Crossbridge and filament compliance in muscle: implications for tension generation and lever arm swing

Autor:	K. W. Ranatunga, Gerald Offer
Rok vydání:	2010
Předmět:	Sarcomeres Ranidae Physiology Movement Edible frog macromolecular substances Isometric exercise Myosins Biochemistry Rana Protein filament Myosin head CrossBridge Isometric Contraction biology.animal Myosin Animals Muscle Skeletal Cytoskeleton Actin biology Chemistry Muscles Cell Biology Anatomy Actins Elasticity Biomechanical Phenomena Models Structural Actin Cytoskeleton Muscle Tonus Biophysics Thermodynamics Rabbits
Zdroj:	Journal of Muscle Research and Cell Motility. 31:245-265
ISSN:	1573-2657 0142-4319
DOI:	10.1007/s10974-010-9232-7
Popis:	The stiffness of myosin heads attached to actin is a crucial parameter in determining the kinetics and mechanics of the crossbridge cycle. It has been claimed that the stiffness of myosin heads in the anterior tibialis muscle of the common frog (Rana temporaria) is as high as 3.3 pN/nm, substantially higher than its value in rabbit muscle (~1.7 pN/nm). However, the crossbridge stiffness measurement has a large error since the contribution of crossbridges to half-sarcomere compliance is obtained by subtracting from the half-sarcomere compliance the contributions of the thick and thin filaments, each with a substantial error. Calculation of its value for isometric contraction also depends on the fraction of heads that are attached, for which there is no consensus. Surprisingly, the stiffness of the myosin head from the edible frog, Rana esculenta, determined in the same manner, is only 60% of that in Rana temporaria. In our view it is unlikely that the value of such a crucial parameter could differ so substantially between two frog species. Since the means of the myosin head stiffness in these two species are not significantly different, we suggest that the best estimate of the stiffness of the myosin heads for frog muscle is the average of these data, a value similar to that for rabbit muscle. This would allow both frog and rabbit muscles to operate the same low-cooperativity mechanism for the crossbridge cycle with only one or two tension-generating steps. We review evidence that much of the compliance of the myosin head is located in the pliant region where the lever arm emerges from the converter and propose that tension generation ("tensing") caused by the rotation and movement of the converter is a separate event from the passive swinging of the lever arm in its working stroke in which the strain energy stored in the pliant region is used to do work.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::825a7c890212fd7c3ac517f5b2d81459 https://doi.org/10.1007/s10974-010-9232-7 Zobrazit plný text záznamu Full text from SpringerLink