Chymotryptic digestion of Tetrahymena 22S dynein. I. Decomposition of three-headed 22S dynein to one- and two-headed particles.

Molecular composition of Tetrahymena ciliary dynein has been examined by electron microscopy and gel electrophoresis. SDS-urea gel electrophoresis revealed that Tetrahymena 22S dynein contains three (A alpha, A beta, and A gamma) heavy chains whereas 14S dynein contains only one. The molecular masses of 22S and 14S dynein heavy chains were estimated to be approximately 490 and 460 kD, respectively. Electron microscopy of negatively stained specimens showed 22S dynein has three globular heads and thin stalks, whereas 14S dynein consists of a single head. Chymotrypsin digested each of the three 22S dynein heavy chains into large fragments with different time courses. Sucrose density gradient centrifugation separated the digestion products as two peaks. The one with a larger sedimentation coefficient mainly consisted of two-headed particles having binding ability to doublet microtubules, whereas the other with a smaller sedimentation coefficient consisted of only isolated globular particles. Both fractions had ATPase activities. Thus, one active head of 22S dynein can be isolated by chymotrypsin digestion.

Chymotryptic digestion of Tetrahymena ciliary dynein. II. Pathway of the degradation of 22S dynein heavy chains.

As shown in the preceding paper (Toyoshima, Y. Y., 1987, J. Cell Biol., 105:887-895) three-headed Tetrahymena 22S dynein consists of three heavy chains (HCs) and is decomposed into two-headed (H) and one-headed (L) fragments by chymotryptic digestion. To accurately determine the presence of multiple ATPases and ultimately the location of various domains, it is necessary to determine the identity of each HC fragment relative to the original HCs in 22S dynein. The degradation pathway of each HC was determined by peptide mapping and immunoblotting. The three HCs (A alpha, A beta, and A gamma) were immunologically different; although SDS-urea gel electrophoresis showed that A gamma HC was apparently resistant to the digestion, actually three distinct HCs contributed to the same band alternately. H fragment was derived from A beta and A gamma HCs, whereas L fragment originated from A alpha HC. Since both fragments were associated with ATPase activity, these results directly demonstrate the presence of multiple ATPase sites in Tetrahymena 22S dynein.

Microtubule translocation properties of intact and proteolytically digested dyneins from Tetrahymena cilia.

Tetrahymena cilia contain a three-headed 22S (outer arm) dynein and a single-headed 14S dynein. In this study, we have employed an in vitro assay of microtubule translocation along dynein-coated glass surfaces to characterize the motile properties of 14S dynein, 22S dynein, and proteolytic fragments of 22S dynein. Microtubule translocation produced by intact 22S dynein and 14S dynein differ in a number of respects including (a) the maximal velocities of movement; (b) the ability of 22S dynein but not 14S dynein to utilize ATP gamma S to induce movement; (c) the optimal pH and ionic conditions for movement; and (d) the effects of Triton X-100 on the velocity of movement. These results indicate that 22S and 14S dyneins have distinct microtubule translocating properties and suggest that these dyneins may have specialized roles in ciliary beating. We have also explored the function of the multiple ATPase heads of 22S dynein by preparing one- and two-headed proteolytic fragments of this three-headed molecule and examining their motile activity in vitro. Unlike the single-headed 14S dynein, the single-headed fragment of 22S dynein did not induce movement, even though it was capable of binding to microtubules. The two-headed fragment, on the other hand, translocated microtubules at velocities similar to those measured for intact 22S dynein (10 microns/sec). This finding indicates that the intact three-headed structure of 22S dynein is not essential for generating microtubule movement, which raises the possibility that multiple heads may serve some regulatory function or may be required for maximal force production in the beating cilium.

Subtilisin cleavage of actin inhibits in vitro sliding movement of actin filaments over myosin.

