Identification of dynamin, a novel mechanochemical enzyme that mediates interactions between microtubules

We report that calf brain microtubules prepared without nucleotide contain, in addition to kinesin and dynein, a polypeptide of 100 kd that could be dissociated by nucleotide. The protein was selectively extracted from microtubules using a combination of GTP and AMP-PNP. The extract contained microtubule-stimulated (6-fold) MgATPase activity that partitioned into two components upon further purification: the 100 kd polypeptide and a soluble activating fraction. The 100 kd protein induced microtubules to form hexagonally packed bundles containing periodic cross bridges spaced 13 nm apart. In the presence of ATP and the activating fraction, bundles fragmented, elongated, and exhibited other behavior indicative of sliding between microtubules. These findings indicate that the 100 kd protein is part of a novel mechanochemical enzyme, which we term "dynamin", that may mediate microtubule sliding in vivo.     

Identification of a kinesin-like microtubule-based motor protein in Dictyostelium discoideum.

Dictyostelium discoideum, a unicellular eukaryote amenable to both biochemical and genetic dissection, provides an attractive system for studying microtubule-based transport. In this work, we have identified microtubule-based motor activities in Dictyostelium cell extracts and have partially purified a protein that induces microtubule translocation along glass surfaces. This protein, which sediments at approximately 9S in sucrose density gradients and is composed of a 105 kd polypeptide, generates anterograde movement along microtubules that is insensitive to 5 mM NEM (N-ethyl-maleimide) but sensitive to 200 microM vanadate, and has similar nucleotide-dependent microtubule binding properties to those of kinesins purified from mammals, sea urchin and Drosophila. This kinesin-like molecule from Dictyostelium, however, is immunologically distinct from bovine and squid neuronal kinesins and supports microtubule movement on glass at four-fold greater velocities (2.0 versus 0.5 microns/sec). Furthermore, AMP-PNP (adenylyl imidodiphosphate), which promotes attachment of previously characterized kinesins to microtubules, decreases the affinity of the Dictyostelium kinesin homolog for microtubules. Thus, an AMP-PNP-induced rigor binding may not be a characteristic of kinesins from lower eukaryotes.     

Characterization of the microtubule movement produced by sea urchin egg kinesin

We have used an in vitro assay to characterize some of the motile properties of sea urchin egg kinesin. Egg kinesin is purified via 5'-adenylyl imidodiphosphate-induced binding to taxol-assembled microtubules, extraction from the microtubules in ATP, and gel filtration chromatography (Scholey, J. M., Porter, M. E., Grissom, P. M., and McIntosh, J. R. (1985) Nature 318, 483-486). This partially purified kinesin is then adsorbed to a glass coverslip, mixed with microtubules and ATP, and viewed by video-enhanced differential interference contrast microscopy. The microtubule translocating activity of the purified egg kinesin is qualitatively similar to the analogous activity observed in crude extracts of sea urchin eggs and resembles the activity of neuronal kinesin with respect to both the maximal rate (greater than 0.5 micron/s) and the direction of movement. Axonemes glide on a kinesin-coated coverslip toward their minus ends, and kinesin-coated beads translocate toward the plus ends of centrosome microtubules. Sea urchin egg kinesin is inhibited by high concentrations of SH reagents ([N-ethylmaleimide] greater than 3-5 mM), vanadate greater than 50 microM, and [nonhydrolyzable nucleotides] greater than or equal to [MgATP]. The nucleotide requirement of sea urchin egg kinesin is fairly broad (ATP greater than GTP greater than ITP), and the rate of microtubule movement increases in a saturable fashion with the [ATP]. We conclude that the motile activity of egg kinesin is indistinguishable from that of neuronal kinesin. We propose that egg kinesin may be associated with microtubule-based motility in vivo.     

