Distribution of polyglutamylated tubulin in the flagellar apparatus of green flagellates

Polyglutamylation is a widely distributed posttranslational modification of tubulin that can be demonstrated either by biochemical analysis or by the use of specific antibodies like GT335. Western blotting using GT335 demonstrated that polyglutamylated tubulin is enriched in isolated basal apparatus of Spermatozopsis similis. Single- and double-labeling experiments, using indirect immunofluorescence and immunogold electron microscopy of isolated cytoskeletons of S. similis and Chlamydomonas reinhardtii, revealed that polyglutamylated tubulin was predominately present in the basal bodies and the proximal part of the axonemes. Using immunogold labeling of whole mounts of Spermatozopsis cytoskeletons, we obtained evidence for a predominant occurrence of polyglutamylated tubulin in the B-tubule of the axonemal doublets. Polyglutamylation occurs early during premitotic basal body assembly in S. similis, whereas the probasal bodies of Chlamydomonas, which are present through interphase, showed a reduced staining with GT335 indicating that polyglutamylation is involved in basal body maturation. During flagella regeneration of C. reinhardtii, polyglutamylation preceded detyrosination and became visible shortly after the onset of flagellar regeneration. In C. reinhardtii and S. similis polyglutamylated tubulin was absent or highly reduced in the flagellar transition region, a specialized part of the flagellum linking the basal body to the axoneme. Furthermore, the transition region and the neighboring part of the axoneme showed reduced staining with L3, an antibody directed against detyrosinated tubulin. The results indicate that differences in the modification pattern can occur in a confined area of individual microtubules. The deficiency of polyglutamylated and detyrosinated tubulin in the transition region could have functional implications for flagellar turnover or excision.     

A Ca(2+)- and voltage-modulated flagellar ion channel is a component of the mechanoshock response in the unicellular green alga Spermatozopsis similis

In flagellate green algae, behavioral responses to photo- and mechanoshock are induced by different external stimuli within 10-15 ms. In the accompanying changes in flagella beat, Ca(2+) has important regulatory roles. Although the axonemal Ca(2+) responsive elements are well characterized, analyses of flagellar channels involved in Ca(2+) signalling as well as other ion channels at the single-channel level were not yet conducted in green algae. To gain a further understanding of these important signaling elements in movement responses, intact flagella of Spermatozopsis similis were isolated and characterized and the solubilized flagellar membrane proteins were reconstituted into liposomes. We observed three types of channel activity, two of which were weakly anion and cation-selective and in the high-conductance regime typical for porin-like solute channels. The dominating channel activity was a voltage dependent, rectifying, low conductance (Lambda=80 pS in 50 mM KCl) cation-selective channel modulated by, and highly permeable to, Ca(2+) ions (SFC1: Spermatozopsis flagellar cation channel 1). Depolarizations necessary to activate SFC1 probably only occur in vivo during avoidance reactions of this alga. Ca(2+)-activation of SFC1 points to a direct link to Ca(2+)-mediated signaling pathway(s) in the flagella. Both the response to mechanoshock and SFC1 activity were inhibited by Gd(3+) and Ba(2+), thus supporting our assumption that SFC1 represents a major flagellar ion channel involved in this green algal avoidance reaction.     

THE CYTOSKELETON OF THE NAKED GREEN FLAGELLATE SPERMATOZOPSZS SIMILIS (CHLOROPHYTA): ANALYSIS OF ISOLATED BASAL APPARATUSES IN THE PARALLEL CONFIGURATION1,2

The biflagellate green alga Spermatozopsis similis is demonstrated to be a model organism for the biochemical and functional analysis of the basal apparatus. Basal apparatuses were isolated in the presence of 10⁻⁶ M Ca²⁺, which induces the reorientation of the basal bodies into the parallel state. Serial thin sectioning of enriched basal apparatuses stained with tannic acid reveals several novel details of the structure of the basal bodies, the distal connecting fiber, and the striated microtubule-associated fibers. We observed a pronounced difference in size of a striated fiber connecting the basal bodies to the five-stranded microtubular roots depending on its association with the developmentally older or younger basal body. Instead of a proximal connecting fiber, the proximal end of each basal body is associated with a striated triangular plate; these plates appear to serve as spacers for the basal bodies in the parallel and antiparallel configurations. We suggest that the plates play a role in maintaining basal body orientation during forward and backward swimming. The results are summarized in representative drawings of the basal apparatus.     

