Monoclonal antibodies reveal complex structure in the membrane skeleton of Tetrahymena.

Twelve monoclonal antibodies were raised that are specific for the membrane skeleton of Tetrahymena. Five were directed against T. pyriformis and seven were directed against T. thermophila. Some cross-reactivity between species was found. Each monoclonal antibody recognized one of the three major components of epiplasm, i.e. the bands A, B, and C identified in electrophoretic separations of epiplasmic proteins. It was found, using these antibodies, that the epiplasmic proteins A, B and C have overlapping but independent distributions within the cell.

Tetrin polypeptides are colocalized in the cortex of Tetrahymena.

There is a complex system of 2- to 5-nm filaments in the oral apparatus of Tetrahymena. Four major subunit proteins, called tetrins, have been isolated from the filaments. These proteins, showing apparent molecular weights in polyacrylamide gels of 79-89 kDa, will assemble in vitro into 2- to 5-nm filaments. Tetrin filaments in vivo show different packing arrangements in different regions of the oral apparatus. We sought to determine the distributions of tetrin polypeptides within the complex oral structure by obtaining monoclonal antibodies specific for individual tetrins, then mapping their distributions within the oral apparatus using standard fluorescence microscopy, confocal laser scanning fluorescence microscopy, and electron microscopy. The results indicate that the four tetrin polypeptides are colocalized everywhere within the oral apparatus of Tetrahymena. Tetrin-binding proteins or specific nucleating structures may need to be invoked to explain the complex organization of the tetrin network. The 16 monoclonal antibodies obtained were also used to search for evidence of immunological relationships between tetrin and cytoskeletal proteins in multicellular organisms. None was found.

Protein polymorphism and evolution in the genus Tetrahymena.

Immunoblotting tests involving cytoskeletal protein arrays and fluorescence microscopical examinations of whole cells using monoclonal antibody 424A8 gave substantially different results in three evolutionary subgroups within the genus Tetrahymena. These responses are described and some implications of the evolutionary divergence indicated in this ciliated protozoan are discussed.

Comparison between ectoderm-conditioned medium and fibronectin in their effects on chondrogenesis by limb bud mesenchymal cells.

Limb bud ectoderm inhibits chondrogenesis by limb bud mesenchymal cells cultured at high density or on collagen gels. This ectodermal antichondrogenic influence has been postulated to function in vivo in regulating the spatial patterning of cartilage and soft connective tissue in the limb. We have developed a method for preparing ectoderm-conditioned medium containing antichondrogenic activity. Using a simple bioassay, we have investigated some characteristics of the ectodermal products and their effects on limb bud mesenchymal cells. Inhibition of chondrogenesis by ectoderm-conditioned medium was tested on limb bud mesenchymal cells cultured on collagen gels. The antichondrogenic influence involves enhanced cell spreading and is alleviated by agents, such as cytochalasin D, that induce cell rounding. Fibronectin resembles ectoderm-conditioned medium in its ability to inhibit chondrogenesis and promote cell spreading in collagen gel cultures of limb bud mesenchymal cells. However, Western blot analysis shows that the antichondrogenic activity of ectoderm-conditioned medium is not due to fibronectin in the medium. Peptides related to the fibronectin cell-binding domain block the antichondrogenic effect of fibronectin, but not that of ectoderm-conditioned medium. On the other hand, an antibody to an integrin, as well as heparan sulfate, alleviates the antichondrogenic effects of both fibronectin and ectoderm-conditioned medium. The antichondrogenic effect of ectoderm-conditioned medium may be mediated by an integrin and by a cell surface heparan sulfate proteoglycan, but it does not depend directly upon fibronectin-mediated cell spreading.