To determine whether the apparent enhanced force-generating capabilities of smooth muscle relative to skeletal muscle are inherent to the myosin cross-bridge, the isometric steady-state force produced by myosin in the in vitro motility assay was measured. In this assay, myosin adhered to a glass surface pulls on an actin filament that is attached to an ultracompliant nm/pN) glass microneedle. The number of myosin cross-bridge heads able to interact with a length of actin filament was estimated by measuring the density of biochemically active myosin adhered to the surface; with this estimate, the average force per cross-bridge head ofsmooth and skeletal muscle myosins is 0.6 pN and 0.2 pN, respectively. Surprisingly, smooth muscle myosin generates approximately three times greater average force per cross-bridge head than does skeletal muscle myosin.All muscles are believed to generate force through the cyclic interaction of two contractile proteins, myosin and actin. The energy that drives this process is derived from the hydrolysis of ATP by the myosin cross-bridge. Smooth muscle, found in virtually all hollow organs of the body, is unique in its ability to generate as much force per cross-sectional area as skeletal muscle with only one-fifth the myosin content (1). Although this apparent difference could possibly be explained at the tissue or cellular level, when these data are interpreted at the molecular level, smooth muscle cross-bridges may generate greater average force than skeletal muscle cross-bridges. To test this hypothesis, we used an in vitro motility assay.The in vitro motility assay has proven a useful tool in studying the molecular mechanism by which myosin generates force and motion as it interacts with actin (2-4). In this assay, fluorescently labeled actin flaments are observed sliding over a myosin-coated surface. Although the velocity of freely moving actin filaments can be readily determined, the measurement of force is far more difficult. In 1988, Kishino and Yanagida (5) described a novel technique for measuring force in this assay. We have adopted this technique ( Fig. 1) to compare the force generated by smooth and skeletal muscle myosin.
MATERIALS AND METHODSAll contractile proteins were prepared as described (4). Either turkey gizzard thiophosphorylated smooth muscle or chicken pectoralis skeletal muscle myosin monomers (250 ,g/ml) in a myosin buffer (300 mM KCl/5 mM MgCl2/25 mM imidazole/1 mM EGTA/10 mM dithiothreitol, pH 7.4) were incubated on a nitrocellulose-coated glass coverslip for 2 min and then washed with bovine serum albumin at 0.5 mg/ml in myosin buffer. Next, a 0.1-ml-solution bead of low-ionic-strength assay buffer containing fluorescent, tetramethylrhodamine B isothiocyanate-labeled actin filaments (-45 0.375% methylcellulose, pH 7.4, with an enzymatic oxygen scavenger system (glucose oxidase at 0.1 mg/ml, catalase at 0.018 mg/ml, and glucose at 2.3 mg/ml)].Actin filaments (10-30 ,um in length), suspended in solution and freely moving on the myosin surface, w...
