Structural and functional reconstitution of inner dynein arms in Chlamydomonas flagellar axonemes

The inner row of dynein arms contains three dynein subforms. Each is distinct in composition and location in flagellar axonemes. To begin investigating the specificity of inner dynein arm assembly, we assessed the capability of isolated inner arm dynein subforms to rebind to their appropriate positions on axonemal doublet microtubules by recombining them with either mutant or extracted axonemes missing some or all dyneins. Densitometry of Coomassie blue-stained polyacrylamide gels revealed that for each inner dynein arm subform, binding to axonemes was saturable and stoichiometric. Using structural markers of position and polarity, electron microscopy confirmed that subforms bound to the correct inner arm position. Inner arms did not bind to outer arm or inappropriate inner arm positions despite the availability of sites. These and previous observations implicate specialized tubulin isoforms or nontubulin proteins in designation of specific inner dynein arm binding sites. Further, microtubule sliding velocities were restored to dynein-depleted axonemes upon rebinding of the missing inner arm subtypes as evaluated by an ATP-induced microtubule sliding disintegration assay. Therefore, not only were the inner arm dynein subforms able to identify and bind to the correct location on doublet microtubules but they bound in a functionally active conformation.     

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.     

Substructure of sea urchin egg cytoplasmic dynein

The substructure of the cytoplasmic dynein molecule was studied using the quick-freeze, deep-etch technique. Cytoplasmic dynein purified as a 12 S form from the eggs of the sea urchin Hemicentrotus pulcherrimus was composed of a single high molecular weight polypeptide. Rotary shadowing images of cytoplasmic dynein either sprayed on to a mica surface or quick-frozen on mica flakes demonstrated a single-headed molecule, in contrast to the two-headed molecule of sea urchin sperm flagellar 21 S dynein. More detailed substructure was visualized by rotary shadowing after quick-freeze deep-etching. Cytoplasmic dynein consisted of a head and a stem. The head was pear-shaped (16 nm X 11 nm) and a little smaller than the pear-shaped head of 21 S dynein (18 nm X 14 nm). The form of the stem was irregular, and its apparent length varied from 0 to 32 nm. Binding of cytoplasmic dynein to brain microtubule in the solution was observed by negative staining, and that in the precipitate was examined by the quick-freeze, deep-etch method as well. Both methods revealed the presence of two kinds of microtubules, one a fully decorated microtubule and the other a non-decorated microtubule. Cytoplasmic dynein bound to microtubule also appeared as a globular particle. Neither the periodic binding nor the crossbridges that were observed with 21 S dynein were formed by cytoplasmic dynein, although cytoplasmic dynein appeared to bind to microtubules co-operatively.     

Two activators of microtubule-based vesicle transport

Cytoplasmic dynein purified by nucleotide dependent microtubule affinity has significant minus end-directed vesicle motor activity that decreases with each further purification step. Highly purified dynein causes membrane vesicles to bind but not move on microtubules. We exploited these observations to develop an assay for factors that, in combination with dynein, would permit minus end-directed vesicle motility. At each step of the purification, non-dynein fractions were recombined with dynein and assayed for vesicle motility. Two activating fractions were identified by this method. One, called Activator I, copurified with 20S dynein by velocity sedimentation but could be separated from it by ion exchange chromatography. Activator I increased only the frequency of dynein-driven vesicle movements. Activator II, sedimenting at 9S, increased both the frequency and velocity of vesicle transport and also supported plus end movements. Our results suggest that dynein-based motility is controlled at multiple levels and provide a preliminary characterization of two regulatory factors.     

Isolated beta-heavy chain subunit of dynein translocates microtubules in vitro

Our goal was to assess the microtubule translocating ability of individual ATPase subunits of outer arm dynein. Solubilized outer arm dynein from sea urchin sperm (Stronglocentrotus purpuratus) was dissociated into subunits by low ionic strength buffer and fractionated by zonal centrifugation. Fractions were assessed by an in vitro functional assay wherein microtubules move across a glass surface to which isolated dynein fractions had been absorbed. Microtubule gliding activity was coincident with the 12-S beta-heavy chain-intermediate chain 1 ATPase fractions (beta/IC1). Neither the alpha-heavy chain nor the intermediate chains 2 and 3 fractions coincided with microtubule gliding activity. The beta/IC1 ATPase induced very rapid gliding velocities (9.7 +/- 0.88 micron/s, range 7-11.5 micron/s) in 1 mM ATP-containing motility buffers. In direct comparison, isolated intact 21-S outer arm dynein, from which the beta/IC1 fraction was derived, induced slower microtubule gliding rates (21-S dynein, 5.6 +/- 0.7 micron/s; beta/IC1, 8.7 +/- 1.2 micron/s). These results demonstrate that a single subdomain in dynein, the beta/IC1 ATPase, is sufficient for microtubule sliding activity.     

