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".     

Partial purification and characterization of dynein adenosine triphosphatase from bovine sperm

Outer dynein arm polypeptides that possess Mg+2-adenosine triphosphatase (ATPase) activity have been extracted from the flagellar axonemes of demembranated bovine sperm. Electron microscopy of intact and salt-extracted sperm demonstrates a relatively selective removal of the outer dynein arms. The salt extract contains a specific ATPase activity of 55 nmoles inorganic phosphate (Pi)/min/mg protein. Sucrose density gradient centrifugation of this extract results in a 6-fold increase in specific activity of ATPase (333 nmole/Pi/min/mg protein), which sediments as a single 13S peak. Concomitant with the increase in specific activity, there is enrichment of three high molecular weight polypeptides (Mr greater than 300,000) characteristic of dynein heavy chains. ATPase activities in the initial extract and in the 13S peak are inhibited by concentrations of vanadate and erythro-9-[3-2-(hydroxynonyl)]adenine similar to those that inhibit ATPase activity in sea urchin sperm dynein. These findings indicate that outer arm dynein ATPase can be extracted and partially purified from bovine sperm.     

The salt-extractable fraction of dynein from sea urchin sperm flagella: An analysis by gel electrophoresis and by adenosine triphosphatase activity

Previous work has shown that the dynein from axonemes of sea urchin sperm consists of two distinct fractions which differ substantially in their extractability by salt. Upon gel electrophoresis of whole demembranated axonemes solubilized with sodium dodecyl sulfate, the dynein fraction shows two closely spaced bands with apparent molecular weights of 520,000 and 460,000; the proteins in these bands are termed the A and B components of the dynein. Similar electrophoresis of the soluble fraction obtained by extracting the axonemes with 0.5 M NaCl shows a single prominent band containing approximately half of the A component of the dynein (A₁ component). The residue of extracted axonemes contain the other half of the A component of the dynein (A₂ component) and all the B component. Densitometry of the bands indicates that the A₁, A₂ and B components of the dynein are present in approximately equal molar quantity. Electron microscopic studies show that the A₁ component of the dynein constitutes the outer arms on the doublet tubules. Assay of ATPase activity in 0.05 M KCl and l mM ATP indicates about 65% of the total ATPase activity becomes soluble when the A₁ component of the dynein is extracted with salt.     

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.     

Strikingly low ATPase activities in flagellar axonemes of a Chlamydomonas mutant missing outer dynein arms

The ATPase activities in Chlamydomonas axonemes were compared between wild type and a mutant (oda) that lacks entire outer dynein arms, at various ionic strengths and pH values, and in the presence of different concentrations of high-molecular-mass dextran. Over a 0-0.2 M KCl concentration range, the ATPase activity of oda axonemes was found to be 5-12 times lower than that of the wild-type axonemes. The low activity in oda is surprising since outer arm-depleted axonemes of sea urchin sperm have been reported to retain about 50% of the normal activity. In both wild type and oda, the ATPase activity of dynein was higher when contained within the axoneme than when released from it with 0.6 M KCl. The ATPase activation within the wild-type axoneme was inhibited by high ionic strengths or by the presence of dextran. The activation in oda axonemes, on the other hand, was not inhibited by these factors. These significantly different ATPase properties suggest that the inner and outer dynein arms perform somewhat different functions in this organism.     

Immunological dissimilarity in protein component (dynein 1) between outer and inner arms within sea urchin sperm axonemes

