Inner arm dynein ATPase fraction of sea urchin sperm flagella causes active sliding of axonemal outer doublet microtubule.

In order to clarify the role of the inner arms of the axoneme in sperm flagellar movement, we prepared an ATPase fraction (12S) from the outer arm-depleted axonemes of sea urchin sperm flagella. When both arm-depleted axonemes were incubated with the 12S ATPase, they exhibited the sliding disintegration of outer doublet microtubules. Electron microscopy revealed that the ATPase rebound to the original inner arm sites of the axoneme. Therefore, it is quite likely that the 12S ATPase is one of the components of the inner arms. We referred to it as "inner arm dynein".     

Polypeptide subunits of dynein 1 from sea urchin sperm flagella

A high-resolution sodium dodecyl sulfate polyacrylamide gel electrophoresis system has been used to show the presence, in both whole sperm and isolated flagellar axonemes, of eight polypeptides migrating in the 300,000–350,000 molecular weight range characteristic of the heavy chains of dynein ATPase. Previously, only five such chains have been discernible. Extraction of isolated axonemes for 10 min at 4°C with a solution containing 0.6 M NaCl, pH 7, releases a mixture of particles that separate, in sucrose density gradient centrifugation, into a major peak, dynein 1 ATPase, sedimenting at 21 S and a minor peak at 12–14S. The polypeptide compositions of these two peaks are different. The dynein 1 peak, which contains most of the protein on the gradient, contains approximately equal quantities of two closely migrating heavy chains, with a small amount of a third, more slowly migrating chain; no other heavy chains appear in this peak. Two groups of smaller polypeptides (three intermediate chains, within the apparent molecular weight range 76,000–122,000 and four newly discovered light chains, within the apparent molecular weight range 14,000–24,000) cosediment with the 21 S peak. The heavy chain composition of the 12–14S peak is more complex, all eight heavy chains occurring in approximately the same ratios as occur in intact axonemes.     

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

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

Some properties of bound and soluble dynein from sea urchin sperm flagella

Axonemes were isolated from sperm of Colobocentrotus by a procedure involving two extractions with 1% Triton X-100 and washing The isolated axonemes contained 7 x 10¹⁵ g protein per µm of their length. Treatment of the axonemes with 0 5 M KCl for 30 min extracted 50–70% of the flagellar ATPase protein, dynein, and removed preferentially the outer arms from the doublet tubules. Almost all of the dynein (85–95%) could be extracted from the axonemes by dialysis at low ionic strength. In both cases the extracted dynein sedimented through sucrose gradients at 12–14S, and no 30S form was observed The enzymic properties of dynein changed when it was extracted from the axonemes into solution. Solubilization had a particularly marked effect on the KCl- and pH-dependence of the ATPase activity. The pH-dependence of soluble dynein was fairly simple with a single peak extending from about pH 6 to pH 10. The pH-dependence of bound dynein was more complex. In 0.1 M KCl, the bound activity appeared to peak at about pH 9, and dropped off rapidly with decreasing pH, reaching almost zero at pH 7; an additional peak at pH 10 0 resulted from the breakdown of the axonemal structure and solubilization of dynein that occurred at about this pH. A similar curve was obtained in the absence of KCl, except for the presence of a further large peak at pH 8 Measurement of the kinetic parameters of soluble dynein showed that both K_m and V_max increased with increasing concentrations of KCl up to 0.5 M When bound dynein was assayed under conditions that would induce motility in reactivated sperm (0 15 M KCl with Mg⁺⁺ activation), it did not obey Michaelis-Menten kinetics, although it did when assayed under other conditions. The complex enzyme-kinetic behavior of bound dynein, and the differences between its enzymic properties and those of soluble dynein, may result from its interactions with tubulin and other axonemal proteins     

