Mutant strains of Chlamydomonas reinhardtii that move backwards only

Mutations at three independent loci in Chlamydomonas reinhardtii result in a striking alteration of cell motility. Mutant cells representing the three mbo loci move backwards only, propelled by a symmetrical "flagellar" type of bending pattern. The characteristic asymmetric "ciliary" type of flagellar bend pattern responsible for forward movement that predominates in wild-type cells is seldom seen in the mutants. This defect in motility was found to be a property of the mutant axonemes themselves: the isolated axonemes, reactivated by addition of ATP, showed exclusively the symmetrical wave form, and the protein composition of these axonemes differed from the wild-type composition. Axonemes obtained from mbo1 , mbo2 , and mbo3 cells were found to be deficient in six polypeptides regularly present in wild type. The mbo2 axonemes were deficient in two additional polypeptides. The polypeptides were identified in autoradiograms of two-dimensional SDS polyacrylamide gel electrophoretograms of 35S- or 32P-labeled axonemes. One of the six polypeptides has previously been identified; it is a component missing in a mutant deficient for inner dynein arms. Of the five axonemal polypeptides newly identified by the mbo mutants, four were shown to be present as phosphoproteins in wild-type axonemes. One of the additional polypeptides deficient in mbo2 axonemes was also shown to be phosphorylated in wild-type axonemes. Detailed ultrastructural analysis of the mbo1 flagella and the mbo1 , mbo2A , and mbo3 axonemes revealed that the mutants specifically lack the beak- like projections found within the B-tubules of outer doublets 5 and 6.     

Functional binding of inner-arm dyneins with demembranated flagella of Chlamydomonas mutants

Experiments were carried out to see if isolated inner arm dyneins could functionally combine with axonemes lacking them. High-salt extract from the axoneme of Chlamydomonas oda1 mutant lacking outer-arm dynein was added to the demembranated cell models of ida1oda1 lacking inner arm dynein f (dynein I1) and outer arm dynein. After incubation, the originally paralyzed ida1oda1 axonemes recovered the ability to beat in the presence of ATP. A similar good motility recovery after incubation with crude oda1 extract was observed in ida9oda2 lacking outer arm and inner arm dynein c, and partial recovery in ida4oda1 lacking outer arm and inner arm species a, c, and d. These observations indicate that dynein f and dynein c can functionally bind with mutant axonemes lacking them. A method for combining isolated inner arm dyneins with axonemes in a functionally active manner should provide a powerful experimental tool with which to study the mechanism of beating.     

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.     

Conserved axoneme symmetry altered by a component beta-tubulin

Ninefold microtubule symmetry of the eukaryotic basal body and motile axoneme has been long established [1-3]. In Drosophila, these organelles contain distinct but similar beta-tubulin isoforms [4-10]: basal bodies contain only beta1-tubulin, and only beta2-tubulin is used for assembly of sperm axonemes. A single alpha-tubulin functions throughout spermatogenesis [11,12]. Thus, differences in organelle assembly reside in beta-tubulin. We tested the ability of beta1 to function in axonemes and found that beta1 alone could not generate axonemes. Small sequence differences between the two isoforms therefore mediate large differences in assembly capacity, even though these two related organelles have a common evolutionarily ancient architecture. In males with equal beta1 and beta2, beta1 was co-incorporated at equimolar ratio into functional sperm axonemes. When beta1 exceeded beta2, however, axonemes with 10 doublets were produced, an alteration unprecedented in natural phylogeny. Addition of the tenth doublet occurred by a novel mechanism, bypassing the basal body. It has been assumed that the instructions for axoneme morphogenesis reside primarily in the basal body, which normally serves as the axonemal template. Our data reveal that beta-tubulin requirements for basal bodies and axonemes are distinct, and that key information for axoneme architecture resides in the axonemal beta-tubulin.     

Immunological dissimilarity of the calcium pump protein of skeletal and cardiac muscle sarcoplasmic reticulum

This paper is the first biochemical presentation on dynein 1 from vertebrate spermatozoa. Axoneme of rainbow trout spermatozoon is surrounded by the functionally differentiated flagellar membrane, the undulating membrane. The long axis of the undulating membrane is perpendicular to the axonemal axis. Dynein 1 was obtained in the salt extract of axonemes and Fragment 1A was purified from the tryptic digest of salt-extracted dynein 1. Dynein 1 and Fragment 1A from trout were compared with those from sea urchin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis could not show the difference in the molecular weights of dynein 1, and subunit components and their molecular weights of Fragment 1A between two species. Anti-dynein 1 and anti-Fragment 1A sera raised against sea urchin antigens also reacted with trout dynein 1 and Fragment 1A, and inhibited their ATPase activities. Ouchterlony's double diffusion test indicated the pattern of “partial identity” between trout and sea urchin Fragment 1A. Immunoelectron microscopy using peroxidase-conjugated anti-IgG shows that the decoration was observed on the outer arms when the axonemes from the fresh spermatozoa were employed.     