The motile beta/IC1 subunit of sea urchin sperm outer arm dynein does not form a rigor bond

We used in vitro translocation and cosedimentation assays to study the microtubule binding properties of sea urchin sperm outer arm dynein and its beta/IC1 subunit. Microtubules glided on glass-absorbed sea urchin dynein for a period of time directly proportional to the initial MgATP2- concentration and then detached when 70-95% of the MgATP2- was hydrolyzed. Detachment resulted from MgATP2- depletion, because (a) perfusion with fresh buffer containing MgATP2- reconstituted binding and gliding, (b) microtubules glided many minutes with an ATP-regenerating system at ATP concentrations which alone supported gliding for only 1-2 min, and (c) microtubules detached upon total hydrolysis of ATP by an ATP-removal system. The products of ATP hydrolysis antagonized binding and gliding; as little as a threefold excess of ADP/Pi over ATP resulted in complete loss of microtubule binding and translocation by the beta/IC1 subunit. In contrast to the situation with sea urchin dynein, microtubules ceased gliding but remained bound to glass-absorbed Tetrahymena outer arm dynein when MgATP2- was exhausted. Cosedimentation assays showed that Tetrahymena outer arm dynein sedimented with microtubules in an ATP-sensitive manner, as previously reported (Porter, M.E., and K. A. Johnson. J. Biol. Chem. 258: 6575-6581). However, the beta/IC1 subunit of sea urchin dynein did not cosediment with microtubules in the absence of ATP. Thus, this subunit, while capable of generating motility, lacks both structural and rigor-type microtubule binding.     

Characterization of the ATP-sensitive binding of Tetrahymena 30 S dynein to bovine brain microtubules

Dynein was obtained by high salt extraction of Tetrahymena cilia and purified by DEAE-Sephacel chromatography. This fraction consisted of a mixture of 30 S dynein (80%) and the 14 S ATPase (15%). The column purification effectively removed tubulin and adenylate kinase. Sodium dodecyl sulfate-polyacrylamide electrophoresis indicated that the 30 S dynein was composed of a major heavy chain (approximately 400 kD, three copies), three intermediate chains (70, 85, and 100 kD), and a group of light chains (approximately 20 kD). The binding of the column-purified dynein to bovine brain microtubules was characterized as follows. (i) Titration of the dynein with microtubules showed a linear increase in turbidity up to an equivalence point of 2.7 mg of dynein/mg of tubulin with apparently tight binding; (ii) the addition of ATP caused the turbidity of the solution of decrease to a level equal to the sum of free dynein plus microtubules; (iii) transmission electron microscopy indicated that microtubules were decorated with dynein arms spaced at a 24-nm longitudinal repeat and that the dynein decoration was removed upon addition of ATP; (iv) cross-section images of microtubules that were saturated with dynein showed six to seven dynein arms around a microtubule consisting of 14 protofilaments, corresponding to a molar ratio of one dynein/six tubulin dimers; (v) the dynein arms were bound primarily by their broader end which corresponds to the end normally bound to the B-subfiber in vivo. Experiments with purified 30 and 14 S dyneins indicated that the dynein-microtubule binding activity and the ATP-induced dissociation were the properties of the 30 S dynein alone. These studies demonstrate that the 30 S dynein under our conditions (50 mM PIPES, pH 6.96, 4 mM MgSO4) interacts with bovine brain microtubules through the ATP-sensitive site of the dynein arm.     

