FAP206 is a microtubule-docking adapter for ciliary radial spoke 2 and dynein c.

Radial spokes are conserved macromolecular complexes that are essential for ciliary motility. A triplet of three radial spokes, RS1, RS2, and RS3, repeats every 96 nm along the doublet microtubules. Each spoke has a distinct base that docks to the doublet and is linked to different inner dynein arms. Little is known about the assembly and functions of individual radial spokes. A knockout of the conserved ciliary protein FAP206 in the ciliate Tetrahymena resulted in slow cell motility. Cryo-electron tomography showed that in the absence of FAP206, the 96-nm repeats lacked RS2 and dynein c. Occasionally, RS2 assembled but lacked both the front prong of its microtubule base and dynein c, whose tail is attached to the front prong. Overexpressed GFP-FAP206 decorated nonciliary microtubules in vivo. Thus FAP206 is likely part of the front prong and docks RS2 and dynein c to the microtubule.

Tubulin glutamylation regulates ciliary motility by altering inner dynein arm activity.

How microtubule-associated motor proteins are regulated is not well understood. A potential mechanism for spatial regulation of motor proteins is provided by posttranslational modifications of tubulin subunits that form patterns on microtubules. Glutamylation is a conserved tubulin modification [1] that is enriched in axonemes. The enzymes responsible for this posttranslational modification, glutamic acid ligases (E-ligases), belong to a family of proteins with a tubulin tyrosine ligase (TTL) homology domain (TTL-like or TTLL proteins) [2]. We show that in cilia of Tetrahymena, TTLL6 E-ligases generate glutamylation mainly on the B-tubule of outer doublet microtubules, the site of force production by ciliary dynein. Deletion of two TTLL6 paralogs caused severe deficiency in ciliary motility associated with abnormal waveform and reduced beat frequency. In isolated axonemes with a normal dynein arm composition, TTLL6 deficiency did not affect the rate of ATP-induced doublet microtubule sliding. Unexpectedly, the same TTLL6 deficiency increased the velocity of microtubule sliding in axonemes that also lack outer dynein arms, in which forces are generated by inner dynein arms. We conclude that tubulin glutamylation on the B-tubule inhibits the net force imposed on sliding doublet microtubules by inner dynein arms.

Targeted gene disruption of dynein heavy chain 7 of Tetrahymena thermophila results in altered ciliary waveform and reduced swim speed.

Tetrahymena thermophila swims by the coordinated beating of hundreds of cilia that cover its body. It has been proposed that the outer arm dyneins of the ciliary axoneme control beat frequency, whereas the inner arm dyneins control waveform. To test the role of one of these inner arms, dynein heavy chain 7 protein (Dyh7p), a knockout mutant was generated by targeted biolistic transformation of the vegetative macronucleus. Disruption of DYH7, the gene which encodes Dyh7p, was confirmed by PCR examination of both genomic and cDNA templates. Both intact and detergent extracted, reactivated cell model preparations of these mutants, which we call DYH7neo3, displayed swim speeds that were almost half that of wild-type cells. Although the DYH7neo3 mutants were slower than wild type, they were able to modulate their swim speed and show ciliary reversal in response to depolarizing stimuli. High-speed video microscopy of intact, free-swimming DYH7neo3 mutants revealed an irregular pattern of ciliary beat and waveform. The mutant cilia appeared to be engaging in less coordinated, swiveling movements in which the typical shape, periodicity and coordination seen in wild-type cilia were absent or disturbed. We propose that the axonemal inner arm dynein heavy chain 7 proteins contribute to the formation of normal ciliary waveform, which in turn governs the forward swimming velocity of these cells.

Mutations in genes encoding inner arm dynein heavy chains in Tetrahymena thermophila lead to axonemal hypersensitivity to Ca2+.

Calcium-dependent ciliary reversals are seen in ciliated protozoans such as Tetrahymena in response to depolarizing stimuli, but the axonemal mechanisms responsible for this response are not well understood. The model is that the outer arm dyneins (OADs) control the beating frequency while the inner arm dyneins (IADs) regulate ciliary waveform. Since ciliary reversal is a type of waveform change, the model would predict that IAD mutations could affect ciliary reversal. We have used gene disruption techniques to generate several behavioral mutants of Tetrahymena with functional disruptions of various IADs. One such mutant, called KO-6, is missing I1 (the two-headed IAD) and is unable to show ciliary reversals in response to any stimuli due to a loss of axonemal Ca2+ sensitivity [Eur J Cell Biol 80 (2001) 486-497; Cell Motil Cytoskeleton 53 (2002) 281-288.]. In contrast, disruption of 3 one-headed IADs [Liu et al., Cell Motil Cytoskeleton 59 (2004), 201-214] produced mutants, which showed over-responsiveness in bioassays measuring either their depolarization-induced avoiding reactions (AR) in Na+ and Ba2+ solutions or their duration of backward swimming (continuous ciliary reversal or CCR) in K+ solutions. Detergent-extracted and reactivated mutants also showed increased probabilities of CCR at lower Ca2+ concentrations suggesting that the behavioral over-responsiveness of these three mutants in vivo is due to increased axonemal Ca2+ sensitivity. Our data suggest the possibility that the one-headed IADs and the two-headed IAD act antagonistically in vivo and that loss of any one of the one-headed IADs leads to behavioral over-responsiveness due to less resistance to I1-induced reversals.