The 0.5 M KCl-treatment solubilizes the outer arms from sea urchin sperm axonemes. Approximately 30 percent of A-polypeptide, corresponding to dynein 1 in SDS- polyacrylamide gel, was solubilized by this treatment (as SEA-dynein 1). Electron microscopic observation indicated that the extracted axonemes lacked the outer arms in various degrees. The DEA-dynein 1 was that the extracted axonemes lacked the outer arms in various degrees. The SEA-dyenin 1 was purified and an antiserum against it was prepared in rabbits. The specificity of antiserum to dynein 1 was determined by immunoelectrophoresis and ouchterlony’s double-diffusion test. The anti-dynein 1 serum inhibited ATPase activity of purified SEA-dynein 1 by 95 percent. By the indirect peroxidase-conjugated antibody method, the loci of SEA-dynein 1 within the intact, salt- extracted and mechanically disrupted axonemes were determined to be the outer arms: deposition of electron-dense materials which represents their localization was detected at the distal ends of the outer arms, in the case of intact axonemes. The 5-6 cross- bridge was hardly decorated. No decoration was seen in the salt-extracted axonemes lacking all the outer arms. In disrupted axonemes, which consist of single to several peripheral doublets, electron-dense materials were deposited only on the outer arms. Approximately 73 percent of axonemal ATPase activity sensitive to antiserum was solubilized by repeated salt-extractions. One-half of A-polypeptide (SEA-dynein 1 located at the outer arms) was contained in the pooled extracts. The extracted axonemes contained another half of A-polypeptide (SUA-dynein 1 supposed to locate at the inner arms) and retained 31 percent of axonemal ATPase activity that was almost resistant to antiserum. Solubilized SUA-dynein 1 was immunologically the same as SEA-dynein 1. This result indicates that in situ SUA-dynein 1 did not receive anti-dynein 1 antibodies, coinciding with the result obtained for salt-extracted axonemes lacking all the outer arms by the enzyme-antibody method mentioned above. These observations suggest that immunological dissimilarity in dynein 1 between outer and inner arms but do not tell us that the inner arms do not contain dynein 1.     

EFFECTS OF TRYPSIN DIGESTION ON FLAGELLAR STRUCTURES AND THEIR RELATIONSHIP TO MOTILITY

Flagellar axonemes isolated from sea urchin sperm were digested with trypsin for various time periods. The course of digestion was monitored turbidimetrically and was found to take two different courses depending on the presence or absence of ATP in the digestion mixture. It was found that ATP induced active disintegration of the axonemes after slight digestion. Samples of the digested axonemes were examined with the electron microscope to determine the effects of trypsin digestion on the substructures of the axonemes. The rate at which trypsin sensitized the axonemes to ATP paralleled the rate at which it damaged the radial spokes and the nexin links, while the dynein arms were removed much more slowly. The results suggest that inactive dynein arms form cross bridges between the adjacent doublet tubules in digested axonemes, and that when activated by the addition of ATP, they induce an active shearing force between adjacent doublets. The radial spokes and the nexin links are not directly involved in the production of mechanical force, but they may participate in regulating the sliding between tubules to produce a propagated bending wave.     

Heterogeneity of dynein structure implies coordinated suppression of dynein motor activity in the axoneme

Axonemal dyneins provide the driving force for flagellar/ciliary bending. Nucleotide-induced conformational changes of flagellar dynein have been found both in vitro and in situ by electron microscopy, and in situ studies demonstrated the coexistence of at least two conformations in axonemes in the presence of nucleotides (the apo and the nucleotide-bound forms). The distribution of the two forms suggested cooperativity between adjacent dyneins on axonemal microtubule doublets. Although the mechanism of such cooperativity is unknown it might be related to the mechanism of bending. To explore the mechanism by which structural heterogeneity of axonemal dyneins is induced by nucleotides, we used cilia from Tetrahymena thermophila to examine the structure of dyneins in a) the intact axoneme and b) microtubule doublets separated from the axoneme, both with and without additional pure microtubules. We also employed an ATPase assay on these specimens to investigate dynein activity functionally. Dyneins on separated doublets show more activation by nucleotides than those in the intact axoneme, both structurally and in the ATPase assay, and this is especially pronounced when the doublets are coupled with added microtubules, as expected. Paralleling the reduced ATPase activity in the intact axonemes, a lower proportion of these dyneins are in the nucleotide-bound form. This indicates a coordinated suppression of dynein activity in the axoneme, which could be the key for understanding the bending mechanism.     

