Helix sliding in the stalk coiled coil of dynein couples ATPase and microtubule binding.

Coupling between ATPase and track binding sites is essential for molecular motors to move along cytoskeletal tracks. In dynein, these sites are separated by a long coiled coil stalk that must mediate communication between them, but the underlying mechanism remains unclear. Here we show that changes in registration between the two helices of the coiled coil can perform this function. We locked the coiled coil at three specific registrations using oxidation to disulfides of paired cysteine residues introduced into the two helices. These trapped ATPase activity either in a microtubule-independent high or low state, and microtubule binding activity either in an ATP-insensitive strong or weak state, depending on the registry of the coiled coil. Our results provide direct evidence that dynein uses sliding between the two helices of the stalk to couple ATPase and microtubule binding activities during its mechanochemical cycle.

Structure and functional role of dynein's microtubule-binding domain.

Dynein motors move various cargos along microtubules within the cytoplasm and power the beating of cilia and flagella. An unusual feature of dynein is that its microtubule-binding domain (MTBD) is separated from its ring-shaped AAA+ adenosine triphosphatase (ATPase) domain by a 15-nanometer coiled-coil stalk. We report the crystal structure of the mouse cytoplasmic dynein MTBD and a portion of the coiled coil, which supports a mechanism by which the ATPase domain and MTBD may communicate through a shift in the heptad registry of the coiled coil. Surprisingly, functional data suggest that the MTBD, and not the ATPase domain, is the main determinant of the direction of dynein motility.

Analysis of cytoskeletal and motility proteins in the sea urchin genome assembly.

The sea urchin embryo is a classical model system for studying the role of the cytoskeleton in such events as fertilization, mitosis, cleavage, cell migration and gastrulation. We have conducted an analysis of gene models derived from the Strongylocentrotus purpuratus genome assembly and have gathered strong evidence for the existence of multiple gene families encoding cytoskeletal proteins and their regulators in sea urchin. While many cytoskeletal genes have been cloned from sea urchin with sequences already existing in public databases, genome analysis reveals a significantly higher degree of diversity within certain gene families. Furthermore, genes are described corresponding to homologs of cytoskeletal proteins not previously documented in sea urchins. To illustrate the varying degree of sequence diversity that exists within cytoskeletal gene families, we conducted an analysis of genes encoding actins, specific actin-binding proteins, myosins, tubulins, kinesins, dyneins, specific microtubule-associated proteins, and intermediate filaments. We conducted ontological analysis of select genes to better understand the relatedness of urchin cytoskeletal genes to those of other deuterostomes. We analyzed developmental expression (EST) data to confirm the existence of select gene models and to understand their differential expression during various stages of early development.

Bovine epigastric heteropagus in Trinidad and Tobago: a case study

Congenital duplications are common causes of dystocia in farm animals, especially in cattle. Heteropagus or conjoined asymmetric twins can be differentiated into a dominant and a parasitic twin, which can be classified further by the development of the parasitic twin and its anatomical attachment to the dominant twin (autosite). In epigastric heteropagus, the parasitic twin is attached to the autosite in the epigastric area. Epigastric heteropagus is a very rare condition in all species, but it has previously been reported in human beings (Chadhaand others 1993). There have been no reports of heteropagus in cattle in Trinidad and Tobago, and there is a paucity of information on bovine epigastric heteropagus in the literature. Reports of congenital abnormalities in Trinidad include craniopagus in a calf (Isitor and Adogwa 1992), perosomus elumbus in a goat (Cazabon and others 1994) and cephalothoracopagus in sheep (Cazabon and Adogwa 2003). The interest in congenital abnormalities lies mainly in the aetiology and its implications, such as genetic defects and environmental toxins. This short communication describes the firstcase of epigastric heteropagus in cattle reported in Trinidad and Tobago.

The affinity of the dynein microtubule-binding domain is modulated by the conformation of its coiled-coil stalk.