Tau directs intracellular trafficking by regulating the forces exerted by kinesin and dynein teams

Organelles, proteins, and mRNA are transported bidirectionally along microtubules by plus‐end directed kinesin and minus‐end directed dynein motors. Microtubules are decorated by microtubule‐associated proteins (MAPs) that organize the cytoskeleton, regulate microtubule dynamics and modulate the interaction between motor proteins and microtubules to direct intracellular transport. Tau is a neuronal MAP that stabilizes axonal microtubules and crosslinks them into bundles. Dysregulation of tau leads to a range of neurodegenerative diseases known as tauopathies including Alzheimer's disease (AD). Tau reduces the processivity of kinesin and dynein by acting as an obstacle on the microtubule. Single‐molecule assays indicate that kinesin‐1 is more strongly inhibited than kinesin‐2 or dynein, suggesting tau might act to spatially modulate the activity of specific motors. To investigate the role of tau in regulating bidirectional transport, we isolated phagosomes driven by kinesin‐1, kinesin‐2, and dynein and reconstituted their motility along microtubules. We find that tau biases bidirectional motility towards the microtubule minus‐end in a dose‐dependent manner. Optical trapping measurements show that tau increases the magnitude and frequency of forces exerted by dynein through inhibiting opposing kinesin motors. Mathematical modeling indicates that tau controls the directional bias of intracellular cargoes through differentially tuning the processivity of kinesin‐1, kinesin‐2, and dynein. Taken together, these results demonstrate that tau modulates motility in a motor‐specific manner to direct intracellular transport, and suggests that dysregulation of tau might contribute to neurodegeneration by disrupting the balance of plus‐ and minus‐end directed transport.      

Presteady state kinetic analysis of vanadate-induced inhibition of the dynein ATPase

The effects of vanadate on the kinetics of ATP binding and hydrolysis by Tetrahymena 30 S dynein were examined by presteady state kinetic analysis. Up to a concentration of 400 microM, vanadate did not inhibit the rate or amplitude of the ATP binding-induced dissociation of the microtubule-dynein complex measured by stopped flow light-scattering methods. Chemical quench flow experiments showed that vanadate (80 microM) did not alter the rate or amplitude of the presteady state ATP binding or ATP hydrolysis transients, but the steady state hydrolysis of ATP was blocked immediately after a single turnover of ATP. Preincubation of the enzyme with ADP and vanadate inhibited both presteady state and steady state hydrolysis. These data suggest that vanadate acts as a phosphate analog to form an enzyme-ADP-vanadate complex, analogous to the transition state during catalysis, by the following pathway: (formula; see text) where V represents vanadate and D represents a dynein active site. ADP and vanadate, added together, induced dissociation of the microtubule-dynein complex at a maximum rate of 0.6 S-1. These observations imply that a microtubule-dynein-ADP-vanadate complex was formed which subsequently dissociated as shown below: (formula; see text) where M denotes a microtubule. The ADP plus vanadate-induced dissociation may represent the reverse of the normal forward pathway involving the binding of a dynein-ADP-phosphate complex to a microtubule.     

Kinetic evidence for multiple dynein ATPase sites

We have examined the kinetics of ATP-induced dissociation of the microtubule-dynein complex at low ATP concentrations in the presence of vanadate, which inhibits the enzyme after the binding and hydrolysis of a single ATP per site (Shimizu, T., and Johnson, K. A. (1983) J. Biol. Chem. 258, 13833-13840). Four aspects of the dissociation reaction could not be explained by a model of dynein with a single ATP-sensitive microtubule binding site. First, titration of the light-scattering amplitude versus ATP concentration in the presence of vanadate gave Mr = 720,000/ATP binding site, indicating approximately 2.8 sites/2 million molecular weight particle. Second, the dissociation reaction was incomplete at concentrations of less than 2 microM ATP in the absence of vanadate, while the addition of vanadate led to complete dissociation at an increased rate. Third, the time course of dissociation induced by less than or equal to 1 microM ATP in the presence of vanadate was biphasic, with a small but distinct lag. Fourth, the ATP concentration dependence of the rate of dissociation in the absence of vanadate was concave upward at concentrations of ATP less than 5 microM, whereas the plot was linear in the presence of vanadate. These data suggest that dynein has three ATP-sensitive microtubule binding sites and each site must bind ATP for dynein to detach from the microtubule.     

Specific cleavage of dynein heavy chains by ultraviolet irradiation in the presence of ATP and vanadate

Irradiation of soluble dynein 1 from sea urchin sperm flagella at 254 nm in the presence of 50 microM ATP and 100 microM inorganic vanadate (Vi) cleaves the alpha and beta heavy chains into approximately equal quantities of two polypeptides of Mr 228,000 and 200,000, with a conversion efficiency of about 63%. A similar cleavage occurs in the presence of Vi and either ADP or 8-azidoadenosine 5'-triphosphate (8-N3ATP); in the latter case, 8-N3ATP becomes covalently bound principally to the Mr 228,000 polypeptide. No detectable amount of these fragments is formed if either the Vi or the nucleotide is omitted or in the presence of Vi and 50 microM AMP. These results emphasize the basic similarity of the two ATPases associated with the alpha and beta heavy chain subunits of dynein 1 and give a mean Mr of 428,000 for the intact heavy chains.     

