One-headed kinesin derivatives move by a nonprocessive, low-duty ratio mechanism unlike that of two-headed kinesin.

A single molecule of the "two-headed" motor enzyme kinesin can move along a microtubule continuously for many enzymatic turnovers (processive movement), and the velocity produced by one kinesin molecule is the same as that produced by many kinesin molecules (high duty ratio). We studied the microtubule movement driven at 1 mM ATP by biotinated N-terminal fragments of Drosophila kinesin heavy chain attached to streptavidin-coated coverslips at various surface densities. K448-BIO has velocity at a high density of vmax = 750 nm s-1 and is dimeric (hence two-headed); K365-BIO (vmax = 200 nm s-1) and K340-BIO (vmax = 90 nm s-1) are monomeric. Escape of microtubules from the surface was prevented by methylcellulose so that continuous trajectories of microtubules not continuously attached to motor molecules could be recorded by video microscopy. The component of instantaneous velocity parallel to the microtubule axis (v) was analyzed in trajectories with a mean velocity 0.4-0.7 times vmax. In K448-BIO trajectories, the distribution of v was bimodal with peaks near 0 and 750 nm s-1. Temporal autocorrelation analysis of v detected lengthy episodes of high-velocity movement consistent with isolated processive microtubule runs driven at vmax by single K448-BIO dimers. K365-BIO and K340-BIO trajectories had unimodal distributions of v and autocorrelation times much shorter than those for K448-BIO. Therefore the monomeric motors have duty ratio < 55% (i.e., no forward movement is generated for at least 45% of the enzymatic cycle time) or processivity below the detection limit of approximately 300 turnovers even in methylcellulose. Continuous movement at maximal velocity thus requires more than one kinesin head.

Structural and functional features of one- and two-headed biotinated kinesin derivatives.

The oligomeric structure was determined for four recombinant kinesin derivatives containing N-terminal fragments of the kinesin alpha-subunit. Some of the proteins were dimeric (two-headed) molecules with mechanochemical properties similar to those of intact kinesin. Comparison of the primary and quaternary structures of the derivatives with those of intact kinesin suggests that structures distinct from the long alpha-helical coiled-coil rod domain contribute to subunit self-association. Three of the proteins contain a single engineered site for post-translational biotination in vivo; this facilitates analysis of motility in experiments in which the proteins are specifically bound to streptavidin-conjugated microscopic plastic beads. One of the derivatives is monomeric (one-headed); like the two-headed derivatives, it is functional in the motility assay and is a microtubule-dependent ATPase. Unlike intact kinesin and the two-headed derivatives, the one-headed enzyme fails to track microtubule protofilaments. This confirms a prediction of proposed "hand-over-hand" mechanisms of kinesin movement. The ability of molecules with a one-headed solution structure to generate movement is consistent with a translocation-generating conformational change internal to the kinesin head. A simple set of coupling rules can be used to formulate consistent mechano-chemical mechanisms that explain movement by both one- and two-headed kinesin molecules.

Failure of a single-headed kinesin to track parallel to microtubule protofilaments.

Kinesin, a two-headed motor enzyme molecule, hydrolyses ATP to direct organelle transport along microtubules. As it moves along a microtubule, kinesin remains associated with, or 'tracks', microtubule protofilaments. We have prepared truncated kinesin derivatives that contain either two mechanochemical head domains or only a single head. Unlike intact kinesin and the two-headed derivatives, the one-headed enzyme frequently fails to track protofilaments, suggesting that it detaches from microtubules during movement. In this way, the one-headed kinesin derivative is similar to the motor enzyme myosin, which frequently detaches from the actin filament during movement. For myosin (which has two heads), the consequence of this detachment is that single molecules do not appear to drive continuous movement along the filament. Our observations suggest that the ability of single two-headed kinesin molecules to drive continuous movement results from a 'hand-over-hand' mechanism in which one head remains bound to the microtubule while the other detaches and moves forwards.

Subunit interactions in dimeric kinesin heavy chain derivatives that lack the kinesin rod.

