Effects of antibodies against tubulin on the movement of reactivated sea urchin sperm flagella

Flagellar oscillation: a commentary on proposed mechanisms

Eukaryotic flagella and cilia have a remarkably uniform internal 'engine' known as the '9+2' axoneme. With few exceptions, the function of cilia and flagella is to beat rhythmically and set up relative motion between themselves and the liquid that surrounds them. The molecular basis of axonemal movement is understood in considerable detail, with the exception of the mechanism that provides its rhythmical or oscillatory quality. Some kind of repetitive 'switching' event is assumed to occur; there are several proposals regarding the nature of the 'switch' and how it might operate. Herein I first summarise all the factors known to influence the rate of the oscillation (the beating frequency). Many of these factors exert their effect through modulating the mean sliding velocity between the nine doublet microtubules of the axoneme, this velocity being the determinant of bend growth rate and bend propagation rate. Then I explain six proposed mechanisms for flagellar oscillation and review the evidence on which they are based. Finally, I attempt to derive an economical synthesis, drawing for preference on experimental research that has been minimally disruptive of the intricate structure of the axoneme. The 'provisional synthesis' is that flagellar oscillation emerges from an effect of passive sliding direction on the dynein arms. Sliding in one direction facilitates force-generating cycles and dynein-to-dynein synchronisation along a doublet; sliding in the other direction is inhibitory. The direction of the initial passive sliding normally oscillates because it is controlled hydrodynamically through the alternating direction of the propulsive thrust. However, in the absence of such regulation, there can be a perpetual, mechanical self-triggering through a reversal of sliding direction due to the recoil of elastic structures that deform as a response to the prior active sliding. This provisional synthesis may be a useful basis for further examination of the problem.

The counterbend phenomenon in dynein-disabled rat sperm flagella and what it reveals about the interdoublet elasticity

Rat sperm that have been rendered passive by disabling the dynein motors with 50 muM sodium metavanadate and 0.1 mM ATP exhibit an interesting response to imposed bending. When the proximal flagellum is bent with a microprobe, the portion of the flagellum distal to the probe contact point develops a bend in the direction opposite the imposed bend. This "counterbend" is not compatible with a simple elastic beam. It can be satisfactorily explained by the sliding tubule model of flagellar structure but only if there are permanent elastic connections between the outer doublets of the axoneme. The elastic component that contributes the bending torque for the counterbend does not reset to a new equilibrium position after an imposed bend but returns the flagellum to a nearly straight or slightly curved final position after release from the probe. This suggests it is based on fixed, rather than mobile, attachments. It is also disrupted by elastase or trypsin digestion, confirming that it is dependent on a protein linkage. Adopting the assumption that the elasticity is attributed to the nexin links that repeat at 96 nm intervals, we find an apparent elasticity for each link that ranges from 1.6 to 10 x 10(-5) N/m. However, the elasticity is nonlinear and does not follow Hooke's law but appears to decrease with increased stretch. In addition, the responsible elastic elements must be able to stretch to more than 10 times their resting length without breakage to account for the observed counterbend formation. Elasticity created by some type of protein unfolding may be the only viable explanation consistent with both the extreme capacity for extension and the nonlinear character of the restoring force that is observed.

The dynein heavy chain: structure, mechanics and evolution

The translocation of dynein along microtubules is the basis for a variety of essential cellular movements. Despite a general domain organization that is found in all the cytoskeletal motors, there are structural features of dynein that set it apart from the other motors. These include a track-binding site that is located at the tip of a long projection, and six nucleotide-binding modules that together form the globular head of dynein. These unique features suggest that dynein produces movement by a mechanism that is different from that used by the other motors.

