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.     

Photosensitized cleavage of dynein heavy chains. Cleavage at the V2 site by irradiation at 365 NM in the presence of oligovanadate

Irradiation of the outer-arm dynein ATPase from sea urchin sperm flagella at 365 nm in the presence of 50-200 microM vanadate (Vi) and 1 mM manganese acetate, in the absence of ATP, cleaves the alpha and beta heavy chains at a specific site, termed the V2 site, to form discrete peptides of Mr approximately 260,000 and 170,000 from the alpha chain and of Mr approximately 255,000 and 175,000 from the beta chain, with a yield of 80%. This cleavage at the V2 site is not correlated with any direct effect on the dynein ATPase activity. In the presence of 100 microM Vi, the half-times for cleavage of the alpha and beta chains are about 12 and 50 min, respectively. The rate of heavy chain cleavage shows a sigmoidal dependence upon Vi concentration, with half-maximal rate occurring at 58 +/- 7 microM, consistent with the chromophore responsible for cleavage being tri-vanadate. Addition of 10 microM ATP or ADP, or of 100 microM CTP or UTP, to the irradiation medium inhibits cleavage at the V2 site, and results in a slow cleavage occurring at the V1 site described previously. The peptides produced by sequential cleavage at the V2 and then the V1 sites indicate that the sites are separated by about 100,000 Da along the length of each heavy chain. Photoaffinity labeling with [alpha-32P] 8-azidoadenosine 5'-triphosphate (8-N3ATP) gives specific incorporation of 32P into both the Mr 255,000 and 175,000 peptides of the beta chain but into only the Mr 260,000 peptide of the alpha chain. These results suggest that V2 cleavage occurs on a loop of the heavy chain that forms part of the ATP-binding site, close to the locus of 8-N3ATP attachment.     

Vanadate-sensitized cleavage of dynein heavy chains by 365-nm irradiation of demembranated sperm flagella and its effect on the flagellar motility

Irradiation of demembranated flagella of sea urchin sperm at 365 nm in the presence of 0.05-1 mM MgATP and 5-10 microM vanadate (Vi) cleaves the alpha and beta heavy chains of the outer arm dynein at the same site and at about the same rate as reported previously for the solubilized dynein (Gibbons, I. R., Lee-Eiford, A., Mocz, G., Phillipson, C. A., Tang, W.-J. Y., and Gibbons, B. H. (1987) J. Biol. Chem. 262, 2780-2786). The decrease in intact alpha and beta heavy chain material is biphasic, with about 80% being lost with a half-time of 8-10 min, and the remainder more slowly. Five other axonemal polypeptides of Mr greater than 350,000 are lost similarly, concomitant with the appearance of at least 9 new peptides of Mr 150,000-250,000. The motility of irradiated sperm flagella upon subsequent dilution into reactivation medium containing 1 mM ATP and 2.5 mM catechol shows a progressive decrease in flagellar beat frequency for irradiation times that produce up to about 50% cleavage of the dynein heavy chains; more prolonged irradiation causes irreversible loss of motility. Competition between photocleaved and intact outer arm dynein for rebinding to dynein-depleted sperm flagella shows that cleavage has little effect upon the ability for rebinding, although the cleaved dynein partially inhibits subsequent motility. Substitution of MnATP for the MgATP in the irradiation medium prevents the loss of all of the axonemal polypeptides during irradiation for up to 60 min and also protects the potential for subsequent flagellar motility. It is concluded that loss of the five axonemal polypeptides upon irradiation results from a Vi-sensitized photocleavage similar to that which occurs in the alpha and beta heavy chains of outer arm dynein and that these polypeptides represent Vi-inhibitable ATPase subunits of dyneins located in the inner arms and possibly elsewhere in the flagellar axoneme.     