Flagellar adenosine triphosphatases from annelid spermatozoa: electrophoretic identification of dyneins

Axonemes of sperm flagella were prepared from the annelid, Tylorrhynchus heterochaetus. Dialysis of the axonemes against 1 mm Tris-HCl buffer (pH 8.3)-0.1 mm EDTA-0.1 mm dithiothreitol (Tris-EDTA solution) caused disintegration of typical 9 + 2 microtubules into each doublet, resulting in extraction of one-third of the protein and almost all ATPase activity. Agarose polyacrylamide gel electrophoresis of the extract showed the presence of three kinds of dyneins actively stained for ATPase (designated as bands I, II, and III) and two non-ATPase proteins (bands IV, V). The polypeptide components of each dynein molecule and intact axoneme were analyzed by subsequent sodium dodecyl sulfate-polyacrylamide gel electrophoresis to obtain the following results: (1) In the highmolecular-weight region, the intact axonemes yield two major polypeptides with molecular weights of 365,000 and 345,000 (designated as bands A and B, respectively) and three minor polypeptides, 310,000, 290,00, and 270,00 (C1, C2, C3). (2) All three dyneins contain A-band polypeptide as a common polypeptide component. In addition, band I dynein and band II dynein also contain B and C1 polypeptides, and C3 polypeptide, respectively, as high-molecular-weight components. (3) Band III dynein also contains four polypeptides in the lower molecular-weight region, which migrate similarly with those of 21 S dynein from sea urchin sperm flagella or 18 S dynein from Chlamydomonas.     

Cytoplasmic dynein of the sea urchin egg. II. Purification, characterization and interactions with microtubules and Ca-calmodulin

Purification of cytoplasmic dynein from unfertilized sea urchin eggs was performed in the presence of protease inhibitors to avoid proteolysis throughout the purification procedure, which comprised several chromatographies, including a calmodulin-Sepharose 4B affinity column chromatography. This is the first report of the purification of cytoplasmic dynein to near homogeneity. The purified fraction was composed of a single high molecular weight polypeptide and some minor low molecular weight polypeptides. The high molecular weight polypeptide comigrated with flagellar dynein A beta chain from sperm on SDS-polyacrylamide gels. There was no polypeptide stainable with periodic acid-Schiff reagent (PAS) in the purified cytoplasmic dynein fraction. Cytoplasmic dynein showed characteristics quite similar to those of axonemal dynein, i.e. high substrate specificity for ATP and inhibition by low concentrations of vanadate, though its Ca-ATPase activity showed almost the same dependence on the concentration of either divalent cations or KC1 as the Mg-ATPase activity. The purified enzyme seemed to possess functional form as judged from its properties: 1) pH dependence of the ATPase activity, 2) dependence of the ATPase activity on MgCl2 and KCl concentration, 3) Km for Mg-ATP, and 4) binding to flagellar doublet microtubules. Cytoplasmic dynein bound to calmodulin-Sepharose 4B only in the presence of Ca2+, and was eluted with EGTA. Furthermore, the ATPase activity was enhanced 6-fold by calmodulin in a Ca2+-dependent manner. The activation by calmodulin was prevented by a stoichiometric amount of trifluoperazine.     

Binding of 30s dynein with the B-tubule of the outer doublet of axonemes from Tetrahymena pyriformis and adenosine triphosphate-induced dissociation of the complex.