A squid dynein isoform promotes axoplasmic vesicle translocation

Axoplasmic vesicles that translocate on isolated microtubules in an ATP-dependent manner have an associated ATP-binding polypeptide with a previously estimated relative molecular mass of 292 kD (Gilbert, S. P., and R. D. Sloboda. 1986. J. Cell Biol. 103:947-956). Here, data are presented showing that this polypeptide (designated H1) and another high molecular mass polypeptide (H2) can be isolated in association with axoplasmic vesicles or optic lobe microtubules. The H1 and H2 polypeptides dissociate from microtubules in the presence of MgATP and can be further purified by gel filtration chromatography. The peak fraction thus obtained demonstrates MgATPase activity and promotes the translocation of salt-extracted vesicles (mean = 0.87 microns/s) and latex beads (mean = 0.92 microns/s) along isolated microtubules. The H1 polypeptide binds [alpha 32P]8-azidoATP and is thermosoluble, but the H2 polypeptide does not share these characteristics. In immunofluorescence experiments with dissociated squid axoplasm, affinity-purified H1 antibodies yield a punctate pattern that corresponds to vesicle-like particles, and these antibodies inhibit the bidirectional movement of axoplasmic vesicles. H2 is cleaved by UV irradiation in the presence of MgATP and vanadate to yield vanadate-induced peptides of 240 and 195 kD, yet H1 does not cleave under identical conditions. These experiments also demonstrate that the actual relative molecular mass of the H1 and H2 polypeptides is approximately 435 kD. On sucrose density gradients, H1 and H2 sediment at 19-20 S, and negatively stained samples reveal particles comprised of two globular heads with stems that contact each other and extend to a common base. The results demonstrate that the complex purified is a vesicle-associated ATPase whose characteristics indicate that it is a squid isoform of dynein. Furthermore, the data suggest that this vesicle-associated dynein promotes membranous organelle motility during fast axoplasmic transport.     

The functional expression and motile properties of recombinant outer arm dynein from Tetrahymena

Cilia and flagella are motile organelles that play various roles in eukaryotic cells. Ciliary movement is driven by axonemal dyneins (outer arm and inner arm dyneins) that bind to peripheral microtubule doublets. Elucidating the molecular mechanism of ciliary movement requires the genetic engineering of axonemal dyneins; however, no expression system for axonemal dyneins has been previously established. This study is the first to purify recombinant axonemal dynein with motile activity. In the ciliated protozoan Tetrahymena, recombinant outer arm dynein purified from ciliary extract was able to slide microtubules in a gliding assay. Furthermore, the recombinant dynein moved processively along microtubules in a single-molecule motility assay. This expression system will be useful for investigating the unique properties of diverse axonemal dyneins and will enable future molecular studies on ciliary movement.     

The substructure of isolated and in situ outer dynein arms of sea urchin sperm flagella

Outer-arm dynein from the sperm of the sea urchin S. purpuratus was adsorbed to mica flakes and visualized by the quick-freeze, deep-etch technique. Replicas reveal particles comprised of two globular heads joined by two irregularly shaped stems which make contact along their length. One head is pear-shaped (18.5 X 12.5 nm) and the other is spherical (14.5-nm diam). The stems are decorated by a complex of bead-like subunits. The same two-headed protein is found in the 21S dynein-1 fraction of sucrose gradients. The beta-heavy chain/intermediate chain 1 (beta/IC-1) dynein subfraction, produced by low-salt dialysis and zonal centrifugation of the high-salt-extracted dynein-1, contains only single-headed molecules with single stems. These heads are predominantly pear-shaped (18.5 X 12.5 nm). Since 21S dynein-1 contains two heavy chains (alpha and beta), and the beta/IC-1 subfraction is comprised of only the beta-heavy chain (Tang et al., 1982, J. Biol. Chem. 257: 508-515), we conclude that each head is formed by a heavy chain, that the pear-shaped head contains the beta-heavy chain, and that the spherical head contains the alpha-heavy chain. The in situ outer dynein arms of demembranated sperm were also studied by the quick-freeze, deep-etch method. When frozen in reactivation buffer devoid of ATP, each arm consists of a large globular head that attaches to the A-microtubule by distally skewed subunits and attaches to the B-microtubule by a slender stalk. In ATP, this head shifts its orientation such that it can be seen to be constructed from two globular domains. We offer possible correlates between the in situ and the in vitro images, and we compare the structure of sea-urchin dynein with dynein previously described from Chlamydomonas and Tetrahymena.     

Microtubule sliding in flagellar axonemes of Chlamydomonas mutants missing inner- or outer-arm dynein: velocity measurements on new types of mutants by an improved method.