A map of photolytic and tryptic cleavage sites on the beta heavy chain of dynein ATPase from sea urchin sperm flagella

NH2-terminal analysis of the alpha and beta heavy chain polypeptides (Mr greater than 400,000) from the outer arm dynein of sea urchin sperm flagella, compared with that of the 230,000- and 200,000-Mr peptides formed upon photocleavage of dynein by irradiation at 365 nm in the presence of vanadate and ATP, shows that the NH2 termini of the intact chains are acetylated and that the 230,000- and 200,000 Mr peptides constitute the amino- and carboxy-terminal portions of the heavy chains, respectively. Tryptic digestion of the beta heavy chain is known to separate it into two particles, termed fragments A and B, that sediment at 12S and 6S (Ow, R. A., W.-J. Y. Tang, G. Mocz, and I. R. Gibbons, 1987. J. Biol. Chem. 262:3409-3414). Immunoblots against monoclonal antibodies specific for epitopes on the beta heavy chain, used in conjunction with photoaffinity labeling, show that the ATPase-containing fragment A is derived from the amino-terminal region of the beta chain, with the two photolytic sites thought to be associated with the purine-binding and the gamma-phosphate-binding areas of the ATP-binding site spanning an approximately 100,000 Mr region near the middle of the intact beta chain. Fragment B is derived from the complementary carboxy-terminal region of the beta chain.     

Labeling of Chlamydomonas 18 S dynein polypeptides by 8-azidoadenosine 5'-triphosphate, a photoaffinity analog of ATP

The 18 S dynein from the outer arm of Chlamydomonas flagella is composed of an alpha subunit containing an alpha heavy chain (Mr = approximately 340,000) and an Mr = 16,000 light chain, and a beta subunit containing a beta heavy chain (Mr = approximately 340,000), two intermediate chains (Mr = 78,000 and 69,000), and seven light chains (Mr = 8,000-20,000). Both subunits contain ATPase activity. We have used 8-azidoadenosine 5'-triphosphate (8-N3 ATP), a photoaffinity analog of ATP, to investigate the ATP-binding sites of intact 18 S dynein. 8-N3ATP is a competitive inhibitor of 18 S dynein's ATPase activity and is itself hydrolyzed by 18 S dynein; moreover, 18 S dynein's hydrolysis of ATP and 8-N3ATP is inhibited by vanadate to the same extent. 8-N3ATP therefore appears to interact with at least one of 18 S dynein's ATP hydrolytic sites in the same way as does ATP. When [alpha- or gamma-32P]8-N3ATP is incubated with 18 S dynein in the presence of UV irradiation, label is incorporated primarily into the alpha, beta, and Mr = 78,000 chains; a much smaller amount is incorporated into the Mr = 69,000 chain. The light chains are not labeled. The incorporation is UV-dependent, ATP-sensitive, and blocked by preincubation of the enzyme with vanadate plus low concentrations of ATP or ADP. These results suggest that the alpha heavy chain contains the site of ATP binding and hydrolysis in the alpha subunit. In the beta subunit, the beta heavy chain and one or both intermediate chains may contain ATP-binding sites.     

Structure of the alpha and beta heavy chains of the outer arm dynein from Chlamydomonas flagella. Nucleotide binding sites