Two distinct isoforms of sea urchin egg dynein.

Extracts of unfertilized sea urchin eggs contain at least two isoforms of cytoplasmic dynein. One exhibits a weak affinity for microtubules and is primarily soluble. The other isoform, HMr-3, binds to microtubules in an ATP-sensitive manner, but is immunologically distinct from the soluble egg dynein (Porter et al.: Journal of Biological Chemistry 263:6759-6771, 1988). We have now further distinguished these egg dynein isoforms based on differences in NTPase activity. HMr-3 copurifies with NTPase activity, but it hydrolyzes CTP at 10 times the rate of ATP. The soluble egg dynein is similar to flagellar dynein in its nucleotide specificity; its MgCTPase activity is ca. 60% of its MgATPase activity. Non-ionic detergents and salt activate the MgATPase activities of both enzymes relative to their MgCTPase activities, but this effect is more pronounced for the soluble egg dynein than for HMr-3. Sucrose gradient-purified HMr-3 promotes an ATP-sensitive microtubule bundling, as seen with darkfield optics. We have also isolated a 20 S microtubule translocating activity by sucrose gradient fractionation of egg extracts, followed by microtubule affinity and ATP release. This 20 S fraction, which contains the HMr-3 isoform, induces a microtubule gliding activity that is distinct from kinesin. Our observations suggest that soluble dynein resembles axonemal dynein, but that HMr-2 is related to the dynein-like enzymes isolated from a variety of cell types and may represent the cytoplasmic dynein of sea urchin eggs.     

Mitotic HeLa cells contain a CENP-E-associated minus end-directed microtubule motor.

A minus end-directed microtubule motor activity from extracts of HeLa cells blocked at prometaphase/metaphase of mitosis with vinblastine has been partially purified and characterized. The motor activity was eliminated by immunodepletion of Centromere binding protein E (CENP-E). The CENP-E-associated motor activity, which was not detectable in interphase cells, moved microtubules at mean rates of 0.46 micron/s at 37 degrees C and 0.24 micron/s at 25 degrees C. The motor activity co-purified with CENP-E through several purification procedures. Motor activity was clearly not due to dynein or to kinesin. The microtubule gliding rates of the CENP-E-associated motor were different from those of dynein and kinesin. In addition, the pattern of nucleotide substrate utilization by the CENP-E-associated motor and the sensitivity to inhibitors were different from those of dynein and kinesin. The CENP-E-associated motor had an apparent native molecular weight of 874,000 Da and estimated dimensions of 2 nm x 80 nm. This is the first demonstration of motor activity associated with CENP-E, strongly supporting the hypothesis that CENP-E may act as a minus end-directed microtubule motor during mitosis.     

Interaction of dynamin with microtubules: its structure and GTPase activity investigated by using highly purified dynamin.

We purified a large amount of dynamin with high enzymatical activity from rat brain tissue by a new procedure. Dynamin 0.48 mg was obtained from 20 g of rat brain. The purity of dynamin was almost 98%. Dynamin plays a role of GTPase rather than ATPase. In the absence of microtubules, Michaelis constant (Km) and maximum velocity (Vmax) for dynamin GTPase were 370 microM and 0.25 min-1, respectively, and in their presence, both were significantly accelerated up to 25 microM and 5.5 min-1. On the other hand, the ATPase activity was very low in the absence of microtubules, and even in their presence, Km and Vmax for dynamin ATPase were 0.2 mM and 0.91 min-1. Despite slow GTPase turnover rate in the absence of microtubules, binding of GTP and its nonhydrolizing analogues was very fast, indicating that GTP binding step is not rate limiting. Dynamin did not cause a one-directional consistent microtubule sliding movement just like kinesin or dynein in the presence of 2 mM ATP or 2 mM GTP. We observed the molecular structure of dynamin with low-angle rotary shadowing technique and revealed that the dynamin molecule is globular in shape. Gel filtration assay revealed that these globules were the oligomers of 100-kDa dynamin polypeptide. Dynamin bound to microtubules with a 1:1 approximately 1.2 molar ratio in the absence of GTP. Quick-freeze deep-etch electron microscopy of the dynamin-microtubule complex showed that dynamin decorates the surface of microtubules helically, like a screw bolt, very orderly and tightly with 11.4 +/- 0.9 (SD)nm period. Contrary to the previous report, microtubules make bundles by the attachment of the dynamin helixes around each adjacent microtubule, and no cross-bridge formation was observed.     

