Dynein isoforms in sea urchin eggs

Purification and assay of mitotic motors

To understand how mitotic kinesins contribute to the assembly and function of the mitotic spindle, we need to purify these motors and analyze their biochemical and ultrastructural properties. Here we briefly review our use of microtubule (MT) affinity and biochemical fractionation to obtain information about the oligomeric state of native mitotic kinesin holoenzymes from eggs and early embryos. We then detail the methods we use to purify full length recombinant Drosophila embryo mitotic kinesins, using the baculovirus expression system, in sufficient yields for detailed in vitro assays. These two approaches provide complementary biochemical information on the basic properties of these key mitotic proteins, and permit assays of critical motor activities, such as MT-MT crosslinking and sliding, that are not revealed by assaying motor domain subfragments.

Two proteins isolated from sea urchin sperm flagella: structural components common to the stable microtubules of axonemes and centrioles

Biochemical fractionation of axonemal microtubules yields the protofilament ribbon (pf-ribbon), an insoluble structure of 3–4 longitudinal protofilaments composed primarily of alpha/beta tubulin, tektins A, B and C, and two previously uncharacterized polypeptides of 77 kDa and 83 kDa. We have isolated the 77/83 kDa polypeptides (termed Sp77 and Sp83) from sperm flagella of the sea urchin Stronglyocentrotus purpuratus and raised polyclonal antibodies against them. Sp77 and Sp83 copurify exclusively with the pf-ribbon. Both the anti-Sp77 and anti-Sp83 antibodies detected the nine outer doublets and the basal bodies of sea urchin sperm by immunofluorescence microscopy. In addition, the anti-Sp83 antibody, but not the anti-Sp77 antibody, detected a single 83 kDa polypeptide on immunoblots of unfertilized sea urchin egg cytoplasm, and a single polypeptide of 80 kDa on blots of isolated mitotic spindles from Chinese hamster ovary (CHO) cells. Previous studies have shown that tektins are present in the basal bodies and centrosomes/centrioles of cells ranging from clam to human. We found that anti-Sp83 decorates the spindle poles in sea urchin zygotes, and the interphase centrosome and spindle poles in CHO cells. In CHO cells arrested in S phase with aphidicolin, anti-Sp83 detects multiple centrosomes. The staining of the centrosome was not disrupted by prolonged nocodazole treatment, suggesting that the 80 kDa polypeptide is associated with the centrioles themselves. Our observations demonstrate that, like tektins, Sp77 and Sp83 are structural proteins associated with stable doublet microtubules, and may be components of basal bodies and centrioles of sea urchins and mammalian cells.

Minus-end-directed motion of kinesin-coated microspheres driven by microtubule depolymerization

Dynamic changes in microtubule (MT) length have long been thought to contribute to intracellular motility. Both the polymerization and depolymerization of tubulin have been shown to do work in vitro, but the biochemical complexity of objects moved, such as chromosomes, has complicated the identification of proteins that couple MT dynamics with motility. Work with MTs grown from and tethered to pellicles of lysed Tetrahymena has shown that disassembly-dependent movement of chromosomes in vitro can be inhibited with antibodies against the motor domain of kinesin. To study proteins that can function in disassembly-dependent motion, we have refined this motility assay, replacing chromosomes with protein-coated latex microspheres. We report here the ability of several enzymes, including kinesin, to support in vitro motility of latex microspheres on disassembling MTs (Fig. 1a). The polarity of kinesin's motor activity can be reversed by MT disassembly and interactions between a motor and a MT end can either slow or speed the rate of tubulin depolymerization.

A cytoplasmic dynein motor in Drosophila: identification and localization during embryogenesis

We have characterized a cytoplasmic dynein motor isoform that is present in extracts of Drosophila embryos. A prominent high molecular weight (HMW) polypeptide (> 400 kDa) is enriched in microtubules prepared from nucleotide-depleted embryonic extracts. Based on its ATP-sensitive microtubule binding activity, 20 S sedimentation coefficient, sensitivity to UV-vanadate and nucleotide specificity, the HMW polypeptide resembles cytoplasmic dyneins prepared from other organisms. The Drosophila cytoplasmic dynein acts as a minus-end motor that promotes microtubule translocation in vitro. A polyclonal antibody raised against the dynein heavy chain polypeptide was used to localize the dynein antigen in whole-mount preparations of embryos by immunofluorescence microscopy. These studies show that the dynein motor is associated with microtubules throughout embryogenesis, including mitotic spindle microtubules and microtubules of the embryonic nervous system.