The photoaffinity analogs 2-azidoadenosine 5'-tri(di)-phosphate (2-N3AT(D)P) and 8-azidoadenosine 5'-triphosphate (8-N3ATP) have been used to probe the substructural organization of the nucleotide binding pockets within the alpha and beta heavy chains of the outer arm dynein from Chlamydomonas flagella. Both 2-N3ATP and 8-N3ATP are competitive inhibitors of dynein ATP hydrolysis, and both analogs are themselves hydrolyzed by the alpha-beta dimer. Following vanadate-dependent photolysis at the V1 site (by UV irradiation in the presence of Mg2+, ATP, and vanadate), both probes exclusively labeled the larger fragment from the alpha chain. In contrast, within the beta chain the predominant insertion sites for the two analogs were located on opposite sides of the V1 site. Therefore, the hydrolytic pockets of these two molecules have different substructures. Vanadate-dependent photolysis of the alpha and beta chains at the V2 sites (by UV irradiation in the presence of vanadate and Mn2+) profoundly affected the predominant modification sites; for example, following photolysis at the V2a site neither fragment of the alpha chain was photolabeled by 2-N3ATP or 8-N3ATP. Based on the photolabeling patterns obtained, the single V2 site within the beta chain is predicted to be analogous to the V2b site within the alpha chain. The results support the hypothesis that the V2 sites occur within the ATP binding pockets, and indicate that these functional domains are composed of portions of the heavy chains which are linearly separated by up to at least 100,000 daltons. Thus, the central region of each dynein heavy chain must be extensively folded so as to bring the widely separated photocleavage and photolabeling sites together within a single catalytic unit.     

Conformational changes of the beta chain of the outer-arm dynein from sea urchin sperm flagella coupled with ATP hydrolysis

Conformational changes of the beta chain of the outer-arm dynein from sea urchin sperm flagella in relation to ATP hydrolysis was examined by tryptic digestion. Tryptic digestion of the beta chain in the presence of 2 mM ATP (ADP) and 100 microM vanadate (Vi) or in the presence of 4 mM ATP gamma S produced different polypeptides from in the case of no addition. The difference was similar to the result previously reported for 21S outer-arm dynein heavy chains [Inaba, K. & Mohri, H. (1989) J. Biol. Chem. 264, 8384-8388]. Unlike the tryptic digestion pattern of 21S dynein heavy chains, however, the 135-kDa polypeptide was consistently produced from the beta chain, even in the presence of ATP (ADP) and Vi. The tryptic digestion pattern of the 21S particle reconstituted from the separated a chain, the beta/IC1 complex and the IC2/IC3 complex [Tang, W.-J.Y., Bell, C.W., Sale, W.S., & Gibbons, I.R. (1982) J. Biol. Chem. 257, 508-515] was similar to that of intact 21S dynein; the 135-kDa polypeptide was only slightly produced in the presence of ATP and Vi. The digestion rate constant of the 135-kDa polypeptide from the beta chain in the presence of ATP and Vi was significantly decreased as compared with in the case of 21S dynein or that of the reconstituted 21S particle. These results suggest that the trypsin sensitivity of the 135-kDa region of the beta chain changes with the association of the beta/ICI complex with the alpha chain and the IC2/IC3 complex in the presence of ATP and Vi.     

Proteolytic analysis of domain structure in the beta heavy chain of dynein from sea urchin sperm flagella.

The stability of different regions of the beta heavy chain of dynein has been investigated by examining the perturbing effects of methanol, temperature, salt, and nucleotide on the pattern of tryptic digestion. In standard low-salt medium, tryptic proteolysis cleaves the beta heavy chain into three principal polypeptides of 130, 215, and 110 kDa, with the 215-kDa central peptide containing the ATP binding site as well as the vanadate and iron photocleavage sites (Mocz, G., Tang, W.-J. Y., & Gibbons, I. R. (1988) J. Cell Biol. 106, 1607-1614). The 130-kDa peptide is the most stable, and its susceptibility to trypsin appears unaffected by methanol concentrations up to 25% or temperatures up to 45 degrees C, although a 5-kDa region at one end is lost in the presence of salt (greater than 20 mM NaCl). The 215-kDa tryptic peptide contains two regions of different stability: its 123-kDa portion adjoining the 130-kDa peptide is destabilized by mild heat (37 degrees C) or by 25% methanol and becomes digested away to leave the more stable region of 92 kDa that is located toward the 110-kDa peptide and retains the V1 photocleavage site and most of the ATP binding site. The 110-kDa peptide is the least stable and at 37 degrees C, or in the presence of low concentrations of methanol or salt, it rapidly digested to small peptides. The presence of ATP during digestion of the beta heavy chain retards the formation of the 130- and 215-kDa peptides and also protects the 215-kDa peptide from further digestion at 37 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure of the alpha and beta heavy chains of the outer arm dynein from Chlamydomonas flagella. Masses of chains and sites of ultraviolet-induced vanadate-dependent cleavage