Microtubule sliding in mutant Chlamydomonas axonemes devoid of outer or inner dynein arms

To clarify the functional differentiation between the outer and inner dynein arms in eukaryotic flagella, their mechanochemical properties were assessed by measuring the sliding velocities of outer-doublet microtubules in disintegrating axonemes of Chlamydomonas, using wild-type and mutant strains that lack either of the arms. A special procedure was developed to induce sliding disintegration in Chlamydomonas axonemes which is difficult to achieve by ordinary methods. The flagella were first fragmented by sonication, demembranated by Nonidet P-40, and then perfused under a microscope with Mg-ATP and nagarse, a bacterial protease with broad substrate specificity. The sliding velocity varied with the Mg-ATP concentration in a Michaelis-Menten manner in the axonemes from the wild type and a motile mutant lacking the outer dynein arm (oda38). The maximal sliding velocity and apparent Michaelis constant for Mg-ATP were measured to be 13.2 +/- 1.0 micron/s and 158 +/- 36 microM for the wild type and 2.0 +/- 0.1 micron/s and 64 +/- 18 microM for oda38. These maximal sliding velocities were significantly smaller than those estimated in beating axonemes; the reason is not clear. The velocities in the presence or absence of 10(-5) M Ca2+ did not differ noticeably. The axonemes of nonmotile mutants lacking either outer arms (pf13A, pf22) or inner arms (pf23) were examined for their ability to undergo sliding disintegration in the presence of 0.1 mM Mg-ATP. Whereas pf13A axonemes underwent normal sliding disintegration, the other two species displayed it only very poorly. The poor ability of pf23 axonemes to undergo sliding disintegration raises the possibility that the outer dynein arm cannot function well in the absence of the inner arm.     

Regulation of flagellar dynein by the axonemal central apparatus

Numerous studies indicate that the central apparatus, radial spokes, and dynein regulatory complex form a signaling pathway that regulates dynein activity in eukaryotic flagella. This regulation involves the action of several kinases and phosphatases anchored to the axoneme. To further investigate the role of the central apparatus in this signaling pathway, we have taken advantage of a microtubule-sliding assay to assess dynein activity in central apparatus defective mutants of Chlamydomonas. Axonemes isolated from both pf18 and pf15 (lacking the entire central apparatus) and from pf16 (lacking the C1 central microtubule) have reduced microtubule-sliding velocity compared with wild-type axonemes. Based on functional analyses of axonemes isolated from radial spokeless mutants, we hypothesized that inhibitors of casein kinase 1 (CK1) and cAMP dependent protein kinase (PKA) would rescue dynein activity and increase microtubule-sliding velocity in central pairless mutants. Treatment of axonemes isolated from both pf18 and pf16 with DRB, a CK1 inhibitor, but not with PKI, a PKA inhibitor, restored dynein activity to wild-type levels. The DRB-induced increase in dynein-driven microtubule sliding was inhibited if axonemes were first incubated with the phosphatase inhibitor, microcystin. Inhibiting CK1 in pf15 axonemes, which lack the central pair as well as PP2A [Yang et al., 2000: J. Cell Sci. 113:91-102], did not increase microtubule-sliding velocity. These data are consistent with a model in which the central apparatus, and specifically the C1 microtubule, regulate dynein through interactions with the radial spokes that ultimately alter the activity of CK1 and PP2A. These data are also consistent with localization of axonemal CK1 and PP2A near the dynein arms.     

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.     

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.     

Stimulation of in vitro motility of Chlamydomonas axonemes by inhibition of cAMP-dependent phosphorylation

When demembranated axonemes of Chlamydomonas were reactivated with Mg-ATP, the proportion of motile axonemes was significantly increased by the presence of either phosphodiesterase (PDE) or protein inhibitor of cAMP-dependent kinase (PKI). The effect of PDE was cancelled by the addition of cAMP. These findings strongly suggest that the axoneme samples have endogenous cAMP, which can reduce the proportion of motile axonemes via phosphorylation. This inhibitory effect of cAMP on Chlamydomonas axonemes is opposite to its stimulatory effect on the axonemal motility in other organisms so far reported. PKI or PDE activated the motility either in the absence of Ca2+, when the axonemes beat with an asymmetric waveform, or in 10(-5) M Ca2+, when the axonemes beat with a symmetric waveform. This cAMP-dependent regulation of motility was observed with the axonemes from which detergent-soluble material had been removed, indicating that the proteins responsible for the regulation still remained in the axonemes. Preliminary in vitro phosphorylation studies have implicated two polypeptides as candidates for the target protein of cAMP-dependent protein kinase: one with a molecular weight of 270 kD and the other with a much larger molecular weight.     

