The relative contributions of the folds and caveolae to the surface membrane of frog skeletal muscle fibres at different sarcomere lengths.

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The relative contributions of the folds and caveolae to the surface membrane of frog skeletal muscle fibres at different sarcomere lengths.

A F Dulhunty and C Franzini-Armstrong

The plasmalemmal area of striated muscle fibres is greater thanthe apparent surface area (A = circumference x length) becauseof variable folds and the invaginations of the caveolae andT-tubules. Freeze-fracture replicas of the surface membraneof sartorius and semitendinosus muscles from Rana pipiens havebeen used to determine the numbers and distribution of foldsand caveolae at different sarcomere lengths. (1) The plasmalemmafolds are variable in size and shape, but are always orientedperpendicular to the long axis of the fibre. The folds varywith stretch, being more prominent at short sarcomere lengths.The caveolae are elliptical invaginations of the plasmalemmawhich open to the outside by a narrow "neck" of approximately20 nm. The caveolar lumen has an average long dimension of 81.6+/- 11.7 nm and an average short dimension of 66.9 +/- 7.9 nm.The caveolar "necks" only can be seen in freeze-fracture replicasand these are distributed in two circumferential bands on eitherside of the Z-line, and in longitudinal bands separated by distancesof 1-5 mum. In the sartorius muscle, at a sarcomere length of2.8 mum, there is an average number of thirty-seven caveolaeper square micrometer of fibre surface. (2) During passive stretchthe opening of folds provides membrane for the necessary increasein surface area up to a sarcomere length of about 3.0 mum. Thislength is defined as the critical sarcomere length (Sc). Thenumber of caveolae remains constant at all sarcomere lengthsless than Sc and thus their "necks" have been used as membranemarkers to determine the amount of folding at different sarcomerelengths. The membrane area contained in folds and caveolae isexpressed as a fraction of the apparent surface area (A). Forexample, in the sartorius muscle, at a sarcomere length of 2.4mum, the membrane area, excluding the T-tubules, is: A + 0.1A(folding) + 0.7A (caveolae) = 1.8A. (3) For stretch beyond Scmembrane is provided by the opening of caveolae. At a sarcomerelength of about 8 mum all the caveolae are open and the fibresrupture with further stretch. (4) The relative contributionsof folds and caveolae vary with sarcomere length in a way thatis consistent with assumptions of constant volume and plasmalemmaarea. The maintenance of constant plasmalemma area, even afterexcessive stretch, suggests that the plasmalemma is relativelyinelastic in this situation.

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