Subtilisin cleaved actin was shown to retain several properties of intact actin including the binding of heavy meromyosin (HMM), the dissociation from HMM by ATP, and the activation of HMM ATPase activity. Similar Vmax but different Km values were obtained for acto-HMM ATPase with the cleaved and intact actins. The ATPase activity of HMM stimulated by copolymers of intact and cleaved actin showed a linear dependence on the fraction of intact actin in the copolymer. The most important difference between the intact and cleaved actin was observed in an in vitro motility assay for actin sliding movement over an HMM coated surface. Only 30% of the cleaved actin filaments appeared mobile in this assay and moreover, the velocity of the mobile filaments was approximately 30% that of intact actin filaments. These results suggest that the motility of actin filaments can be uncoupled from the activation of myosin ATPase activity and is dependent on the structural integrity of actin and perhaps, dynamic changes in the actin molecule.

Nucleotide specificity of the enzymatic and motile activities of dynein, kinesin, and heavy meromyosin.

The substrate specificities of dynein, kinesin, and myosin substrate turnover activity and cytoskeletal filament-driven translocation were examined using 15 ATP analogues. The dyneins were more selective in their substrate utilization than bovine brain kinesin or muscle heavy meromyosin, and even different types of dyneins, such as 14S and 22S dynein from Tetrahymena cilia and the beta-heavy chain-containing particle from the outer-arm dynein of sea urchin flagella, could be distinguished by their substrate specificities. Although bovine brain kinesin and muscle heavy meromyosin both exhibited broad substrate specificities, kinesin-induced microtubule translocation varied over a 50-fold range in speed among the various substrates, whereas heavy meromyosin-induced actin translocation varied only by fourfold. With both kinesin and heavy meromyosin, the relative velocities of filament translocation did not correlate well with the relative filament-activated substrate turnover rates. Furthermore, some ATP analogues that did not support the filament translocation exhibited filament-activated substrate turnover rates. Filament-activated substrate turnover and power production, therefore, appear to become uncoupled with certain substrates. In conclusion, the substrate specificities and coupling to motility are distinct for different types of molecular motor proteins. Such nucleotide "fingerprints" of enzymatic activities of motor proteins may prove useful as a tool for identifying what type of motor is involved in powering a motility-related event that can be reconstituted in vitro.

Length dependence of displacement fluctuations and velocity in microtubule sliding movement driven by sea urchin sperm outer arm beta dynein in vitro.

We have studied the dependence on microtubule length of sliding velocity and positional fluctuation from recorded trajectories of microtubules sliding over sea urchin sperm outer arm beta dynein in a motility assay in vitro. The positional fluctuation was quantified by calculating the mean-square displacement deviation from the average, the calculation of which yields an effective diffusion coefficient. We have found that (1) the sliding velocity depends hyperbolically on the microtubule length, and (2) the effective diffusion coefficients do not depend on the length for sufficiently long microtubules. The length dependence of the sliding velocity indicates that the duty ratio, defined as the force producing period over the total cycle time of beta dynein interaction with microtubule, is very small. The length independence of the effective diffusion coefficient indicates that there is a correlation in the sliding movement fluctuation of microtubules.

Monte Carlo study for fluctuation analysis of the in vitro motility driven by protein motors.

The fluctuation properties of the sliding movement of an individual cytoskeletal filament driven by protein motors in vitro can be analyzed by calculating the mean-square deviation of the displacement from the average within its single trajectory. For this purpose, a Monte Carlo simulation was used to define the conditions and limitations of a method for smoothing (curved) noisy trajectories without affecting either the steady or fluctuation characteristics inherent to the individual filament sliding movement. By applying the method to real experimental trajectory data, we show that an effective diffusion coefficient from displacement fluctuations of a sliding filament can be obtained from its single noisy trajectory even when it is curved.

Isolation and characterization of pos mutants defective in correct positioning of septum in Schizosaccharomyces pombe.

We have isolated mutants of fission yeast defective in correct positioning of septum. In visual screening, we obtained 16 clones showing unequal septation at restrictive temperature, which were classified into three complementation groups. At restrictive temperature, all the mutants underwent nuclear division normally. In cytokinesis, however, a contractile ring was formed at the site independent of the mitotic spindle. These results suggest that positional information for cytokinesis are not accurately transmitted to the cell equator. Furthermore, all the mutants frequently displayed incorrect orientation and/or distortion of septum, which suggests that the septum positioning is closely related to correct orientation and organization of septum.

How are myosin fragments bound to nitrocellulose film?