Isolation and characterization of a novel dynein that contains C and A heavy chains from sea urchin sperm flagellar axonemes

A novel dynein (C/A dynein), which is composed of C and A heavy chains, two intermediate chains and several light chains, was isolated from sea urchin sperm flagella. The C/A dynein was released by the treatment with 0.7 M NaCl plus 5 mM ATP from the axonemes depleted of outer arm 21 S dynein. Sedimentation coefficient of this dynein was estimated by sucrose density gradient centrifugation to be 22–23 S. The C/A dynein particle appeared to be composed of three distinct domains; two globular head domains and one rod domain as seen by negative staining electron microscopy. The mobility of ‘A’ heavy chain of C/A dynein on SDS-gel electrophoresis was similar to that of A heavy chains (A alpha and A beta) of 21 S dynein. However, UV-cleavage patterns of C and A heavy chains of C/A dynein were different from those of A heavy chains of 21 S dynein. Furthermore, an antiserum raised against A heavy chain of C/A dynein did not crossreact with A heavy chains of 21 S dynein. Under the conditions in which the C/A dynein was released, some of inner arms were removed concomitantly from axonemes as observed by electron microscopy. These results suggested that C/A dynein is a component of the inner arms.

22S axonemal dynein is preassembled and functional prior to being transported to and attached on the axonemes

In an earlier study we reported the isolation of a cytoplasmic dynein from the cytosol of Paramecium multimicronucleatum. In this study we report the isolation and characterization of two cytosolic axonemal dyneins (22S and 12S) as well as a 19S cytoplasmic dynein from the cytosol of whole or deciliated cells using preformed bovine brain microtubules. These three dynein species were characterized according to mass, morphology, vanadate photocleavage patterns, CTPase/ATPase ratios, Km and Vmax values, temperature optima and reactivity with a mAb. For comparison, 22S and 12S axonemal dyneins (ADs) were also isolated and purified from the demembranated axonemes. The 22S and 12S soluble dyneins appear to be related to ciliary ADs in that the 22S soluble dynein is three-headed while the 12S is a one-headed dynein, as determined by negative staining. Ciliary ADs and their corresponding 22S and 12S soluble dyneins isolated from the cytosol also have similar Km and Vmax values as well as vanadate photocleavage patterns and temperature optima. A mAb raised against the soluble 22S dynein reacted with the 22S ciliary dyneins but not the 12S axonemal or the 19S cytoplasmic dynein. All isolated dyneins supported similar microtubule gliding rates but had different ionic requirements for the translocation buffer. These results suggest that: (i) the two soluble 22S and 12S dyneins are precursor molecules of the ciliary dyneins, (ii) the subunits of the outer arm dynein are already assembled in the cytosol as a three-headed bouquet, and (iii) the 22S and 12S soluble dyneins are functional prior to being transported and attached to the axonemes of the cilia.

Ciliary dynein of Paramecium tetraurelia: photolytic maps of the three heavy chains

The ciliate Paramecium tetraurelia presents a powerful system to define the structural basis for dynein functional diversity within a single cell. This analysis will depend on the biochemical resolution of the dynein proteins. As an important first step, the three heavy chains of the ciliary outer arm dynein of paramecium were characterized. Sucrose density gradient centrifugation in a high salt buffer separated the dynein into a 22S species, which contained the alpha and beta heavy chains, and a 12S species, which contained the gamma chain as well as the inner arm dynein heavy chains. Both the 22S and 12S species retained enzymatic latency as indicated by stimulation of MgATPase activity by 0.1% Triton X-100. An unusual ATP-independent V1-like photolysis of only the beta chain provided the basis for estimating that the beta chain contributes almost half of the 22S MgATPase activity that is susceptible to V1 photolysis. The combination of the density gradient separation of the partially dissociated dynein and the ATP-independent V1-like photolysis of only the beta chain led to the unambiguous assignment of the V1 photolytic products to the appropriate parent heavy chains. An estimate of the molecular sizes of the three heavy chains was obtained. The photolytic peptide maps, which define the ATP-binding domains, were determined for the three heavy chains.