Molecular cloning and characterization of a radial spoke head protein of sea urchin sperm axonemes: involvement of the protein in the regulation of sperm motility

Monoclonal antibodies raised against axonemal proteins of sea urchin spermatozoa have been used to study regulatory mechanisms involved in flagellar motility. Here, we report that one of these antibodies, monoclonal antibody D-316, has an unusual perturbating effect on the motility of sea urchin sperm models; it does not affect the beat frequency, the amplitude of beating or the percentage of motile sperm models, but instead promotes a marked transformation of the flagellar beating pattern which changes from a two-dimensional to a three-dimensional type of movement. On immunoblots of axonemal proteins separated by SDS-PAGE, D-316 recognized a single polypeptide of 90 kDa. This protein was purified following its extraction by exposure of axonemes to a brief heat treatment at 40 degrees C. The protein copurified and coimmunoprecipitated with proteins of 43 and 34 kDa, suggesting that it exists as a complex in its native form. Using D-316 as a probe, a full-length cDNA clone encoding the 90-kDa protein was obtained from a sea urchin cDNA library. The sequence predicts a highly acidic (pI = 4.0) protein of 552 amino acids with a mass of 62,720 Da (p63). Comparison with protein sequences in databases indicated that the protein is related to radial spoke proteins 4 and 6 (RSP4 and RSP6) of Chlamydomonas reinhardtii, which share 37% and 25% similarity, respectively, with p63. However, the sea urchin protein possesses structural features distinct from RSP4 and RSP6, such as the presence of three major acidic stretches which contains 25, 17, and 12 aspartate and glutamate residues of 34-, 22-, and 14-amino acid long stretches, respectively, that are predicted to form alpha-helical coiled-coil secondary structures. These results suggest a major role for p63 in the maintenance of a planar form of sperm flagellar beating and provide new tools to study the function of radial spoke heads in more evolved species.

The polyglutamylated lateral chain of alpha-tubulin plays a key role in flagellar motility

To investigate whether a specific isotype of tubulin is involved in flagellar motility, we have developed and screened a panel of monoclonal antibodies (mAb) generated against sea urchin sperm axonemal proteins. Antibodies were selected for their ability to block the motility of permeabilized sperm models. The antitubulin mAb B3 completely inhibited, at low concentrations, the flagellar motility of permeabilized sperm models from four sea urchin species. On immunoblots, B3 recognized predominantly alpha-tubulin in sea urchin sperm axonemes and equally well brain alpha- and beta-tubulins. Subtilisin cleavage of tubulin removed the B3 epitope, indicating that it was restricted to the last 13 amino acid residues of the C-terminal domain of alpha-tubulin. In enzyme-linked immunosorbant assays, B3 reacted with glutamylated alpha-tubulin peptides from sea urchin or mouse brain but did not bind to the unmodified corresponding peptide, indicating that it recognized polyglutamylated motifs in the C-terminal domain of alpha-tubulin. On the other hand, other tubulin antibodies directed against various epitopes of the C-terminal domain, with the exception of the antipolyglutamylated mAb GT335, had no effect on motility while having binding properties similar to that of B3. B3 and GT335 acted by decreasing the beating amplitude without affecting the flagellar beat frequency. B3 and GT335 were also capable of inhibiting the motility of flagella of Oxyrrhis marina, a 400,000,000 year old species of dinoflagellate, and those of human sperm models. Localization of the antigens recognized by B3 and GT335 by immunofluorescence techniques revealed their presence along the whole axoneme of sea urchin spermatozoa and flagella of O. marina, except for the distal tip and the cortical microtubule network of the dinoflagellate. Taken together, the data reported here indicate that the polyglutamylated lateral chain of alpha-tubulin plays a dynamic role in a dynein-based motility process.

Purification, cloning, and sequence analysis of a Mr = 30,000 protein from sea urchin axonemes that is important for sperm motility. Relationship of the protein to a dynein light chain