The N-terminal residues of the two heavy chains of the motor enzyme kinesin form two globular "heads"; the heads are attached to a "rod" domain which is a two-stranded alpha-helical coiled-coil. Interaction between the heads is thought to be important to kinesin function. The rod may not be necessary for head-head interactions because a heavy chain N-terminal fragment containing only residues from the head and adjacent region forms dimers (Huang, T.-G., Suhan, J., and Hackney, D. D. (1994) J. Biol. Chem. 269, 16502-16507). However, the nature and stability of the subunit-subunit interactions in such derivatives are unclear. To examine the physical properties of heavy chain interaction in and near the head domains, we characterized the self-association behavior of two dimeric kinesin derivatives predicted (Lupas, A., van Dyke, M., and Stock, J. (1991) Science 252, 1162-1164) to lack the rod. Derivative K448-BIO contains the 448 N-terminal residues of Drosophila kinesin heavy chain fused at the C terminus to a 2-residue linker and a C-terminal fragment from Escherichia coli biotin carboxyl carrier protein; derivative K448-L is the same except that it lacks the biotin carboxyl carrier protein fragment. Both derivatives expressed in insect cells display microtubule-stimulated ATPase activity; K448-BIO also displays microtubule motility. Equilibrium sedimentation and gel filtration indicate that purified K448-BIO and K448-L at 0.02-0.4 mg/ml form homogeneous solutions of homodimers with no detectable formation of monomers or higher order oligomers. Derivative self-association is non-covalent but extremely stable with an association constant > or = 2 x 10(8) M-1. Stable subunit-subunit association induced by structures in and near the kinesin heads may be necessary for full mechanochemical function.

Microtubule movement by a biotinated kinesin bound to streptavidin-coated surface.

Kinesin, an ATP-dependent microtubule motor, can be studied in vitro in motility assays where the kinesin is nonspecifically adsorbed to a surface. However, adsorption can inactivate kinesin and may alter its reaction kinetics. We therefore prepared a biotinated kinesin derivative, K612-BIO, and characterized its activity in solution and when bound to streptavidin-coated surfaces. K612-BIO consists of the N-terminal 612 amino acids of the Drosophila kinesin alpha subunit linked to the 87-amino acid C-terminal domain of the biotin carboxyl carrier protein subunit of Escherichia coli acetyl-CoA carboxylase. The C-terminal domain directs the efficient post-translational biotination of the protein. We expressed K612-BIO at high levels using the baculovirus expression vector system and purified it to near-homogeneity. The expressed protein is completely soluble, and > 90% is bound by streptavidin. K612-BIO steady-state ATPase kinetics (KM,ATP = 24 microM, K0.5, microtubule = 0.61 mg ml-1, Vmax = approximately 25 s-1 head-1, 25 degrees C) are similar to those reported for intact kinesin. ATPase kinetics are not affected by the addition of streptavidin. Enzyme bound to a surface coated with streptavidin drove microtubule gliding in the presence of 2 mM ATP at 750 +/- 130 nm s-1 (26 degrees C). Activity was abolished by pretreatment of the surface with biotin, indicating that the microtubule movements are due to specifically bound enzyme. Motility assays based on specific attachment of biotinated enzyme to streptavidin-coated surfaces will be useful for quantitative analysis of kinesin motility and may provide a way to detect activity in kinesin derivatives or kinesin-like proteins that have not yet been shown to move microtubules.

Platinum levels and clinical responses of tumours treated by cisplatin with and without concurrent hyperthermia: a case study.

The heterogeneity of platinum distributed within tissue after clinical administration of cisplatin was evaluated for the first time. Platinum levels were correlated with the observed clinical responses of separate superficial histiocytic sarcomas located in the forearm of a 74-year-old male patient. One of four lesions received four weekly treatments with hyperthermia administered concurrently with 30 mg/m2 cisplatin, while three lesions were treated with cisplatin alone. The lesion receiving hyperthermia concurrently with cisplatin had a solid partial response during a 6-week period following this therapy, whereas two other tumours receiving cisplatin alone progressed. One lesion could not be clinically evaluated. Platinum levels were determined in multiple samplings from three of the four lesions and normal tissue in order to evaluate the validity of taking a single tumour sample of 100 mg or less for the analysis of platinum content. Such a small single sample might provide a value significantly different from the true average because of sampling error. The range in platinum distribution encompassed an average of three-fold difference within eight separate sample groups, with a factor of six being the greatest difference in a single sample group. This degree of heterogeneity is great enough to suggest that conclusions made from the analysis of small and single random tissue samples could be sufficiently in error to misdirect investigative or medical decisions.