The microtubule-binding domain (MTBD) of dynein is separated from the AAA (ATPase with any other activity) core of the motor by an approximately 15-nm stalk that is predicted to consist of an antiparallel coiled coil. However, the structure of this coiled coil and the mechanism it uses to mediate communication between the MTBD and ATP-binding core are unknown. Here, we sought to identify the optimal alignment between the hydrophobic heptad repeats in the two strands of the stalk coiled coil. To do this, we fused the MTBD of mouse cytoplasmic dynein, together with 12-36 residues of its stalk, onto a stable coiled-coil base provided by Thermus thermophilus seryl-tRNA synthetase and tested these chimeric constructs for microtubule binding in vitro. The results identified one alignment that yielded a protein displaying high affinity for microtubules (2.2 microM). The effects of mutations applied to the MTBD of this construct paralleled those previously reported (Koonce, M. P., and Tikhonenko, I. (2000) Mol. Biol. Cell 11, 523-529) for an intact dynein motor unit in the absence of ATP, suggesting that it resembles the tight binding state of native intact dynein. All other alignments showed at least 10-fold lower affinity for microtubules with the exception of one, which had an intermediate affinity. Based on these results and on amino acid sequence analysis, we hypothesize that dynein utilizes small amounts of sliding displacement between the two strands of its coiled-coil stalk as a means of communication between the AAA core of the motor and the MTBD during the mechanochemical cycle.

Expression and genomic analysis of midasin, a novel and highly conserved AAA protein distantly related to dynein.

BACKGROUND: The largest open reading frame in the Saccharomyces genome encodes midasin (MDN1p, YLR106p), an AAA ATPase of 560 kDa that is essential for cell viability. Orthologs of midasin have been identified in the genome projects for Drosophila, Arabidopsis, and Schizosaccharomyces pombe. RESULTS: Midasin is present as a single-copy gene encoding a well-conserved protein of approximately 600 kDa in all eukaryotes for which data are available. In humans, the gene maps to 6q15 and encodes a predicted protein of 5596 residues (632 kDa). Sequence alignments of midasin from humans, yeast, Giardia and Encephalitozoon indicate that its domain structure comprises an N-terminal domain (35 kDa), followed by an AAA domain containing six tandem AAA protomers (approximately 30 kDa each), a linker domain (260 kDa), an acidic domain (approximately 70 kDa) containing 35-40% aspartate and glutamate, and a carboxy-terminal M-domain (30 kDa) that possesses MIDAS sequence motifs and is homologous to the I-domain of integrins. Expression of hemagglutamin-tagged midasin in yeast demonstrates a polypeptide of the anticipated size that is localized principally in the nucleus. CONCLUSIONS: The highly conserved structure of midasin in eukaryotes, taken in conjunction with its nuclear localization in yeast, suggests that midasin may function as a nuclear chaperone and be involved in the assembly/disassembly of macromolecular complexes in the nucleus. The AAA domain of midasin is evolutionarily related to that of dynein, but it appears to lack a microtubule-binding site.

Model for the motor component of dynein heavy chain based on homology to the AAA family of oligomeric ATPases.

BACKGROUND: Recent iterative methods for sequence alignment have indicated that the 380 kDa motor unit of dynein belongs to the AAA class of chaperone-like ATPases. These alignments indicate that the core of the 380 kDa motor unit contains a concatenated chain of six AAA modules, of which four correspond to the ATP binding sites with P-loop signatures described previously, and two are modules in which the P loop has been lost in evolution. RESULTS: We report predicted structures for the six AAA modules in the beta heavy chain of axonemal dynein, based upon their homology to a template of structurally conserved regions derived from three AAA proteins with experimentally determined structures (pdb:1A5T, pdb:1DOO, and pdb:1NSF). The secondary structural elements of the AAA modules in dynein correspond to regions of sequence that are relatively well conserved in different dynein isoforms. The tertiary structure of each AAA module comprises a major alpha/beta N domain from which a smaller all-alpha C domain protrudes at an angle, as part of the putative nucleotide binding cavity. The structures of the six modules are assembled into a ring, approximately 125 A in diameter, that resembles the structure of the dynein motor unit observed by electron microscopy. CONCLUSION: The predicted structures are supported by procedures that assess global, regional, and local quality, with the module containing the hydrolytic ATP binding site being supported the most strongly. The structural resemblance of the dynein motor to the hexameric assembly of AAA modules in the hsp100 family of chaperones suggests that the basic mechanism underlying the ATP-dependent translocation of dynein along a microtubule may have aspects in common with the ATP-dependent translocation of polypeptides into the interior compartment of chaperones.

