Abstract
Titin is a giant elastomeric protein responsible for the generation of passive muscle force. Mechanical force unfolds titin’s globular domains, but the exact structure of the overstretched titin molecule is not known. Here we analyzed, by using high-resolution atomic force microscopy, the structure of titin molecules overstretched with receding meniscus. The axial contour of the molecules was interrupted by topographical gaps with a mean width of 27.7 nm that corresponds well to the length of an unfolded globular (immunoglobulin and fibronectin) domain. The wide gap-width distribution suggests, however, that additional mechanisms such as partial domain unfolding and the unfolding of neighboring domain multimers may also be present. In the folded regions we resolved globules with an average spacing of 5.9 nm, which is consistent with a titin chain composed globular domains with extended interdomain linker regions. Topographical analysis allowed us to allocate the most distal unfolded titin region to the kinase domain, suggesting that this domain systematically unfolds when the molecule is exposed to overstretching forces. The observations support the prediction that upon the action of stretching forces the N-terminal ß-sheet of the titin kinase unfolds, thus exposing the enzyme’s ATP-binding site and hence contributing to the molecule’s mechanosensory function.
Highlights
Titin forms a filamentous scaffold within the muscle sarcomere [1,2,3,4]
Titin is a linear chain of globular domains interrupted with unique sequences, most notably the unstructured proline (P), glutamate (E), valine (V) and lysine (K)-rich PEVK domain [5]
Stretching Titin with Receding Meniscus Titin was extended by molecular combing with receding meniscus based on steps reported earlier [24] (Fig. 1)
Summary
Titin ( known as connectin) forms a filamentous scaffold within the muscle sarcomere [1,2,3,4]. The response of titin to mechanical forces has been quite extensively studied in single-molecule experiments [9,10,11], suggesting that titin behaves as an entropic polymer chain in which mechanical force induces domain unfolding. The mechanical stabilities of a few recombinant globular titin domains have been characterized and compared [22], and it is generally thought that force imposes a temporal order on the domain-unfolding sequence so that mechanically weak domains unfold first [11]. In the present work we combined molecular combing, driven by a receding meniscus, with high-resolution atomic force microscopy (AFM) imaging, which enabled us to resolve detail, including the presence of individual unfolded and globular domains in overstretched single titin molecules. Based on topographical distance mapping we infer that the unfolded titin region nearest its M-line end is likely part of the kinase domain, which is consistent with prior experimental evidence [26] suggesting that the titin kinase may sense forces via mechanically-driven partial unfolding
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