Papers Published

  1. Li, H. B. and Linke, W. A. and Oberhauser, A. F. and Carrion-Vazquez, M. and Kerkviliet, J. G. and Lu, H. and Marszalek, P. E. and Fernandez, J. M., Reverse engineering of the giant muscle protein titin, Nature, vol. 418 no. 6901 (2002), pp. 998-1002 .
    (last updated on 2007/11/30)

    Through the study of single molecules it has become possible to explain the function of many of the complex molecular assemblies found in cells(1-5). The protein titin provides muscle with its passive elasticity. Each titin molecule extends over half a sarcomere, and its extensibility has been studied both in situ(6-10) and at the level of single molecules(11-14). These studies suggested that titin is not a simple entropic spring but has a complex structure-dependent elasticity. Here we use protein engineering and single-molecule atomic force microscopy(15) to examine the mechanical components that form the elastic region of human cardiac titin(16,17). We show that when these mechanical elements are combined, they explain the macroscopic behaviour of titin in intact muscle(6). Our studies show the functional reconstitution of a protein from the sum of its parts.