Probing the nucleotide binding sites of axonemal dynein with the fluorescent nucleotide analogue 2'(3')-O-(-N-Methylanthraniloyl)-adenosine 5'-triphosphate.

MantATP [2'(3')-O-(-N-methylanthraniloyl)-adenosine 5'-triphosphate] was employed as a fluorescence probe of the nucleotide-binding sites of dynein from sea urchin sperm flagella. MantATP binds specifically with enhanced fluorescence (approximately 2.2-fold), homogeneous lifetime (8.4 ns), and high anisotropy (r approximately 0.38) to dynein and can be displaced by ATP and ADP added to the medium. The association constants of mantATP complexed with dynein were determined from anisotropy titration data. Using a multiple stepwise equilibrium model, the average values of the first two association constants are K1 = 2.7 x 10(5) M-1 and K2 = 1.8 x 10(4) M-1. This value of K1 is 7-8 times higher than that found previously for unsubstituted ATP, whereas K2 is little changed [Mocz and Gibbons (1996) Biochemistry 35, 9204-9211]. The lower-affinity binding sites, K3 and K4, observed previously could not be studied with mantATP within the available protein concentrations. The alpha and beta heavy chain subfractions have binding parameters similar to those of intact dynein. Formation of the stable ternary complex of mantATP with dynein and monomeric vanadate is accompanied by only a moderate increase in the binding affinities. Oligomeric vanadate reduces the binding affinities by approximately 50%. Addition of TritonX-100, methanol, or various salts changes the binding affinities by up to 50%, suggesting that the microenvironment of the nucleotide-binding sites involves significant contributions from both polar and apolar interactions. The distinct affinities of the individual binding sites are consistent with a physiological role in regulating nucleotide binding.

The role of dynein in microtubule-based motility.

Dyneins are high molecular weight ATPases that function as microtubule-based molecular motors. The axonemal dyneins, discovered 30 years ago, are responsible for the beating movement of cilia and sperm flagella, which they generate by producing sliding between adjacent microtubules. Cytoplasmic dynein, more recently discovered, is involved in diverse activities, including intracellular transport, nuclear migration, and the orientation of the cell spindle at mitosis.

Phase partition analysis of nucleotide binding to axonemal dynein.

The binding of nucleoside triphosphates and related ligands to dynein ATPase from sea urchin sperm flagella has been studied by equilibrium partition analysis in an aqueous biphasic system containing dextran and poly(ethylene glycol). The stoichiometry of binding and the corresponding stepwise binding constants are obtained from direct binding isotherms fitted to the primary data. The results suggest that dynein possesses four different binding sites for nucleoside triphosphates per mole of heavy chain. The stepwise binding constants for MgATP range from approximately 10(4) M-1 to approximately 10(5) M-1. The isolated alpha and beta heavy chains have binding parameters similar to intact dynein. The amount of ADP bound normally is approximately 75% that of ATP, both for the intact dynein and for the separated heavy chains, although full saturation is achieved at high nucleotide concentrations. In the presence of the ATPase inhibitor vanadate, ADP binds with affinities similar to those of ATP, with binding constants close to those of ATP in the absence of vanadate. No appreciable binding of AMP or EDTA/ATP is observed. The substitution of Ca2+ or Fe3+ for Mg2+ does not significantly alter the amount of ATP bound; however, CaATP is bound with a somewhat lower affinity. Scatchard and Hill plots of the binding data and the calculated site-binding constants suggest that ATP and ADP bind in a weakly cooperative manner. These results suggest that the multiple binding of nucleotide to dynein heavy chains occurs at physiological concentrations, putatively at the four binding sites predicted earlier on the basis of their amino acid sequences. The data are consistent with a model in which, in addition to a single catalytic site, nucleotide binding occurs at additional noncatalytic sites that represent an as yet unknown functional aspect of dynein.

Effect of beat frequency on the velocity of microtubule sliding in reactivated sea urchin sperm flagella under imposed head vibration.