We have generated a series of monoclonal antibodies against axonemal proteins from sea urchin spermatozoa in order to identify novel proteins involved in the regulation of flagellar motility. The monoclonal antibody D405-14 inhibited the motility of demembranated-reactivated sperm models at low concentrations and recognized a single polypeptide of 33 kDa (p33) on immunoblots of sea urchin axonemal proteins. Fractionation of the axonemes with high salt solutions, heat, and detergent resulted in the selective extraction of p33 into a 0.6 M NaCl-soluble and a 0.5% sodium lauryl sarcosinate (Sarkosyl)-soluble form. Both forms of p33 were purified to apparent homogeneity by immunoaffinity chromatography on monoclonal antibody D405-14-Sepharose. We have also isolated and sequenced a full-length cDNA clone encoding the 33-kDa protein. The sequence predicts a polypeptide of 260 amino acids having a mass of 29,730 Da and an isoelectric point of 9.3. Sequence comparison indicates that p33 is 66% identical (74% similar) to the p28 light chain of axonemal inner dynein arm of Chlamydomonas reinhardtii. Taken together, these results suggest that we have identified a p28 light chain homolog in sea urchin sperm axoneme and that this protein may play a dynamic role in flagellar motility.

Axonemal tubulin polyglycylation probed with two monoclonal antibodies: widespread evolutionary distribution, appearance during spermatozoan maturation and possible function in motility

Two monoclonal antibodies, AXO 49 and TAP 952, probed with carboxy-terminal peptides from Paramecium axonemal tubulin and with polyglycylated synthetic peptides, are found to recognize differently tubulin polyglycylation, the most recently identified posttranslational modification discovered in Paramecium axonemal tubulin. With these antibodies, we show that tubulin polyglycylation is widely distributed in organisms ranging from ciliated protozoa to mammals; it arose early in the course of evolution, but seems to be absent in primitive protozoa such as the Euglenozoa. Tubulin polyglycylation is the last posttranslational modification which takes place in the course of Drosophila spermatogenesis and its occurrence corresponds to the end of spermatozoan maturation. An involvement of polyglycylated tubulin in axoneme motility is suggested since AXO 49 and TAP 952 specifically inhibit the reactivated motility of sea urchin spermatozoa.

Inhibition of flagellar beat frequency by a new anti-beta-tubulin antibody

A panel of monoclonal antibodies (mAbs) has been generated against sea urchin sperm axonemes and selected for their ability to inhibit the motility of sea urchin sperm models. The mAb C9 recognized a 50 kDa protein on blots of sea urchin sperm axonemes. Two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that C9 recognized isoforms of beta-tubulin. Low concentrations of C9 (0.1-1.0 microgram/ml) blocked the motility of sea urchin sperm models by decreasing the sliding velocity and frequency of flagellar beating to less than 1 Hz and by modifying the shear angle along the axoneme, especially the distal end. Other antitubulin antibodies had little effect on motility at concentrations 100-fold higher than those effective for C9. The effects on motility were not restricted to flagella of sea urchin spermatozoa. Flagellar beating of the dinoflagellate Oxyrrhis marina was completely blocked by C9 in a manner reminiscent of that of sea urchin sperm flagella. The mAb also inhibited the motility of human spermatozoa and Chlamydomonas reinhardtii. Immunofluorescence techniques revealed that C9 stains the whole axoneme of sea urchin spermatozoa and O. marina flagella together with the cortical network of O. marina cell body. C9 is the first antitubulin antibody reported to interfere with flagellar beat frequency. The observation that this antibody arrests the motility of flagella from sea urchin sperm along with that of dinoflagellate, algae, and human sperm flagella suggests that the epitope recognized by C9 is conserved over a long period of evolution and plays an important role in sperm motility.

Microtubule sliding, bend initiation, and bend propagation parameters of Ciona sperm flagella altered by viscous load

The effect of altered viscous resistance on flagellar bending has been reexamined, utilizing ATP-reactivated sperm flagella from Ciona and newer methods that resolve metachronous and synchronous components of microtubule sliding and allow the examination of bend initiation as well as bend propagation. Large changes in amplitude and wavelength of bend propagation occur with little change in bend initiation parameters, other than frequency, indicating that bend initiation and bend propagation are regulated by quite different mechanisms. At increased viscosity, reduced amplitude of propagating bends, measured as metachronous shear amplitude, is associated with both reduced amplitude during bend initiation and amplitude adjustment after bends begin to propagate. This combination of effects was seen previously when reduced amplitudes were induced by increased salt concentration, and it was suggested to be caused by an imbalance between active moments and viscous resistances. However, in contrast to the results at increased salt concentrations, which involved significant reduction in bend curvature and little reduction in wavelength, increased viscosity causes very little change in curvature and causes a major reduction in wavelength. This difference can be explained by a model of flagellar bending in which inner arm dyneins have primary responsibility for maintaining bend curvature and outer arm dyneins have primary responsibility for performing work against viscous resistances. Both sets of dyneins would be inhibited by increased salt concentration, but increased viscous resistance would be irrelevant to the operation of inner arm dyneins.