To help understand the functional properties of inner and outer dynein arms in axonemal motility, sliding velocities of outer doublets were measured in disintegrating axonemes of Chlamydomonas mutants lacking either of the arms. Measurements under improved solution conditions yielded significantly higher sliding velocities than those observed in a previous study [Okagaki and Kamiya, 1986, J. Cell Biol. 103:1895-1902]. As in the previous study, it was found that the velocities in axonemes of wild type (wt) and a mutant (oda1) missing the outer arm differ greatly: 18.5 +/- 4.1 microns/sec for wt and 4.4 +/- 2.3 microns/sec for oda1 at 0.5 mM Mg-ATP. In contrast, axonemes of two types of mutants (ida2 and ida4) that lacked different sets of two inner-arm heavy chains displayed velocities almost identical with the wild-type velocity. Moreover, axonemes of a non-motile double mutant ida2 X ida4 underwent sliding disintegration at a similar high velocity, although less frequently than in axonemes of single mutants. These observations support the hypothesis that the inner and outer dynein arms in disintegrating axonemes drive microtubules at different speeds and it is the faster outer arm that determines the overall speed when both arms are present. The inner arm may be important for the initiation of sliding. The axoneme thus appears to be equipped with two (or more) types of motors with different intrinsic speeds.     

The LC7 light chains of Chlamydomonas flagellar dyneins interact with components required for both motor assembly and regulation

Members of the LC7/Roadblock family of light chains (LCs) have been found in both cytoplasmic and axonemal dyneins. LC7a was originally identified within Chlamydomonas outer arm dynein and associates with this motor's cargo-binding region. We describe here a novel member of this protein family, termed LC7b that is also present in the Chlamydomonas flagellum. Levels of LC7b are reduced approximately 20% in axonemes isolated from strains lacking inner arm I1 and are approximately 80% lower in the absence of the outer arms. When both dyneins are missing, LC7b levels are diminished to <10%. In oda9 axonemal extracts that completely lack outer arms, LC7b copurifies with inner arm I1, whereas in ida1 extracts that are devoid of I1 inner arms it associates with outer arm dynein. We also have observed that some LC7a is present in both isolated axonemes and purified 18S dynein from oda1, suggesting that it is also a component of both the outer arm and inner arm I1. Intriguingly, in axonemal extracts from the LC7a null mutant, oda15, which assembles approximately 30% of its outer arms, LC7b fails to copurify with either dynein, suggesting that it interacts with LC7a. Furthermore, both the outer arm gamma heavy chain and DC2 from the outer arm docking complex completely dissociate after salt extraction from oda15 axonemes. EDC cross-linking of purified dynein revealed that LC7b interacts with LC3, an outer dynein arm thioredoxin; DC2, an outer arm docking complex component; and also with the phosphoprotein IC138 from inner arm I1. These data suggest that LC7a stabilizes both the outer arms and inner arm I1 and that both LC7a and LC7b are involved in multiple intradynein interactions within both dyneins.     

The IC138 and IC140 intermediate chains of the I1 axonemal dynein complex bind directly to tubulin

Dyneins are minus end directed microtubule motors that play a critical role in ciliary and flagellar movement. Ciliary dyneins, also known as axonemal dyneins, are characterized based on their location on the axoneme, either as outer dynein arms or inner dynein arms. The I1 dynein is the best-characterized subspecies of the inner dynein arms; however the interactions between many of the components of the I1 complex and the axoneme are not well defined. In an effort to elucidate the interactions in which the I1 components are involved, we performed zero-length crosslinking on axonemes and studied the crosslinked products formed by the I1 intermediate chains, IC138 and IC140. Our data indicate that IC138 and IC140 bind directly to microtubules. Mass-spectrometry analysis of the crosslinked product identified both α- and β-tubulin as the IC138 and IC140 binding partners. This was further confirmed by crosslinking experiments carried out on purified I1 fractions bound to Taxol-stabilized microtubules. Furthermore, the interaction between IC140 and tubulin is lost when IC138 is absent. Our studies support previous findings that intermediate chains play critical roles in the assembly, axonemal targeting and regulation of the I1 dynein complex.     

