Regulation of ncd by the oligomeric state of tubulin.

We have compared the interaction of ncd (non-claret disjunctional), a kinesin related protein, with microtubules and tubulin heterodimer. Ultracentrifugation experiments revealed that the ncd motor domain, residues 335-700 (ncd335), does not induce tubulin polymerization but stabilizes pre-formed microtubules with a maximum effect at a 1:1 ncd335:tubulin ratio. Ncd335 binding to tubulin or microtubules was estimated by following the change in fluorescence polarization of an exogenous dye attached to Cys670 of ncd335. Ncd335 binding to tubulin (containing GTP or GDP-bound) is characterized by a 2:1 stoichiometry, a higher affinity and an increased sensitivity towards salt, ADP, ATP and AMPPNP, as compared with ncd335 binding to microtubules. Maximum ATPases were 0.06-0.08 sec(-1) and 1.8-2.0 sec(-1) for the ncd335-tubulin and ncd335-microtubules complexes, respectively. Only the polymerized complex is fully functional, suggesting the presence of additional contacts between adjacent protofilaments. Moreover, the data reveal that the oligomeric state of microtubules is a potent regulator for the activity of kinesin related proteins.

[Mechanisms of action and cellular functions of molecular motors]. / Mécanismes d'action et fonctions cellulaires des moteurs moléculaires.

Cytoskeleton based molecular motors support most of the cellular movements and by consequence they are associated with a variety of human disorders. The wide functional diversity of these molecular motors is now explained by the presence of three different families: the myosin, kinesin and dynein families. Although they are functionally distinct, these motors present unexpected structural homologies at the ATP and actin or microtubule binding sites. However, these homologies do not seem sufficient to design a common molecular mechanism which allows these proteins to move along the cytoskeleton.

Effect of nucleotides and actin on the orientation of the light chain-binding domain in myosin subfragment 1.

The X-ray structure of myosin head (S1) reveals the presence of a long alpha-helical structure that supports both the essential and the regulatory light chains. It has been proposed that small structural changes in the catalytic domain of S1 are amplified by swinging the long alpha-helix (the "lever arm") to produce approximately 11 nm steps. To probe the spatial position of the putative lever in various S1 states, we have measured, by fluorescence resonance energy transfer (FRET), the effect of nucleotides and actin on the distances between Cys-177 of the essential light chain A1 (which is attached to the alpha-helix) and three loci in the catalytic domain. Cys-177 (donor) was labeled with 1,5-IAEDANS. The trinitrophenylated ADP analog (TNP-ADP, acceptor) was used to measure the distance to the active site. Lys-553 at the actin-binding site, labeled with a fluorescein derivative, and Lys-83 modified with trinitrobenzenesulfonic acid served as two other acceptors. FRET measurements were performed for S1 alone, for its complexes with MgADP and MgATP, for the analogs of the transition state of the ATPase reaction, S1.ADP.BeFx, S1.ADP.AlF4, and S1.ADP.VO4, and for acto-S1 in the absence and in the presence of ADP. When the transition state and acto-S1 complexes were formed, the change in the Cys-177 --> Lys-83 distance was <1.1 A, for the distance Cys-177 --> Lys-553, the change was +/-2.5 A. These distance changes correspond to rotations by <10 degrees and approximately 25 degrees, respectively. For the Cys-177 --> TNP-ADP the interprobe separation decreased by approximately 6 A in the presence of BeFx and AlF4- but only 1.9 A in the presence of vanadate; we do not interpret the 6 A change as resulting from the lever rotation. Using the coordinates of the acto-S1 complex, we have computed the expected changes in these distances resulting from rotation of the lever. These changes were much greater than the ones observed. The above results are inconsistent with models of force generation by S1 in which the head assumes two distinct conformations characterized by large differences in the angle between the motor and the light chain-binding domain. Several alternative mechanisms are proposed.