The binding properties of dynein arms to the A- and B-tubules of outer doublets of cilia from Tetrahymena pyriformis were examined, with the following results: 1. When 30s dynein purified from Tetrahymena cilia was added to doublets deficient in dynein arms, it bound to both A- and B-tubules almost equally and formed arms along the edges. The overall length of arms bound to the A-tubule was 22 +/- 3 nm, and that of arms bound to the B-tubule was 24 +/- 3 nm. Each arm bound to the A- and B-tubules was pointed toward the base at angles of 55 degrees +/- 7 degrees and 48 degrees +/- 7 degrees, respectively. In the presence of sufficient amounts of dynein, the arms along the A- and B-tubules were located at intervals of 22.8 +/- 1.5 nm and 22.5 +/- 1.7 nm, respectively. 2. On adding ATP, only the arms bound to the B-tubule were dissociated from the doublet decorated with arms on both sides. The dissociated arms rebound themselves to the B-tubule after hydrolysis of the ATP. When several doublets decorated with arms along both A- and B-tubules were arrayed side by side, the interdoublet spacing increased from 14 +/- 2 nm to 17 +/- 2 nm on addition of ATP. 3. The turbidity of a suspension of trypsin [EC 3.4.21.4]-treated axonemes decreased rapidly on addition of ATP, then recovered partially. Observations by dark-field microscopy and electron microscopy showed that the doublets which had slid out from the axonemes on ATP addition formed large aggregates after hydrolysis of the ATP. The dynein arms were also solubilized from the axonemes upon addition of ATP, and rebound themselves to the B-tubule after hydrolysis of the added ATP. 4. The double-reciprocal plot for the ATPase [EC 3.6.1.3] activity of the trypsin-treated axonemes against ATP concentration was composed of two straight lines, from which the Km values were estimated to be 1.0 and 12.7 micrometer. The dependence of the decrease in turbidity of the axonemal suspension on ATP concentration indicated that the binding of ATP to sites with an apparent dissociation constant of 1 micrometer induced dissociation of the arms from the B-tubule.     

Specific anion effects on ATPase activity, calmodulin sensitivity, and solubilization of dynein ATPases

The basal ATPase activity of 30S dynein, whether obtained by extraction of ciliary axonemes with a high (0.5 M NaCl) or low (1 mM Tris-0.1 mM EDTA) ionic strength buffer is increased by NaCl, NaNO3, and Na acetate, with NaNO3 causing the largest increase. The calmodulin-activated ATPase activity of 30S dynein is also increased by addition of NaCl, NaNO3, or Na acetate, but the effects are less pronounced than on basal activity, so that the calmodulin activation ratio (CAR) decreases to 1.0 as salt concentration increases to 0.2 M. These salts also reduce the CAR of 14S dynein ATPase to 1.0 but by strongly inhibiting the calmodulin-activated ATPase activity and only slightly inhibiting the basal activity. Sodium fluoride differs both quantitatively and qualitatively from the other three salts studied. It inhibits the ATPase activity of both 14S and 30S dyneins at concentrations below 5 mM and, by a stronger inhibition of the calmodulin-activated ATPase activities, reduces the CAR to 1.0. Na acetate does not inhibit axonemal ATPase, nor does it interfere with the drop in turbidity caused by ATP and extracts very little protein from the axonemes. NaCl and, especially, NaNO3, cause a slow decrease in A350 of an axonemal suspension and an inhibition of the turbidity response to ATP. NaF, at concentrations comparable to those that inhibit the ATPase activities of the solubilized dyneins, also inhibits axonemal ATPase activity and the turbidity response. Pretreatment of demembranated axonemes with a buffer containing 0.25 M sodium acetate for 5 min followed by extraction for 5 min with a buffer containing 0.5 M NaCl and resolution of the extracted dynein on a sucrose density gradient generally yields a 30S dynein that is activated by calmodulin in a heterogeneous manner, ie, the "light" 30S dynein ATPase fractions are more activated than the "heavy" 30S dynein fractions. These results demonstrate specific anion effects on the basal and calmodulin-activated dynein ATPase activities, on the extractability of proteins from the axoneme, and on the turbidity response of demembranated axonemes to ATP. They also provide a method that frequently yields 30S dynein fractions with ATPase activities that are activated over twofold by added calmodulin.     

Inhibition of sperm motility by the volatile anesthetic halothane

The inhalational anesthetic halothane reversibly inhibits the motility of sea urchin sperm dose-dependently at concentrations up to 5 mM. Experiments with Triton X-100 extracted, trypsinized axonemes showed that halothane has no effect on the rate of axonemal disintegration in the presence of ATP. These results suggest that halothane inhibits flagellar activity by acting at a site other than the dynein ATPase component of the flagellum.     