The alpha subunit of sea urchin sperm outer arm dynein mediates structural and rigor binding to microtubules

Glass-adsorbed intact sea urchin outer arm dynein and its beta/IC1 subunit supports movement of microtubules, yet does not form a rigor complex upon depletion of ATP (16). We show here that rigor is a feature of the isolated intact outer arm, and that this property subfractionates with its alpha heavy chain. Intact dynein mediates the formation of ATP-sensitive microtubule bundles, as does the purified alpha heavy chain, indicating that both particles are capable of binding to microtubules in an ATP-sensitive manner. In contrast, the beta/IC1 subunit does not bundle microtubules. Bundles formed with intact dynein are composed of ribbon-like sheets of parallel microtubules that are separated by 54 nm (center-to-center) and display the same longitudinal repeat (24 nm) and cross-sectional geometry of dynein arms as do outer doublets in situ. Bundles formed by the alpha heavy chain are composed of microtubules with a center-to-center spacing of 43 nm and display infrequent, fine crossbridges. In contrast to the bridges formed by the intact arm, the links formed by the alpha subunit are irregularly spaced, suggesting that binding of the alpha heavy chain to the microtubules is not cooperative. Cosedimentation studies showed that: (a) some of the intact dynein binds in an ATP-dependent manner and some binds in an ATP-independent manner; (b) the beta/IC1 subunit does not cosediment with microtubules under any conditions; and (c) the alpha heavy chain cosediments with microtubules in the absence or presence of MgATP2-. These results suggest that the structural binding observed in the intact arm also is a property of its alpha heavy chain. We conclude that whereas force-generation is a function of the beta/IC1 subunit, both structural and ATP-sensitive (rigor) binding of the arm to the microtubule are mediated by the alpha subunit.     

Further studies on knockout mice lacking a functional dynein heavy chain (MDHC7). 1. Evidence for a structural deficit in the axoneme

Male mice had previously been generated in which the inner dynein arm heavy chain 7 gene (MDHC7) was inactivated by the substitution of four exons encoding the ATP-binding site (P1-loop) with the neomycin resistance gene, giving a putative non-functional gene product. We have used additional techniques of electron microscopy to determine what effect the truncated, non-functional heavy chain has on the assembly of the inner dynein arm complex. From a comparison of MDHC7-/- with the wild-type morphology, we have found that the expected loss of a C-terminal (globular) domain is associated with inner dynein arm 3, a change from two visible "heads" to one. This deficit was seen in replicas of rapidly-frozen, deeply-etched spermatozoa, and was confirmed in filtered images of 20-nm-thin sections, cut in longitudinal planes. Assembly of the other IDAs appeared unaffected. This study is the first to reveal the location of a specific dynein heavy chain within the 96-nm repeat pattern of the inner dynein arms of the mammalian axoneme.     

Structure and mass analysis of 12S and 19S dynein obtained from bull sperm flagella

The Brookhaven scanning transmission electron microscope (STEM) was used to elucidate the structures and masses of 12S and 19S dynein extracted from bull sperm flagella. The 12S particle was a single globular particle with an average mass of 311 +/- 10 kdaltons. The 19S dynein particles consisted of two globular heads joined to a common base. The average mass of the 19S particle was 1.6 +/- 0.04 X 10(6) daltons. Thus, with the exception of the larger mass, the bull sperm 19S dynein molecule resembles the two-headed 21S dynein obtained from sea urchin sperm flagella and the 18S dynein obtained from Chlamydomonas with the possibility of a third head giving rise to the 12S particle. The structure, mass and polypeptide composition of bull sperm flagella dynein is compared with outer arm dyneins previously obtained from Chlamydomonas, Tetrahymena, and sea urchin sperm flagella.     

Activation of the dynein adenosinetriphosphatase by cross-linking to microtubules

The microtubule-dynein complex consisting of 22S dynein from Tetrahymena cilia and MAP-free microtubules was subjected to treatment with various concentrations of 1-ethyl-3-[3-(dimethylamino)-propyl]carbodiimide (EDC), a zero-length cross-linker, at 28 degrees C for 1 h. Following cross-linking of the microtubule-dynein complex, nearly all of the ATPase activity cosedimented with the microtubules in the presence of ATP. Electron microscopic observation by negative staining revealed that, following treatment with 1 mM EDC, the complex did not dissociate in the presence of ATP, although the dynein decoration pattern was disordered. The complex treated with 3 mM EDC exhibited normal microtubule-dynein patterns even after the addition of ATP. The ATPase activity of the microtubule-dynein complex was enhanced about 30-fold by the treatment with 1-3 mM EDC. These results indicate that the ATPase activation was caused by the close proximity of the dynein ATPase sites to the microtubules and provide further support for the functional interaction of all three dynein heads with the microtubule. The maximal specific activity was 12 mumol min-1 (mg of dynein)-1, corresponding to a turnover rate of 150 s-1, which may be the rate-limiting step at infinite microtubule concentration and may represent the maximum rate of force production in the axoneme.     

