Effects of adenosine triphosphate on N-ethylmaleimide-induced modification of 30S dynein from Tetrahymena cilia.

Ciliary 30S dynein of Tetrahymena was investigated with regard to modification of the ATPase activity with N-ethylmaleimide (NEM) in the presence of ATP. The elevation of enzyme activity due to the modification was largely repressed by addition of ATP at a concentration of 1 mM or more during preincubation of 20 h at 0 degrees C. The repression was highly specific for ATP, though ADP and AMPPNP showed slight repressive effects. After complete hydrolysis of ATP added to the preincubation mixture, however, elevation of 30S dynein ATPase activity occurred. It is suggested that the repression by ATP of NEM-induced elevation of 30S dynein ATPase activity is simply due to a protecting effect of ATP on certain SH group(s) (probably SH1-type group(s)) around the active center of 30S dynein. When 30S dynein was maximally activated by modification with NEM, ATP or ADP did not significantly promote the inactivation of the modified enzyme upon further treatment with NEM, indicating that 30S dynein lacks the characteristics of SH2-type groups. On the other hand, ATP also showed a protective effect against inhibition of native 30S dynein by high concentrations of NEM. High concentrations of ADP and AMPPNP were inhibitory to 30S dynein ATPase activity but inorganic phosphate did not inhibit 14S or 30S dynein ATPase activities at all.     

Structural conformation of ciliary dynein arms and the generation of sliding forces in Tetrahymena cilia

The sliding tubule model of ciliary motion requires that active sliding of microtubules occur by cyclic cross-bridging of the dynein arms. When isolated, demembranated Tetrahymena cilia are allowed to spontaneously disintegrate in the presence of ATP, the structural conformation of the dynein arms can be clearly resolved by negative contrast electron microscopy. The arms consist of three structural subunits that occur in two basic conformations with respect to the adjacent B subfiber. The inactive conformation occurs in the absence of ATP and is characterized by a uniform, 32 degrees base-directed polarity of the arms. Inactive arms are not attached to the B subfiber of adjacent doublets. The bridged conformation occurs strictly in the presence of ATP and is characterized by arms having the same polarity as inactive arms, but the terminal subunit of the arms has become attached to the B subfiber. In most instances the bridged conformation is accompanied by substantial tip-directed sliding displacement of the bridged doublets. Because the base-directed polarity of the bridged arms is opposite to the direction required for force generation in these cilia and because the bridges occur in the presence of ATP, it is suggested that the bridged conformation may represent the initial attachment phase of the dynein cross-bridge cycle. The force-generating phase of the cycle would then require a tip-directed deflection of the arm subunit attached to the B subfiber.     

The substrate specificity of dynein from Tetrahymena cilia

The substrate specificity of the 22S dynein ATPase from Tetrahymena cilia was investigated. The 22S dynein exhibited a high specificity for ATP in terms of both apparent Km and Vmax: naturally occurring nucleoside triphosphates other than ATP were hydrolyzed slowly with an apparent Km of 0.25-1 mM, a sharp contrast to that of ATP hydrolysis (1-4 microM). Pyrophosphate was a poor inhibitor for the dynein ATPase, indicating weak affinity. Since dynein binds ATP tightly and hydrolyzes it at a high rate, a method to determine a trace amount of ATP in the presence of other nucleoside triphosphates has been developed by taking advantage of this enzymatic characteristic of dynein. The effect of P1,P5-di(adenosine-5'-)-pentaphosphate (Ap5A) on the 22S dynein ATPase was also investigated. Ap5A acted as a weak competitive inhibitor of the ciliary 22S dynein ATPase and the nonlinearity of the double-reciprocal plot of the ATPase was confirmed in the presence of Ap5A.     

