Effects of calcium ions on triton-extracted lamellibranch gill cilia: Ciliary arrest response in a model system

Ion channels and calcium signaling in motile cilia

The beating of motile cilia generates fluid flow over epithelia in brain ventricles, airways, and Fallopian tubes. Here, we patch clamp single motile cilia of mammalian ependymal cells and examine their potential function as a calcium signaling compartment. Resting motile cilia calcium concentration ([Ca²⁺] ~170 nM) is only slightly elevated over cytoplasmic [Ca²⁺] (~100 nM) at steady state. Ca²⁺ changes that arise in the cytoplasm rapidly equilibrate in motile cilia. We measured Ca_V1 voltage-gated calcium channels in ependymal cells, but these channels are not specifically enriched in motile cilia. Membrane depolarization increases ciliary [Ca²⁺], but only marginally alters cilia beating and cilia-driven fluid velocity within short (~1 min) time frames. We conclude that beating of ependymal motile cilia is not tightly regulated by voltage-gated calcium channels, unlike that of well-studied motile cilia and flagella in protists, such as Paramecia and Chlamydomonas.

DOI:http://dx.doi.org/10.7554/eLife.11066.001

Certain specialized cells in the brain, airways and Fallopian tubes have large numbers of hair-like structures called motile cilia on their surface. By beating in a synchronized manner, these cilia help to move fluids across the surface of the cells: for example, cilia on lung cells beat to clear mucus away, while those in the brain help the cerebrospinal fluid to circulate.

Motile cilia in mammals are structurally similar to the flagella that propel sperm cells and certain single-celled organisms around their environments. These flagella have specialized pore-forming proteins called ion channels in their membrane through which calcium ions can move. This flow of calcium ions controls the beating of the flagella. However, it is unclear whether a similar movement of calcium ions across the cilia membrane regulates motile cilia beating in mammals.

Doerner et al. have now used a method called patch clamping to study the movement of calcium ions across the membrane of the motile cilia found on a particular type of mouse brain cell. This revealed that unlike flagella, these motile cilia have very few voltage-gated calcium channels; instead, the vast majority of these ion channels reside in the main body of the cell. Furthermore, the level of calcium ions in the motile cilia follows changes in calcium ion levels that originate in the cell body.

Overall, Doerner et al. demonstrate that the activity of voltage-gated calcium channels does not control the beating rhythm of the motile cilia in the mouse brain or how quickly the fluid above the cell surface moves. Future work should investigate whether this is also the case for the cells that line the trachea and Fallopian tubes.

DOI:http://dx.doi.org/10.7554/eLife.11066.002

Calcium sensors of ciliary outer arm dynein: functions and phylogenetic considerations for eukaryotic evolution

The motility of eukaryotic cilia and flagella is modulated in response to several extracellular stimuli. Ca(2+) is the most critical intracellular factor for these changes in motility, directly acting on the axonemes and altering flagellar asymmetry. Calaxin is an opisthokont-specific neuronal calcium sensor protein first described in the sperm of the ascidian Ciona intestinalis. It binds to a heavy chain of two-headed outer arm dynein in a Ca(2+)-dependent manner and regulates 'asymmetric' wave propagation at high concentrations of Ca(2+). A Ca(2+)-binding subunit of outer arm dynein in Chlamydomonas reinhardtii, the light chain 4 (LC4), which is a Ca(2+)-sensor phylogenetically different from calaxin, shows Ca(2+)-dependent binding to a heavy chain of three-headed outer arm dynein. However, LC4 appears to participate in 'symmetric' wave propagation at high concentrations of Ca(2+). LC4-type dynein light chain is present in bikonts, except for some subclasses of the Excavata. Thus, flagellar asymmetry-symmetry conversion in response to Ca(2+) concentration represents a 'mirror image' relationship between Ciona and Chlamydomonas. Phylogenetic analyses indicate the duplication, divergence, and loss of heavy chain and Ca(2+)-sensors of outer arm dynein among excavate species. These features imply a divergence point with respect to Ca(2+)-dependent regulation of outer arm dynein in cilia and flagella during the evolution of eukaryotic supergroups.