Properties of the full-length heavy chains of Tetrahymena ciliary outer arm dynein separated by urea treatment

An important challenge is to understand the functional specialization of dynein heavy chains. The ciliary outer arm dynein from Tetrahymena thermophila is a heterotrimer of three heavy chains, called alpha, beta and gamma. In order to dissect the contributions of the individual heavy chains, we used controlled urea treatment to dissociate Tetrahymena outer arm dynein into a 19S beta/gamma dimer and a 14S alpha heavy chain. The three heavy chains remained full-length and retained MgATPase activity. The beta/gamma dimer bound microtubules in an ATP-sensitive fashion. The isolated alpha heavy chain also bound microtubules, but this binding was not reversed by ATP. The 19S beta/gamma dimer and the 14S alpha heavy chain could be reconstituted into 22S dynein. The intact 22S dynein, the 19S beta/gamma dimer, and the reconstituted dynein all produced microtubule gliding motility. In contrast, the separated alpha heavy chain did not produce movement under a variety of conditions. The intact 22S dynein produced movement that was discontinuous and slower than the movement produced by the 19S dimer. We conclude that the three heavy chains of Tetrahymena outer arm dynein are functionally specialized. The alpha heavy chain may be responsible for the structural binding of dynein to the outer doublet A-tubule and/or the positioning of the beta/gamma motor domains near the surface of the microtubule track.     

Inhibition of gliding movement by calcium in doublet microtubules on Tetrahymena ciliary dyneins in vitro.

We examined the effects of Ca ions on the gliding movement of Tetrahymena ciliary doublet microtubules induced by 14S or 22S dyneins in an in vitro motility assay system. The doublet microtubule appeared as circular-arc in solution, about 5 to 6 microns in length [1]. The doublet microtubules glided distal-end first on a 14S or 22S dynein-coated glass surface either clockwise or counterclockwise following the addition of ATP. The diameter of the circular path changed according to Ca concentration in the solution. Gliding velocity was from 1 to 5 microns/s. The addition of 0.1% Nonidet P-40 was necessary to induce the gliding movement on 22S dynein. This movement on 22S dynein was strongly inhibited above 0.5 mM ATP in the presence of 10(-9) M Ca, and at 0.05 to 1 mM ATP in the presence of 10(-3) M Ca. Many studies have indicated that Ca ions regulate ciliary movement [2-8] in which dyneins and doublet microtubule in the axoneme may play an essential role. The inhibition of the gliding movement of doublet microtubule on dyneins at appropriate concentrations of Ca and ATP as observed in this study may be the key for understanding Ca regulation of ciliary motility.     

Directional instability of microtubule transport in the presence of kinesin and dynein, two opposite polarity motor proteins

Kinesin and dynein are motor proteins that move in opposite directions along microtubules. In this study, we examine the consequences of having kinesin and dynein (ciliary outer arm or cytoplasmic) bound to glass surfaces interacting with the same microtubule in vitro. Although one might expect a balance of opposing forces to produce little or no net movement, we find instead that microtubules move unidirectionally for several microns (corresponding to hundreds of ATPase cycles by a motor) but continually switch between kinesin-directed and dynein-directed transport. The velocities in the plus-end (0.2-0.3 microns/s) and minus-end (3.5-4 microns/s) directions were approximately half those produced by kinesin (0.5 microns/s) and ciliary dynein (6.7 microns/s) alone, indicating that the motors not contributing to movement can interact with and impose a drag upon the microtubule. By comparing two dyneins with different duty ratios (percentage of time spent in a strongly bound state during the ATPase cycle) and varying the nucleotide conditions, we show that the microtubule attachment times of the two opposing motors as well as their relative numbers determine which motor predominates in this assay. Together, these findings are consistent with a model in which kinesin-induced movement of a microtubule induces a negative strain in attached dyneins which causes them to dissociate before entering a force-generating state (and vice versa); reversals in the direction of transport may require the temporary dissociation of the transporting motor from the microtubule. The bidirectional movements described here are also remarkably similar to the back-and-forth movements of chromosomes during mitosis and membrane vesicles in fibroblasts. These results suggest that the underlying mechanical properties of motor proteins, at least in part, may be responsible for reversals in microtubule-based transport observed in cells.