ATPase activity of Tetrahymena cilia before and after extraction of dynein

Cilia from Tetrahymena pyriformis were extracted twice with Tris-EDTA. The first extraction increased the total ATPase activity by about one-third. No increase in activity occurred as a result of the second extraction, but 40% of the original ATPase activity remained in the pellet. The activity remaining in the pellet differed in its substrate specificity, its thermostability, and its sensitivity to monovalent cation chlorides from the solubilized dynein. Several of the properties of the ATPase activity of whole cilia differed from those computed for a mixture of 40% pellet ATPase + 60% solubilized dynein ATPase. From these differences it was deduced that dynein in situ is more thermostable than is solubilized dynein and, in contrast to solubilized dynein, is slightly inhibited by KCl, NaCl, LiCl, and NH₄Cl. The increase in total activity upon solubilization of the dynein and the changes in thermostability and in sensitivity to monovalent cations indicates that dynein ATPase in situ is modified by interaction with other components of the axonemal bend generating system.The pellet remaining after extraction of dynein by two dialyses against Tris-EDTA was treated with 0.4% Triton X-100 to solubilize ciliary membranes. Less than half of the ATPase activity was solubilized by this treatment. The possibility that the activity remaining in the Tris-EDTA- and Triton X-100-extracted residue represents an additional ATPase of cilia is discussed.     

Tryptic fragmentation of 30-S dynein from Tetrahymena cilia.

30-S dynein ATPase from Tetrahymena cilia was digested with trypsin (dynein: trypsin = 20:1, by weight) at 25 degrees C for 20 min, resulting in the release of a 12-S fragment possessing ATPase activity. The 12-S ATPase fraction obtained by sucrose gradient centrifugation contained several polypeptide chains as indicated by SDS gel electrophoresis. The largest chain was smaller than the subunit of 30-S dynein and almost the same size as 14-S dynein. On the other hand, when 14-S dynein was digested in a similar manner, its sedimentation value changed from 14 to 12 S, but the peak of ATPase activity was retained at 14 S, suggesting differences in amino acid sequences between the 30 and 14-S dyneins. When the time course of tryptic digestion of 30-S dynein was investigated in a trypsin:dynein ratio of 1:200, discrete fragmentation took place, producing an intermediate fragment of 24 S and the 12-S fragment. The 24-S fragment recombined with outer fibers to some extent, while the 12-S fragment lacked this ability. However, the 12-S fragment was somewhat stimulated to recombine with outer fibers in the presence of other components involved in the trypsin digest. The enzymatic characteristics of the 12-S fraction were different from those of 30-S dynein, especially the activity dependence on pH showing a typical bell-shaped curve.     

Isolation of cilia from porcine tracheal epithelium and extraction of dynein arms

Milligram amounts of mammalian ciliary axonemes were isolated from porcine tracheas. These were reactivated upon addition of ATP, indicating intact functional capability with a mean beat frequency at 37 degrees C of 8.2 Hz. Electron microscopy showed typical ultrastructure of the isolated demembranated axonemes. Electrophoresis into polyacrylamide gradient gels containing sodium dodecyl sulfate revealed reproducible protein profiles from ten different tracheal preparations. Four major protein bands were observed in the 300-330 K molecular weight region, as well as tubulin at 51-54K. Extraction of the isolated tracheal axonemes with 0.6M KCl removed the outer dynein arms seen in electron microscopic cross-section of axonemes, preferentially solubilized two of the high molecular weight proteins at 320 and 330 K, and resulted in a three- to four-fold increase in ATPase specific activity. Sedimentation of the dialyzed salt extract on a 5-30% sucrose density gradient and subsequent fractionation yielded two peaks of ATPase activity. The faster migrating, 19S major ATPase peak correlated with the 320 and 330 K proteins, and two other proteins at 81 and 67 K. The slower sedimenting, 12S minor ATPase peak corresponded to a 308 K protein and two smaller proteins at 33 and 48 K. Thus, the outer dynein arm of tracheal cilia appeared to be associated with at least two high molecular weight proteins. These results demonstrate that adequate quantities of functionally intact axonemes can be reproducibly isolated from porcine tracheas, allowing further fractionation and analysis of mammalian cilia.     

