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.

Genetic analysis of the fimbrin-actin binding interaction in Saccharomyces cerevisiae.

Yeast fimbrin is encoded by the SAC6 gene, mutations of which suppress temperature-sensitive mutations in the actin gene (ACT1). To examine the mechanism of suppression, we have sequenced 17 sac6 suppressor alleles, and found that they change nine different residues, all of which cluster in three regions of one of the two actin-binding domains of Sac6p. Two of these clusters occur in highly conserved regions (ABS1 and ABS3) that have been strongly implicated in the binding of related proteins to actin. The third cluster changes residues not previously implicated in the interaction with actin. As changes in any of nine different residues can suppress several different act1 alleles, it is likely that the suppressors restore the overall affinity, rather than specific lost interactions, between Sac6p and actin. Using mutagenesis, we have identified two mutations of the second actin-binding domain that can also suppress the act1 mutations of interest. This result suggests the two actin-binding domains of Sac6p interact with the same region of the actin molecule. However, differences in strength of suppression of temperature-sensitivity and sporulation indicate that the two actin-binding domains are distinct, and explain why second-domain mutations were not identified previously.

Actin mutations that show suppression with fimbrin mutations identify a likely fimbrin-binding site on actin.

Actin interacts with a large number of different proteins that modulate its assembly and mediate its functions. One such protein is the yeast actin-binding protein Sac6p, which is homologous to vertebrate fimbrin (Adams, A. E. M., D. Botstein, and D. G. Drubin. 1991. Nature (Lond.). 354:404-408.). Sac6p was originally identified both genetically (Adams, A. E. M., and D. Botstein. 1989. Genetics. 121:675-683.) by dominant, reciprocal suppression of a temperature-sensitive yeast actin mutation (act1-1), as well as biochemically (Drubin, D. G., K. G. Miller, and D. Botstein. 1988. J. Cell Biol. 107: 2551-2561.). To identify the region on actin that interacts with Sac6p, we have analyzed eight different act1 mutations that show suppression with sac6 mutant alleles, and have asked whether (a) these mutations occur in a small defined region on the crystal structure of actin; and (b) the mutant actins are defective in their interaction with Sac6p in vitro. Sequence analysis indicates that all of these mutations change residues that cluster in the small domain of the actin crystal structure, suggesting that this region is an important part of the Sac6p-binding domain. Biochemical analysis reveals defects in the ability of several of the mutant actins to bind Sac6p, and a reduction in Sac6p-induced cross-linking of mutant actin filaments. Together, these observations identify a likely site of interaction of fimbrin on actin.

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.

The formation of basal body domains in the membrane skeleton of Tetrahymena.

Differentiated regions within the membrane skeleton are described around basal bodies in the ciliary rows of Tetrahymena. These domains, approximately 1 micron in diameter, are characterized by a relatively dense ultrastructure, the presence of a family of proteins called K antigens (Mr 39-44 x 10(3)) that are recognized by mAb 424A8, and the apparent exclusion of major membrane skeleton proteins that are present in most other regions of the cell (Mr 135, 125 x 10(3]. Mature basal body domains are asymmetric, reflecting the polarity of the cell as a whole. A similar differentiation of the membrane skeleton occurs in the oral apparatus, except here the K antigens surround four clusters of basal bodies (from which this cell takes its name) rather than the individual basal bodies. The development of new basal body domains in the cell cycle is described, with similarities and differences noted between somatic and oral regions of the cell. It is concluded that the capacity of this cell for precise topographic regulation of molecular events in the membrane skeleton makes it a useful model for the study of cortical differentiation in cells generally.

Tetrins: polypeptides that form bundled filaments in Tetrahymena.

The cortex of the ciliated protozoan Tetrahymena contains a number of fibrous elements, including a network of filaments that pervades the feeding organelle of this organism. The cluster of polypeptides (79-89K; K = 10(3) Mr) in Tetrahymena pyriformis GL-C that constitute these filaments has been purified by in vitro assembly after solubilization in 1.0 M KI. Four distinct sets of these polypeptides, designated 'tetrins', have been shown to be distinguishable from each other by immunochemical and biochemical criteria. The smallest filaments reassembled in vitro were 3-4 nm in diameter and these fine filaments were seen to be bundled together into thicker strands of varying diameters, similar to those within the cell. The thicker filament bundles were clearly distinguishable from intermediate filaments, but fine filaments in these bundles were superficially similar to the 2-5 nm filaments described as microtubule-associated proteins in other organisms. The ultrastructure of the tetrin filaments localized within the feeding organelle reveals a substantial presence of these filaments apart from microtubules. In addition, circular dichroism measurements indicate a relatively low alpha-helical content for these filaments and suggest that the tetrins may be substantially different from other fine filament proteins such as the tektins and giardins.

