralization process. In Favus, M. J., ed., Primer on the Metabolic Bone Diseases and Disorders of Mineral Metabolism. New York, Raven Press: 2125.Google Scholar
Theil, E. C. 1987 Ferritin: Structure, gene regulation and cellular function in animals, plants and microorganisms. In Annual Reviews of Biochemistry 56: 289315. Palo Alto, California, Annual Reviews Inc. Google Scholar
Tuma, D. J., Hoffman, T. and Sorrel, M. F. 1991 The chemistry of acetaldehyde-protein adducts. Alcohol Alcoholism , Supplement 1: 271276.Google Scholar
Tuross, N., Eyre, D. R., Holtrop, M. E., Glimcher, M. J. and Hare, P. E. 1978 Collagen in fossil bones. In Hare, P. E., ed., Biochemistry in Amino Acids. New York, John Wiley & Sons: 5363.Google Scholar
Tuross, N. and Strathoples, L. 1993 Ancient proteins in fossil bones. Methods in Enzymology 224: 121129.CrossRefGoogle ScholarPubMed