The heads of demembranated spermatozoa of the sea urchin Tripneustes gratilla, reactivated at different concentrations of ATP, were held by suction in the tip of a micropipette and vibrated laterally with respect to the head axis. This imposed vibration resulted in a stable rhythmic beating of the reactivated flagella that was synchronized to the frequency of the micropipette. The reactivated flagella, which in the absence of imposed vibration had an average beat frequency of 39 Hz at 2 mmol l-1 ATP, showed stable beating synchronized to the pipette vibration over a range of 20-70 Hz. Vibration frequencies above 70 Hz caused irregular, asymmetrical beating, while those below 20 Hz induced instability of the beat plane. At ATP concentrations of 10-100 mumol l-1, the range of vibration frequency capable of maintaining stable beating was diminished; an increase in ATP concentration above 2 mmol l-1 had no effect on the range of stable beating. In flagella reactivated at ATP concentrations above 100 mumol l-1, the apparent time-averaged sliding velocity of axonemal microtubules decreased when the imposed frequency was below the undriven flagellar beat frequency, but at higher imposed frequencies it remained constant, with the higher frequency being accompanied by a decrease in bend angle. This maximal sliding velocity at 2 mmol l-1 ATP was close to the sliding velocity in the distal region of live spermatozoa, possibly indicating that it represents an inherent limit in the velocity of active sliding.(ABSTRACT TRUNCATED AT 250 WORDS)

Saccharomyces cerevisiae kinesin- and dynein-related proteins required for anaphase chromosome segregation.

The Saccharomyces cerevisiae kinesin-related gene products Cin8p and Kip1p function to assemble the bipolar mitotic spindle. The cytoplasmic dynein heavy chain homologue Dyn1p (also known as Dhc1p) participates in proper cellular positioning of the spindle. In this study, the roles of these motor proteins in anaphase chromosome segregation were examined. While no single motor was essential, loss of function of all three completely halted anaphase chromatin separation. As combined motor activity was diminished by mutation, both the velocity and extent of chromatin movement were reduced, suggesting a direct role for all three motors in generating a chromosome-separating force. Redundancy for function between different types of microtubule-based motor proteins was also indicated by the observation that cin8 dyn1 double-deletion mutants are inviable. Our findings indicate that the bulk of anaphase chromosome segregation in S. cerevisiae is accomplished by the combined actions of these three motors.

Dynein family of motor proteins: present status and future questions.

Analysis of sequence relationships in dynein heavy chains shows that dynein motor proteins comprise a single homologous family with three main branches, cytoplasmic dynein, axonemal dynein, and a third branch represented by DYH1B that lies between the other two. In all branches of the family the dynein heavy chain has four copies of the P-loop motif for a nucleotide-binding site spaced approximately 300 residues apart in its midregion, with the amino acid sequence GPAGTGKT in the P-loop of the hydrolytic ATP-binding site. Cytoplasmic dyneins appear more primitive in that the heavy chain usually occurs as a homodimer, with traces of the early evolution of its four P-loop motifs by gene duplication being recognizable. In the axonemal subfamily the heavy chain occurs as heterodimers or heterotrimers encoded by multiple genes, and their non-hydrolytic P-loop motifs are much more divergent with little trace of their origin by gene duplication. The DYH1B subfamily is more closely related to the cytoplasmic dyneins in sequence, but appears related to axonemal dyneins in function since it becomes upregulated during reciliation and has not been found in organisms, such as yeast and Dictyostelium, that are totally without cilia or flagella.

Phylogeny and expression of axonemal and cytoplasmic dynein genes in sea urchins.

Transcripts approximately 14.5 kilobases in length from 14 different genes that encode for dynein heavy chains have been identified in poly(A)+ RNA from sea urchin embryos. Analysis of the changes in level of these dynein transcripts in response to deciliation, together with their sequence relatedness, suggests that 11 or more of these genes encode dynein isoforms that participate in regeneration of external cilia on the embryo, whereas the single gene whose deduced sequence closely resembles that of cytoplasmic dynein in other organisms appears not to be involved in this regeneration. The four consensus motifs for phosphate binding found previously in the beta heavy chain of sea urchin dynein are present in all five additional isoforms for which extended sequences have been obtained, suggesting that these sites play a significant role in dynein function. Sequence analysis of a approximately 400 amino acid region encompassing the putative hydrolytic ATP-binding site shows that the dynein genes fall into at least six distinct classes. Most of these classes in sea urchin have a high degree of sequence identity with one of the dynein heavy chain genes identified in Drosophila, indicating that the radiation of the dynein gene family into the present classes occurred at an early stage in the evolution of eukaryotes. Evolutionary changes in cytoplasmic dynein have been more constrained than those in the axonemal dyneins.