Two heavy chains of 21S dynein from sea urchin sperm flagella

The biochemical properties of 21S dynein derived from sea urchin sperm flagella and of its components dissociated by low salt treatment were studied. SDS-urea gel electrophoresis and two-dimensional gel electrophoresis showed that the 21S dynein preparation contains two distinct heavy chains. These two heavy chains, termed A alpha and A beta, had apparently the same molecular weight of 500,000 but showed different mobilities on SDS-urea gels. The isoelectric points of A alpha and A beta heavy chains were 5.7 and 5.2, respectively, in the presence of urea. Proteolytic digestion patterns of these two heavy chains were clearly different, but the amino acid compositions were similar. Low salt treatment and sucrose density gradient centrifugation could partially separate the components of 21S dynein into two fractions: the one with larger sedimentation coefficient contained the A alpha heavy chain, and the other with smaller sedimentation coefficient contained the A beta heavy chain and three intermediate chains. These two fractions showed distinctly different kinetic properties, and thus may play different roles in dynein-microtubule interaction.     

Kinetic analysis of axoneme and dynein ATPase from sea urchin sperm

The behavior of the ATPase of axoneme (detergent-treated flagellum) and dynein from sea urchin sperm was investigated. The activation of the ATPase by divalent cations was attributed to formation of a complex of ATP and the divalent cation; the metal-ATP complex is an effective substrate. However, free ATP is a modifier of the ATPase. Free ATP markedly changes the affinity of the metal-ATP complex to the enzymes. Calcium-activated ATPase activity of axoneme decreased at high concentration of CaCl₂, but that of dynein did not decrease.     

Properties of an antiserum against native dynein 1 from sea urchin sperm flagella

Effects of an antiserum against native dynein 1 from sperm flagella of the sea urchin Strongylocentrotus purpuratus were compared with effects of an antiserum previously obtained against an ATPase-active tryptic fragment (fragment 1A) of dynein 1 from sperm flagella of the sea urchin, Anthocidaris crassispina. Both antisera precipitate dynein 1 and do not precipitate dynein 2. Only the fragment 1A antiserum precipitates fragment 1A and produces a measurable inhibition of dynein 1 ATPase activity. Both antisera inhibit the movement and the movement-coupled ATP dephosphorylation of reactivated spermatozoa. The inhibition of movement by the antiserum against dynein 1 is much less than by the antiserum against fragment 1A, suggesting that a specific interference with the active ATPase site may be required for effective inhibition of movement. Both antisera reduce the bend angle as well as the beat frequency of reactivated S. purpuratus spermatozoa, suggesting that the bend angle may depend on the activity of the dynein arms which generate active sliding.     

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.     

Conformational change in the outer doublet microtubules from sea urchin sperm flagella

Dark-field microscopy with a high-powered light source revealed that the outer doublet microtubules (DMTs) from sea urchin (Pseudocentrotus depressus and Hemicentrotus pulcherrimus) sperm flagella assume helically coiled configurations (Miki-Noumura, T., and R. Kamiya. 1976. Exp. Cell Res. 97: 451.). We report here that the DMTs change shape when the pH or Ca-ion concentration is changed. The DMTs assumed a left-handed helical shape with a diameter of 3.7 +/- 0.5 micron and a pitch of 2.8 +/- 0.7 micron at pH 7.4 in the presence of 0.1 mM CaCl2, 1 mM MgSO4, and 10 mM Tris-HCl. When the pH was raised to 8.3, the helical diameter and pitch decreased to 2.1 +/- 0.1 micron and 1.3 +/- 0.3 micron, respectively. This transformation was a rapid and reversible process and was completed within 1 min. Between pH 7.2 and 8.3, the DMTs assumed intermediate shapes. When the Ca-ion concentration was depleted with EGTA, the helical structure became significantly larger in both pitch and diameter. For instance, the diameter was 3.8 +/- 0.4 micron at pH 8.3 in the presence of 1 mM EGTA and 2 mM MgSO4. Using a Ca-buffer system, we obtained results which suggested that this Ca-induced transformation took place at a Ca concentration of approximately 10(-7) M. These results were highly reproducible. The conformational changes in the DMT may play some role in the bending wave form of flagellar movement.     

A latent adenosine triphosphatase form of dynein 1 from sea urchin sperm flagella.