Disruption of genes encoding predicted inner arm dynein heavy chains causes motility phenotypes in Tetrahymena.

The multi-dynein hypothesis [Asai, 1995: Cell Motil Cytoskeleton 32:129-132] states: (1) there are many different dynein HC isoforms; (2) each isoform is encoded by a different gene; (3) different isoforms have different functions. Many studies provide evidence in support of the first two statements [Piperno et al., 1990: J Cell Biol 110:379-389; Kagami and Kamiya, 1992: J Cell Sci 103:653-664; Gibbons, 1995: Cell Motil Cytoskeleton 32:136-144; Porter et al., 1996: Genetics 144:569-585; Xu et al., 1999: J Eukaryot Microbiol 46:606-611] and there is evidence that outer arms and inner arms play different roles in flagellar beating [Brokaw and Kamiya, 1987: Cell Motil. Cytoskeleton 8:68-75]. However, there are few studies rigorously testing in vivo whether inner arm dyneins, especially the 1-headed inner arm dyneins, play unique roles. This study tested the third tenet of the multi-dynein hypothesis by introducing mutations into three inner arm dynein HC genes (DYH8, 9 and 12) that are thought to encode HCs associated with 1-headed inner arm dyneins. Southern blots, Northern blots, and RT-PCR analyses indicate that all three mutants (KO-8, 9, and 12) are complete knockouts. Each mutant swims slower than the wild-type cells. The beat frequency of KO-8 cells is lower than that of the wild-type cells while the beat frequencies of KO-9 and KO-12 are not different from that of wild-type cells. Our results suggest that each inner arm dynein HC is essential for normal cell motility and cannot be replaced functionally by other dynein HCs and that not all of the 1-headed inner arm dyneins play the same role in ciliary motility. Thus, the results of our study support the multi-dynein hypothesis [Asai, 1995: Cell Motil Cytoskeleton 32:129-132].

PPNDS is an agonist, not an antagonist, for the ATP receptor of Paramecium.

Paramecium represents a simple, eukaryotic model system to study the cellular effects of some neuroactive drugs. They respond to the agonist beta,gamma-methylene ATP with a transient depolarizing receptor potential, Ca(2+)-based action potentials and repetitive bouts of forward and backward swimming called 'avoiding reactions' (AR). In vivo [(32)P]ATP binding assays showed saturable [(32)P]ATP binding with an apparent K(d) of approximately 23 nmol l(-1). Prolonged (15 min) exposure to 25 micro mol l(-1) beta,gamma-methylene ATP caused behavioral adaptation and losses of AR, ATP receptor potentials and [(32)P]ATP binding. While screening various ATP receptor inhibitors, we found that the P2X1 'antagonist' pyridoxal-phosphate naphthylazo-nitro-disulfate (PPNDS) is actually an agonist, producing the same responses as beta,gamma-methylene ATP. [(32)P]ATP binding assays suggest that both agonists may bind to the same site as [(32)P]ATP. Cross-adaptation is also seen between PPNDS and beta,gamma-methylene ATP in terms of losses in AR, depolarizing receptor potentials and [(32)P]ATP binding. We conclude that the inhibition caused by PPNDS in Paramecium is due to agonist-induced desensitization. Either this represents a unique new class of ATP receptors, in which PPNDS is an agonist instead of an antagonist, or PPNDS (and other drugs like it) may actually be an agonist in many other cell types in which prolonged exposure is necessary for inhibition.

Inner arm dynein 1 is essential for Ca++-dependent ciliary reversals in Tetrahymena thermophila.

Cilia in many organisms undergo a phenomenon called ciliary reversal during which the cilia reverse the beat direction, and the cell swims backwards. Ciliary reversal is typically caused by a depolarizing stimulus that ultimately leads to a rise in intraciliary Ca++ levels. It is this increase in intraciliary Ca++ that triggers ciliary reversal. However, the mechanism by which an increase in intraciliary Ca++ causes ciliary reversal is not known. We have previously mutated the DYH6 gene of Tetrahymena thermophila by targeted gene knockout and shown that the knockout mutants (KO6 mutants) are missing inner arm dynein 1 (I1). In this study, we show that KO6 mutants do not swim backward in response to depolarizing stimuli. In addition to being unable to swim backwards, KO6 mutants swim forward at approximately one half the velocity of wild-type cells. However, the ciliary beat frequency in KO6 mutants is indistinguishable from that of wild-type cells, suggesting that the slow forward swimming of KO6 mutants is caused by an altered waveform rather than an altered beat frequency. Live KO6 cells are also able to increase and decrease their swim speeds in response to stimuli, suggesting that some aspects of their swim speed regulation mechanisms are intact. Detergent-permeabilized KO6 mutants fail to undergo Ca++-dependent ciliary reversals and do not show Ca++-dependent changes in swim speed after MgATP reactivation, indicating that the axonemal machinery required for these responses is insensitive to Ca++ in KO6 mutants. We conclude that Tetrahymena inner arm dynein 1 is not only an essential part of the Ca++-dependent ciliary reversal mechanism but it also may contribute to Ca++-dependent changes in swim speed and to the formation of normal waveform during forward swimming.