Study of the mechanism of vanadate inhibition of the dynein cross-bridge cycle in sea urchin sperm flagella

The effect of vanadate on the ATP-induced disruption of trypsin-treated axonemes and the ATP-induced straightening of rigor wave preparations of sea urchin sperm was investigated. Addition of ATP to a suspension of trypsin-treated axonemes results in a rapid decrease in turbidity (optical density measured at 350 nm) concomitant with the disruption of the axonemes by sliding between microtubules to form tangles of connected doublet microtubules (Summers and Gibbons, 1971; Sale and Satir, 1977). For axonemes digested to approximately 93 percent of their initial turbidity, 5 {muM} vanadate completely inhibits the ATP-induced decrease in turbidity and the axonemes maintain their structural integrity. However, with axonemes digested to approximately 80 percent of their initial turbidity, vanadate fails to inhibit the ATP-induced decrease in turbidity and the ATP-induced structural disruption of axonemes, even when the vanadate concentration is raised as high as 100 μm. For such axonemes digested to 80 percent of their initial turbidity, the form of ATP-induced structural changes, in the presence of 25 μM vanadate, was observed by dark-field light microscopy and revealed that the axonemes become disrupted into curved, isolated doublet microtubules, small groups of doublet microtubules, and “banana peel” structures in which tubules have peeled back from the axoneme. Addition of 5 μM ATP to rigor wave sperm, which were prepared by abrupt removal of ATP from reactivated sperm, causes straightening of the rigor waves within 1 min, and addition of more than 10 μM ATP causes resumption of flagellar beating. Addition of 40 μM vanadate to the rigor wave sperm does not inhibit straightening of the rigor waves of 2 μM-1 mM ATP, although oscillatory beating is completely inhibited. These results suggest that vanadate inhibits the mechanochemical cycle of dyein at a step subsequent to the MgATP(2-)-induced release of the bridged dynein arms.     

A monoclonal antibody against the dynein IC1 peptide of sea urchin spermatozoa inhibits the motility of sea urchin, dinoflagellate, and human flagellar axonemes.

To investigate the role of axonemal components in the mechanics and regulation of flagellar movement, we have generated a series of monoclonal antibodies (mAb) against sea urchin (Lytechinus pictus) sperm axonemal proteins, selected for their ability to inhibit the motility of demembranated sperm models. One of these antibodies, mAb D1, recognizes an antigen of 142 kDa on blots of sea urchin axonemal proteins and of purified outer arm dynein, suggesting that it acts by binding to the heaviest intermediate chain (IC1) of the dynein arm. mAb D1 blocks the motility of demembranated sea urchin spermatozoa by modifying the beating amplitude and shear angle without affecting the ATPase activity of purified dynein or of demembranated immotile spermatozoa. Furthermore, mAb D1 had only a marginal effect on the velocity of sliding microtubules in trypsin-treated axonemes. This antibody was also capable of inhibiting the motility of flagella of Oxyrrhis marina, a primitive dinoflagellate, and those of demembranated human spermatozoa. Localization of the antigen recognized by mAb D1 by immunofluorescence reveals its presence on the axonemes of flagella from sea urchin spermatozoa and O. marina but not on the cortical microtubule network of the dinoflagellate. These results are consistent with a dynamic role for the dynein intermediate chain IC1 in the bending and/or wave propagation of flagellar axonemes.     

Mechanochemical coupling in eukaryotic flagella

Quantitative analyses of ATP hydrolysis coupled to movement of eukaryotic flagella is important for understanding the relationship between ATP hydrolysis and movement. The difference in ATPase activity between intact motile axonemes (that is the cytoskeletal core of flagella) and homogenized or immotile axonemes has been assumed to be coupled to movement. However, recent findings on rates of steps in the dynein ATPase cycle and the effect of interaction with microtubules on those steps call for reassessment of movement-coupled ATPase. From these studies, it is clear that dynein ATPase activity is not as tightly coupled to interaction with microtubules as myosin ATPase activity is coupled to interaction with actin. The method by which axonemal movement is inhibited will critically affect the interpretation of difference in ATPase activity. If the homogenization or similar methods uncouple dynein, the difference in ATPase activity is not a useful measurement. Greater understanding of the relationship between dynein kinetics and axonemal movement may be obtained by use of conditions and substrates with known effects at specific steps in the dynein mechanochemical cycle and quantitating their effects on movement.     