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.

Microtubule sliding in reduced-amplitude bending waves of Ciona sperm flagella: resolution of metachronous and synchronous sliding components of stable bending waves

Microtubule sliding associated with the bending of reactivated flagella of demembranated spermatozoa of the tunicate, Ciona, has been analyzed using a descriptive model that permits quantitation of metachronous and synchronous components of sliding. Reduced-amplitude bending waves, obtained by addition of increased salt (K acetate), lithium, or vanadate to the reactivation solutions, have been examined. Increased K acetate can decrease bend angle by as much as 70% with little change in frequency. In all cases, a decrease in the amplitude, or bend angle, of propagated bends is measured as a decrease in the metachronous component of sliding and is associated with a reduction in the growth of new bends after they begin to propagate during the second half-cycle of bend development. At higher K acetate concentrations, bend growth during the second half-cycle of bend development is very strongly reduced and may even become negative. A disparity between the rates of bend growth in the first and second half-cycles of bend development corresponds to a large amount of synchronous sliding in the distal portion of the flagellum. When the synchronous sliding component is large, the sliding velocity in a propagating bend decreases to near-0 values and may even reverse its direction as the bend propagates through the mid-region of the flagellum. Since these large perturbations of sliding velocity do not interfere with regular propagation of bends with nearly constant bend angle, the bend propagation mechanism cannot operate by metachronous control of the velocity of sliding, and is unlikely to operate by local monitoring of either the amount or velocity of sliding. These observations therefore argue against models in which active sliding is regulated by shear or sliding velocity, and make curvature-controlled models relatively more attractive. In many cases, a reduction in sliding during bend initiation (the first half-cycle of development of new bends) also contributes to the decreased amplitude of propagated bends. These changes in bend initiation are similar in both full-length flagella and in flagella shortened by breakage. The amount of sliding that occurs during bend initiation is relatively independent of the distribution of sliding between metachronous and synchronous components in the distal part of the flagellum. These observations therefore provide additional evidence that bend initiation and bend propagation are independent and separable processes.

Conserved beta-tubulin binding domain for the microtubule-associated motors underlying sperm motility and fast axonal transport

An antiserum against tubulin, NS20, has been previously shown to inhibit anterograde and retrograde axonal transport by 50% in vivo and in vitro. We report here that Protein A purified NS20 antibodies also attenuate sperm motility by 50% in demembranated sea urchin sperm. This inhibition is absorbed out by preincubating the NS20 antibodies with a biochemically purified porcine microtubule preparation, with recombinant Trypanosoma beta- (but not alpha-) tubulin and most specifically, with a 37 amino acid (a.a.) synthetic peptide corresponding to a domain near (but not including) the porcine beta-tubulin C terminus. Furthermore, addition of this beta-tubulin peptide alone is sufficient to attenuate motility by 50% in demembranated sperm, indicating that this critical 37a.a. NS20 antigen is a motor binding domain. Together, the results suggest that at least two phenotypically distinct forms of microtubule-based motility, axonal transport and flagellar beating, are homologous at the fundamental level of the microtubule domains (the beta-tubulin peptide and we suggest a distinct but similarly located alpha-tubulin domain) mediating the attachment of tubulin-associated motors.