Cytoplasmic dynein is required for normal nuclear segregation in yeast.

We have identified the gene DYN1, which encodes the heavy chain of cytoplasmic dynein in the yeast Saccharomyces cerevisiae. The predicted amino acid sequence (M(r) 471,305) reveals the presence of four P-loop motifs, as in all dyneins known so far, and has 28% overall identity to the dynein heavy chain of Dictyostelium [Koonce, M. P., Grissom, P. M. & McIntosh, J. R. (1992) J. Cell Biol. 119, 1597-1604] with 40% identity in the putative motor domain. Disruption of DYN1 causes misalignment of the spindle relative to the bud neck during cell division and results in abnormal distribution of the dividing nuclei between the mother cell and the bud. Cytoplasmic dynein, by generating force along cytoplasmic microtubules, may play an important role in the proper alignment of the mitotic spindle in yeast.

ATP-insensitive interaction of the amino-terminal region of the beta heavy chain of dynein with microtubules.

The ATP-insensitive microtubule-binding site of dynein has been investigated by limited proteolysis of sea urchin sperm flagellar axonemes. Mild tryptic digestion cleaved the dynein beta chain at either of two principal cleavage sites, generating two sets of complementary peptides. Inclusion of ATP in the digestion medium had no effect on the generation of these primary fragments. Sucrose density gradient separation and immunostaining with monoclonal antibodies against epitopes on the beta chain showed that extraction of the digested axonemes with 1-3 mM ATP solubilizes the peptides located at the carboxy-terminal end of the original heavy chain. The solubilization of the peptides containing the amino end required the presence of 0.6 M NaCl and was not affected by ATP. While the outer arm dynein is in situ on the axoneme, the N-terminal 125-kDa domain of the beta chain was not digested by trypsin, whereas in soluble dynein this domain becomes rapidly degraded. These data suggest that the N-terminal domain of the beta chain is involved in its ATP-insensitive attachment to microtubules and support the hypothesis that the N-terminal 125-kDa peptide corresponds to the flexible tail of the dynein molecule seen in electron micrographs.

The phase of sperm flagellar beating is not conserved over a brief imposed interruption.

We have studied the phase component of flagellar beating by holding the head of a sea urchin sperm in the tip of a sinusoidally vibrating micropipet and then abruptly displacing the pipet laterally at a speed of 2.5 microns/ms for various durations. This rapid displacement of the pipet delayed the initiation of the next bend for as long as the displacement continued, up to a duration of 1 beat cycle, corresponding to a delay of 0.5 beat cycle. At the end of this displacement, the movement of the pipet was stopped completely without resumption of the initial vibration. Analysis of the flagellar waveform showed that immediately when the pipet was stopped, the flagellum started to beat by spontaneously initiating the bend that had been delayed. The flagellum then continued steady-state beating, with normal waveform and a new phase that was independent of the original phase of beating. These data suggest that the information on the phase of beating is located only at the basal end of the flagellum, and not in oscillators distributed along the axoneme. After this information has been lost, the flagellum can resume beating at any arbitrary phase relative to its original phase.

A cytoplasmic dynein heavy chain in sea urchin embryos.

By making the hypothesis that the pattern of conserved sequence residues in the vicinity of the hydrolytic ATP-binding site of dynein would resemble that in myosins from a broad variety of sources, we designed degenerate oligonucleotide primers capable of amplifying this region of multiple dynein isoforms from sea urchin embryo poly(A)+ RNA. Quantification of the expression of two of these dynein isoforms has shown that the level of mRNA encoding for the beta-heavy chain, like that of tubulin, increases 2-3-fold after deciliation of the embryos, whereas the expression of the second dynein isoform, like that of actin, is essentially unaffected. This second isoform is believed to be the cytoplasmic dynein of sea urchin embryos.