Treatment of demembranated sea urchin sperm axonemes with an extraction solution containing 0.6 M NaCl, pH 7.0 for 10 min at 4 degrees C yields a solution of dynein 1 having a low, latent specific ATPase activity of about 0.25 mumol of Pi mg(-1) min(-1). Exposure of this dynein solution to 0.1% Triton-X-100 for 10 min at 25 degrees C causes an increase in its ATPase activity to about 3 mumol of Pi mg(-1) min(-1). A similar activation can be obtained by treating at 42 degrees C or by reacting with 60 mol of p-chloromercuribenzene sulfonate/10(6) g of protein. The effects of these activating procedures are not additive, suggesting that they lead to a common activated state. Purification of the latent activity dynein 1 by sucrose density gradient centrifugation yields a monodisperse preparation sedimenting at 21 S, and having a molecular weight of 1,250,000 as determined by sedimentation diffusion and sedimentation equilibrium. Activation of the latent dynein 1 with Triton X-100 converts it to a form sedimenting at 10 to 14 S. The 21 S dynein is also converted to a 10 S form by dialysis against 5 mM imidazole/NaOH buffer, 0.1 mM EDTA, 5 mM 2-mercaptoethanol, pH 7, although in this case, the ATPase activity is increased only about 3-fold, with another 3-fold activation being obtainable upon subsequent treatment with Triton X-100. The 21 S latent form of dynein 1 may represent the intact dynein arms that form moving cross-bridges and generate active sliding between adjacent doublet tubules of the flagellar axoneme. Electrophoretic analysis on polyacrylamide gels in the presence of sodium dodecyl sulfate suggests a model in which the 21 S dynein 1 particle is composed of three subunits of about 330,000 daltons and one of each of three medium weight subunits of 126,000, 95,000, and 77,000 daltons. When latent dynein 1 is added back to NaCl-extracted axonemes in the presence of 0.15 M NaCl, it recombines stoichiometrically and restores the arms on the doublet tubules with a 6-fold activation of its ATPase activity measured in the absence of KCl.     

Bending patterns of ATP-reactivated sea urchin sperm flagella following high salt extraction for removal of outer dynein arms

Two procedures were used for extraction of demembranated sea urchin sperm flagella with increased KCl concentrations, to remove outer dynein arms. Extraction with 0.55 M KCl in the Triton-demembranation solution produced a rapid fall in average sliding velocity to 50% of its unextracted value, with extensive changes in bending behavior of the distal half of the flagellum. Extraction with 0.42 M KCl following demembranation and activation by incubation with cAMP produced a more gradual fall in sliding velocity, reaching 50% of the unextracted value after 180 sec extraction. This procedure produced somewhat more normal bending patterns. In both cases, the bending pattern of the basal region of the flagellum is altered very little by extraction, in agreement with data from Chlamydomonas mutant flagella deficient in outer arm dyneins.     

Inhibition of axoneme and dynein ATPase from sea urchin sperm by free ATP

Sea urchin sperm flagellar ATPase (EC 3.6.1.3) has magnesium-ATP as an effective substrate and is inhibited by free ATP. The inhibition is prevented by high concentration of KCl or NaCl. 0.4 M KCl extracts 48% of ATPase activity from axoneme. The 0.4 M KCl extract and 0.4 M KCl-treated axoneme are also inhibited by free ATP and this inhibition is reversed by KCl. Dynein purified twice by sucrose density gradient centrifugation is alsof inhibited by free ATP; this inhibition is also reversed by KCl.     

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.     

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

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

Movement of sea urchin sperm flagella

The motion of the sea urchin sperm flagellum was analyzed from high-speed cinemicrographs. At all locations on the flagellum the transversal motion and the curvature were found to vary sinusoidally in time. The curvatures of the flagella increase strongly near the proximal junction. Two sperm are described in transient from rest to normal motion. The full wave motion developed in both sperm within 40 ms.     

Inhibition of axoneme and dynein ATPase from sea urchin sperm by free ATP.

Sea urchin sperm flagellar ATPase (EC 3.6.1.3) has magnesium-ATP as an effective substrate and is inhibited by free ATP. The inhibition is prevented by high concentration of KCl or NaCl. 0.4 M KCl extracts 48% of ATPase activity from axoneme. The 0.4 M KCl extract and 0.4 M KCl-treated axoneme are also inhibited by free ATP and this inhibition is reversed by KCl. Dynein purified twice by sucrose density gradient centrifugation is also inhibited by free ATP; this inhibition is also reversed by KCl.     