In an attempt to identify the binding sites of myosin fragments to the nitrocellulose film in a flow cell, proteolytic digestion was performed of myosin fragments bound to the substrate. Chymotryptic digestion of papain.Mg-subfragment-1 (S1) showed that a large proportion of S1 were bound near the tail and that the digestion site was protected for some S1. The binding of S1 near the tail was also confirmed by the production of extra long subfragment-2 (S2) by chymotryptic digestion of heavy meromyosin (HMM). Papain digestion of HMM released slightly smaller HMM from the substrate and impaired the motility at the same time. Hence, the motility of HMM is supported largely by those bound to the substrate near the C terminus. These results demonstrate the importance of flexible regions of myosin in generating active movements.

Bidirectional movement of actin filaments along tracks of heavy meromyosin and native thick filaments.

Flexibility of the myosin molecule was studied by an in vitro motility assay in terms of the direction of actin movement. Actin filaments can move in both directions on tracks of heavy meromyosin made on a nitrocellulose surface, and, furthermore, along the native thick filaments passing over their central bare zone. These observations indicate that the myosin molecule has a considerable flexibility in interacting with actin filaments.

Flexibility in actin-myosin motility system revealed by in vitro motility assay.

Flexibility of myosin molecule was studied by in vitro motility assay in terms of the direction of actin movement. Electron microscopy showed that HMM scattered on a nitrocellulose surface can bind actin filaments and form arrowhead-like patterns. Actin filaments can move in both directions on tracks of HMM made on a nitrocellulose surface. Further, actin filaments can move bidirectionally along native thick filaments over their central bare zone. These observations indicate that there is considerable flexibility in a myosin molecule and that the direction of the movement is determined by the polarity of actin filaments.

Rotation and translocation of microtubules in vitro induced by dyneins from Tetrahymena cilia.

Dynein, the force-generating enzyme that powers the movement of cilia and flagella, has been characterized biochemically, but no simple system has been available for examining its motile properties. Here we describe a quantitative in vitro motility assay in which dynein adsorbed onto a glass surface induces linear translocation of purified bovine microtubules. Using this assay, we show that both 22S and 14S dyneins from Tetrahymena cilia induce movement but have distinct motile properties. A unique property of 14S dynein, which has not been described for other motility proteins, is its ability to generate torque that causes microtubules to rotate during forward translocation. In the axoneme, 14S dynein-induced torque may induce rotation of central-pair microtubules and may play an important role in generating three-dimensional ciliary beating patterns.

Regulation of monomeric dynein activity by ATP and ADP concentrations.

Axonemal dyneins are force-generating ATPases that produce ciliary and flagellar movement. A dynein has large heavy chain(s) in which there are multiple (4-6) ATP-binding consensus sequences (P-loops) as well as intermediate and light chains, constituting a very large complex. We purified a monomeric form of dynein (dynein-a) that has at least three light chains from 14S dyneins of Tetrahymena thermophila and characterized it. In in vitro motility assays, dynein-a rotated microtubules around their longitudinal axis as well as translocated them with their plus-ends leading. ATPase activity at 1 mM ATP was doubled in the presence of a low level of ADP (> or = 20 microM). Both ATPase activity and translocational velocities in the presence of ADP (> or = 20 microM) fit the Michaelis-Menten equation well. However, in the absence of ADP (< 0.1 microM), neither of the activities followed the Michaelis-Menten-type kinetics, probably due to the effect of two ATP-binding sites. Our results also indicate that dynein-a has an ATP-binding site that is very sensitive to ADP and affects ATP hydrolysis at the catalytic site. This study shows that a monomeric form of a dynein molecule regulates its activity by direct binding of ATP and ADP to itself, and thus the dynein molecule has an intramolecular regulating system.

Processive movement of single 22S dynein molecules occurs only at low ATP concentrations.

