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.

Bending motion of Chlamydomonas axonemes after extrusion of central-pair microtubules.

Relatively little is known about the functions of central-pair microtubules (Tamm, S. L., and G. A. Horridge, 1970, Proc. Roy. Soc. Lond. B, 175: 219-233; Omoto, C. K., and C. Kung, 1979, Nature (Lond.). 279:532-534) and radial spokes (Warner, F. D., and P. Satir, 1974, J. Cell Biol., 63:35-63), although a sliding microtubule mechanism has been established for the flagellar movement (Summers, K. E., and I. R. Gibbons, 1971, Proc. Natl. Acad. Sci. USA., 68:3092-3096). In the present report, an attempt was made to determine the functions of central-pair microtubules in flagellar motility. Central-pair microtubules were found to extrude from the tips of elastase-digested axonemes of demembranated Chlamydomonas flagella after the addition of ATP. The length of the extruded central-pair microtubules was approximately 70-100% that of the axoneme. After extrusion, axonemes continued to swim slowly backwards in the reactivation medium, with a trailing central pair attached like a tail to the flagellar tip. During bending movement of the axonemes, partially extruded central pairs rotated counterclockwise about the axoneme axis, as viewed from the distal end (Kamiya, R., 1982, Cell Motil. [Suppl.]:169-173). Axonemes swam backwards with a symmetric waveform and a beat frequency of approximately 10 Hz in the reactivation medium containing 10(-9)-10(-4) M Ca ions. Even at a lower Ca++ concentration, no ciliary-type swimming was noted on the axonemes.

ATPase sites in two-headed fragment of Tetrahymena 22S ciliary dynein.

Three-headed Tetrahymena 22S ciliary dynein was found to consist of three heavy chains (HCs) and decompose into two-headed and single-headed fragments upon chymotrypsin digestion. The three HCs (A alpha, A beta, and A gamma) were immunologically different, and presumed to be located on each of the head regions. The two-headed fragment contained A beta and A gamma HCs, while the A alpha HC originated in the single-headed fragment. Both fragments were associated with ATPase activity (Toyoshima, Y. (1987a) J. Cell Biol. 105, 887-895 and Toyoshima, Y. (1987b) J. Cell Biol. 105, 897-901). Using the two-headed dynein fragment, we attempted to determine the site of ATP hydrolysis in the fragment. After digestion of the fragment with 100 micrograms/ml thermolysin for 45 min, we noted eight thermolysin-digested polypeptides (TH 1, 2, 3, 4, 5 alpha, 5 beta, 6 alpha, and 6 beta). By precisely analyzing the degradation process and the products using peptide mapping, immunoblotting and high pressure liquid chromatography, it appeared that the two-headed fragment is dissociated as two separate fragments, each of which contained A beta or A gamma HC. Thermolysin digests, TH 1, 2, 5 alpha and 6 beta were found to be derived from A beta HC, while TH 3, 4, 5 beta and 6 alpha originated in the A gamma HC. Based on the measurements of ATPase activity of these polypeptides, we concluded that the ATPase site is located in the A beta and A gamma HCs, which may have their origins in each head of the two-headed fragment of Tetrahymena 22S ciliary dynein.

Flexural rigidity of singlet microtubules estimated from statistical analysis of their contour lengths and end-to-end distances.

Microtubules in solutions, observed under a dark-field microscope, show incessant Brownian movement such as translational, rotational and flexing motion. A large number of microtubules, spontaneously stuck to the under surface of a coverslip, were photographed and the contour lengths and end-to-end distances of their images were measured. From the statistical analysis of the contour lengths and end-to-end distances, a value for the parameter lambda representing the flexibility of singlet microtubules was estimated to be lambda = (6.8 +/- 0.8) . 10(-3) micrometers-1. From the value of lambda, the elastic modulus for bending, epsilon, and Young's modulus, Y, of singlet microtubules were computed to be epsilon = approximately 10(-16) and Y = approximately 10(9) dyne . cm-2, respectively. The microscopic elastic constant, k, of bonding between two tubulin monomers neighboring along the singlet microtubule was computed to be k = congruent to 10(2) dyne . cm-1. A singlet microtubule is an order of magnitude as strong against bending and as weak against stretching as an F-actin filament.

Stabilization of microtubules by dynein-binding in vitro. Stability of microtubule-dynein complex.