Immunological relation between 14 S dynein and 30 S dynein from the cilia of Tetrahymena pyriformis.

The immunological relation between 14 S dynein and 30 S dynein obtained from Tetrahymena cilia was investigated by using antisera specific for each dynein subunit or some dynein subunits separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Although 14 and 30 S dynein main subunits have different electrophoretic mobilities, our immunodiffusion tests showed that there exists a close immunological relation between them. At least three immunologically different polypeptides designated polypeptides A, B and C are included in the 30 S dynein main band which has been recognized as a single component by electrophoresis, and that the polypeptides designated A',B' and C' are included in the 14 S dynein main bands. Polypeptides A and A',B and B', or C and C' appeared to have a certain common antigenic determinant(s). Polypeptide C of 30 S dynein was shown to possess a certain antigenic determinant(s) specific for 30 S dynein, besides the determinant common with that of polypeptide C' of 14S dynein. The second main component of 30 S dynein proved to be a specific polypeptide of 30 S dynein but not to be a degraded product of the main polypedtide. All antisera reacted with native dynein molecules to some extent, but did not inhibit dynein ATPase (ATP phosphohydrase, EC 3.6.1.3) activity significantly.     

Structure and mass analysis of 14S dynein obtained from Tetrahymena cilia

Scanning transmission electron microscopic analysis revealed that the 14S fraction of Tetrahymena dynein was of a mixture of two types of particles in approximately equal proportions. The 14S dynein molecules were roughly ellipsoid in shape with approximate axes of 9.5 and 14.5 nm. About half of the particles had tails 20-24-nm long. By the integration of electron scattering intensities, particles with tails had an average mass of 510 kD with a SD of 90 kD. The globular heads of both types of particles had an average mass of 330 kD with a SD of 60 kD. The mass of the tail structure was about 180 kD. By SDS-PAGE, the 14S dynein consisted of two high molecular mass polypeptides above 300 kD that could be distinguished by immunoblot analysis.     

Interactions of Tetrahymena dynein with microtubule protein. Tubulin-induced stimulation of dynein ATPase activity.

The ATPase (EC 3.6.1.3) activity of 30 S dynein from Tetrahymena cilia was remarkably stimulated by porcine brain tubulin at pH 10. The activity increased with increasing concentration of tubulin until the molar ratio of tubulin dimer to 30 S dynein reached approx. 10. The optimum of the ATPase activity of 30 S dynein in the presence of tubulin was 1-2 mM for MgCl2 and 2 mM for CaCl2. Increasing ionic strength gradually inhibited the stimulation effects of tubulin. Activation energies of 30 S dynein in the presence and absence of tubulin were almost the same. At the temperatures beyond 25 degrees C stimulation effects of tubulin disappeared. ATP was a specific substrate even in the presence of tubulin. In kinetic investigations parallel reciprocal plots were observed in a constant ratio of divalent cations to ATP of 2, indicating that tubulin was less tightly bound to 30 S dynein in the presence of ATP than the absence. The similar results were obtained at pH 8.2. 14 S dynein and the 12 S fragment which have poor ability to recombine with outer fibers were also activated with brain tubulin.     

The effects of adenosine triphosphate and related compounds on some hydrodynamic properties of glycerinated cilia

Cilia were isolated from Tetrahymena pyriformis by a glycerol method. The addition of low concentrations of ATP, but not of other nucleoside triphosphates, caused an increase of up to twofold in the amount of cilia pelleted in a low-speed centrifugation assay and decreased the density of the pellets compared to control pellets. Pellet size and density depend on pH, both in the absence and in the presence of low concentrations of ATP. High concentrations (5 mM and above) of ATP and of other nucleoside triphosphates tend to "dissolve" the cilia. Heating the cilia for 11 min at 40°C abolishes the increase in pellet size and the decrease in pellet density caused by low ATP, but slightly increases the ATPase activity of the cilia. Heat treatment, however, does not prevent the dissolving effect of high ATP. There are, thus, two independent effects of ATP on the hydrodynamic properties of cilia suspensions.     

