The in situ supermolecular structure of type I collagen

Orgel, Joseph P. R. O.; Miller, Andrew; Irving, Thomas C.; Fischetti, Robert F.; Hammersley, Andrew P.; Wess, Tim J.

Affiliations

¹Centre for Extracellular Matrix Biology, Department of Biological Sciences, University of Stirling, Stirling FK9 4LA, United Kingdom

²Center for Synchrotron Radiation Research and Instrumentation, Department of Biological, Chemical, and Physical Sciences, Illinois Institute of Technology, 3101 South Dearborn Street, Chicago, Illinois 60616

³European Synchrotron Radiation Facility BP220 Grenoble F-38043, France

Abstract and keywords

Background: The proteins belonging to the collagen family are ubiquitous throughout the animal kingdom. The most abundant collagen, type I, readily forms fibrils that convey the principal mechanical support and structural organization in the extracellular matrix of connective tissues such as bone, skin, tendon, and vasculature. An understanding of the molecular arrangement of collagen in fibrils is essential since it relates molecular interactions to the mechanical strength of fibrous tissues and may reveal the underlying molecular pathology of numerous connective tissue diseases.

Results: Using synchrotron radiation, we have conducted a study of the native fibril structure at anisotropic resolution (5.4 Å axial and 10 Å lateral). The intensities of the tendon X-ray diffraction pattern that arise from the lateral packing (three-dimensional arrangement) of collagen molecules were measured by using a method analogous to Rietveld methods in powder crystallography and to the separation of closely spaced peaks in Laue diffraction patterns. These were then used to determine the packing structure of collagen by MIR.

Conclusions: Our electron density map is the first obtained from a natural fiber using these techniques (more commonly applied to single crystal crystallography). It reveals the three-dimensional molecular packing arrangement of type I collagen and conclusively proves that the molecules are arranged on a quasihexagonal lattice. The molecular segments that contain the telopeptides (central to the function of collagen fibrils in health and disease) have been identified, revealing that they form a corrugated arrangement of crosslinked molecules that strengthen and stabilize the native fibril.

Keywords: collagen; extracellular matrix; structure; X-ray diffraction; packing; fibril

Links

DOI: 10.1016/S0969-2126(01)00669-4

PubMed: 11709170

WoS: 000172132300007

History

Received: 2001-06-01

Revised: 2001-09-06

Accepted: 2001-09-10

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2014	Reznikov N, Shahar R, Weiner S. Bone hierarchical structure in three dimensions. Acta Biomater. September 2014;10(8):3815-3826.
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2020	Maghsoudi-Ganjeh M, Wang X, Zeng X. Nanomechanics and ultrastructure of bone: a review. Comput Model Eng Sci. 2020;125(1):1-32.
2005	Lorenzo AC, Caffarena ER. Elastic properties, Young’s modulus determination and structural stability of the tropocollagen molecule: a computational study by steered molecular dynamics. J Biomech. July 2005;38(7):1527-1533.
2011	Uzel SGM, Buehler MJ. Molecular structure, mechanical behavior and failure mechanism of the C-terminal cross-link domain in type I collagen. J Mech Behav Biomed Mater. February 2011;4(2):153-161.
2012	Alexander B, Daulton TL, Genin GM, Lipner J, Pasteris JD, Wopenka B, Thomopoulos S. The nanometre-scale physiology of bone: steric modelling and scanning transmission electron microscopy of collagen-mineral structure. J R Soc Interface. August 7, 2012;9(73):1774-1786.
2011	Gautieri A, Vesentini S, Redaelli A, Buehler MJ. Hierarchical structure and nanomechanics of collagen microfibrils from the atomistic scale up. Nano Lett. February 9, 2011;11(2):757-766.
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2011	Reisinger AG. Modeling and Validation of Multiscale Lamellar Bone Elasticity [PhD thesis]. Vienna University of Technology; November 2011.
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2014	Reznikov N. The Adaptation of Mechanical Properties of Lamellar Bone Tissue [PhD thesis]. Weizmann Institute of Science; July 2014.