We have studied the effects of dynein binding on the stability of microtubules in vitro, using Tetrahymena ciliary dynein and microtubules (three-cycled purified microtubules: 3 X-Mts and phosphocellulose-column purified microtubules: PC-Mts). To determine the relative stability of the microtubules, we first prepared the microtubules bound with dynein (Mts--dynein complex) and subjected the Mts-dynein complex to treatments that depolymerize the microtubules, such as dilution to below critical concentration of tubulin, calcium ions and lower temperature. Dark-field microscopy revealed that the microtubules in the Mts--dynein complex appeared intact under conditions which otherwise result in microtubule depolymerization. However, when dynein was dissociated from the Mts--dynein complex with addition of ATP, no microtubule was found in the specimens under the same conditions. That is, the microtubules in the Mts--dynein complex did not depolymerize upon dilution with the buffer solution to below critical concentration of tubulin. However, addition of ATP to the diluted specimen caused dynein to become separated from the Mts, resulting in complete depolymerization of the microtubules. Stability of the microtubules was also studied by the turbidity changes and was confirmed by the patterns of stained gel bands in electrophoresis. With the addition of calcium ion, the Mts--dynein complex decomposed into separate molecules dynein and tubulin. At the lower temperature of 0 degrees C, the 3 X-Mts--dynein complex was decomposed into dynein and tubulin, while the microtubules in the PC-Mts--dynein complex did not depolymerize. Although we have not yet studied the effects of cytoplasmic dynein binding on the microtubules, the results suggest that the stabilizing effect of dynein binding to the microtubules is one of the important functions of dynein in vivo.

Studies on the de novo formation of centrioles: aster formation in the activated eggs of sea urchin.

Aster formation was studied in sea-urchin eggs artificially activated by Loeb's double method. The number of asters found in an activated egg ranged from 15-40. Observation by electron microscopy revealed the presence of a centriole in a high percentage of isolated asters, strongly suggesting that these centrioles are formed de novo in the activated eggs. Using negatively stained specimens, which were isolated with 5% hexylene glycol solution containing buffer and EGTA, the whole aster could be examined by electron microscopy. A microtubular framework in the aster, extending radially from the astral centre was observed. The effect of mitotic inhibitors on aster formation was found to be similar to that on cell division.

Recovery of sliding ability in arm-depleted flagellar axonemes after recombination with extracted dynein I.

We compared sliding velocity between outer doublet tubules in demembranated axonemes of sea-urchin (Pseudocentrotus depressus) sperm flagella with that of arm-depleted axonemes recombined with extracted dynein I. The outer arm-depleted axonemes after extraction with 0.5 M NaCl had a velocity of 6.9 +/- I.0 micrometer/s, while the intact axonemes had a velocity of 14.3 +/- I.5 micrometer/s in the presence of I mM ATP and 2 microgram/ml trypsin at 25 degrees C. The sliding velocity was closely related to the number of remaining outer arms following the NaCl-extraction process. When the outer arm-depleted axonemes were recombined with dynein I, the sliding velocity increased to 11.3 +/- 1.3 micrometer/s. Electron microscopy confirmed the recovery of 94% of outer arms in the axonemes. After extraction with Tris-EDTA solution for 10 min, the axonemes lost their sliding ability completely, even in the presence of ATP and trypsin. Such axonemes lacked most of both inner and outer arms, although sometimes the basal segment of the arms appeared to remain. When the exogenous dynein I fraction extracted from other axonemes was added, the axonemes could extrude tubules, and both types of arms reappeared clearly and distinctly in the axonemes. The recombined axonemes with one-fold stoichiometric excess of dynein I recovered 58% of the total number of arms and had a velocity of 7.4 +/- 1.6 micrometer/s. Those with 2-fold stoichiometric excess had a velocity of 11.0 +/- 1.5 micrometer/s, up to 82% of the arms in these axonemes being restored. These results indicated that the exogenous dynein I fraction derived from the outer arms restored sliding ability to arm-depleted axonemes, recombining with th outer doublet tubules as inner and outer arms, and that the sliding velocity had a close relationship to the total number of arms in the axonemes, irrespective of their being inner or outer arms.

Inhibition of gliding movement by calcium in doublet microtubules on Tetrahymena ciliary dyneins in vitro.

We examined the effects of Ca ions on the gliding movement of Tetrahymena ciliary doublet microtubules induced by 14S or 22S dyneins in an in vitro motility assay system. The doublet microtubule appeared as circular-arc in solution, about 5 to 6 microns in length [1]. The doublet microtubules glided distal-end first on a 14S or 22S dynein-coated glass surface either clockwise or counterclockwise following the addition of ATP. The diameter of the circular path changed according to Ca concentration in the solution. Gliding velocity was from 1 to 5 microns/s. The addition of 0.1% Nonidet P-40 was necessary to induce the gliding movement on 22S dynein. This movement on 22S dynein was strongly inhibited above 0.5 mM ATP in the presence of 10(-9) M Ca, and at 0.05 to 1 mM ATP in the presence of 10(-3) M Ca. Many studies have indicated that Ca ions regulate ciliary movement [2-8] in which dyneins and doublet microtubule in the axoneme may play an essential role. The inhibition of the gliding movement of doublet microtubule on dyneins at appropriate concentrations of Ca and ATP as observed in this study may be the key for understanding Ca regulation of ciliary motility.