Measurement of the force and torque produced in the calcium response of reactivated rat sperm flagella

Rat sperm that are demembranated with Triton X-100 and reactivated with Mg-ATP show a strong mechanical response to the presence of free calcium ion. At pCa < 4, the midpiece region of the flagellum develops a strong and sustained curvature that gives the cell the overall appearance of a fishhook [Lindemann and Goltz, 1988: Cell Motil. Cytoskeleton 10:420-431]. In the present study, the force and torque that maintain the calcium-induced hook have been examined quantitatively. In addition, full-length and shortened flagella were manipulated to evaluate the plasticity of the hooks and determined the critical length necessary for maintaining the curvature. The hooks were found to be highly resilient, returning to their original configuration (>95%) after being straightened and released. The results from manipulating the shortened flagella suggest that the force holding the hook in the curved configuration is generated in the basal 60 microm of the flagellum. The force required to straighten the calcium-induced hooks was measured with force-calibrated glass microprobes, and the bending torque was calculated from the measured force. The force and torque required to straighten the flagellum were found to be proportional to the change in curvature of the hooked region of the flagellum, suggesting an elastic-like behavior. The average torque to open the hooks to a straight position was 2.6 (+/-1.4) x 10(-7) dyne x cm (2.6 x 10(-14) N x m) and the apparent stiffness was 4.3 (+/-1.3) x 10(-10) dyne x cm(2) (4.3 x 10(-19) N x m(2)). The stiffness of the hook was determined to be approximately one quarter the rigor stiffness of a rat sperm flagellum measured under comparable conditions.

A model for flagellar motility

Experimental investigation has provided a wealth of structural, biochemical, and physiological information regarding the motile mechanism of eukaryotic flagella/cilia. This chapter surveys the available literature, selectively focusing on three major objectives. First, it attempts to identify those conserved structural components essential to providing motile function in eukaryotic axonemes. Second, it examines the relationship between these structural elements to determine the interactions that are vital to the mechanism of flagellar/ciliary beating. Third, the vital principles of these interactions are incorporated into a tractable theoretical model, referred to as the Geometric Clutch, and this hypothetical scheme is examined to assess its compatibility with experimental observations.

Dynein from serotonin-activated cilia and flagella: extraction characteristics and distinct sites for cAMP-dependent protein phosphorylation

Serotonin, an activator of adenylate cyclase, stimulates motility in molluscan gill cilia and sperm flagella. To determine and compare potential targets of cAMP action, dynein was prepared from the lateral gill.cilia and sperm flagella of the mussel Mytilus edulis and the clam Spisula solidissima. In the flagella of both species, high-salt extraction removes about half of the ATPase activity, half of the alpha and beta heavy chains, and the outer arms. The dynein from both species sediments at 18–20 S, contains two or three intermediate chains, and three light chains. High-salt plus detergent removes most of the remaining dynein ATPase, alpha and beta heavy chains, and inner arms, also yielding a stable 18–20 S particle. In gill cilia of both species, high-salt extraction removes only 12–18% of the ATPase, up to 1/3 of the alpha heavy chains, an equivalent amount of beta heavy chain, and a subset of the outer arms. The dynein sediments at 18–20 S and, in Spisula, the heavy, intermediate, and light chains precisely co-sediment. High-salt plus detergent removes another 1/3 of the alpha heavy chains, an equivalent amount of beta heavy chain, and the remaining outer arms. The ATPase sediments mainly as a 13–14 S form showing considerable dissociation of co-sedimenting intermediate and light chains. The inner arms and at least half of the ciliary dynein ATPase activity remain unextractable, corresponding in mass mainly to an apparent beta heavy chain that is vanadate-cleavable. Cyclic AMP-dependent, calcium-independent phosphorylation takes place on specific dynein light chains in cilia but on only the dynein alpha heavy chain in flagella. Pre-activation of the flagella prevents subsequent addition of labeled phosphate. Phosphorylation has no effect on the steady-state ATPase properties. The single phosphate added to the flagellar alpha chain is located within the LUV1 vanadate photocleavage fragment. Considering the probable locus of the light chains and the site of the alpha heavy chain phosphorylation, both beyond the active site and toward the base of the molecule, these distinct phosphorylations may regulate dynein action by modulating arm flexibility or interaction.