Molecular cloning and expression of sea urchin embryonic ciliary dynein beta heavy chain

The determination of the structure and the expression of dynein during embryonic development are central to the understanding of dynein function. As an important first step toward these objectives, cDNAs encoding portions of sea urchin ciliary dynein were identified by antibody screening of a sea urchin cDNA expression library. Because of the complete lack of protein sequence data, it was first necessary to prove the identity of the dynein cDNAs. Of the five cDNA inserts initially cloned, one, designated P72A1, was characterized extensively. Four independent criteria demonstrated that P72A1 encoded a portion of a dynein heavy chain. (1) The beta-galactosidase-P72A1 fusion protein affinity-purified dynein-specific antibodies from crude antiserum. (2) Two other antisera to dynein, raised independently of the antiserum used to screen the cDNA library, reacted with the fusion protein. (3) A new antiserum raised against the fusion protein reacted with authentic dynein heavy chain on Western blots and stained embryonic cilia by indirect immunofluorescence microscopy. (4) Two new antisera, elicited against opposite ends of the P72A1 open reading frame, each reacted with authentic dynein heavy chain protein. Western blot analyses of dissociated dynein heavy chains revealed that P72A1 encoded a portion of the beta heavy chain. Epitope mapping experiments confirmed the identity of P72A1 as part of the beta heavy chain and also demonstrated that P72A1 encoded epitopes of the carboxyl-terminal fragment B domain of the dynein beta heavy chain. Northern blot analyses of poly(A)+ RNA revealed that P72A1 hybridized with a large RNA species ca. 12.5 kb in length. The dynein mRNA concentration increased during embryonic development. Dot blot analyses of RNA isolated at various times after embryo deciliation demonstrated that the dynein beta heavy chain mRNA accumulated rapidly in response to deciliation. The accumulation was similar to but not identical with the induction of tubulin mRNA in response to the same stimulus.

Effects of cis-4-hydroxy-L-proline, and inhibitor of Schwann cell differentiation, on the secretion of collagenous and noncollagenous proteins by Schwann cells

The proline analog cis-4-hydroxy-L-proline (CHP) was previously shown to inhibit both Schwann cell (SC) differentiation and extracellular matrix (ECM) formation in cultures of rat SCs and dorsal root ganglion neurons. We confirmed that CHP inhibits basal lamina formation by immunofluorescence with antibodies to laminin, type IV collagen, and heparan sulfate proteoglycan. In order to test the hypothesis that CHP inhibits SC differentiation by specifically inhibiting the secretion of collagen, cultures grown in the presence or absence of CHP were metabolically labeled with [3H]leucine and the media were analyzed for relative amounts of (a) collagenous and noncollagenous proteins by assay with bacterial collagenase and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), or (b) triple-helical collagen by pepsin digestion followed by SDS-PAGE. The results indicate that although CHP inhibited the accumulation of secreted collagen in the culture medium and disrupted collagen triple-helix formation, it also significantly inhibited the accumulation of secreted noncollagenous proteins in the medium. CHP had no significant effect on either total protein synthesis (medium plus cell layer) or cell number. We conclude that CHP does not act as a specific inhibitor of collagen secretion in this system, and thus data from these experiments cannot be used to relate SC collagen production to other aspects of SC differentiation. We discuss the evidence for and against specificity of CHP action in other systems.

Sulfated proteoglycans produced by rat dorsal root ganglion cells

Primary organotypic cultures of embryonic rat dorsal root ganglia, which contain sensory neurons, Schwann cells, and fibroblasts, produce an extensive extracellular matrix. These cultures actively incorporated 35SO4 into glycosaminoglycans, of which 30% were heparan sulfate, 65% chondroitin sulfate, and 5% dermatan sulfate. Sulfate-labeled proteoglycans made by these cells were extracted with 4 M guanidine-hydrochloride and purified by CsCl density gradient centrifugation, gel filtration chromatography, and DEAE-cellulose chromatography. Eight individual species were resolved, of which five were subjected to further analysis. One low-density (less than 1.35 g/ml) proteoglycan, with a Kav on Sepharose Cl-4B = 0.34 contained heparan sulfate chains of Mr = 20,000. The other four proteoglycans, with Kav on Sepharose Cl-4B of 0.04, 0.35 (two), and 0.44, contained predominantly chondroitin sulfate chains with Mr ranging from 30,000 to 40,000. To determine possible functions of these proteoglycans, cultures were grown in medium containing 1 mM 4-methyl-umbelliferyl-beta-D-xyloside. The drug inhibited 35SO4 proteoglycan accumulation in the cell layer by approximately 90%. Drug-treated cultures exhibited several developmental abnormalities, including decreased migration of fibroblast-like cells, abnormal morphology of these cells, and decreased myelination of axons by Schwann cells.