Identification and localization of major cortical proteins in the ciliated protozoan, Euplotes eurystomus.

Shape-preserving cortical residues have been isolated from Euplotes eurystomus cells by the application of Triton X-100 at high ionic strength. These integrated structures consist of articulated plates and widely interspersed cages that formerly contained basal bodies associated with the clusters of cilia characteristic of this cell type. Using SDS-PAGE and immunolocalization procedures, we have identified major subunit proteins of both the plates (116, 110 (X10(3] Mr, and the basal body cages (86 X 10(3) Mr). The potential for studies of these proteins in contributing to our understanding of cortical development and evolution in Euplotes is discussed.

Properties of microtubule-free cortical residues isolated from Paramecium tetraurelia.

We have found that shape-preserving residues devoid of microtubules can be prepared from Paramecium using Triton X-100 at high ionic strength. These residues contain many proteins, including one showing antigenic relationship to chicken alpha-spectrin, and three showing antigenic relationship to Tetrahymena cortical proteins. These antigens have been localized by immunofluorescence microscopy, and the isolated cortical residues have been characterized ultrastructurally. These preparations should be useful in detailed studies of the structure, development and evolutionary relationships of cortical architecture in ciliated protozoa.

The assembly and positioning of cytoskeletal elements in Tetrahymena.

The oral skeleton of Tetrahymena is a precisely arranged assemblage of basal bodies, microtubule bundles and connecting filaments found associated with the feeding structure in this cell type. Tubulin and filament proteins have been isolated but no actin has been recovered. The conditional mutant NP1 of Tetrahymena thermophila forms a normal oral skeleton at the permissive temperature (28 degrees C), but forms an abnormal one at the restrictive temperature (37 degrees C). Antibodies against tubulin and oral filament protein OF1 were used to visualize the abnormal oral skeleton and stages in its development, and ultrastructural comparisons of abnormal and wild-type oral skeletons were made. It was found that the overall pattern of organization was altered in the mutant, whereas the substructure appeared everywhere to be normal. Studies of cells in which the mutant phenotype was coming to expression revealed that normal basal bodies in the oral skeleton failed to move from the disordered state characteristic of early stages of development into the correct pattern of four organized clusters characteristic of later stages. Together, these results suggest that the lesion in NP1 does not affect cytoskeleton assembly per se, but instead affects a discrete mechanism responsible for the positioning of cytoskeletal elements with respect to each other after they have been formed (meta-assembly). Reasons for suspecting the involvement of the membrane skeleton are presented.

Regional differentiation of the membrane skeleton in Tetrahymena.

Antisera have been raised in rabbits against three high molecular weight proteins that are present in Triton X-100-insoluble residues of Tetrahymena pyriformis GL cells. These proteins, called A, B and C, have apparent molecular weights of 235, 135 and 125 (X 10(3)), respectively, in SDS-polyacrylamide gels. The antisera obtained are specific for these proteins, as shown by immunoblotting. Immunolocalization studies are reported that suggest that these proteins are present throughout the epiplasmic layer beneath the cell surface (membrane skeleton). Images obtained with the fluorescence microscope, however, suggest that the membrane skeleton is modified in discrete zones: (1) around somatic basal bodies, (2) within the oral apparatus, (3) in the cytoproct, (4) in contractile vacuole pores, (5) in the fission zone in late division, and (6) at the mating junction in conjugating cells. These regions may represent areas of increased rigidity at the cell surface. The transition from pliable to rigid epiplasm in spatially delimited areas is apparently a recurring theme in cortical morphogenesis in Tetrahymena. Together, the two types of epiplasm probably allow for extensive changes in cell shape while preserving essential relationships between structural elements within the cortex.

Oral filament proteins and their regulation in Tetrahymena pyriformis.

Two proteins from the Triton X-100-insoluble fraction of Tetrahymena pyriformis have been isolated and shown by immunological methods to be major components of a pervasive system of filaments localized within the oral apparatus. These proteins, OF-1 and OF-2, have apparent molecular weights (MWapp) in polyacrylamide gels of 87,000 and 80,000 D, respectively. Peptide maps obtained and the absence of immunological cross-reactivity suggest that these proteins are not closely related to each other. Indirect immunofluorescence studies on dividing cells have shown that the oral filament system forms late in the cell cycle. The filaments appeared first after the basal bodies in the oral primordium had organized into groups and the fission furrow had begun to form. Dedifferentiation of the oral filament system in the anterior (old) oral apparatus was also observed at this point in the cell cycle. Following this, the oral filament systems in both old and new oral apparatuses completed development synchronously. Proteins showing antigenic similarity to OF-1 were found in a number of other cell types. Tests with heterologous antisera failed to demonstrate a relationship between vertebrate cytoskeletal proteins and the oral filament proteins of Tetrahymena.