The head or motor domain of the ncd (non-claret disjunctional) molecular motor is 41% identical to that of kinesin, yet moves along microtubules in the opposite direction to kinesin. We show here that despite the reversed directionality of ncd, its kinetics in solution are homologous in key respects to those of kinesin.
In vitro and at physiological ionic strength, unphosphorylated smooth muscle myosin filaments dissolve on addition of ATP, forming folded (10S) myosin monomers. By following the fate of ATP and the time course of filament disassembly we have established details of the mechanism of this process. Myosin filaments first bind and hydrolyse 2.0 mol/mol of ATP before significant filament dissolution occurs. Following dissolution, the hydrolysis products ADP.Pi are retained on the heads of the folded myosin monomers, and are released so slowly (half time approximately 100 min at 100 mM KCl) as to be effectively trapped. The straight (6S) conformation of myosin, stable at greater than 225 mM KCl, did not exhibit this product trapping, and neither did myosin filaments held under conditions which disfavour ATP‐induced disassembly. The implications of these results for filament stability in vivo are discussed in terms of a simple, testable model for smooth muscle myosin self‐assembly.
A rapid purification procedure has been developed for the isolation of caldesmon from hog stomach smooth muscle utilizing a KI extract of washed myofibrils as source material. On SDS-PAGE this mammalian caldesmon showed a closelyspaced doublet around 155 kd. By low-angle rotary shadowing caldesmon was shown to be an elongated, highly flexible molecule which tends to form end-to-end diners that are structurally very similar to ifiamin. When added to F-actin solutions caldesmon increased the high-shear viscosity considerably, but by an extent that depended on sample preparation. The effect was shown to be due to caldesmon and not to a trace contaminant by its full reversibility after addition of a monospecific caldesmon antibody. Recent investigations have shown that in smooth muscle two structurally distinct domains can be distinguished: an actomyosin domain and an actin-intermediate ifiament domain. Immunocytochemistry of ultrathin sections of smooth muscle at the light and electron microscope level revealed that caldesmon is present in the actomyosin domain. Caldesmon is thus a potential regulator of the actomyosin system in smooth muscle.
Using cryo-electron microscopy, we characterize the architecture of microtubules assembled from Schizosaccharomyces pombe tubulin, in the presence and absence of their regulatory partner Mal3. Cryo-electron tomography reveals that microtubules assembled from S. pombe tubulin have predominantly B-lattice interprotofilament contacts, with protofilaments skewed around the microtubule axis. Copolymerization with Mal3 favors 13 protofilament microtubules with reduced protofilament skew, indicating that Mal3 adjusts interprotofilament interfaces. A 4.6-Å resolution structure of microtubule-bound Mal3 shows that Mal3 makes a distinctive footprint on the S. pombe microtubule lattice and that unlike mammalian microtubules, S. pombe microtubules do not show the longitudinal lattice compaction associated with EB protein binding and GTP hydrolysis. Our results firmly support a structural plasticity view of microtubule dynamics in which microtubule lattice conformation is sensitive to a variety of effectors and differently so for different tubulins.
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