We report here on the UV-induced vanadate-dependent cleavage of the alpha and beta heavy chains of the outer arm dynein from Chlamydomonas flagella. Both polypeptides are cleaved at a single site (termed the V1 site) by UV irradiation in the presence of Mg2+, ATP, and vanadate. The alpha chain yields fragments of Mr 290,000 and 190,000. Fragments of Mr 255,000 and 185,000 are obtained from the beta chain. Ultraviolet irradiation of the alpha and beta chains in the presence of vanadate and Mn2+ (but no nucleotide) induces cleavage of both molecules at sites (termed the V2 sites) distinct from the V1 sites. The single V2 site within the beta chain is located 75,000 daltons from the site of V1 cleavage within the Mr 255,000 V1 fragment. The alpha chain contains three distinct sites of V2 cleavage; all are located within the Mr 290,000 V1 fragment, 60,000, 90,000, and 100,000 daltons from the site of V1 cleavage. From these studies, we estimate the masses of the alpha and beta heavy chains to be 480,000 and 440,000 daltons, respectively.     

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.     

Effects of proteolysis on the adenosinetriphosphatase activities of thymus myosin

Limited proteolysis was used to identify regions on the heavy chains of calf thymus myosin which may be involved in ATP and actin binding. Assignments of the various proteolytic fragments to different parts of the myosin heavy chain were based on solubility, gel filtration, electron microscopy, and binding of 32P-labeled regulatory light chains. Chymotrypsin rapidly cleaved within the head of thymus myosin to give a 70,000-dalton N-terminal fragment and a 140,000-dalton C-terminal fragment. These two fragments did not dissociate under nondenaturing conditions. Cleavage within the myosin tail to give heavy meromyosin occurred more slowly. Cleavage at the site 70,000 daltons from the N-terminus of the heavy chain caused about a 30-fold decrease in the actin concentration required to achieve half-maximal stimulation of the magnesium-adenosinetriphosphatase (Mg-ATPase) activity of unphosphorylated thymus myosin. The actin-activated ATPase activity of this digested myosin was only slightly affected by light chain phosphorylation. Actin inhibited the cleavage at this site by chymotrypsin. In the presence of ATP, chymotrypsin rapidly cleaved the thymus myosin heavy chain at an additional site about 4000 daltons from the N-terminus. Cleavage at this site caused a 2-fold increase in the ethylenediaminetetraacetic acid-ATPase activity and 3-fold decreases in the Ca2+- and Mg-ATPase activities of thymus myosin. Thus, cleavage at the N-terminus of thymus myosin was affected by ATP, and this cleavage altered ATPase activity. Papain cleaved the thymus myosin heavy chain about 94,000 daltons from the N-terminus to give subfragment 1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Outer-arm dynein from trout spermatozoa: substructural organization.

