Actin-filament motion in the in vitro motility assay has a periodic component.

The interaction between actin and myosin can be studied in the in vitro motility assay, where fluorescently labelled actin filaments are observed to move over a lawn of myosin heads. To examine details of this movement, we measured systematically the velocities of the front end, rear end, and centroid of the actin filament as the filament translated over the assay surface. We found that these velocities exhibited an unexpectedly periodic component, alternating regularly between high and low values, superimposed on the steady velocity component. The period of the oscillatory component was approximately 380 ms. When translation was stopped by an increase in osmolarity, the filaments wiggled with a periodicity similar to the translating filament, implying that wiggling and translation may be related. Rigor filaments showed no periodicity. From the frequency content of the auto- and cross-correlation functions derived from the velocities of the front end, rear end, and centroid of the actin filament, we infer a deterministic, possibly wave-like process travelling along the actin filament. Potential molecular mechanisms underlying this phenomenon are considered.

Ca2+ channel antagonists enhance tension in skinned skeletal and heart muscle fibres.

Striated muscle fibres, both skeletal and cardiac of different species including human, skinned by freeze-drying, were activated in solutions strongly buffered for Ca2+. The single fibres were immersed in solutions with different [Ca2+]. Sarcomere length was set and controlled by laser diffraction. Fibre type was determined by Sr2+ activation. The relation between the negative logarithm of the Ca2+ concentration and the normalized tension, the Ca2+ sensitivity curve, was investigated. The effect on the contractile machinery of three different Ca2+ channel antagonists (verapamil, diltiazem and nifedipine) in a therapeutic concentration (10(-6) M) was investigated. The possible effects on the Ca2+ sensitivity curve were quantified by: (1) the change in maximal tension developed at pCa2+ = 4.4; (2) the change in pCa2+ value at which 50% of the tension induced at pCa2+ = 4.4; (3) the steepness of the Ca2+ sensitivity curve in this point. The three drugs tested, at a therapeutic concentration of 1 microM, all enhanced maximal induced tension by respectively 25, 20 and 7%. The sarcomere length dependency of the effect proved to be dependent upon the drug, but also slightly on fibre type (skeletal or cardiac), or on species. It is concluded that the drug influences the cooperativity of the two different types of binding sites on troponin-C (low- and high-affinity sites). Tension enhancement was due to increased stiffness of the actin-myosin interaction site.