Reactivation of newt lung cilia: evidence for a possible temperature- and MgATP-induced activation mechanism

Optimal conditions have been developed for the isolation and reactivation of highly coupled, demembranated ciliary axonemes from newt lungs [Hard, Cypher, and Schabtach, 1988, Cell Motil. Cytoskeleton 10:271-284]. In the present study, the motility of these cilia was further characterized by examining the effects of nucleotides, divalent cations, and temperature on beat frequency. When exposed to a reactivating solution containing Mg2+ and ATP, nearly 100% of the axonemes were motile and beat at frequencies of 0-50 Hz, depending on [MgATP] and temperature. Divalent cations were required for movement, with Mg2+ 2-3 times more effective than Ca2+. There was no absolute requirement for Ca2+ for motility. The beat frequencies obtained with fixed ATP and varying Mg2+ concentrations indicate that MgATP serves as the actual substrate. The effects of MgATP on beat frequency depended on the degree of mechanochemical coupling and temperature. When highly coupled preparations were reactivated at 21 degrees C, double reciprocal plots of beat frequency vs. [MgATP] were biphasic with extrapolated Fmax values of 22 and 44.8 Hz. However, when reactivated at 10 degrees C and 30 degrees C, linear plots were generated with Fmax values of 18.3 and 48.9 Hz, respectively. The beat frequencies of cultured cells and reactivated axonemes also varied biphasically with temperature. Our data suggest that newt lung respiratory cilia possess an intra-axonemal activation mechanism involving a temperature- and MgATP-induced transition between two distinct states whose maximum beat frequencies differ by 200-300%.

Calcium sensors in sea urchin sperm flagella

The asymmetry of ATP-reactivated flagellar bending waves of Triton-demembrated sea urchin spermatozoa has been measured over a range of free Ca2+ ion concentrations from 10(-9) to 10(-4) M. Detailed examination of the gradual response of asymmetry to Ca2+ ion concentration over this wide range indicates the presence of two Ca2+ sensors. A high-affinity sensor operates at Ca2+ concentrations near 10(-7.5) M. A lower-affinity sensor operates at Ca2+ concentrations above 10(-6) M, in the typical range for calmodulin-mediated responses. Incubation of demembranated sperm flagella at high Ca2+ concentrations to release calmodulin is required to enable these Ca2+ responses to be observed. This treatment also causes a decrease in the apparent affinity of the flagella for calmodulin, as determined by measuring the increase in asymmetry in response to addition of exogenous calmodulin at low Ca2+ concentration.

Control of reactivation and microtubule sliding by calcium, strontium, and barium in detergent-extracted macrocilia of Beroë

Macrocilia of the ctenophore Beroë are activated to beat continuously in the normal direction by membrane-mediated Ca2+ influx (Tamm: Journal of Comparative Physiology [A] 163:23-31, 1988a). Using saponin or Brij-58 permeabilized models of macrocilia, we show that ATP-reactivation of beating requires microM levels of free Ca2+, Ba2+, or Sr2+. Isolated macrocilia beat initially in reactivation solution (RS) containing Ca2+, Ba2+, or Sr2+ and then undergo microtubule sliding disintegration without added proteases. Addition of protease inhibitors to RS + 10(-5) M Ca2+ prevents sliding disruption. Pretreatment in wash solution (containing 1 mM EGTA) without protease inhibitors, followed by RS + 10(-5) M Ca2+ with protease inhibitors results in extensive sliding disintegration. However, treatment in wash solution followed by RS + protease inhibitors does not induce sliding. Therefore, Ca2+ is not required for proteolysis by endogenous proteases, but is necessary for sliding disintegration. Local iontophoretic application of Ca2+, Ba2+, or Sr2+ to permeabilized macrocilia in RS lacking these cations triggers motility and/or sliding disintegration. Extrusion of microtubules occurs from the tip or the base, depending on whether or not the macrocilium remains attached to its large actin bundle. Thin sheets of microtubules telescope out initially, due to synchronized sliding of subsets of doublet microtubules from parallel rows of axonemes. Macrocilia are one of the first examples of ATP-induced microtubule sliding which retains Ca2+ sensitivity. In addition, the finding that Ba2+ and Sr2+ also trigger active sliding provides an additional method for investigating the control of dynein-powered microtubule movements.