Outer-arm dynein purified from trout spermatozoa was disrupted by low-ionic-strength dialysis, and the resulting subunits were separated by sucrose density-gradient centrifugation. The intact 19 S dynein, containing the alpha- an beta-heavy chains, intermediate chains (ICs) 1-5 and light chains (LCs) 1-6, yielded several discrete particles: a 17.5 S adenosine triphosphatase (ATPase) composed of the alpha- and beta-chains ICs 3-5 and LC 1; a 9.5 S complex containing ICs 1 and 2 together with LCs 2, 3, 4, and 6; and a single light chain (LC 5), which sedimented at approximately 4 S. In some experiments, ICs 3-5 also separated from the heavy chain complex and were obtained as a distinct subunit. Further dissociation of the 17.5 S particle yielded a 13.1 S ATPase that contained the beta-heavy chain and ICs 3-5. The polypeptide compositions of the complexes provide new information on the intermolecular associations that occur within dynein. Substructural features of the trout dynein polypeptides also were examined. The heavy chains were subjected to vanadate-mediated photolysis at the V1 sites by irradiation at 365 nm in the presence of Mg2+, ATP, and vanadate. Fragment pairs of relative molecular mass (Mr) 245,000/185,000 and 245,000/170,000 were obtained from the alpha- and beta-heavy chains, respectively. Photolysis of these molecules at their V2 sites, by irradiation in the presence of vanadate and Mn2+, yielded fragments of Mr 160,000/270,000 and 165,000/250,000, respectively. These values confirm that the alpha- and beta-heavy chains have masses of 430,000 and 415,000 daltons, respectively. Immunological analysis using monoclonal antibodies revealed that one intermediate chain from trout dynein (IC 2) contains epitopes present in two different intermediate chains from Chlamydomonas dynein. This indicates that specific sequences within the dynein intermediate chains have been highly conserved throughout evolution.     

Structure of the gamma heavy chain of the outer arm dynein from Chlamydomonas flagella

We describe here the vanadate-dependent photocleavage of the gamma heavy chain from the Chlamydomonas outer arm dynein and the pathways by which this molecule is degraded by endoproteases. UV irradiation in the presence of ATP, Mg2+, and vanadate cleaves the gamma chain at a single site (termed V1) to yield fragments of Mr 235,000 and 180,000. Irradiation in the presence of vanadate and Mn2+ results in cleavage of the gamma chain at two other sites (termed V2a and V2b) to yield fragment pairs of Mr 215,000/200,000 and 250,000/165,000. The mass of the intact chain is therefore estimated to be 415,000 D. We have located the major tryptic and staphylococcal protease cleavage sites in the gamma chain, determined the origins of the resulting fragments, and identified the regions which contain the epitopes recognized by two different monoclonal antibodies. Both antibodies react with the smaller V1 fragment; the epitope recognized by antibody 25-8 is within 9,000-52,000 D of the original gamma-chain terminus contained in that fragment, whereas that recognized by antibody 12 gamma B is within 16,000 D of the V1 site. The data permit the construction of a linear map showing the structural organization of the polypeptide. The substructure of the gamma chain is similar to that of the alpha and beta chains of the outer arm dynein with regard to polarity as defined by the sites of vanadate-dependent photocleavage, and to that of the beta chain with regard to a highly sensitive protease site located approximately 10,000 D from the original terminus contained in the smaller V1 fragment.     

Conformational changes of dynein: mapping and sequence analysis of ATP/Vanadate-dependent trypsin-sensitive sites on the outer arm dynein b heavy chain from sea urchin sperm flagella

Conformational changes of dynein during ATP hydrolysis are demonstrated by the difference in the tryptic fragments of the dynein heavy chain between in the absence and presence of ATP and vanadate. Here tryptic sites in the presence of ATP and vanadate (Tav sites) have been mapped on the betaheavy chain of outer arm dynein from sea urchin sperm flagella. Tav sites are located not only near the central catalytic domain which includes four P-loops, but also near the carboxyl-terminal coiled-coil region. The Tav2 site is located in the most carboxyl-terminal region, which is nearly 850 amino acid residues apart from the the fourth P-loop (P4 site). The region from the most amino-terminal Tav site (Tav1 site) to the Tav2 site covers approximately 2,100 amino acid residues, which is almost half the whole betaheavy chain. Comparison of the sequences around the tryptic sites of the sea urchin b chain and those of the dynein heavy chains from other organisms reveals that the sequence around the Tav1 site is highly conserved in both cytoplasmic and axonemal dyneins but that around Tav2 sites is only conserved in axonemal dyneins, suggesting functional differences in the Tav2 region between the two subfamilies of dynein.     