An antiserum to the sea urchin 20 S egg dynein reacts with embryonic ciliary dynein but it does not react with the mitotic apparatus

Unfertilized sea urchin eggs contain one or more dynein-like enzymes which may be able to serve as microtubule translocators during embryonic development. There are at least two interesting possibilities for the function of the egg dynein: the enzyme may be involved in cytoplasmic microtubule movement such as mitotic spindle anaphase motion; or the enzyme may be a stored precursor for the dynein that functions in embryonic cilia, which are expressed and highly motile at the blastula stage of development. In order to determine directly the distribution and possible function of one of the previously described egg dyneins, the latent-activity 20 S egg dynein (Asai and Wilson, 1985), an antiserum was produced which was highly reactive with the important high Mr polypeptides of 20 S dynein. This antiserum reacted in "Western" immunoblots and in dot-blotting experiments with egg dynein and with embryonic ciliary dynein, but it did not react with any component of sperm flagella. Indirect double immunofluorescence microscopy demonstrated that the anti-20 S antiserum could brightly stain embryonic cilia but it did not stain the sperm flagella from the same sea urchin species. Under the same conditions that the antiserum stained cilia, anti-20 S did not stain the mitotic apparatus but it did appear to stain the cortical region of the dividing egg. In a time-course experiment, the antigen reactive with the anti-20 S antiserum gradually accumulated in the developing early sea urchin embryo. The most significant increase in the apparent concentration of the 20 S dynein occurred just prior to embryonic ciliation and during a period when the mitotic activity of the embryo was in decline. These results lead to two conclusions. First, ciliary dynein and sperm flagellar dynein, although derived from very similar organelles and from the same species of sea urchin, are immunologically distinct. Second, the 20 S egg dynein may be a stored precursor of embryonic ciliary dynein and does not appear to be a component of the mitotic apparatus.

Motile detergent-extracted cells of Tetrahymena and Chlamydomonas

Tetrahymena and Chlamydomonas cells treated with high (0.25-0.5%) concentrations of the detergent Nonidet P-40 in appropriate buffers retain the shape of the intact cells but are devoid of any ciliary activity unless supplied with MgATP. ATP causes them to swim actively, with beat parameters and swimming patterns indistinguishable from those of intact cells. Both types of detergent-extracted cells are completely devoid of ciliary membranes. The Tetrahymena preparations also lack all cellular membranes, whereas cellular membranes remain intact in the Chlamydomonas preparations. Experiments demonstrating the effects of ATP, ADP, vanadate, erythro-9-[3-2-(hydroxynonyl)]-adenine, and Ca++ are described to illustrate the use of these detergent-extracted cells in research on ciliary motility.