Activation of sea urchin sperm flagellar dynein ATPase activity by salt-extracted axonemes

When 21S dynein ATPase [EC 3.6.1.3] from sea urchin sperm flagellar axonemes was mixed with the salt-extracted axonemes, the ATPase activity was much higher than the sum of ATPase activities in the two fractions, as reported previously (Gibbons, I.R. & Fronk, E. (1979) J. Biol. Chem. 254, 187-196). This high ATPase level was for the first time demonstrated to be due to the activation of the 21S dynein ATPase activity by the axonemes. The mode of the activation was studied to get an insight into the mechanism of dynein-microtubule interaction. The salt-extracted axonemes caused a 7- to 8-fold activation of the 21S dynein ATPase activity at an axoneme : dynein weight ratio of about 14 : 1. The activation was maximal at a low ionic strength (no KCl) at pH 7.9-8.3. Under these conditions, 21S dynein rebound to the salt-extracted axonemes. The maximal binding ratio of 21S dynein to the axonemes was the same as that observed in the maximal activation of 21S dynein ATPase. The sliding between the outer doublet microtubules in the trypsin-treated 21S dynein-rebound axonemes took place upon the addition of 0.05-0.1 mM ATP in the absence of KCl. During the sliding, the rate of ATP hydrolysis was at the same level as that of the 21S dynein activated by the salt-extracted axonemes. However, it decreased to the level of 21S dynein alone after the sliding. These results suggested that an interaction of the axoneme-rebound 21S dynein with B-subfibers of the adjacent outer doublet microtubules in the axoneme causes the activation of the ATPase activity.     

Structure of the dynein-1 outer arm in sea urchin sperm flagella. II. Analysis by proteolytic cleavage

The structure of the 21 S latent activity dynein-1 (LAD-1) particle has been investigated by limited proteolytic cleavage with trypsin and with chymotrypsin. The A alpha and A beta heavy polypeptide chains show different characteristic digestion patterns which remain essentially unchanged whether the chains are components of the 21 S LAD-1 particle or are in the form of separated fractions, although changes in their relative digestion rates upon separation suggest that the A beta chain in the 21 S particle is partially protected from digestion by the presence of the A alpha chain and intermediate chains 2 and 3. The progressive digestion of the A chains and intermediate chains causes an eventual dissociation of the 21 S particle to smaller particles sedimenting in the range 10 to 14 S. Within this broad peak, the fragments from the A alpha chain peak in the 10 to 12 S region, while those from the A beta chain peak in the 12 to 14 S region. Digestion of whole axonemes to a stage at which the A alpha chain is substantially digested but the A beta chain remains mostly intact, enables a large amount of 21 S dynein-1 to be solubilized by 3 mM MgATP2(-) in the presence of 0.1 M NaCl, pH 7.0. This indicates that the affinity of the 0.6 M NaCl-sensitive bond of the outer arm to the A-tubule is diminished substantially by the early stages of digestion of the A alpha chain.     

Calcium sensors in sea urchin sperm flagella

The asymmetry of ATP-reactivated flagellar bending waves of Triton-demembrated sea urchin spermatozoa has been measured over a range of free Ca2+ ion concentrations from 10(-9) to 10(-4) M. Detailed examination of the gradual response of asymmetry to Ca2+ ion concentration over this wide range indicates the presence of two Ca2+ sensors. A high-affinity sensor operates at Ca2+ concentrations near 10(-7.5) M. A lower-affinity sensor operates at Ca2+ concentrations above 10(-6) M, in the typical range for calmodulin-mediated responses. Incubation of demembranated sperm flagella at high Ca2+ concentrations to release calmodulin is required to enable these Ca2+ responses to be observed. This treatment also causes a decrease in the apparent affinity of the flagella for calmodulin, as determined by measuring the increase in asymmetry in response to addition of exogenous calmodulin at low Ca2+ concentration.