Photochemical probes of the active site of myosin. Irradiation of trapped 3'-O-(4-benzoyl)benzoyladenosine 5'-triphosphate labels the 50-kilodalton heavy chain tryptic peptide

3'-O-(4-Benzoyl)benzoyl-ATP (Bz2ATP), an analog of ATP containing a photoreactive benzophenone moiety, was used as a probe of the ATP binding site of myosin subfragment 1 (SF1). The inactivation of SF1 NH+4-EDTA ATPase by the bifunctional thiol crosslinking system cobalt(II)/cobalt(III) phenanthroline complexes was enhanced by Bz2ATP to the same degree as by ATP. This treatment resulted in the stable trapping of Bz2ATP at the active site in nearly stoichiometric amounts in a manner exactly analogous to ATP (Wells, J.A., and Yount, R.G. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 4966-4970). Irradiation of SF1 containing trapped [3H]Bz2ATP gave approximately 50% covalent incorporation of the trapped nucleotide into the enzyme. Analysis of photolabeled SF1 by gel electrophoresis showed that all of the [3H]Bz2ATP was attached to the 95-kDa heavy chain fragment. No label was found in the light chains. Similar analysis of the same protein after limited trypsin treatment demonstrated that approximately 75% of the [3H]Bz2ATP was bound to the central 50-kDa peptide and its 75-kDa precursor from the heavy chain. The N-terminal 25-kDa tryptic peptide, shown to be photolabeled by other ATP analogs (Szilagyi, L., Balint, M., Sreter, F.A., and Gergely, J. (1979) Biochem. Biophys. Res. Commun. 87, 936-945; Okamoto, Y., and Yount, R.G. (1983) Biophys. J. 41, 298a), was not labeled (less than 1%) by Bz2ATP. These results demonstrate that portions of the 50 kDa-peptide of the heavy chain are within 6-7 A of the ATP binding site on SF1 and possibly contribute to nucleotide binding.     

Dynein isoforms in sea urchin eggs

Biochemical and immunological analysis of unfertilized sea urchin eggs has revealed the presence of at least two distinct isoforms of cytoplasmic dyneins, one soluble and the other microtubule-associated. The soluble enzyme is a 20 S particle with a MgATPase activity that can be activated 5-fold by nonionic detergents. It contains heavy chain polypeptides that 1) comigrate with the dynein heavy chains of embryonic cilia; 2) cross-react with antibodies against flagellar dynein; and 3) are cleaved by UV irradiation in the presence of MgATP and sodium vanadate into specific peptide fragments. The soluble egg dynein is, therefore, closely related to axonemal dynein and may be a ciliary precursor. Egg microtubule preparations contain a distinct dynein-like polypeptide, previously designated HMr-3 (Scholey, J.M., Neighbors, B., McIntosh, J.R., and Salmon, E.D. (1984) J. Biol Chem. 259, 6516-6525). HMr-3 binds microtubules in an ATP-sensitive fashion; it sediments at 20 S on sucrose density gradients, and it is susceptible to vanadate-sensitized UV cleavage. However, HMr-3 can be distinguished from the soluble cytoplasmic dynein on the basis of its weak cross-reactivity with antiflagellar dynein antibodies, its heavy chain composition on high resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis, its low specific ATPase activity, and the molecular weight of its vanadate-induced UV cleavage fragments. HMr-3 may represent a dynein-like polypeptide that is distinct from the pool of ciliary dynein precursors.     

Regulation of monomeric dynein activity by ATP and ADP concentrations.