Activation of dynein 1 adenosine triphosphatase by organic solvents and by Triton X-100

The presence of low concentrations of methanol or isopropyl alcohol (2-5%, v/v) in the assay medium stabilizes the latency of dynein 1 from sea urchin sperm flagella, with about a 50% decrease in ATPase level compared to that in the absence of solvent. Somewhat higher concentrations (10-20%, v/v) of these solvents in the assay give a 5-10-fold activation of ATPase activity. Dioxane, formamide, and dimethylformamide, on the other hand, always activate the ATPase activity, with a 5-10-fold increase observed at about 15% (v/v). The activation of latent ATPase activity by solvents is reversible for short exposures, especially in the presence of ATP and at low temperature, but the activation becomes irreversible upon more prolonged exposure. The rate constant for irreversible activation by 16% methanol at 21 degrees C is 0.08 min-1, compared to rates of 0.44 and 0.02 min-1 for activation by 0.05% Triton X-100 at 21 and 0 degree C, respectively. The slowness of this reversible activation induced by methanol and by Triton X-100 suggests that it is the result of large-scale conformational changes in the structure of the dynein. However, the activation by methanol occurs without the dissociation of the alpha and beta subunits of dynein that is observed with Triton X-100. The presence of 1 mM MgATP, or of 100 microM MgATP and 10 microM vanadate substantially protects latent dynein from activation by 0.05% Triton X-100.     

Microtubule and motor-dependent endocytic vesicle sorting in vitro

Endocytic vesicles undergo fission to sort ligand from receptor. Using quantitative immunofluorescence and video imaging, we provide the first in vitro reconstitution of receptor-ligand sorting in early endocytic vesicles derived from rat liver. We show that to undergo fission, presegregation vesicles must bind to microtubules (MTs) and move upon addition of ATP. Over 13% of motile vesicles elongate and are capable of fission. After fission, one vesicle continues to move, whereas the other remains stationary, resulting in their separation. On average, almost 90% receptor is found in one daughter vesicle, whereas ligand is enriched by approximately 300% with respect to receptor in the other daughter vesicle. Although studies performed on polarity marked MTs showed approximately equal plus and minus end-directed motility, immunofluorescence microscopy revealed that kinesins, but not dynein, were associated with these vesicles. Motility and fission were prevented by addition of 1 mM 5'-adenylylimido-diphosphate (AMP-PNP, an inhibitor of kinesins) or incubation with kinesin antibodies, but were unaffected by addition of 5 microM vanadate (a dynein inhibitor) or dynein antibodies. These studies indicate an essential role of kinesin-based MT motility in endocytic vesicle sorting, providing a system in which factors required for endocytic vesicle processing can be identified and characterized.     

A three-domain structure of kinesin heavy chain revealed by DNA sequence and microtubule binding analyses

The structure and function of kinesin heavy chain from D. melanogaster have been studied using DNA sequence analysis and analysis of the properties of truncated kinesin heavy chain synthesized in vitro. Analysis of the sequence suggests the existence of a 50 kd globular amino-terminal domain that contains an ATP binding consensus sequence, followed by another 50-60 kd domain that has sequence characteristics consistent with the ability to fold into an alpha helical coiled coil. The properties of amino- and carboxy-terminally truncated kinesin heavy chains synthesized in vitro reveal that a 60 kd amino-terminal fragment has the nucleotide-dependent microtubule binding activities of the intact kinesin heavy chain, and hence is likely to be a "motor" domain. Finally, the sequence data indicate the presence of a small carboxy-terminal domain. Because it is located at the end of the molecule away from the putative "motor" domain, we propose that this domain is responsible for interactions with other proteins, vesicles, or organelles. These data suggest that kinesin has an organization very similar to that of myosin even though there are no obvious sequence similarities between the two molecules.     

