Axonemal tubules in the distal sperm tail of Wolbachia-infected Drosophila simulans males contain ring-like intraluminal structures that persist after axoneme fragmentation.

Wolbachia are obligate intracellular alphaproteobacteria that enhance their spreading by altering the reproductive mechanisms of several invertebrates. Among the reproductive alterations, Wolbachia also causes cytoplasmic incompatibility that leads to embryo death when infected males are crossed with uninfected females, thus selecting infected females. However, the presence of Wolbachia has important fitness costs and infected Drosophila simulans males produce less sperm than their uninfected counterparts. Such sperm suffer, indeed, of some structural alterations that hinder their proper function. We took advantage of the fact that several sperm have abnormal distal regions of the tail, in which the plasma membrane is broken and the axonemal components splayed, making the ultrastructural aspects clearly observable. We found that axoneme reduction in the distal region of the sperm does not follow a unique pattern as observed in other insects, but occurs by losing accessory tubules or peripheral doublets. The axonemal tubules contain distinct coaxial ring-like structures that are still observed after axoneme fragmentation and form large clusters of several units.

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.

Wolbachia Induces Structural Defects Harmful to Drosophila simulans Riverside Spermiogenesis.

The relationship between cytoplasmic incompatibility and the obligate intracellular alphaproteobacteria Wolbachia has for a long time been reported. Although the molecular mechanisms responsible for this reproductive alteration are beginning to be understood, the effects of Wolbachia on germ cell structure and dynamics have not yet been fully investigated. We report here that the presence of Wolbachia in infected cysts of elongating spermatids is associated with major structural defects that become more evident in mature sperm. We find mitochondrial defects, an improper axoneme structure, reduced sperm numbers, and individualization failures. The large heterogeneous variety of the ultrastructural defects found in elongating spermatids and mature sperm provide the first cytological evidence for the reduced fertility associated with Wolbachia infection in Drosophila simulans males. The observed abnormalities could be the result of the mechanical stress induced by the high bacteria numbers during the process of spermatid elongation, rather than the result of the released factors affecting the proper morphogenesis of the germ cells. Moreover, high Wolbachia densities in male germ cells may not be appropriate for causing cytoplasmic incompatibility as the bacteria are harmful for spermatid differentiation, leading to abnormal sperm that is unlikely to be functional.

The distal central pair segment is structurally specialised and contributes to IFT turnaround and assembly of the tip capping structures in Chlamydomonas flagella.

BACKGROUND INFORMATION: Cilia and flagella are dynamic organelles whose assembly and maintenance depend on an activetrafficking process known as the IntraFlagellar Transport (IFT), during which trains of IFT protein particles are moved by specific motors and carry flagellar precursors and turnover products along the axoneme. IFT consists of an anterograde (from base to tip) and a retrograde (from tip to base) phase. During IFT turnaround at the flagellar tip, anterograde trains release their cargoes and remodel to form the retrograde trains. Thus, turnaround is crucial for correct IFT. However, current knowledge of its mechanisms is limited. RESULTS: We show here that in Chlamydomonas flagella the distal ∼200 nm central pair (CP) segment is structurally differentiated for the presence of a ladder-like structure (LLS). During IFT turnaround, the IFT172 subunit dissociates from the IFT- B protein complex and binds to the LLS-containing CP segment, while the IFT-B complex participates in the assembly of the CP capping structures. The IFT scaffolding function played by the LLS-containing CP segment relies on anchoring components other than the CP microtubules, since IFT turnaround occurs also in the CP-devoid pf18 mutant flagella. CONCLUSIONS: During IFT turnaround in Chlamydomonas flagella, i) the LLS and the CP terminal plates act as anchoring platforms for IFT172 and the IFT-B complex, respectively, and ii) during its remodeling, the IFT-B complex contributes to the assembly of the CP capping structures. SIGNIFICANCE: Our results indicate that in full length Chlamydomonas flagella IFT remodeling occurs by a specialized mechanism that involves flagellar tip structures and is distinct from the previously proposed model in which the capability to reverse motility would be intrinsic of IFT train and independent by any other flagellar structure.