Contour length and refolding rate of a small protein controlled by engineered disulfide bonds

doi:10.1529/biophysj.106.091561

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Biophys. J. BioFAST: First Published October 6, 2006. doi:10.1529/biophysj.106.091561
© 2006 by the Biophysical Society.

A more recent version of this article appeared on January 1, 2007.

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PROTEINS

Contour length and refolding rate of a small protein controlled by engineered disulfide bonds

Sri Rama Koti ainavarapu ¹^*, Jasna Brujic ¹, Hector H. Huang ¹, Arun P. Wiita ¹, Hui Lu ², Lewyn Li ³, kirstin A. Walther ¹, Mariano Carrion-Vazquez ⁴, Hongbin Li ⁵ and Julio M. Fernandez ¹

¹ Columbia University
² University of Illinois at Chicago
³ Columbia university
⁴ Instituto Cajal, Consejo Superior de Investigaciones Cientificas
⁵ University of British Columbia

^* To whom correspondence should be addressed. E-mail: sra2104{at}columbia.edu.

Submitted on June 17, 2006
Revised on August 5, 2006
Accepted on 13 September 2006

Abstract
The introduction of disulfide bonds into proteins creates additionalmechanical barriers and limits the unfolded contour length (i.e.,the maximal extension) measured by single-molecule force spectroscopy.Here, we engineer single disulfide bonds into four differentlocations of the human cardiac titin module (I27) to controlthe contour length, while keeping the distance to the transitionstate unchanged. This enables the study of several biologicallyimportant parameters. First, we are able to precisely determinethe end-to-end length of the transition state prior to unfolding(53 Å), which is longer than the end-to-end length ofthe protein obtained from NMR spectroscopy (43 Å). Secondly,the measured contour length per amino acid from five differentmethods (4.0 ± 0.2 Å) is longer than the end-to-endlength obtained from the crystal structure (3.6 Å). Ourmeasurement of the contour length takes into account all theinternal degrees of freedom of the polypeptide chain, whilecrystallography measures the end-to-end length within the 'frozen'protein structure. Furthermore, the control of contour lengthand therefore the number of amino acids unraveled prior to reachingthe disulfide bond (n) facilitates the test of the chain lengthdependence on the folding time ( ${tau}$ _F). We find that both a powerlaw scaling ${tau}$ _F~n with ${lambda}$ = 4.4, and an exponential scaling withn^0.6 fit the data range, in support of different protein foldingscenarios.

Key Words: disulfide engineering, force spectroscopy, mechanical unfolding, protein folding, single molecule, titin I27

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