An interrelatedness of the potentiation of radiation-induced bacterial cell killing by cisplatin and binuclear rhodium carboxylates.

Cisplatin and binuclear rhodium (Rh2) carboxylates appear to potentiate radiation-induced killing of Salmonella typhimurium cells largely as a consequence of one-electron reduction that leads to an active radiolytic product. This conclusion is supported by results from experiments wherein the hydrated electron and the hydroxyl radical are competed for in the presence of cisplatin and Rh2 carboxylates, and by the similarly shaped radiation survival curves for cisplatin and Rh2 carboxylates wherein potentiation is expressed beyond variable thresholds of radiation dose. Increasing concentrations of phosphate and chloride also inhibit radiation potentiation by both cisplatin and Rh2 carboxylates, further supporting the contention for similar mechanisms. Radiation potentiation by cisplatin is relatively much more sensitive to the inhibition by chloride.

Potentiation of radiation-induced bacterial cell killing by binuclear rhodium(II) carboxylates.

A series of binuclear rhodium(II) tetracarboxylate complexes was examined for potentiation of radiation-induced killing of Salmonella typhimurium cells. Carboxylate bridging ligands were varied as formate, acetate, trifluoroacetate, and propionate. All complexes caused hypoxic non-dose-modifying radiation potentiation in that variable thresholds were obtained with the radiation dose response. In phosphate-buffered saline (PBS), decreasing threshold doses, i.e., increasing potentiating efficiencies, were seen in the order of acetate = trifluoroacetate less than propionate less than formate. Beyond the threshold dose, the degree of potentiation for all complexes in PBS approximated 12 times the degree of radiation sensitivity seen for the N2 baseline of the radiation dose-response curve. No radiation potentiation by Rh2 carboxylates was seen for fully oxic suspensions. Irradiation of cells in the absence of phosphate increased the efficiency as well as the degree of radiation potentiation. It is hypothesized that bacterial radiation potentiation is initiated by one-electron reduction of the Rh2 carboxylates, most likely involving the hydrated electron, followed then by formation of an active product. These events likely occur outside the bacterial cell.

Potentiation of radiation-induced bacterial cell killing by binuclear rhodium(II) complexes and their amines.

Rhodium(II) binuclear complexes were surveyed for potentiation of radiation-induced cell killing of hypoxic and fully oxic Salmonella typhimurium cells. The Rh2 tetracarbonate ion substantially potentiated hypoxic cell radiation sensitivity. Phosphate interfered with this potentiation. In the latter two respects, radiation potentiation by Rh2 tetracarbonate is similar to that found for Rh2 tetracarboxylates. Amines such as ammonia, methylamine, ethylamine, n-propylamine, and n-butylamine were examined with both Rh2 tetracarbonate and tetraacetate complexes. With Rh2 tetraacetate in phosphate-buffered saline, these amines variably increased radiation potentiation to a maximum of nearly that seen by Rh2 tetraacetate alone in the absence of phosphate. With Rh2 tetracarbonate, particular amines were found to either enhance or restrict radiation potentiation. Results as a whole support the hypothesis that a radiolytic Rh species initiated in a one-electron reduction process external to the cell is responsible for the potentiation by Rh2 complexes in bacteria. Phosphate interference of potentiation by Rh2 tetracetate appears to be limited competitively by amines, suggesting that axial associations of phosphate with the Rh2 center may be involved in the inhibition of radiation potentiation. Of interest in this regard is the finding that 5'-adenosinemonophosphate eliminates the potentiation seen with Rh2 tetraacetate.