The roles of noncatalytic ATP binding and ADP binding in the regulation of dynein motile activity in flagella

The regulation of dynein activity to produce microtubule sliding in flagella has not been well understood. To gain more insight into the roles of ATP and ADP in the regulation, we examined the effects of fluorescent ATP analogues and fluorescent ADP analogues on the ATPase activity and motile activity of dynein. 21S dynein purified from the outer arms of sea urchin sperm flagella hydrolyzed BODIPY(R) FL ATP (FL-ATP) at 78% of the rate for ATP hydrolysis. FL-ATP at 0.1-1 mM, however, induced neither microtubule translocation on a dynein-coated glass surface nor sliding disintegration of elastase-treated axonemes. Direct observation of single molecules of the fluorescent analogues showed that both the ATP and ADP analogues were stably bound to dynein over several minutes (dissociation rates = 0.0038-0.0082/s). When microtubule translocation on 21S dynein was induced by ATP, the initial increase of the mean velocity was accelerated by preincubation of the dynein with ADP. Similar increase was also induced by the preincubation with the ADP analogues. Even after preincubation with ADP, FL-ATP did not induce sliding disintegration of elastase-treated axonemes. After preincubation with a nonhydrolyzable ATP analogue, AMPPNP (adenosine 5'-(beta:gamma-imido)triphosphate), however, FL-ATP induced sliding disintegration in approximately 10% of the axonemes. These results indicate that both noncatalytic ATP binding and stable ADP binding, in addition to ATP hydrolysis, are involved in the regulation of the chemo-mechanical transduction in axonemal dynein.     

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     

A biochemical study of flagellar dynein from starfish spermatozoa: protein components of the arm structure.

Half of the adenosine triphosphatase (dynein) activity of starfish sperm tail axonemes was extracted with 0.6 m KCl-10 mm Tris · HCl (pH 7.8)-0.1 mm EDTA-0.5 mm dithiothreitol (KCl-EDTA), while with 1 mm Tris · HCl (pH 7.8)-0.1 mm EDTA-0.5 mm dithiothreitol (Tris-EDTA) around 90% of the activity was extracted. The main adenosine triphosphatase (ATPase) in the KCl-EDTA extract had a sedimentation coefficient of 20S and that in the Tris-EDTA extract had a sedimentation coefficient of 12S. The effects of divalent cations, pH, and an SH-blocking reagent and the K_m for ATP were different for the activities of the two forms of dynein ATPase. These two forms of dynein can interconvert to some extent when the ionic strength of the medium is changed. In a medium suitable for recombination of dynein to outer doublet microtubules (recombination buffer, 20 mm Tris-HCl (pH 7.6)-2 mm MgCl₂-0.5 mm dithiothreitol), the 20S ATPase converted to a 24S ATPase. Recombination of the ATPase activity from the KCl-EDTA extract was almost complete while that from the Tris-EDTA extract was around 50%. Outer arms disappeared preferentially by the treatment with KCl-EDTA, and the extracted arms could be reconstituted in the recombination buffer. In the case of the Tris-EDTA extraction, both the outer and inner arms disappeared and the reconstitution of the arms could not be confirmed. From the above results it can be considered that the 20 or 24S dynein represented the arm structure. The 20 or 24S ATPase fraction contained two large polypeptide chains as main components having electrophoretic mobilities in the presence of sodium dodecylsulfate similar to those of Tetrahymena ciliary dyneins and of sea urchin sperm flagellar dyneins. The relationship between these chains and dynein subunits is discussed.