Fine oral filaments in Paramecium: a biochemical and immunological analysis.

In Paramecium, several kinds of the oral networks of fine filaments are defined at the ultrastructural level. Using the sodium chloride-treated oral apparatus of Paramecium as an antigen to produce monoclonal antibodies, we have begun to identify the proteins constituting these networks. Immunoblotting showed that all positive antibodies were directed against three bands (70-, 75-and 83-kD), which corresponded to quantitatively minor components of the antigen; there was no antibody specific for the quantitatively major components (58- and 62-kD). Immunolocalization with four of these antibodies directed against one or several of these three bands showed that these proteins are components of the fine filaments supporting the oral area; a decoration of the basal bodies and the outer lattice was also observed on the cortex. Immunofluorescence on interphase cells suggested that the three proteins colocalized on the left side of the oral apparatus, whereas only the 70-kD band was detected on the right side. During division, the antigens of the antibodies were detected at different stages after oral basal body assembly. The antibodies cross-reacted with the tetrins, which are oral filament-forming proteins in Tetrahymena, demonstrating that tetrin-related proteins are quantitatively minor components of the oral and the somatic cytoskeleton of Paramecium.

Basal body-associated nucleation center for the centrin-based cortical cytoskeletal network in Paramecium.

The infraciliary lattice, a contractile cortical cytoskeletal network of Paramecium, is composed of a small number of polypeptides including centrins. Its overall pattern reflects a hierarchy of structural complexity, from assembly and bundling of microfilaments to formation of polygonal meshes arranged in a continuous network subtending the whole cell surface, with local differentiations in the shape and size of the meshes. To analyse how the geometry of this complex network is generated and maintained, we have taken two approaches. Firstly, using monoclonal antibodies raised against the purified network, we have shown that all the component polypeptides colocalize, in agreement with previous biochemical data indicating that the infraciliary lattice is formed of large complexes comprising all the component polypeptides. Secondly, by taking advantage of different experimental conditions leading to disassembly of the network, we have followed its reassembly. Cytological analysis of the process revealed 1) that the network regrows exclusively from specific infraciliary lattice organizing centers (ICLOC), precisely localized near each basal body and, 2) that the global organization is not precisely controlled by genetic information but by the basal body pattern. Finally, slight ultrastuctural differences between reassembled and control lattices suggest that the organization of the filament bundles is partly templated by that of the preexisting ones.