Regulation of flagellar dynein by calcium and a role for an axonemal calmodulin and calmodulin-dependent kinase

Ciliary and flagellar motility is regulated by changes in intraflagellar calcium. However, the molecular mechanism by which calcium controls motility is unknown. We tested the hypothesis that calcium regulates motility by controlling dynein-driven microtubule sliding and that the central pair and radial spokes are involved in this regulation. We isolated axonemes from Chlamydomonas mutants and measured microtubule sliding velocity in buffers containing 1 mM ATP and various concentrations of calcium. In buffers with pCa > 8, microtubule sliding velocity in axonemes lacking the central apparatus (pf18 and pf15) was reduced compared with that of wild-type axonemes. In contrast, at pCa4, dynein activity in pf18 and pf15 axonemes was restored to wild-type level. The calcium-induced increase in dynein activity in pf18 axonemes was inhibited by antagonists of calmodulin and calmodulin-dependent kinase II. Axonemes lacking the C1 central tubule (pf16) or lacking radial spoke components (pf14 and pf17) do not exhibit calcium-induced increase in dynein activity in pCa4 buffer. We conclude that calcium regulation of flagellar motility involves regulation of dynein-driven microtubule sliding, that calmodulin and calmodulin-dependent kinase II may mediate the calcium signal, and that the central apparatus and radial spokes are key components of the calcium signaling pathway.     

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.     

Reactivation of outer-arm-depleted lung axonemes: evidence for functional differences between inner and outer dynein arms in situ.

Demembranated axonemes isolated from newt lung ciliated cells show a complex beat frequency response to varying [MgATP] and temperature [Hard and Cypher, 1992, Cell Motil. Cytoskeleton 21:187-198]. The present study was undertaken to ascertain whether the beat frequency of outer-arm-depleted newt lung axonemes is controlled in a manner similar to that of intact axonemes. Populations of demembranated ciliary axonemes were isolated by Triton X-100 extraction of lungs from the newt, Taricha granulosa. Aliquots of the demembranated axonemes were further treated with solutions containing high salt (0.375 M KC1) and 1.25 mM MgATP. This treatment resulted in the selective removal of outer dynein arms and a concomitant decrease in beat frequency to a stable level, 33-35% of control values. The effects of pH, salt concentration, nucleotides, and temperature on the beat frequency of reactivated outer-arm-depleted axonemes were ascertained and compared with those of intact axonemes. Some reactivation properties, such as nucleotide specificity, the effect of pH on beat frequency and the threshold [MgATP] required for reactivation (approximately 5 microM) were similar to those observed for intact axonemes. Other properties, such as the relationship between beat frequency and varying [MgATP] or salt concentration, differed both qualitatively and quantitatively from those of control axonemes, as did their response to temperature over the range, 5 degrees-32 degrees C. The nature of the results obtained with temperature and MgATP suggests that inner and outer dynein arms are not functionally equivalent in situ.     

Direction of force generated by the inner row of dynein arms on flagellar microtubules

Our goal was to determine the direction of force generation of the inner dynein arms in flagellar axonemes. We developed an efficient means of extracting the outer row of dynein arms in demembranated sperm tail axonemes, leaving the inner row of dynein arms structurally and functionally intact. Sperm tail axonemes depleted of outer arms beat at half the beat frequency of sperm tails with intact arms over a wide range of ATP concentrations. The isolated, outer arm-depleted axonemes were induced to undergo microtubule sliding in the presence of ATP and trypsin. Electron microscopic analysis of the relative direction of microtubule sliding (see Sale, W. S. and P. Satir, 1977, Proc. Natl. Acad. Sci. USA, 74:2045-2049) revealed that the doublet microtubule with the row of inner dynein arms, doublet N, always moved by sliding toward the proximal end of the axoneme relative to doublet N + 1. Therefore, the inner arms generate force such that doublet N pushes doublet N + 1 tipward. This is the same direction of microtubule sliding induced by ATP and trypsin in axonemes having both inner and outer dynein arms. The implications of this result for the mechanism of ciliary bending and utility in functional definition of cytoplasmic dyneins are discussed.     

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.     