Microtubule sliding movement in tilapia sperm flagella axoneme is regulated by Ca2+/calmodulin-dependent protein phosphorylation

Demembranated euryhaline tilapia Oreochromis mossambicus sperm were reactivated in the presence of concentrations in excess of 10(-6) M Ca(2+). Motility features changed when Ca(2+) concentrations were increased from 10(-6) to 10(-5) M. Although the beat frequency did not increase, the shear angle and wave amplitude of flagellar beating increased, suggesting that the sliding velocity of microtubules in the axoneme, which represents dynein activity, rises with an increase in Ca(2+). Thus, it is possible that Ca(2+) binds to flagellar proteins to activate flagellar motility as a result of the enhanced dynein activity. One Ca(2+)-binding protein (18 kDa, pI 4.0), calmodulin (CaM), was detected by (45)Ca overlay assay and immunologically. A CaM antagonist, W-7, suppressed the reactivation ratio and swimming speed, suggesting that the 18 kDa Ca(2+)-binding protein is CaM and that CaM regulates flagellar motility. CaMKIV was detected immunologically as a single 48 kDa band in both the fraction of low ion extract of the axoneme and the remnant of the axoneme, suggesting that CaMKIV binds to distinct positions in the axoneme. It is possible that CaMKIV phosphorylates the axonemal proteins in a Ca(2+)/CaM-dependent manner for regulating the dynein activity. A (32)P-uptake in the axoneme showed that 48, 75, 120, 200, 250, 380, and 400 kDa proteins were phosphorylated in a Ca(2+)/CaM kinase-dependent manner. Proteins (380 kDa) were phosphorylated in the presence of 10(-5) M Ca(2+). It is possible that an increase in Ca(2+) induces Ca(2+)/CaM kinase-dependent regulation, including protein phosphorylation for activation/regulation of dynein activity in flagellar axoneme.     

Immune localization of calmodulin in the ciliated cells of hamster tracheal epithelium

Melachronous beating of cilia of epithelial surfaces of most respiratory airways moves the overlying mucous layer in a caudal direction. The molecular mechanisms controlling ciliary beat remain largely unknown. Calcium, an element in its cationic form, is ubiquitous in biological functions and its concentration is critical for ciliary beating. Calmodulin, a calcium-binding protein which regulates the activity of many enzymes and cellular processes, may regulate ciliary beating by controlling enzymes responsible for mechanochemical movement between adjacent peripheral microtubule doublets composing the ciliary axoneme. As a first step in describing a calmodulin-related controlling mechanism for ciliary beating, calmodulin was localized in the ciliated cells lining the respiratory tracts of hamsters by electron microscopy, using an indirect immunoperoxidase technique with anticalmodulin antibodies as the molecular probe. Thin-sections revealed calmodulin located on microtubules and dynein arms of the ciliary shaft, basal body, apical cytoskeletal microtubules, and plasma membranes in specimens fixed with 1 mM Ca+2. Specimens fixed with less Ca+2 (1 microM), Mn+2, Mg+2, and EGTA showed a diffuse pattern of calmodulin with loci of greatest densities on basal body microtubule triplets. Demembranated specimens showed a less specific localization on axonemal microtubules but only on cells fixed with Ca+2. Calmodulin, by binding calcium, may function in ciliary beating in the respiratory tract of mammals either directly or indirectly through its effects on the energy-producing enzymes and by control of Ca+2 flux through plasma membranes.     

Synchronous triggering of trout sperm is followed by an invariable set sequence of movement parameters whatever the incubation medium.