Two states of the conformation of 21S outer arm dynein coupled with ATP hydrolysis

Tryptic digestion of 21S outer arm dynein from sea urchin sperm flagella in the presence of ATP (or ADP) and vanadate produced quite different polypeptides from those obtained in the absence of ATP (ADP) and/or vanadate (Inaba and Mohri (1989) J. Biol. Chem. 264, 8384-8388). The 21S dynein heavy chains were consistently digested into 165- and 135-kDa polypeptides in the absence of both ATP (ADP) and vanadate. In the presence of 2 mM ADP and 100 microM vanadate, 300-kDa polypeptide, which appeared to be a precursor of 165- and 135-kDa polypeptides, became less accessible to trypsin, and 165- and 135-kDa polypeptides were digested into 150-/148-kDa and 96-kDa polypeptides, respectively. Quantitative analysis of the degradation of 165- and 135-kDa polypeptides showed that the conformations of these polypeptides change remarkably in the presence of ATP (ADP) and vanadate, and slightly in the presence of ATP gamma S. Photoaffinity labeling with 8-azidoadenosine 5'-triphosphate and vanadate-mediated photocleavage of dynein heavy chains revealed that both adenine- and gamma-Pi-binding sites were located on 165- and 150-/148-kDa polypeptides, but not on 135-kDa polypeptide. These results suggest that the conformational change occurring in the 165-kDa region on binding ATP spreads to the 135-kDa region and causes the conformational change of the 135-kDa region.     

In vitro motility of liver connexin vesicles along microtubules utilizes kinesin motors

Trafficking of the proteins that form gap junctions (connexins) from the site of synthesis to the junctional domain appears to require cytoskeletal delivery mechanisms. Although many cell types exhibit specific delivery of connexins to polarized cell sites, such as connexin32 (Cx32) gap junctions specifically localized to basolateral membrane domains of hepatocytes, the precise roles of actin- and tubulin-based systems remain unclear. We have observed fluorescently tagged Cx32 trafficking linearly at speeds averaging 0.25 μm/s in a polarized hepatocyte cell line (WIF-B9), which is abolished by 50 μM of the microtubule-disrupting agent nocodazole. To explore the involvement of cytoskeletal components in the delivery of connexins, we have used a preparation of isolated Cx32-containing vesicles from rat hepatocytes and assayed their ATP-driven motility along stabilized rhodamine-labeled microtubules in vitro. These assays revealed the presence of Cx32 and kinesin motor proteins in the same vesicles. The addition of 50 μM ATP stimulated vesicle motility along linear microtubule tracks with velocities of 0.4-0.5 μm/s, which was inhibited with 1 mM of the kinesin inhibitor AMP-PNP (adenylyl-imidodiphosphate) and by anti-kinesin antibody but only minimally affected by 5 μM vanadate, a dynein inhibitor, or by anti-dynein antibody. These studies provide evidence that Cx32 can be transported intracellularly along microtubules and presumably to junctional domains in cells and highlight an important role of kinesin motor proteins in microtubule-dependent motility of Cx32.     

Photosensitized cleavage of dynein heavy chains. Cleavage at the "V1 site" by irradiation at 365 nm in the presence of ATP and vanadate

Irradiation of soluble dynein 1 from sea urchin sperm flagella at 365 nm in the presence of MgATP and 0.05-50 microM vanadate (Vi) cleaves the alpha and beta heavy chains (Mr 428,000) at their V1 sites to give peptides of Mr 228,000 and 200,000, without the nonspecific side effects produced by irradiation at 254 nm as described earlier (Lee-Eiford, A., Ow, R. A., and Gibbons, I. R. (1986) J. Biol. Chem. 261, 2337-2342). The decrease in intact heavy chain material is biphasic; in 10 microM Vi, approximately 80% occurs with a half-time of 7 min and the remainder with a half-time of about 90 min, and the yield of cleavage peptides is better than 90%. Loss of dynein ATPase activity appears to be a direct result of the cleavage process and is not significantly affected by the presence of up to 0.1 M cysteamine (CA, 60-23-1) or 2-aminoethyl carbamimidothioic acid dihydrobromide (CA, 56-10-0) as free radical trapping agents. The concentration of Vi required for 50% maximal initial cleavage rate is 4.5 microM, while that for 50% ATPase inhibition is 0.8 microM, both in a 0.6 M NaCl medium. In the presence of 20 microM Vi, CTP and UTP support cleavage at about half the rate of ATP, whereas GTP and ITP support cleavage only if the Vi concentration is raised to about 200 microM. Substitution of any of the transition metal cations Cr2+, Mn2+, Fe2+, or Co2+ for the usual Mg2+ suppresses the photocleavage, presumably by quenching the excited chromophore prior to scission of the heavy chain. The photocleaved dynein 1 binds to dynein-depleted flagella similarly to intact dynein 1, but upon reactivation of the flagella with 1 mM ATP their motility is partially inhibited, rather than being augmented as with intact dynein. These results indicate that Vi acts as a photosensitizing catalyst and suggest that the cleavage proceeds through excitation of Vi bound to dynein at the hydrolytic ATP binding site on each heavy chain, probably in a dynein X MgADP X Vi complex. The exquisite specificity of Vi-sensitized photocleavage will aid the peptide mapping of dynein heavy chains and may be of broader use in studies of protein structure.     