Microtubule-associated motility in cytoplasmic extracts of sea urchin eggs

We have developed a method for producing sea urchin egg cytoplasmic extracts which support substantial microtubule-associated motility, particularly minus end-directed motility characteristic of cytoplasmic dynein. Particles translocated along microtubules and axonemes predominantly in the minus end direction; microtubules and axonemes glided across the coverslip surface only in the plus end direction (as expected for a minus-end directed motor bound to the coverslip surface); and microtubules crosslinked into bundles in an antiparallel orientation. Velocities of particle and microtubule translocation were in the range of 0.5-1.8 microns/sec. Vanadate at 10 microM inhibited all gliding of the microtubules and axonemes, yet bidirectional particle transport persisted. Vanadate at concentrations of 25 microM and higher inhibited nearly all microtubule-based motility in the preparation and produced parallel bundling of the microtubules. Motility was slowed but not stopped in the presence of 5 mM AMP-PNP. Usually when a particle bound to a microtubule wall, it moved to the microtubule minus end. These particles often remained attached to the minus end. When a microtubule plus end in the shortening phase of dynamic instability reached a stationary particle on the microtubule, sometimes normal minus end-directed motility was activated, or at other times the particle remained attached to the shortening plus end.

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.

Microtubule motors in the early sea urchin embryo

Sea urchin gametes and early embryos have proven to be a useful system for studying the roles of microtubule (MT)-associated motors in axonemal motility and cytoplasmic MT-based movements in dividing cells. In this brief article, known and potential sea urchin MT motors are listed and their possible biological functions are discussed.

Molecular cloning and expression of sea urchin embryonic ciliary dynein beta heavy chain

The determination of the structure and the expression of dynein during embryonic development are central to the understanding of dynein function. As an important first step toward these objectives, cDNAs encoding portions of sea urchin ciliary dynein were identified by antibody screening of a sea urchin cDNA expression library. Because of the complete lack of protein sequence data, it was first necessary to prove the identity of the dynein cDNAs. Of the five cDNA inserts initially cloned, one, designated P72A1, was characterized extensively. Four independent criteria demonstrated that P72A1 encoded a portion of a dynein heavy chain. (1) The beta-galactosidase-P72A1 fusion protein affinity-purified dynein-specific antibodies from crude antiserum. (2) Two other antisera to dynein, raised independently of the antiserum used to screen the cDNA library, reacted with the fusion protein. (3) A new antiserum raised against the fusion protein reacted with authentic dynein heavy chain on Western blots and stained embryonic cilia by indirect immunofluorescence microscopy. (4) Two new antisera, elicited against opposite ends of the P72A1 open reading frame, each reacted with authentic dynein heavy chain protein. Western blot analyses of dissociated dynein heavy chains revealed that P72A1 encoded a portion of the beta heavy chain. Epitope mapping experiments confirmed the identity of P72A1 as part of the beta heavy chain and also demonstrated that P72A1 encoded epitopes of the carboxyl-terminal fragment B domain of the dynein beta heavy chain. Northern blot analyses of poly(A)+ RNA revealed that P72A1 hybridized with a large RNA species ca. 12.5 kb in length. The dynein mRNA concentration increased during embryonic development. Dot blot analyses of RNA isolated at various times after embryo deciliation demonstrated that the dynein beta heavy chain mRNA accumulated rapidly in response to deciliation. The accumulation was similar to but not identical with the induction of tubulin mRNA in response to the same stimulus.

Analysis of mammalian dynein using antibodies against A polypeptides of sea urchin sperm flagellar dynein

Two different affinity-purified polyclonal antibodies were prepared against A polypeptides of dynein 1 extracted from sea urchin sperm. These antibodies, named AD1 and AD2, reacted exclusively with the alpha and beta heavy chains of dynein 1. Using these antibodies, we analyzed their cross-reactivity with dynein of mammalian cells. Immunohistochemically, both AD1 and AD2 stained dynein-related structures such as cilia of rabbit tracheal epithelia and flagella of rat spermatozoa. Immunoblots of the proteins extracted from mammalian cilia and flagella revealed the presence of A polypeptide-like proteins which cross-reacted with AD1 and AD2. Immunoblot analysis showed that the cross-reactive proteins were localized to the 370-kDa band of rabbit cilia and the 390- and 350-kDa bands of rat sperms. The reaction patterns showed that there were some differences between the two antibodies. On ciliary protein immunoblots, AD1 recognized about half of the broad band region which reacted with AD2, and AD1 also recognized only the 350-kDa band of the flagella extract, suggesting that the antibody reveals only a beta-like polypeptide. Immunoprecipitation studies using the ciliary proteins and AD2 confirmed that the immunoreactive protein had ATPase activity. Given these results, we have characterized mammalian dyneins previously reported by other laboratories.

