Dynein-2 affects the regulation of ciliary length but is not required for ciliogenesis in Tetrahymena thermophila.

Eukaryotic cilia and flagella are assembled and maintained by the bidirectional intraflagellar transport (IFT). Studies in alga, nematode, and mouse have shown that the heavy chain (Dyh2) and the light intermediate chain (D2LIC) of the cytoplasmic dynein-2 complex are essential for retrograde intraflagellar transport. In these organisms, disruption of either dynein-2 component results in short cilia/flagella with bulbous tips in which excess IFT particles have accumulated.

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.

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.

Dephosphorylation of inner arm 1 is associated with ciliary reversals in Tetrahymena thermophila.

In many organisms, depolarizing stimuli cause an increase in intraciliary Ca2+, which results in reversal of ciliary beat direction and backward swimming. The mechanism by which an increase in intraciliary Ca2+ causes ciliary reversal is not known. Here we show that Tetrahymena cells treated with okadaic acid or cantharidin to inhibit protein phosphatases do not swim backwards in response to depolarizing stimuli.

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.