ATP-dependent structural changes of the outer dynein arm in Tetrahymena cilia: a freeze-etch replica study

With the rapid-freeze, deep-etch replica technique, the structural conformations of outer dynein arms in demembranated cilia from Tetrahymena were analyzed under two different conditions, i.e., in the absence of ATP and in the presence of ATP and vanadate. In the absence of ATP, the lateral view of axonemes was characterized by the egg- shaped outer dynein arms, which showed a slightly baseward tilt with a mean inclination of 11.1 degrees +/- 3.4 degrees SD from the perpendicular to the doublet microtubules. On the other hand, in the presence of 1 mM ATP and 100 microM vanadate, the outer arms were extended and slender and showed an increased baseward tilt with a mean inclination of 31.6 degrees +/- 4.9 degrees SD. In ATP-activated axonemes, these two types of arms coexisted, each type occurring in groups along one row of outer arms. These findings strongly suggest that the interdoublet sliding is caused by dynamic structural changes of dynein arms that follow the hydrolysis of ATP.     

Steady-state kinetic study on the inhibition of the adenosinetriphosphatase activity of dynein from Tetrahymena cilia by glycerol

The characteristics of glycerol-induced inhibition of the dynein ATPase extracted from Tetrahymena cilia were investigated. Fifty percent inhibition was observed at about 15% (v/v) glycerol with the 22S dynein Mg-ATPase. Ethylene glycol was equally inhibitory, while sucrose, a kind of polyol, was less effective. The glycerol-induced inhibition of the 22S dynein Mg-ATPase was not influenced by pH or by raising the ionic strength of the assay solution. An aqueous glycerol solution treated with anion or cation exchanger or charcoal was equally inhibitory to a non-treated solution. The inhibition was most likely to be due to glycerol or ethylene glycol itself, not to a contaminant. The inhibition of the 22S dynein Mg-ATPase was apparently noncompetitive: only the Vmax was reduced without a significant change in the apparent Km. The dynein ATPase is known to be inhibited potently by vanadate. Glycerol reduced the sensitivity of the dynein ATPase to the vanadate-induced inhibition. Glycerol exhibited a decelerating effect on the rate of the oxygen exchange between phosphate and water catalyzed by 22S dynein in the presence of ADP and Mg2+. If it is assumed that the rate constants of the ATP hydrolysis step are not affected by glycerol, it may be implied that the phosphate release from the E.ADP.P1 intermediate was decelerated by glycerol and that the deceleration of the phosphate release paralleled the reduction of the overall ATPase activity over a wide range of glycerol concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonparallel isometric tension response of rabbit soleus skinned muscle fibers to magnesium adenosine triphosphate and magnesium inosine triphosphate

The isometric tension response of single "skinned' rabbit soleus muscle fibers to MgATP and McITP in the absence of calcium was studied. [MgATP] or [MgITP] was varied in solutions of ionic strength 0.30 and temperature 20 degrees C. Steady-state tension that developed in MgATP or MgITP solutions was a biphasic bell-shaped function of log [MgATP] or log [MgITP] which increased from zero to maximum tension and then declined again to zero. Analysis of the data showed that, under comparable ionic conditions, percent tension vs. log [MgATP] and percent tension vs. log [MgITP] curves are not parallel. Instead, the percent tension vs. log [MgITP] curve is much broader. Additionally, under comparable ionic conditions maximum tension in MgITP solutions was higher than in MgATP solutions. In addition, in MgATP solutions, pH, [K+], and excess ATP were varied. Raising pH from 7 to 8, [K+] from 46 mM to 200 mM, or decreasing excess ATP from 2 to 0.5 mM all increased maximum tension. None of these factors, however, influenced the shape or position of the percent tension vs. log [MgATP] curve.