The cilium like region of the Drosophila bifurca spermatocyte: Elongation of a giant axoneme without intraflagellar transport.

The growth of the ciliary axonemes mainly depends on the evolutionary conserved intraflagellar transport (IFT) machinery. However, insect spermatocytes are characterized by cilium-like regions (CLRs) that elongate in the absence of IFT. It is generally believed that the dynamics of these structures relies on the free diffusion of soluble tubulin from the cytoplasm. However, this passive process could allow the elongation of short ciliary axonemes, but it is unclear whether simple diffusion of tubulin molecules can ensure the correct assembly of elongated ciliary structures. To decipher this point we analyzed the assembly of the CLRs held by the primary spermatocytes of Drosophila bifurca. These ciliary structures consist of a very elongated axoneme that grows without IFT and, therefore, could represent a good model in which to evaluate the role played by the free diffusion of soluble tubulin. The observation of wavy microtubules in the axonemal lumen of fully elongated CLRs of D. bifurca may be consistent with the diffusion of tubulin within the axonemal lumen. Progressive consumption of soluble tubulin used for axoneme growth at the apical tip of the CLRs could result in a gradient sufficient to move tubulin from the cytoplasm to the apical end of the forming ciliary structure. When the axoneme reaches its full length, tubulin molecules are not drawn to the tip of the CLRs and accumulate at the base of the axoneme, where its concentration may exceed the threshold need for microtubule polymerization. The presence of γ-TuRCs at the proximal ends of the supernumerary microtubules could enhance their nucleation.