Assembly of flagellar radial spoke proteins in Chlamydomonas: identification of the axoneme binding domain of radial spoke protein 3

Radial spokes of the eukaryotic flagellum extend from the A tubule of each outer doublet microtubule toward the central pair microtubules. In the paralyzed flagella mutant of Chlamydomonas pf14, a mutation in the gene for one of 17 polypeptides that comprise the radial spokes results in flagella that lack all 17 spoke components. The defective gene product, radial spoke protein 3 (RSP3), is, therefore, pivotal to the assembly of the entire spoke and may attach the spoke to the axoneme. We have synthesized RSP3 in vitro and assayed its binding to axonemes from pf14 cells to determine if RSP3 can attach to spokeless axonemes. In vitro, RSP3 binds to pf14 axonemes, but not to wild-type axonemes or microtubules polymerized from purified chick brain tubulin. The sole axoneme binding domain of RSP3 is located within amino acids 1-85 of the 516 amino acid protein; deletion of these amino acids abolishes binding by RSP3. Fusion of amino acids 1-85 or 42-85 to an unrelated protein confers complete or partial binding activity, respectively, to the fusion protein. Transformation of pf14 cells with mutagenized RSP3 genes indicates that amino acids 18-87 of RSP3 are important to its function, but that the carboxy-terminal 140 amino acids can be deleted with little effect on radial spoke assembly or flagellar motility.     

Effects of trypsin-digested outer-arm dynein fragments on the velocity of microtubule sliding in elastase-digested flagellar axonemes

Flagellar movement is caused by the coordinated activity of outer and inner dynein arms, which induces sliding between doublet microtubules. In trypsin-treated flagellar axonemes, microtubule sliding induced by ATP is faster in the presence than in the absence of the outer arms. To elucidate the mechanism by which the outer arms regulate microtubule sliding, we studied the effect of trypsin-digested outer-arm fragments on the velocity of microtubule sliding in elastase-treated axonemes of sea urchin sperm flagella. We found that microtubule sliding was significantly slower in elastase-treated axonemes than in trypsin-treated axonemes, and that this difference disappeared after the complete removal of the outer arms. After about 95% of the outer arms were removed, however, the velocity of sliding induced by elastase and ATP increased significantly by adding outer arms that had been treated with trypsin in the presence of ATP. The increase in sliding velocity did not occur in the elastase-treated axonemes from which the outer arms had been completely removed. Among the outer arm fragments obtained by trypsin treatment, a polypeptide of about 350 kDa was found to be possibly involved in the regulation of sliding velocity. These results suggest that the velocity of sliding in the axonemes with only inner arms is similar to that in the axonemes with both inner and outer arms, and that the 350 kDa fragment, probably of the alpha heavy chains, increases the sliding activity of the intact outer and inner arms on the doublet microtubules.     

Submicromolar levels of calcium control the balance of beating between the two flagella in demembranated models of Chlamydomonas

When detergent-extracted, demembranated cell models of Chlamydomonas were resuspended in reactivation solutions containing less than 10(-8) M Ca++, many models initially swam in helical paths similar to those of intact cells; others swam in circles against the surface of the slide or coverslip. With increasing time after reactivation, fewer models swam in helices and more swam in circles. This transition from helical to circular swimming was the result of a progressive inactivation of one of the axonemes; in the extreme case, one axoneme was completely inactive whereas the other beat with a normal waveform. At these low Ca++ concentrations, the inactivated axoneme was the trans-axoneme (the one farthest from the eyespot) in 70-100% of the models. At 10(-7) or 10(-6) M Ca++, cell models also proceeded from helical to circular swimming as a result of inactivation of one of the axonemes; however, under these conditions the cis-axoneme was usually the one that was inactivated. At 10(-8) M Ca++, most cells continued helical swimming, indicating that both axonemes were remaining relatively active. The progressive, Ca++-dependent inactivation of the trans- or cis-axoneme was reversed by switching the cell models to higher or lower Ca++ concentrations, respectively. A similar reversible, selective inactivation of the trans-flagellum occurred in intact cells swimming in medium containing 0.5 mM EGTA and no added Ca++. The results show that there are functional differences between the two axonemes of Chlamydomonas. The differential responses of the axonemes to submicromolar concentrations of Ca++ may form the basis for phototactic turning.     

Ultrastructure of Spermiogenesis in Acanthocotyle and Myxinidocotyle (Platyhelminthes,Monogenea, Acanthocotylidae)

Abstract Spermiogenesis was studied by transmission electron microscopy in the acanthocotylid monogeneans Myxinidocotyle californica (from Eptatretus stoutii) and Acanthocotyle lobianchi (from Raja clavata). In Myxinidocotyle and Acanthocotyle, the zone of differentiation shows two 9+‘1’ axonemes, the elongating nucleus and mitochondrion, and a single cortical cytoplasmic microtubule. This single microtubule is found in the mature spermatozoon of both species and was also noted in capsalids. This requires a modified definition of ‘pattern 2’ of spermatozoa which becomes: ‘spermatozoa with two axonemes and no cortical microtubules, except one single element much shorter than the spermatozoon’. A very unusual structure was found in Myxinidocotyle, but not in Acanthocotyle: the centriolar derivative of one of the 9+‘1’ axonemes is made up of 18 diverging singlets of unequal length associated with electron-dense cytoplasm. This seems to be the first case of a centriolar derivative without nine-fold symmetry associated with an axoneme with nine-fold symmetry.     

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.