Quantitation of the dynein pool in unfertilized sea urchin eggs

A dynein-like ATPase activity has been isolated previously from soluble extracts of unfertilized sea urchin eggs. However, the use of non-quantitative isolation techniques, in particular affinity for microtubules or Ca2+/calmodulin, has precluded accurate estimates of dynein pool size. We have taken the unique approach of using dynein-like ATPase activity to quantitate the egg dynein pool. This approach is based on the isolation by anion-exchange chromatography on DEAE-Sephacel of a peak of dynein-like ATPase activity comprising 65% of soluble ATPase activity in the cytosolic extract. Identification of cytoplasmic dynein was based on dose-dependent inhibition by erythro-9-[3-(2-hydroxynonyl)]adenine and orthovanadate, low GTPase activity and a sedimentation coefficient of 12 S. Two high molecular weight polypeptides corresponding to the A- and D-bands of axonemal dynein were shown to copurify with dynein-like ATPase activity and to undergo specific photocrosslinking with [alpha-32P]ATP, suggesting that they were egg dynein catalytic polypeptides. The specific ATPase activity of these putative catalytic polypeptides was determined to be 1.2 mumol.min-1.mg-1. The specific dynein-like ATPase activity of the crude soluble extract of unfertilized sea urchin eggs was determined to be 0.004 mumol.min-1.mg-1. The concentration of putative dynein catalytic polypeptides was therefore determined from the ratio of the specific activities of crude to pure cytoplasmic dynein catalytic polypeptide to be 0.33% of soluble protein, or 99 pg per egg. This is approximately 3-fold greater than the mass of dynein catalytic polypeptides estimated to be present in cilia at the blastula stage of sea urchin embryonic development. The large amount of cytoplasmic dynein in unfertilized eggs suggests that it could act as a precursor of embryonic ciliary dynein. Three minor peaks of ATPase activity were also resolved from cytosolic extracts and shown to be dynein-like. However, their GTPase activities were 2-4-fold higher than that of cytoplasmic dynein, raising the possibility that egg cytoplasm may contain several isoforms of dynein.

Preparation of microtubules from rat liver and testis: cytoplasmic dynein is a major microtubule associated protein

A microtubule associated protein from brain tissue (MAP 1C), has been found to possess many properties in common with ciliary and flagellar dyneins (Paschal et al.:J. Cell Biol. 105:1273-1282, 1987). However, this protein, now designated as cytoplasmic dynein, exhibited several properties which distinguish it from axonemal forms of the enzyme. We have investigated these characteristics further in a study of cytoplasmic dyneins from non-neuronal tissues. Rat liver and testis in particular were found to contain high levels of cytoplasmic dynein. The yield of dynein from testis was over 70 micrograms/g of tissue, making this the best source of cytoplasmic dynein of all tissues so far examined. The characterization of dynein from these sources has confirmed and extended our previous observations concerning the unique properties of cytoplasmic dynein. Activation of liver and testis dynein occurred at low (less than 1 mg/ml) tubulin concentration. Polypeptides identified as subunits of brain cytoplasmic dynein (74, 59, 57, 55, and 53 kDa) were present in liver and testis preparations. In addition, polypeptides at 150 and 45 kDa were found to copurify with the non-neuronal dyneins. The liver and testis enzyme hydrolyzed pyrimidine nucleotides at rates up to 12.5 times faster than ATP, though the relative affinity of cytoplasmic dynein for CTP was much lower (Km = 1.0 mM) than that for ATP. The properties of the testis enzyme were consistent with its identification as a cytoplasmic dynein rather than a sperm axonemal precursor. These data indicate that cytoplasmic dyneins may be widespread in distribution and that they share certain biochemical properties unique from those of axonemal dyneins. These characteristics are consistent with the proposal that cytoplasmic dynein plays a universal role in retrograde organelle motility.