The culture of chick embryo mesoderm cells in hydrated collagen gels

Chick embryo mesoderm cells are various stages of differentiation were cultured in three-dimensional matrices of hydrated collagen. The tissues used were: stage 5 mesoderm from regions adjacent to the primitive streak; stage 12 mesoderm, comprising somitic, unsegmented (segmental plate) and lateral plate mesoderm; and stage 18 sclerotome. Explants were examined by phase contrast microscopy, including time-lapse, and scanning and transmission electron microscopy. The cells showed an increased ability to adhere to, and move in, the collagen gel with advancing stage. Of the stage 12 tissues, the unsegmented mesoderm was initially the slowest to grow out of the explant. Sclerotome cells showed by far the greatest ability to move within the gel. Where the collagen fibrils were randomly oriented, the cell morphology was polypodial and advancing lamellipodia showed clear undulations at their leading edges. A distinction was drawn between these undulations and the classical major ruffles which are seen in two-dimensional culture to uplift and pass back along the cell surface. The latter were not seen in the collagen matrix and were presumably suppressed by the three-dimensional culture configuration while the leading edge undulations were not. Ultrastructural examination showed that the cells possessed patches of amorphous material on their surface, which was sometimes interposed between the plasma membrane and collagen fibrils. Addition of hyaluronic acid (2 mg/ml) had an effect only the segmented mesoderm, where outgrowth was enhanced. Although the addition of plasma fibronectin (50 micrograms/ml) to the cultures did not affect any of the tissues, the removal of this substance, by antifibronectin antiserum or by the use of fibronectin depleted serum, inhibited outgrowth in most cases. The only tissue not reproducibly inhibited in this way was sclerotome. Alignment of the collagen fibres by the explants was observed, accompanied by an elongation of the outgrowing cells which, in bipolar form, preferentially moved up and down the aligned tracts. Scanning electron microscopy suggested that cell processes attached to, and presumably exerted tension on, bundles of fibrils thereby pulling them into line. Cell-to-cell contact was not accompanied by contact paralysis as judged by time-lapse micrography.

Effects of exogenous proteins on cytoplasmic streaming in perfused Chara cells

Cytoplasmic streaming in characean algae is thought to be generated by interaction between subcortical actin bundles and endoplasmic myosin. Most of the existing evidence supporting this hypothesis is of a structural rather than functional nature. To obtain evidence bearing on the possible function of actin and myosin in streaming, we used perfusion techniques to introduce a number of contractile and related proteins into the cytoplasm of streaming Chara cells. Exogenous actin added at concentrations as low as 0.1 mg/ml is a potent inhibitor of streaming. Deoxyribonuclease I (DNase I), an inhibitor of amoeboid movement and fast axonal transport, does not inhibit streaming in Chara. Fluorescein-DNase I stains stress cables and microfilaments in mammalian cells but does not bind to Chara actin bundles, thus suggesting that the lack of effect on streaming is due to a surprising lack of DNase I affinity for Chara actin bundles. Heavy meromyosin (HMM) does not inhibit streaming, but fluorescein-HMM (FL-HMM), having a partially disabled EDTA ATPase, does. Quantitative fluorescence micrography provides evidence that inhibition of streaming by FL-HMM may be due to a tendency for FL-HMM to remain bound to Chara actin bundles even in the presence of MgATP. Perfusion with various control proteins, including tubulin, ovalbumin, bovine serum albumin, and irrelevant antibodies, does not inhibit streaming. These results support the hypothesis that actin and myosin function to generate cytoplasmic streaming in Chara.

Analysis of the movement of Chlamydomonas flagella:" the function of the radial-spoke system is revealed by comparison of wild-type and mutant flagella

The mutation uni-1 gives rise to uniflagellate Chlamydomonas cells which rotate around a fixed point in the microscope field, so that the flagellar bending pattern can be photographed easily. This has allowed us to make a detailed analysis of the wild-type flagellar bending pattern and the bending patterns of flagella on several mutant strains. Cells containing uni-1, and recombinants of uni-1 with the suppressor mutations, suppf-1 and suppf-3, show the typical asymmetric bending pattern associated with forward swimming in Chlamydomonas, although suppf-1 flagella have about one-half the normal beta frequency, apparently as the result of defective function of the outer dynein arms. The pf-17 mutation has been shown to produce nonmotile flagella in which radial spoke heads and five characteristic axonemal polypeptides are missing. Recombinants containing pf-17 and either suppf-2 or suppf-3 have motile flagella, but still lack radial-spoke heads and the associated polypeptides. The flagellar bending pattern of these recombinants lacking radial-spoke heads is a nearly symmetric, large amplitude pattern which is quite unlike the wild-type pattern. However, the presence of an intact radial-spoke system is not required to convert active sliding into bending and is not required for bend initiation and bend propagation, since all of these processes are active in suppfpf-17 recombinants. The function of the radial-spoke system appears to be to convert the symmetric bending pattern displayed by these recombinants into the asymmetric bending pattern required for efficient swimming, by inhibiting the development of reverse bends during the recovery phase of the bending cycle.