The movement of live trout spermatozoa is very brief (25 sec at 20 degrees C) and conditions have been developed to get synchronous initiation of sperm motility which allowed quantification of the major parameters of sperm movement during the motility phase. Recorded flagellar beat frequencies decreased steadily from values of 55 Hz at the beginning to 20 Hz at the end of the motility phase. Sperm forward velocities followed a similar pattern from 250 to 20 microns.sec-1 in the same conditions and the diameters of sperm trajectories were reduced from 370 to 40 microns. Thus none of the characteristics of sperm movement was constant during the motile phase which ended abruptly by a straightening of the flagella. The decrease in flagellar beat frequencies and sperm velocities are much greater than what could be extrapolated from the decrease of intracellular ATP (Christen R. et al: Eur. J. Biochem, 166: 667-671, 1987) or from measurements of ATP-dependence of reactivated sperm velocities (Okuno M. and Morisawa N.: In Biological Functions of Microtubules and Related Structures. New York: Academic Press, pp. 151-162, 1982). Therefore, the cessation of flagellar beating at 25 sec is not directly the result of the low concentration of intracellular ATP. The decrease in the diameters of sperm trajectories which occurred during the first part of the motility phase was correlated with [Ca]i measurements (Cosson M.P. et al, Cell Motil. Cytoskeleton, 14:424-434, 1989). The effect of Ca2+ at the axonemal level does not indicates that Ca2+ influx is previous to flagellar beating but rather suggests a classical Ca2+ regulation of the flagellar assymetry. The short duration of the motility phase and the characteristics of sperm movement were very similar in various conditions (high external K+, low pH media) where increased external Ca2+ or divalent ions were shown to overcome K+ and H+ inhibition of sperm motility, both conditions which have been shown to depolarize the plasma membrane potential (Gatti J.L. et al: J. Cell Physiol., 143:546-554, 1990). The present study of the parameters of sperm movement suggests that once motility is initiated, a defined set of axonemal events will take place whatever the external conditions.     

Calcium control of waveform in isolated flagellar axonemes of chlamydomonas

The effect of Ca(++) on the waveform of reactivated, isolated axonemes of chlamydomonas flagella was investigated. Flagella were detached and isolated by the dibucaine procedure and demembranated by treatment with the detergent Nonidet; the resulting axomenes lack the flagellar membrane and basal bodies. In Ca(++)-buffered reactivation solutions containing 10(-6) M or less free Ca(++), the axonemes beat with a highly asymmetrical, predominantly planar waveform that closely resembled that of in situ flagella of forward swimming cells. In solutions containing 10(-4) M Ca(++), the axonemes beat with a symmetrical waveform that was very similar to that of in situ flagella during backward swimming. In 10(-5) M Ca(++), the axonemes were predominantly quiescent, a state that appears to be closely associated with changes in axomenal waveform or direction of beat in many organisms. Experiments in which the concentrations of free Ca(++), not CaATP(--) complex were independently varied suggested that free Ca(++), not CaATP(--), was responsible for the observed changes. Analysis of the flagellar ATPases associated with the isolated axonemes and the nonidet- soluble membrane-matrix fraction obtained during preparation of the axonemes showed that the axonemes lacked the 3.0S Ca(++)-activated ATPase, almost all of which was recovered in the membrane-matrix fraction. These results indicate that free Ca(++) binds directly to an axonemal component to alter flagellar waveform, and that neither the 3.0S CaATPase nor the basal bodies are directly involved in this change.     

Photosensory transduction in the flagellated alga, Euglena gracilis I. Action of divalent cations, Ca2+ antagonists and Ca2+ ionophore on motility and photobehavior.

1. The flagellated alga, Euglena gracilis, swims forward essentially in a straight path under constant light intensity. Strong motility of the cells can be supported by Mg2+ alone but optimum motility is found in the presence of Mg2+, Ca2+ and K+. 2. Ca2+, Co2+, Mn2+ and Ba2+ induce a concentration-dependent increase in the rate at which the cells change the direction of their swimming path (a klinokinesis). Ni2+ immobilizes the flagellum. 3. On perception of a reduction ('step-down stimulus') in blue light intensity in their environment, Euglena rotate in place (tumble) for a finite period (the step-down photophobic response). 4. The duration of the tumbling is enhanced in the presence of divalent cations following the series Ca2+ greater than Ba2+ greater than Mn2+ greater than Co2+ greater than Mg2+ = Ni2+ = 0. 5. Neither the tumbling response in the presence of low concentrations of Ca2+ or the Ca2+-stimulated response is altered by verapamil (a Ca2+ conductance antagonist). The Ca2+ conductance/active transport antagonist, ruthenium red, is also inactive. 6. The Ca2+ ionophore, A23187, has little effect on flagellar activity in the absence of extracellular Ca2+. However, in the presence of A23187, Ca2+ induces a specific light-independent, concentration-dependent discontinuous tumbling response of the cells. 7. The data support a role for Ca2+ and Mg2+ in control of flagellar activity. However, blue light-induced tumbling behavior would not appear to be the direct result of a light-mediated alteration in the Ca2+ conductance of the flagellar membrane to affect flagellar reorientation. The results are discussed in connection with previous theories on control of flagella activity in green alga.     