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

A Chlamydomonas outer arm dynein mutant missing the alpha heavy chain

A novel Chlamydomonas flagellar mutant (oda-11) missing the alpha heavy chain of outer arm dynein but retaining the beta and gamma heavy chains was isolated. Restriction fragment length polymorphism analysis with an alpha heavy chain locus genomic probe indicated that the oda-11 mutation was genetically linked with the structural gene of the alpha heavy chain. In cross-section electron micrographs, the oda-11 axoneme lacked the outermost appendage of the outer arm, indicating that the alpha heavy chain should be located in this region in the wild-type outer arm. This mutant swam at 119 microns/s at 25 degrees C, i.e., at an intermediate speed between those of wild type (194 microns/s) and of oda-1 (62 microns/s), a mutant missing the entire outer dynein arm. The flagellar beat frequency (approximately 50 Hz) was also between those of wild type (approximately 60 Hz) and oda-1 (approximately 26 Hz). These results indicate that the outer dynein arm of Chlamydomonas can be assembled without the alpha heavy chain, and that the outer arm missing the alpha heavy chain retains partial function.     

Homology of egg and flagellar dynein. Comparison of ATP-binding sites and primary structure

Unfertilized sea urchin eggs contain a Mg2+-ATPase which shares physical and enzymatic characteristics with dynein, the enzyme which powers ciliary and flagellar movement. To further investigate the homology of the egg ATPase and axonemal dynein, ATP-binding subunits in preparations of each of the enzymes were identified using a photoaffinity probe of ATP, 8-azido-ATP (8-N3ATP), and three high molecular weight (HMW) polypeptide components of the two enzymes were compared by one-dimensional peptide mapping. Two heavy chains (A and B) of both the flagellar and egg ATPases bound [alpha-32P]8-N3ATP. The labeling of the HMW bands was specifically inhibited by ATP or ADP. Both the cytoplasmic ATPase and flagellar dynein utilized 8-N3ATP as a substrate indicating that the reagent binds to the active site. The two HMW ATP-binding polypeptides and one other HMW component of the egg ATPase were compared to flagellar dynein heavy chains by peptide mapping. Digestion of the egg versus flagellar HMW polypeptides with Staphylococcus V8 protease or alpha-chymotrypsin produced a highly similar group of peptides, and each pair of heavy chains was qualitatively estimated to be over 85% homologous. These data support the identification of the egg ATPase heavy chains as components of a cytoplasmic dynein and suggest that the HMW polypeptides form active enzymatic sites in flagellar and egg dynein which are substantially homologous.     

Cytoplasmic dynein ATPase activity is regulated by dynactin-dependent phosphorylation

Cytoplasmic dynein is a microtubule-associated motor that utilizes ATP hydrolysis to conduct minus-end directed transport of various organelles. Dynactin is a multisubunit complex that has been proposed to both link dynein with cargo and activate dynein motor function. The mechanisms by which dynactin regulates dynein activity are not clear. In this study, we examine the role of dynactin in regulating dynein ATPase activity. We show that dynein-microtubule binding and ATP-dependent release of dynein from microtubules are reduced in dynactin null mutants, Deltaro-3 (p150(Glued)) and Deltaro-4 (Arp1), relative to wild-type. The dynein-microtubule binding activity, but not the ATP-dependent release of dynein from microtubules, is restored by in vitro mixing of extracts from dynein and dynactin mutants. Dynein produced in a Deltaro-3 mutant has approximately 8-fold reduced ATPase activity relative to dynein isolated from wild-type. However, dynein ATPase activity from wild-type is not reduced when dynactin is separated from dynein, suggesting that dynein produced in a dynactin mutant is inactivated. Treatment of dynein isolated from the Deltaro-3 mutant with lambda protein phosphatase restores the ATPase activity to near wild-type levels. The reduced dynein ATPase activity observed in dynactin null mutants is mainly due to altered affinity for ATP. Radiolabeling experiments revealed that low molecular mass proteins, particularly 20- and 8-kDa proteins, that immunoprecipitate with dynein heavy chain are hyperphosphorylated in the dynactin mutant and dephosphorylated upon lambda protein phosphatase treatment. The results suggest that cytoplasmic dynein ATPase activity is regulated by dynactin-dependent phosphorylation of dynein light chains.