Isolation and reactivation of highly-coupled newt lung cilia

The paired lungs of the newt, Taricha granulosa, are simple, unbranched sacs, 3.5-5.0 cm in length. The inner epithelium overlying the pulmonary vein is differentiated into a mucociliary tract that extends the entire length of the lung. Populations of single, demembranated ciliary axonemes, 12-13 micron in length, can be isolated by extracting whole lungs or primary cultures of the ciliated epithelium with Triton X-100. The motile capabilities of the isolated axonemes are the highest yet obtained for any ciliary model. When exposed to a suitable reactivating medium containing Mg2+ and ATP, nearly 100% of the axonemes become motile. Uniform reactivation of high quality requires short extraction times, minimization of mechanical damage, and strict adherence to optimal conditions throughout the extraction, storage, and reactivation procedures. Significant deviations from either pH 7.0 or 0.12 M salt can lead to a rapid, irreversible decrease in the beat frequency of reactivated axonemes. Both DTT and EDTA serve to stabilize their motility. The isolated axonemes beat at 29.5 Hz in the presence of 1.75 mM ATP at 21 degrees C, matching the beat frequencies measured for cultured cells at the same temperature. With 5 mM ATP, beat frequencies over 40 Hz are measured. Our results show that neither the plasma membrane, accessory structures, nor hydrodynamic coupling of cilia are required for this activity and imply that the lack of these factors is not responsible for the low motile capabilities of ciliary models isolated previously.

EGTA induces prolonged summed depolarizations in Mytilus gill coupled ciliated epithelial cells: implications for the control of ciliary motility

Abfrontal ciliated cells of Mytilus edulis gill beat when mechanically stimulated, a consequence of a Ca++-based generator potential and regenerative response. In contrast, the lateral ciliated epithelial cells arrest when stimulated, a consequence of a Ca++-based generator potential and a Na+/Ca++-based regenerative response. Iontophoretic injection of EGTA in abfrontal cells, followed by mechanical stimulation, results in a large, prolonged depolarization that returns to the resting level stepwise. It has been hypothesized that this phenomenon is caused by successive Ca++-dependent repolarizations in coupled cells, first in adjacent cells and then in the injected cell, in accord with relative EGTA loading. We have now demonstrated this same stepwise repolarization phenomenon in the Na+/Ca++-dependent lateral ciliated cells. In this case, each repolarization step is often preceded by a small spike. With either cell type, using two-electrode recording techniques, we can detect the stepwise repolarization in distant cells, proportionately decremented when the second (KCl) electrode is some distance from the injection (EGTA) electrode and stimulus. When force is applied between the electrodes and nearest the KCl electrode, a greater initial response is recorded from this electrode, presumably resulting from depolarization of its impaled cell, prolonged by EGTA diffusion through the intervening cell junctions. The subsequent repolarization steps are of approximately the same size, suggesting repolarization of cells between the two electrodes. These observations are consistent with the cell coupling/EGTA loading hypothesis and indicate that both cell types mediate repolarization through Ca++ and propagate ciliary beat or arrest through intracellular coupling.

Control of ciliary beat frequency in the gill of Mytilus--I. Activation of the lateral cilia by cyclic AMP

The effect of cyclic AMP on the beat frequency of the lateral cilia on the gill of Mytilus edulis was investigated. Dibutyryl cyclic AMP (0.1 mM) weakly stimulated the cilia to beat. The activation was augmented by 1 mM theophylline. The cilia were hardly activated by cyclic AMP (0.1 mM) but a strong activation was observed when it was applied with saponin (0.0025-0.01% w/v) and theophylline (1 mM). The results suggest that cyclic AMP is involved in the mechanism of ciliary activation by 5-hydroxytryptamine.

Control of ciliary beat frequency in the gill of Mytilus--II. Effects of saponin and Brij-58 on the lateral cilia

The effects of saponin and Brij-58 on the beat activation of the lateral cilia on the gill of Mytilus edulis were investigated. The ciliary activation by 5-hydroxytryptamine (5HT) decreased as the saponin-induced permeabilization progressed, increasing the reactivation of the ciliary beat by extracellularly applied ATP (1 mM). The cilia were activated by 5HT even after the treatment with saponin (0.01 and 0.02% w/v) or Brij-58 (0.07%) rendered the preparation capable of the reactivation by ATP. The saponin treatment itself stimulated the beat of the cilia. Theophylline (1 mM) augmented the saponin-induced activation of the cilia.