A polyclonal antibody (anticentrin) distinguishes between two types of fibrous flagellar roots in green algae

Summary The two main types of fibrous flagellar roots present in the flagellar apparatus of green algae (system I and system II fibers) are immunologically distinct as indicated by the localization of a Ca²⁺-modulated contractile protein (centrin) exclusively in one type (system II fibers) but not in the other type (system I fibers). A polyclonal antibody generated against the major protein of the striated flagellar roots (system II fibers) of the quadriflagellate green algaTetraselmis striata was used to localize centrin by immunofluorescence and pre- and postembedding immunogold electron microscopy in the flagellar apparatus ofSpermatozopsis similis, S. exsultans, Chlamydomonas reinhardtii, Dunaliella bioculata, Polytomella parva and gametes ofMonostroma grevillei andEnteromorpha sp. Whereas the antibody recognizes centrin in connecting fibers and system II fibers, no labeling occurs in system I fibers in all taxa investigated. This study presents the first evidence that system I fibers lack centrin and indicates that the two main types of fibrous flagellar roots in green algae are biochemically distinct.     

IMMUNOLOCALIZATION OF CENTRIN IN OXYRRHIS MARINA (DINOPHYCEAE)1

A new polyclonal antibody was raised against centrin isolated from the flagellate green alga Spermatozopsis similis (Chlorophyta; anti-SSC). It stains by immunofluorescence and immunoelectron microscopy well-known reference systems for centrin like the nucleus–basal body connectors in Chlamydomonas reinhardtii (Chlorophyta) and the system II fibers (rhizoplasts) of Scherffelia dubia (Chlorophyta). In addition, it recognizes in immunoblots a single 20-kDa protein in isolated cytoskeletons of Spermatozopsis similis and Tetraselmis striata (Chlorophyta) as well as purified centrin isolated from Tetraselmis striata. Using this antibody, centrin was localized in whole cells and isolated cytoskeletons of Oxyrrhis marina Dujardin (Dinophyceae) by immunofluorescence and immunogold electron microscopy. In the flagellar apparatus of O. marina, five different structures were antigenic. Four short fibers (connectives 1–4) link the basal bodies to the four major fibrous flagellar roots, which do not cross-react with anti-centrin. The most prominent of the labeled structures (connective 5), a crescent-shaped fiber, extends from the flagellar canal of the transverse flagellum along the base of the tentacle to the flagellar canal of the longitudinal flagellum, interconnecting the distal parts of the microtubular roots/bands in the basal apparatus. For most of its length, it underlies and is connected to a transversely oriented subamphiesmal microtubular band. In immunoblot analyses, anti-SSC recognizes only a single 20-kDa protein in cytoskeletons of O. marina. Functional and phylogenetic aspects of centrin-containing structures in dinoflagellates are discussed.     

Localization of p210-related proteins in green flagellates and analysis of flagellar assembly in the green alga Dunaliella bioculatawith monoclonal anti-p210

Recently, p210 was identified as a component of the flagellar basal apparatus in the green flagellate Spermatozopsis similis. In a search for potential homologues to p210, isolated cytoskeletons of several green flagellates were probed with a monoclonal antibody, BAS4.13, against p210. In Western blots, cross-reacting bands in the molecular-mass range of 210 kDa were detected only in the quadriflagellate Spermatozopsis exsultans. As described earlier for S. similis, the flagellar transition region was decorated in Chlamydomonas reinhardtii and several other green flagellates, whereas in the marine alga Dunaliella bioculata the antigen was present in the proximal part of the axoneme. Double immunofluorescence of D. bioculata with an antitubulin antibody further revealed dotlike signals at sites where the probasal bodies are located. Since most of the antigen in D. bioculata was located in the axoneme, deflagellation offered a possibility to study the kinetics of its incorporation during flagellar regeneration. The antigen was only detected after a flagellum reached a length of 3-4 microm and its integration into the growing flagellar proceeded from proximal to distal. A similar delay in the incorporation of the antigen was also observed during flagellar assembly on new basal bodies during cell division. Thus, the antigen of BAS4.13 was incorporated late and from proximal to distal into the growing flagellum. We conclude that the pace and site by which individual proteins are integrated into the flagellum differ greatly.     

Analysis of cell vibration for assessing axonemal motility in Chlamydomonas

Flagellar mutants of Chlamydomonas have greatly contributed to our understanding of the function of axonemes and axonemal dyneins. An important step in studying mutants is to correlate the molecular and structural defects in the axoneme with motility. This is not always easy, however, partly because it is often necessary to quantify axonemal motility by measuring the cell's swimming velocity, the flagellar beat frequency, or flagellar waveform in a number of cells or axonemes. To skip this time-consuming step, a quick method for measuring the average flagellar beat frequency in a population of cells is developed based on fast Fourier transform (FFT) analysis of the vibration of cell bodies. This method yields the average beat frequency within 10-60 s and has been used as a powerful tool for identifying mutants lacking various dynein species. It is also particularly useful for studies analyzing detergent-extracted cell models under various reactivation conditions.     

