AI Article Synopsis
- Type I collagen is crucial for the structure and strength of connective tissues, but its triple-helical forms are unstable at body temperature, prompting studies on its stability at the fibril level.* -
- Experiments show that heating collagen fibrils causes a decrease in stiffness (Young's modulus) until 58°C, after which stabilization occurs due to intermolecular interactions, alongside water absorption and increased internal friction.* -
- The findings suggest a new intermolecular mechanism for collagen stability, which could enhance our understanding of how these proteins maintain their function in biological tissues.*
Article Abstract
Background: Type I collagen is the most common protein among higher vertebrates. It forms the basis of fibrous connective tissues (tendon, chord, skin, bones) and ensures mechanical stability and strength of these tissues. It is known, however, that separate triple-helical collagen macromolecules are unstable at physiological temperatures. We want to understand the mechanism of collagen stability at the intermolecular level. To this end, we study the collagen fibril, an intermediate level in the collagen hierarchy between triple-helical macromolecule and tendon.
Methodology/principal Finding: When heating a native fibril sample, its Young's modulus decreases in temperature range 20-58°C due to partial denaturation of triple-helices, but it is approximately constant at 58-75°C, because of stabilization by inter-molecular interactions. The stabilization temperature range 58-75°C has two further important features: here the fibril absorbs water under heating and the internal friction displays a peak. We relate these experimental findings to restructuring of collagen triple-helices in fibril. A theoretical description of the experimental results is provided via a generalization of the standard Zimm-Bragg model for the helix-coil transition. It takes into account intermolecular interactions of collagen triple-helices in fibril and describes water adsorption via the Langmuir mechanism.
Conclusion/significance: We uncovered an inter-molecular mechanism that stabilizes the fibril made of unstable collagen macromolecules. This mechanism can be relevant for explaining stability of collagen.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3823754 | PMC |
| http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0078526 | PLOS |
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