TY - JOUR
T1 - Different molecular mechanics displayed by titin's constitutively and differentially expressed tandem Ig segments
AU - Watanabe, Kaori
AU - Muhle-Goll, Claudia
AU - Kellermayer, Miklós S.Z.
AU - Labeit, Siegfried
AU - Granzier, Henk
N1 - Funding Information:
We gratefully acknowledge Dr. Robert Yamasaki for purifying I91–98, and the generous financial support by the Deutsche Forschungsge-meinschaft (MU 1606/1-1 to C.M.G.; La668/6-2 to S.L.) and the NIH (HL61497 and HL62881 to H.G.), and by the Hungarian Science Foundation (OTKA F025353) TO M.S.Z.K. M.S.Z.K. is a Howard Hughes Medical Institute International Research Scholar.
PY - 2002
Y1 - 2002
N2 - Titin is a giant elastic protein responsible for passive force generated by the stretched striated-muscle sarcomere. Passive force develops in titin's extensible region which consists of the PEVK segment in series with tandemly arranged immunoglobulin (Ig)-like domains. Here we studied the mechanics of tandem Ig segments from the differentially spliced (I65-70) and constitutive (I91-98) regions by using an atomic force microscope specialized for stretching single molecules. The mechanical stability of I65-70 domains was found to be different from that of I91-98 domains. In the range of stretch rates studied (0.05-1.00 μm/s) lower average domain unfolding forces for I65-70 were associated with a weaker stretch-rate dependence of the unfolding force, suggesting that the differences in the mechanical stabilities of the segments derive from differences in the zero force unfolding rate (Ku0) and the characteristic distance (location of the barrier) along the unfolding reaction coordinate (ΔXu). No effect of calcium was found on unfolding forces and persistence length of unfolded domains. To explore the structural basis of the differences in mechanical stabilities of the two fragment types, we compared the amino acid sequence of I65-70 domains with that of I91-98 domains and by using homology modeling analyzed how sequence variations may affect folding free energies. Simulations suggest that differences in domain stability are unlikely to be caused by variation in the number of hydrogen bonds between the force-bearing β-strands at the domain's N- and C-termini. Rather, they may be due to differences in hydrophobic contacts and strand orientations.
AB - Titin is a giant elastic protein responsible for passive force generated by the stretched striated-muscle sarcomere. Passive force develops in titin's extensible region which consists of the PEVK segment in series with tandemly arranged immunoglobulin (Ig)-like domains. Here we studied the mechanics of tandem Ig segments from the differentially spliced (I65-70) and constitutive (I91-98) regions by using an atomic force microscope specialized for stretching single molecules. The mechanical stability of I65-70 domains was found to be different from that of I91-98 domains. In the range of stretch rates studied (0.05-1.00 μm/s) lower average domain unfolding forces for I65-70 were associated with a weaker stretch-rate dependence of the unfolding force, suggesting that the differences in the mechanical stabilities of the segments derive from differences in the zero force unfolding rate (Ku0) and the characteristic distance (location of the barrier) along the unfolding reaction coordinate (ΔXu). No effect of calcium was found on unfolding forces and persistence length of unfolded domains. To explore the structural basis of the differences in mechanical stabilities of the two fragment types, we compared the amino acid sequence of I65-70 domains with that of I91-98 domains and by using homology modeling analyzed how sequence variations may affect folding free energies. Simulations suggest that differences in domain stability are unlikely to be caused by variation in the number of hydrogen bonds between the force-bearing β-strands at the domain's N- and C-termini. Rather, they may be due to differences in hydrophobic contacts and strand orientations.
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U2 - 10.1006/jsbi.2002.4458
DO - 10.1006/jsbi.2002.4458
M3 - Article
C2 - 12064950
AN - SCOPUS:18744374455
SN - 1047-8477
VL - 137
SP - 248
EP - 258
JO - Journal of Structural Biology
JF - Journal of Structural Biology
IS - 1-2
ER -