ATP-induced sliding of microtubules on tracks of 22S dynein molecules aligned with the same polarity.

Chlamydomonas and Tetrahymena axonemal dyneins have previously been found to bind to porcine brain microtubules to produce a microtubule-dynein complex. At appropriate microtubule:dynein concentration, microtubules in the complex became covered to saturation by dynein arms of the same polarity and at a spacing of 24 nm [Haimo et al., 1979; Haimo and Fenton, 1988; Haimo, 1989; Porter and Johnson, 1983a]. In the present study, two different types of microtubule-dynein complexes (alpha- and beta-complexes) were prepared from Tetrahymena ciliary 22S dynein and porcine brain tubulin. The characteristics of the adenosine triphosphate (ATP)-induced extrusion of microtubules from these complexes were analyzed, as a simple and direct in vitro assay for the ATP-induced extrusion of singlet microtubules. The alpha-complex prepared by adding dynein to microtubules showed an interrupted sliding movement, which would stop and start several times following the addition of ATP. In the beta-complex, prepared by adding dynein bound to DEAE-tubulin to pre-assembled microtubules, microtubules became covered with dynein molecules whose orientation and binding were uniform with respect to microtubule polarity. The microtubules in the beta-complex extruded at 12 microns/second following the addition of ATP. Dark-field and electron microscopy indicated that the extruded microtubules had undergone sliding on a dynein-track that had become detached from the complexes and had been absorbed onto the surface of the glass slide. At higher light intensity under a dark-field microscope, the dynein-track was seen to be composed of rows of dynein molecules arranged densely. The orientation of dynein molecules in rows appeared to be uniform, considering the images of bound dynein in the beta-complex under electron microscope. The higher sliding velocity of the microtubules on these dynein-tracks compared to that seen on slides coated at random with dynein [Vale and Toyoshima, 1988, 1989], may be due to more efficient force generation by this dense arrangement of dynein molecules with the same polarity on the tracks.

Light-microscopic observations of individual microtubules reconstituted from brain tubulin.

The course of polymerization of individual brain microtubules could be observed with a light microscope employing dark-field illumination. Statistical analysis of the increase in microtubule length during the polymerization was in accordance with the time course of viscosity change of the tubulin solution. After a plateau level in viscosity was attained, there was no significant change in histograms showing length distribution. These observations were confirmed with fixed and stained microtubules, using a phase-contrast microscope. Observations with dark-field illumination revealed that reconstituted microtubules depolymerized and disappeared immediately upon exposure to buffer containing CaCl2 or sulphydryl reagents such as p-chloromercuriphenyl sulphonic acid (PCMPS) and p-chloromercuribenzoic acid (PCMB). They were also cold-labile. The growth of heterogeneous microtubules which were assembled by mixing purified tubulin dimers with ciliary outer fibres could also be followed with these optical systems.

Extrusion of rotating microtubules on the dynein-track from a microtubule-dynein gamma-complex.

Applying a new in vitro motility assay system for microtubules and 22S dynein, we recently reported on an ATP-induced extrusion of microtubules from microtubule-dynein alpha- and beta-complexes [Mimori and Miki-Noumura, 1994: Cell Motil. Cytoskeleton 27:180-191]. In the present study, we prepared a gamma-complex by copolymerizing porcine brain tubulin and Tetrahymena ciliary 22S dynein, and examined the ATP-induced microtubule movement from the gamma-complex. The extrusion process appeared quite similar to that of the beta-complex. The sliding velocity was 18.39 +/- 2.20 microns/sec, which was a value comparable to that of trypsin-digested flagellar axonemes [Yano and Miki-Noumura, 1980: J. Cell Sci. 44:169-186]. Higher velocity may be due to a densely arranged dynein-track with the same polarity, which was detached from the gamma-complex and absorbed in rows on a glass surface of the slide. Sometimes a free-floating microtubule in the perfusion chamber was observed riding and sliding on the dynein-track remaining on the slide after extrusion. Unexpectedly, we found that when the front part of the microtubule was fixed to a glass surface, a continuous sliding microtubule at the rear part on the dynein-track often transformed into a left-handed helix, and subsequently a twisted helix with several turns. The helix formation may be due to some rigidity in the microtubule and a right-handed torque component in the sliding force of 22S dynein. The addition of ATP may release some distortion accumulated in the complex structure during copolymerization of tubulin and 22S dynein, inducing reverse rotation of the microtubule.

Sliding velocity between outer doublet microtubules of sea-urchin sperm axonemes.