Hyperactivated motility of bull sperm is triggered at the axoneme by Ca2+ and not cAMP

Hyperactivated motility, a swimming pattern of mammalian sperm in the oviduct, is essential for fertilization in vivo. It is characterized by high-amplitude flagellar waves and, usually, highly asymmetrical flagellar beating. It had been suggested, but not tested, that Ca2+ and cAMP switch on hyperactivation by directly affecting the flagellar axoneme. In this study, the direct affects of these agents on the axoneme were tested by using detergent-demembranated bull sperm. As confirmed by TEM, treatment of sperm with 0.2% Triton X-100 disrupted the plasma, acrosomal, and inner mitochondrial membranes, leaving axonemes intact. In the presence of 2 mM ATP, the percentage of reactivated sperm that were hyperactivated increased to 80% when free Ca2+ was increased from 50 to 400 nM. The effect of the Ca2+ in this range was to increase beat asymmetry by increasing the curvature of the principal bend. No additional increases were observed above 400 nM free Ca2+, but motility was suppressed at 1 mM. The ability of Ca2+ to produce hyperactivation depended on ATP availability, such that more ATP was required to produce the high amplitude flagellar bends characteristic of hyperactivated motility than to produce activated motility. Cyclic AMP was not required for reactivation, nor for hyperactivation. Production of hyperactivated motility also required an alkaline environment (pH 7.9-8.5). These results suggest that, provided sufficient ATP is present and pH is sufficiently alkaline, Ca2+ switches on hyperactivation by enabling curvature of the principal bends to increase.     

Structure of striated microtubule-associated fibers of flagellar roots. Comparison of native and reconstituted states.

Several fiber systems are associated with the flagella and basal bodies of eukaryotic cells. Apart from the contractile and Ca(2+)-sensitive system-II fibers, these include the noncontractile system-I fibers that run parallel to flagellar root microtubules. Using electron microscopy and image reconstruction, we have investigated the structure of the system-I fibers of the flagellate green alga Spermatozopsis similis. The fibers were observed in three different states: (1) in situ, (2) after isolation of the intact fibers, (3) after disassembly and reconstitution of fibers in vitro from their 34 kDa subunit protein. The fibers are highly ordered; they show a constant repeat of 28 nm, they are polar, and they contain several transverse and longitudinal striations. A model is discussed showing the system-I fiber to be built from rod-like molecules with a staggered arrangement and identical polarities.     

FLAGELLAR REGENERATION IN SPERMATOZOPSIS SIMILIS (CHLOROPHYTA)

The unicellular green alga Spermatozopsis similis Preisig et Melkonian bears two flagella of unequal length. After deflagellation, cells first regenerated the longer flagellum to about one third of its original length, before the shorter flagellum started to develop. Growth rates were similar for both flagella. Thus, the length difference between both flagella was restored by a lag-phase during regeneration of the shorter flagellum. To explain the lag-phase, we have considered a gating mechanism near the flagellar base that controls the entry of precursors into the flagellum. This would allow cells to restrict the time of effective flagellar growth and thereby control flagellar length. Our data indicated that cells are capable of individually regulating flagellar assembly onto basal bodies. We discuss a recent model of flagellar length regulation based on a balance of assembly and disassembly and conclude that flagellar length is controlled by additional factors, including the availability of flagellar proteins and the developmental status of basal bodies.     

Basal body replication in green algae--when and where does it start?

Basal body duplication in the green alga Spermatozopsis similis was reinvestigated using GT335, an antibody binding to polyglutamylated tubulins, and antibodies directed to p210, a component of the flagellar transition region which represents the distal border of the basal body. p210 was also detected in small spots at the base of each basal body which increased in size prior to mitosis. The presence of p210 on one of the microtubular flagellar roots suggested a transport of basal body material along these tracks. Immunogold electron microscopy confirmed the presence of p210 in the probasal bodies. Further, small probasal bodies are apparently connected to the mature basal bodies by centrin fibers as observed after artificially induced basal body separation in Xenopus egg extract. While basal bodies grew, most of the p210 remained at the tip of elongating basal bodies, but two or four additional spots were observed in distinct patterns near the base of the basal bodies. In cytokinesis, basal body pairs separated and p210 was observed in a strong signal at the tip and a weaker one in the vicinity of the proximal end of each basal body. We interpret the data as indicating that a new p210-containing structure forms near the proximal end of the basal bodies during basal body elongation, representing the precursor of the next generation of basal bodies. Thus, basal bodies appear to seed the succeeding generation already during their own development, a mechanism which could ensure the correct number and position of basal bodies.     