mNUDC is required for plus‐end‐directed transport of cytoplasmic dynein and dynactins by kinesin‐1

Lissencephaly is a devastating neurological disorder caused by defective neuronal migration. The LIS1 (or PAFAH1B1) gene was identified as the gene mutated in lissencephaly patients, and was found to regulate cytoplasmic dynein function and localization. In particular, LIS1 is essential for anterograde transport of cytoplasmic dynein as a part of the cytoplasmic dynein–LIS1–microtubule complex in a kinesin‐1‐dependent manner. However, the underlying mechanism by which a cytoplasmic dynein–LIS1–microtubule complex binds kinesin‐1 is unknown. Here, we report that mNUDC (mammalian NUDC) interacts with kinesin‐1 and is required for the anterograde transport of a cytoplasmic dynein complex by kinesin‐1. mNUDC is also required for anterograde transport of a dynactin‐containing complex. Inhibition of mNUDC severely suppressed anterograde transport of distinct cytoplasmic dynein and dynactin complexes, whereas motility of kinesin‐1 remained intact. Reconstruction experiments clearly demonstrated that mNUDC mediates the interaction of the dynein or dynactin complex with kinesin‐1 and supports their transport by kinesin‐1. Our findings have uncovered an essential role of mNUDC for anterograde transport of dynein and dynactin by kinesin‐1.     

A functional in vitro model for studies of intracellular motility in digitonin-permeabilized erythrophores

Phase contrast cine results demonstrate that erythrophores maintain saltatory particle motion for hours after permeabilization with 0.001% digitonin in a cytoskeletal stabilizing solution at 23 degrees C. High voltage electron microscopy (HVEM) studies reveal that cytoskeletal elements are retained intact, except in immediate subplasmalemmal regions where the plasma membrane is punctured by digitonin. During digitonin treatments, cells are permeable to ions, small molecules, and antibodies. We find that motion is Ca2+ and ATP-sensitive, and optimal in PIPES buffer (pH 7.2 containing 1 mM Mg2+/ATP and EGTA-CA2+ (10(-7) M Ca2+) at 37 degrees C. Experiments testing the inhibitory effects of vanadate (0.4-10 microM), ouabain (100-600 microM), N-ethyl maleimide, and the cytochalasins B and D indicate that a dyneinlike ATPase may provide the motive force for driving saltatory pigment motion in erythropores.     

Dynein, dynactin, and kinesin II's interaction with microtubules is regulated during bidirectional organelle transport

The microtubule motors, cytoplasmic dynein and kinesin II, drive pigmented organelles in opposite directions in Xenopus melanophores, but the mechanism by which these or other motors are regulated to control the direction of organelle transport has not been previously elucidated. We find that cytoplasmic dynein, dynactin, and kinesin II remain on pigment granules during aggregation and dispersion in melanophores, indicating that control of direction is not mediated by a cyclic association of motors with these organelles. However, the ability of dynein, dynactin, and kinesin II to bind to microtubules varies as a function of the state of aggregation or dispersion of the pigment in the cells from which these molecules are isolated. Dynein and dynactin bind to microtubules when obtained from cells with aggregated pigment, whereas kinesin II binds to microtubules when obtained from cells with dispersed pigment. Moreover, the microtubule binding activity of these motors/dynactin can be reversed in vitro by the kinases and phosphatase that regulate the direction of pigment granule transport in vivo. These findings suggest that phosphorylation controls the direction of pigment granule transport by altering the ability of dynein, dynactin, and kinesin II to interact with microtubules.     

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.