Mechanical stimulation activates beating in calcium-arrested lateral cilia of Mytilus edulis gill

Lateral cilia of Mytilus edulis gill arrest upon mechanical stimulation, the result of calcium influx. A mechanical stimulus that deflects these cilia toward the effective stroke, and is normally sufficient to cause transient arrest in beating lateral cilia or transient movement into the recovery stroke in quiescent cilia, initiates beating in Ca2+ ionophore-arrested cilia at 9-15 Hz, for periods as long as 30 s. This movement is restricted to the stimulated cilia and the beat pattern appears constrained in the first half of the beat cycle. Application of dopamine causes ciliary arrest in the presence (but not absence) of Ca2+ and mechanical stimulation will also activate such cilia to beat. In the presence of ATP, mechanical stimulation of detergent-permeabilized lateral cell models arrested in the presence of 50 microM Ca2+ will also cause activation comparable in frequency, duration, and beat pattern to that seen in Ca2+-arrested cells, but the initiation is more difficult. Upon application of ionophore in Ca2+-free (EGTA) seawater, the cilia become quiescent, stopped at the end of the recovery stroke. Mechanical stimulation will cause activation of beat, with a similar range of frequencies and duration as in Ca2+-arrested lateral cilia, but the beat pattern is normal and cilia of adjacent cells may also beat, presumably initiated by mechanical coupling. Gently lifting cilia at their basal ends, using small, slow movements of a mechanical probe, will initiate several beat cycles in quiescent lateral cilia but will cause Ca2+-arrested cilia to 'snap' into the effective stroke and back.(ABSTRACT TRUNCATED AT 250 WORDS)

Electrophysiological control of ciliary motor responses in the ctenophore Pleurobrachia

Prey capture by a tentacle of the ctenophore Pleurobrachia elicits a reversal of beat direction and increase in beat frequency of comb plates in rows adjacent to the catching tentacle (Tamm and Moss 1985). These ciliary motor responses were elicited in intact animals by repetitive electrical stimulation of a tentacle or the midsubtentacular body surface with a suction electrode. An isolated split-comb row preparation allowed stable intracellular recording from comb plate cells during electrically stimulated motor responses of the comb plates, which were imaged by high-speed video microscopy. During normal beating in the absence of electrical stimulation, comb plate cells showed no changes in the resting membrane potential, which was typically about -60 mV. Trains of electrical impulses (5/s, 5 ms duration, at 5-15 V) delivered by an extracellular suction electrode elicited summing facilitating synaptic potentials which gave rise to graded regenerative responses. High K+ artificial seawater caused progressive depolarization of the polster cells which led to volleys of action potentials. Current injection (depolarizing or release from hyperpolarizing current) also elicited regenerative responses; the rate of rise and the peak amplitude were graded with intensity of stimulus current beyond a threshold value of about -40 mV. Increasing levels of subthreshold depolarization were correlated with increasing rates of beating in the normal direction. Action potentials were accompanied by laydown (upward curvature of nonbeating plates), reversed beating at high frequency, and intermediate beat patterns. TEA increased the summed depolarization elicited by pulse train stimulation, as well as the size and duration of the action potentials. TEA-enhanced single action potentials evoked a sudden arrest, laydown and brief bout of reversed beating. Dual electrode impalements showed that cells in the same comb plate ridge experienced similar but not identical electrical activity, even though all of their cilia beat synchronously. The large number of cells making up a comb plate, their highly asymmetric shape, and their complex innervation and electrical characteristics present interesting features of bioelectric control not found in other cilia.