We have analyzed the movement of single 22S dynein molecules from Tetrahymena cilia by using a nanometer measuring system equipped with optical tweezers. Statistical analysis proved that a single molecule of 22S dynein can move processively and develop force at low concentrations of ATP (<20 microM). The maximum force was approximately 4.7 pN, and the force-velocity curve was convex down. During force development, dynein molecules showed stepwise displacement of approximately 8 nm and frequently exhibited backward steps of approximately 8 nm. At higher concentrations of ATP (>/=20 microM) single molecules of 22S dynein were not observed to move processively. Twenty-two S dynein seems to switch over from a processive mode to a nonprocessive mode, sensing a subtle change of ATP concentrations. These observations indicate that the processivity, maximum force, and step size of dynein are similar to those of kinesin, but the ATP concentration-dependence, force-velocity relationship, and backward steps are clearly distinct from kinesin.

The myosin step size: measurement of the unit displacement per ATP hydrolyzed in an in vitro assay.

Chemomechanical coupling in muscle contraction may be due to "swinging crossbridges," such that a change in the angle at which the myosin head binds to the actin filament is tightly coupled to release of products of ATP hydrolysis. This model would limit the step size, the unit displacement of actin produced by a single ATP hydrolysis, to less than twice the chord length of the myosin head. Recent measurements have found the step size to be significantly larger than this geometric limit, bringing into question any direct correspondence between the crossbridge and ATP-hydrolysis cycles. We have measured the rate of ATP hydrolysis due to actin sliding movement in an in vitro motility assay consisting of purified actin and purified myosin. We have calculated an apparent myosin step size well within the geometric limit set by the size of the myosin head. These data are consistent with tight coupling between myosin crossbridge movement and ATP hydrolysis.

Site-directed mutations of Dictyostelium actin: disruption of a negative charge cluster at the N terminus.

Aspartic acid residues in the N-terminal negative charge cluster of Dictyostelium actin were replaced with histidine residues by site-directed mutagenesis of the actin gene. The mutant actins were expressed in Dictyostelium cells and were purified to homogeneity by HPLC. Functional properties of the mutant actins were compared with those of the wild-type actin. (i) In vitro assays of the sliding movement of actin filaments driven by myosin showed that the movement was slowed by the mutations. (ii) The mutations diminished the actin-activated ATPase activity of myosin in such a way that the maximum turnover rate at infinite actin concentration (Vmax) dropped sharply without an appreciable change in the apparent affinity of actin and myosin (Kapp). These results indicate that the N-terminal negative charge cluster of actin is essential for the ATP-dependent actin-myosin interaction.

Bidirectional movement of actin filaments along tracks of myosin heads.

It is well established that muscle contraction results from the relative sliding of actin and myosin filaments. Both filaments have definite polarities and well-ordered structures. Thick filaments, however, are not vital for supporting movement in vitro. Previously we have demonstrated that actin filaments can move continuously on myosin fragments (subfragment-1 or heavy meromyosin (HMM] that are bound to a nitrocellulose surface. Here we report that actin filaments can move in opposite directions on tracks of myosin heads formed when actin filaments decorated with HMM are placed on a nitrocellulose surface. The actin filaments always move forward, frequently changing the direction of the movement, but never move backward reversing the polarity of the movement. The direction of movement is therefore determined by the polarity of the actin filament. These results indicate that myosin heads have considerable flexibility.

Fluctuation in the microtubule sliding movement driven by kinesin in vitro.

We studied the fluctuation in the translational sliding movement of microtubules driven by kinesin in a motility assay in vitro. By calculating the mean-square displacement deviation from the average as a function of time, we obtained motional diffusion coefficients for microtubules and analyzed the dependence of the coefficients on microtubule length. Our analyses suggest that 1) the motional diffusion coefficient consists of the sum of two terms, one that is proportional to the inverse of the microtubule length (as the longitudinal diffusion coefficient of a filament in Brownian movement is) and another that is independent of the length, and 2) the length-dependent term decreases with increasing kinesin concentration. This latter term almost vanishes within the length range we studied at high kinesin concentrations. From the length-dependence relationship, we evaluated the friction coefficient for sliding microtubules. This value is much larger than the solvent friction and thus consistent with protein friction. The length independence of the motional diffusion coefficient observed at sufficiently high kinesin concentrations indicates the presence of correlation in the sliding movement fluctuation. This places significant constraint on the possible mechanisms of the sliding movement generation by kinesin motors in vitro.