Using a dark-field microscope equipped with a high-efficiency TV camera including a video tape-recorder, we recorded the sliding movement between outer doublet microtubules of the demembranated axonemes of sea-urchin (Pseudocentrotus depressus and Hemicentrotus pulcherrimus) sperm flagella by adding ATP and trypsin at 25 degrees C. The time and length of the sliding doublet microtubules from axonemes were measured directly from the image on the picture monitor from the video tape. The sliding velocity was almost constant in the range from 0 to 2% polyethylene glycol concentration in the reactivation medium and decreased a little at more than 2%. We prepared various lengths of axoneme fragments by homogenizing whole axonemes and found that the shorter fragments showed similar sliding velocity to that of longer ones at less than 200 microM ATP, but slightly decreased speed at more than 500 microM. ATP. The sliding movement sometimes stopped and the percentage of sliding axonemes was lower below 2 micrograms/ml trypsin. Above 3 micrograms/ml, the process appeared to be more like disintegration than sliding movement, which may be due to excess digestion by trypsin. Sliding speed was therefore measured in a reactivation medium containing 2% polyethylene glycol with the addition of ATP and 2 micrograms/ml trypsin. The velocity increased in proportion to the increase in ATP concentration. Vmax was approximately 14 micrograms/s at 2 mM ATP. In order to compare the Km for the sliding velocity with that of the ATPase activity of the axonemes, we measured ATPase activity of axonemes prepared and assayed under conditions in which sliding movement in the axonemes could be induced. Neither the curve of ATPase activity nor the curve of sliding velocity plotted against ATP concentration obeyed Michaelis-Menten kinetics. The close relationship between ATPase activity and sliding velocity suggested that 'sliding-movement-coupled ATPase activity' may well be reflected in the axoneme ATPase reported here.

Regulatory role of nucleotides in axonemal function.

Axonemal sliding involves both sliding velocity and the extent of sliding, that is how many doublets slide. It is clear that axonemes cannot beat if all doublets were to slide simultaneously, thus sliding extent is important. Using the turbidimetric assay of sliding disintegration of Tetrahymena axonemes, we examined the sliding extent and th effect of APD, ATP, and ATP analogs on the sliding extent. Of course, ATP is necessary to produce sliding disintegration, but ATP alone did not produce extensive sliding disintegration. The additions of higher ATP concentration even in the presence of ADP inhibited sliding disintegration. We also observed sliding disintegration using ribose-modified ATP analogs, anthraniloylATP, and methylanthraniloylATP. The extent of sliding disintegration was proportional to the analog concentration. Thus in contrast to ATP, higher analog concentration was not inhibitory. These results indicate that high ATP concentration acts to inhibit the extent of sliding disintegration and that ADP relieves this inhibition. We propose a model in which the affinity of of multiple cooperative active sites are regulated by the binding of ATP or ADP to a regulatory site. This model provides a mechanism by which nucleotides regulate the extent of sliding necessary for effective axonemal bending.

Cleavage initiation activities of microtubules and in vitro reassembled tubulins of sperm flagella.

Cleavage of fish (Oryzias latipes) eggs was induced by injection of heterologous (sea urchin Hemicentrotus pulcherrimus and oyster Crassostrea gigas) sperm microtubules. Cleavage initiating CI activity of microtubules was higher in 3% PVP suspension than in 6% BSA, and not affected significantly by the concentration of microtubules themselves. The CI activity of microtubules suspended in 3% PVP was comparatively stable in the frozen state. Heat-treatment at more than 55 degrees C resulted in the loss of most or all of their CI activity. Such activity was observed in side-by-side aggregates of tubulin linear polymers of sea urchin (Hemicentrotus pulcherrimus) spermatozoa but not in dispersed linear polymers or tubulin dimers. Microtubules with CI activity seem to participate in initiating cleavage as astral centers, or a "seed" for polymerization of ooplasmic tubulins in activated eggs.

ATP-driven tubule extrusion from axonemes without outer dynein arms of sea-urchin sperm flagella.

We have prepared axonemes without outer dynein arms from sea-urchin (Pseudocentrotus depressus, Hemicentrotus pulcherrimus) sperm flagella by selective solubilization with NaCl. Electron microscopy revealed that the axonemes gradually lost their outer arms in 0.5 M NaCl during 10 min. Such axonemes retained 42.8 +/- 7.3% of their total axonemal ATPase activity and showed C, A, D and B bands in the dynein region of 4% SDS-gel, while a solubilized fraction of the outer arms consisted almost entirely of A band polypeptide. We have succeeded in causing extrusion of the outer doublets from such axonemes by addition of ATP and trypsin. A bundle of outer doublets was sometimes observed to be extruded first from an axoneme and to show bending motion for a while, subsequently followed by a sliding of separate doublets past each other. The speed of the tubule extrusion process was slower and around 60% of that of intact axonemes having both types of arm. These observations indicate that the inner arms have a function equivalent to that of the outer arms, of sliding on adjacent doublets, although the inner arms seem to be constituted from polypeptide(s) different from that of the outer arms.