Cyclic AMP and calcium in the differential control of Mytilus gill cilia

Lateral (L) cilia of Mytilus gill are activated by serotonin which, in molluscan systems, is known to activate adenylate cyclase. Triton-extracted models of L-cells, arrested at greater than 10(-6) M Ca++, are stimulated to beat by the addition of 10(-5) M cAMP while still under Ca++ arrest conditions, suggesting that cAMP-activation is not mediated by alterations of Ca++ levels. Using isolated, permeabilized cilia, we find, independent of [Ca++], that cAMP-dependent protein phosphorylation in L-cilia occurs uniquely and reversibly on three low molecular weight polypeptides of 23,000, 18,000, and 14,000 daltons. Phosphorylation is maximal at cAMP concentrations above 0.5 microM. The phosphorylated chains partially co-extract at high salt with a 14S dynein fraction and have approximately the same molecular weights as reported for dynein light chains. Such conditions mainly extract the outer dynein arm, about 40% of the Mg++-ATPase activity, and a corresponding amount of the cAMP phosphorylated chains. However, the three polypeptides sediment together at 10-11S, clearly separable from the 14S dynein ATPase. Using a gel-overlay technique, we find that calmodulin binds to axonemal polypeptides of L-cilia with molecular weights of 18,000 and 13,000, independent of Ca++, while in mixed-population cilia, only a 12,000 dalton chain binds calmodulin, in a Ca++ dependent manner. In neither case are calmodulin binding proteins found in the high salt fraction containing the cAMP-dependent phosphorylated chains, indicating that, in spite of some similarity in molecular weight, the cAMP-phosphorylated and calmodulin binding polypeptides are different. Also, double-labelling indicates that only the 18,000 dalton chains co-migrate.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-dependent phosphatidylinositol phosphorylation in lamellibranch gill lateral cilia

Pure lateral (L) cilia may be separated from the remaining (R) cilia types of Mytilus edulis gill by serotonin activation after hypertonic shock. The two classes of cilia were permeabilized with 0.012% Triton X-100 and incubated with 32P-labeled ATP at low Ca++ (10(-7) M), where L cilia beat, or in high Ca++ (2-20 microM), where L cilia arrest but R cilia are active. The labeled cilia were separated into axoneme and membrane-matrix fractions by detergent extraction, subjected to SDS-PAGE on 5-15% gels, and autoradiographed. Neither cilia type undergoes Ca++-dependent phosphorylation of specific proteins, suggesting that neither Ca++-induced arrest in L cilia nor the Ca++ activation of other cilia is phosphorylation-dependent. However, lipid phosphorylation in L cilia is highly Ca++-dependent. Identified by thin-layer chromatography, the phospholipid that is phosphorylated in a Ca++-dependent manner is phosphatidylinositol 4-phosphate (PIP), yielding the 4,5-bisphosphate (PIP2). PIP2 increases at least 3-fold under Ca++-arrest conditions. Aequipecten gill lateral cilia, which require higher Ca++ levels for arrest, show even more striking changes. In both cases, the effect is maximal at micromolar Ca++ levels. Phosphorylation of other lipids is Ca++-independent. In the Ca++-insensitive or activated R cilia, PIP2 levels are intermediate, increasing only marginally with increased [Ca++]. The formation of PIP2 in response to Ca++, as opposed to its breakdown to form inositol 1,4,5-trisphosphate and diacylglycerol, may be characteristic of a Ca++ transport system. Mechanically sensitive, the L cilia arrest as a consequence of an inward flux of Ca++ ions, acting directly on the axoneme.(ABSTRACT TRUNCATED AT 250 WORDS)

The antagonistic effects of 5-hydroxytryptamine and methylxanthine on the gill cilia of Mytilus edulis