Identification of 11-cis and all-trans-retinal in the photoreceptive organelle of a flagellate green alga

Isolation of intact photoreceptive organelles (eyespot apparatuses) involved in blue-light mediated photoresponses in a flagellate green alga (Spermatozopsis similis) allowed for the first time the identification of both 11-cis- and all-trans-retinal in a plant cell. Both isomers were identified by HPLC analysis in conjunction with UV spectra. Additionally, reconstitution of a distinct absorption band, centered around 540 nm, was achieved by addition of exogenous 9-cis-retinal to bleached, isolated eyespot apparatuses.     

Rhodopsin-mediated photosensing in green flagellated algae

Green flagellated algae possess a primitive visual system that regulates the activity of their motor apparatus. Photoexcitation of a rhodopsin-type photoreceptor protein gives rise to the photoreceptor current, which, above a certain threshold of stimulus intensity, induces the flagellar current. It is probable that the photoinduced alteration in flagellar beating is governed by changes in intracellular Ca2+ concentration. This rhodopsin-mediated sensory system serves to align the swimming path with the direction of the light stimulus, whereas processes of energy metabolism determine whether the oriented movement is directed towards or away from the light source.     

A Novel 95-kD Protein Is Located in a Linker between Cytoplasmic Microtubules and Basal Bodies in a Green Flagellate and Forms Striated Filaments In Vitro

The flagellar basal apparatus comprises the basal bodies and the attached fibrous structures, which together form the organizing center for the cytoskeleton in many flagellated cells. Basal apparatus were isolated from the naked green flagellate Spermatozopsis similis and shown to be composed of several dozens of different polypeptides including a protein band of 95 kD. Screening of a cDNA library of S. similis with a polyclonal antibody raised against the 95-kD band resulted in a full-length clone coding for a novel protein of 834 amino acids (90.3 kD). Sequence analysis identified nonhelical NH₂- and COOH-terminal domains flanking a central domain of ~650 residues, which was predicted to form a series of coiled-coils interrupted by short spacer segments. Immunogold labeling using a polyclonal antibody raised against the bacterially expressed 95-kD protein exclusively decorated the striated, wedge-shaped fibers, termed sinister fibers (sf-fibers), attached to the basal bodies of S. similis. Striated fibers with a periodicity of 98 nm were assembled in vitro from the purified protein expressed from the cloned cDNA indicating that the 95-kD protein could be a major component of the sf-fibers. This structure interconnects specific triplets of the basal bodies with the microtubular bundles that emerge from the basal apparatus. The sf-fibers and similar structures, e.g., basal feet or satellites, described in various eukaryotes including vertebrates, may be representative for cytoskeletal elements involved in positioning of basal bodies/centrioles with respect to cytoskeletal microtubules and vice versa.     

Distinct axonemal processes underlie spontaneous and stimulated airway ciliary activity

Cilia are small organelles protruding from the cell surface that beat synchronously, producing biological transport. Despite intense research for over a century, the mechanisms underlying ciliary beating are still not well understood. Even the nature of the cytosolic molecules required for spontaneous and stimulated beating is debatable. In an effort to resolve fundamental questions related to cilia beating, we developed a method that integrates the whole-cell mode of the patch-clamp technique with ciliary beat frequency measurements on a single cell. This method enables to control the composition of the intracellular solution while the cilia remain intact, thus providing a unique tool to simultaneously investigate the biochemical and physiological mechanism of ciliary beating. Thus far, we investigated whether the spontaneous and stimulated states of cilia beating are controlled by the same intracellular molecular mechanisms. It was found that: (a) MgATP was sufficient to support spontaneous beating. (b) Ca(2+) alone or Ca(2+)-calmodulin at concentrations as high as 1 microM could not alter ciliary beating. (c) In the absence of Ca(2+), cyclic nucleotides produced a moderate rise in ciliary beating while in the presence of Ca(2+) robust enhancement was observed. These results suggest that the axonemal machinery can function in at least two different modes.