Two different monoclonal antibodies to alpha-tubulin inhibit the bending of reactivated sea urchin spermatozoa

Two monoclonal antibodies reactive for alpha-tubulin but not for beta-tubulin have been prepared, characterized in terms of their relative binding to tubulins from different sources by a solid-phase binding assay, immunoautoradiography, and indirect immunofluorescence, and utilized to study flagellar motility. Our results demonstrate that alpha-tubulins from different species, and even from different tissues of the same species, are nonidentical. Especially interesting was the observation that one of the antibodies, Ab2, immunofluorescently stained microtubules of chick embryo fibroblast cells, but was completely unreactive for microtubules of rat kangaroo (PtK2) fibroblasts; a different antibody, Ab1, stained both cell types. Results of these and additional experiments clearly show that Ab1 and Ab2 recognize discrete and different epitopes on alpha-tubulin. Monoclonal antitubulins Ab1 and Ab2 each inhibited the bend amplitude of reactivated sea urchin spermatozoa without affecting beat frequencies or the ability of the outer doublet microtubules to slide past each other in elastase-digested models. These results, together with those obtained previously using rabbit polyclonal antitubulin antibodies [Asai and Brokaw, 1980], demonstrate that inhibition of bend amplitude is a common property of antitubulin antibodies and is not due to the binding of antibodies to one specific site on the axoneme. Our results suggest that tubulin subunit conformational changes may occur on the outer doublet lattice and may be integrally involved in the mechanism and control of flagellar bending.

Effects of antibodies against dynein and tubulin on the stiffness of flagellar axonemes

Antidynein antibodies, previously shown to inhibit flagellar oscillation and active sliding of axonemal microtubules, increase the bending resistance of axonemes measured under relaxing conditions, but not the bending resistance of axonemes measured under rigor conditions. These observations suggest that antidynein antibodies can stabilize rigor cross-bridges between outer-doublet microtubules, by interfering with ATP-induced cross-bridge detachment. Stabilization of a small number of cross-bridge appears to be sufficient to cause substantial inhibition of the frequency of flagellar oscillation. Antitubulin antibodies, previously shown to inhibit flagellar oscillation without inhibiting active sliding of axonemal microtubules, do not increase the static bending resistance of axonemes. However, we observed a viscoelastic effect, corresponding to a large increase in the immediate bending resistance. This immediate bending resistance increase may be sufficient to explain inhibition of flagellar oscillation; but several alternative explanations cannot yet be excluded.

Dynein binding to microtubules containing microtubule-associated proteins

Microtubule-associated proteins (MAPs), isolated from brain tubulin, bound to and saturated outer fibers of Chlamydomonas flagella. MAPs present on these microtubules prevented the subsequent recombination of dynein. MAPs also bound to intact axonemes and thus did not specifically bind to the dynein binding sites on the A subfiber. A molar ratio of 1 mole MAP2 per 27 moles tubulin dimers at saturation of the outer fibers with MAP2 suggested that MAPs could effectively interfere with dynein recombination only if the MAPs were near the dynein binding sites to sterically prevent binding. However, electron microscopic observations indicated that MAPs were not localized but, instead, were dispersed around the outer fibers. In addition, MAP2 present at saturating amounts on in vitro assembled brain microtubules had no significant effect on dynein binding. Dynein-decorated microtubules contained clusters of arms suggesting that there may be cooperative interaction between the arms during dynein binding. Because the A subfiber of axonemes contains sites to which dynein preferentially attaches, MAPs may prevent recombination by interfering with cooperative binding to these specific sites. Dynein presumably binds with equal affinity to any protofilament on in vitro assembled microtubules, and, therefore, the MAPs may not be capable of effectively interfering with cooperative binding of dynein to these microtubules.