The laterofrontal (LF) cirri on isolated gill filaments of Mytilus edulis, prepared in natural seawater, are active and initially beat with an average frequency of about 8 Hz (with a range of 6-14 Hz). However, the lateral (L) cilia on these filaments are arrested in a position at the end of their recovery stroke. Perfusion of the filament with artificial seawater (ASW), with or without 1% ethanol, has little or no biological effect on the activity of the LF cirri, although a transitory decrease in frequency often accompanies the perfusion process. The L cilia remain arrested during perfusion with ASW. The exposure of the gill to low levels of 5-hydroxytryptamine (5HT) (10(-8) less than 5HT less than 10(-7) M) has no effect on the activity of the LF cirri but stimulates the L cilia to beat. Exposure to higher concentrations of 5HT (greater than 10(-7) M) elevates the beat frequency of the L cilia and simultaneously inhibits the activity of the LF cirri, leading to their arrest in a position at the end of the effective stroke. This arrest of the LF cirri occurs as the L cilia attain a 5HT-induced beat frequency between 12 to 14 Hz. The influence of 5HT on the L cilia and the LF cirri can be reversibly mimicked or enhanced by the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX). A concentration of 0.5 mM IBMX mimics low 5HT concentrations (about 10(-7) M) by stimulating the L cilia to beat without affecting the beat frequency of the LF cirri. A combination of 10(-7) M 5HT and 0.5 mM IBMX in ASW mimics high (greater than 10(-6) M) 5HT concentrations by arresting the LF cirri and increasing the beat frequency of the L cilia. Under these conditions, the threshold of the LF cirri arrest response is again found to occur as the L cilia attain a beat frequency of 12-14 Hz. These results suggest that the mechanisms of LF cirri arrest and L cilia activation are mediated by 5HT-induced changes in intracellular cyclic AMP levels.

Isolation of newt lung ciliated cell models: characterization of motility and coordination thresholds

Demembranated ciliated cell models are useful for studying mechanisms responsible for the regulation of ciliary coordination and waveform. This paper describes procedures for isolating ciliated cells from the newt, Taricha granulosa, by trypsin dissociation, their subsequent demembranation by Triton X-100, and their reactivation with MgATP to produce highly motile, coordinated, ciliated cell models. Reactivation of cell models with a high degree of mechanochemical coupling depended on avoiding mechanical damage and maintaining optimal conditions during all stages of isolation and reactivation. Highly motile models were prepared from cells incubated in trypsin, treated briefly with EDTA, separated by gentle agitation, and concentrated by centrifugation at low gravitational forces. Optimal demembranation and reactivation conditions were similar to those described previously for isolated newt lung axonemes. Under these conditions, nearly 100% of the models were reactivated when provided with MgATP and 90-95% beat with coordinated waves. The ciliary tufts beat at frequencies within the range measured in living cells and their reactivated motility was stable for at least 30 min at constant MgATP. These highly coupled models were used to show (1) that development of coordination in the ciliary tuft occurs at a higher substrate concentration range (10-25 microM) than that required to initiate motility per se (2-10 microM; (2) that outer dynein arms may not contribute to beat frequency at substrate concentrations below 35 microM; and (3) that vanadate has effects both on beat frequency and coordination of the tufts.

Evidence for a role of 13S axonemal ATPase in modulation of ciliary microtubule sliding

We recently demonstrated that elevated concentrations (greater than 20 microM) of the dynein substrate MgATP2- inhibit the spontaneous ATP-induced sliding disintegration of isolated, Triton-demembranated Tetrahymena cilia. We have used a turbidimetric assay (delta A350 nm) and electron microscopy to examine the effect of ATP on sliding disintegration when activated by other divalent cations. Mg2+, Ca2+, and Mn2+ are each capable of activating sliding, but only with Mg2+ and Mn2+ is disintegration inhibited by elevated ATP concentrations (greater than or equal to 1 mM). The two major ATPase activities obtained by KCl extraction of Tetrahymena axonemes differ in their cation specificities such that Mg2+ and Ca2+ activate the 21S dynein ATPase with equal efficiency, whereas the 13S axonemal ATPase activity is reduced by approximately 50% when CaATP2- replaces MgATP2- as substrate. With 1 mM MgATP2- as substrate, 10(-7) to 10(-2) M added CaCl2 alleviates the ATP-dependent inhibition of disintegration and likewise represses 13S MgATPase activity. In contrast, free Ca2+ has no effect on either the disintegration response or Mg-ATPase activity. In contrast to Triton-treated cilia, glycerinated cilia, which beat in 1 mM MgATP2-, are inhibited from beating by high CaATP2- concentrations. These substrate specificities suggest that concentration-dependent, substrate inhibition of sliding disintegration may be a manifestation of a physiological mechanism that is mediated by the 13S axonemal ATPase and that may function to modulate sliding during bend formation. However, the effects of added CaCl2 probably do not reflect a physiological mechanism for regulating beat parameters, but rather may result from CaATP2- competing for MgATP2- binding sites on the 13S ATPase, thereby blocking expression of the 13S ATPase.