Abstract
Individual molecules of the giant protein titin span the A-bands and I-bands that make up striated muscle. The I-band region of titin is responsible for passive elasticity in such muscle1,2,3,4, and contains tandem arrays of immunoglobulin domains. One such domain (I27) has been investigated extensively, using dynamic force spectroscopy and simulation5,6,7,8,9,10,11,12. However, the relevance of these studies to the behaviour of the protein under physiological conditions was not established. Force studies reveal a lengthening of I27 without complete unfolding, forming a stable intermediate that has been suggested to be an important component of titin elasticity6. To develop a more complete picture of the forced unfolding pathway, we use mutant titins—certain mutations allow the role of the partly unfolded intermediate to be investigated in more depth. Here we show that, under physiological forces, the partly unfolded intermediate does not contribute to mechanical strength. We also propose a unified forced unfolding model of all I27 analogues studied, and conclude that I27 can withstand higher forces in muscle than was predicted previously.
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Acknowledgements
P.M.W. is an EPSRC Advanced Research Fellow, and J.C. is a Wellcome Trust Senior Research Fellow. Funding was provided by the EPSRC, the MRC and the Wellcome Trust. S.B.F. was supported by the EPSRC and Newnham College, and R.B.B. by the Cambridge Commonwealth Trust.
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41586_2003_BFnature01517_MOESM1_ESM.pdf
Supplementary Information: Extends Methods section of manuscript. Describes data analysis in detail. Discusses alternative analysis method. (PDF 150 kb)
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Williams, P., Fowler, S., Best, R. et al. Hidden complexity in the mechanical properties of titin. Nature 422, 446–449 (2003). https://doi.org/10.1038/nature01517
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DOI: https://doi.org/10.1038/nature01517
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