Nuclear proteins involved in cell division in the ciliate, Tetrahymena

For the purpose of clarifying the presence of nuclear proteins which may induce cell division, we conducted experiments using ciliate Tetrahymena which can be synchronized at the G2 phase in the cell cycle easily by periodic heat shock treatment (HST): We obtained proteins from the nuclei isolated from the cells grown at the early mid log-phase, at the G2 phase (60 min) and at the G1 phase (150 min), after HST. The proteins were studied by comparing the spots separated by isoelectric point, 10-20% gradient SDS two-dimensional electrophoresis. As a result, in comparison with the intranuclear protein at the log-phase, the proteins at the G2 phase showed a marked increase, but with no great change in the electrophoretic pattern. Meanwhile, the proteins at the G1 phase differed greatly from those at the G2 phase not only in the quantitative changes, but in the electrophoretic patterns. It is considered that the level of the accumulation of the nuclear proteins which should be closely involved in cell division must increase markedly at the G2 phase and decrease at the G1 phase. We confirmed the presence of four proteins: pI 5.8 MW 68 kDa, pI 6.1 MW 75 kDa, pI 8.6 MW 48 kDa and pI 6.6 MW 57 kDa, and then prepared monoclonal antibodies using these nuclear proteins as antigens. Among them, the antibody (IgM) against the pI 8.6 MW 48 kDa polypeptide (p48) was recognized the nuclei by indirect immunofluorescence in ancellular system at the S, G2 and the mid-M phases. However, nuclei at the late M and G1 phases were not stained.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin treatment affects the behaviour of Tetrahymena pyriformis and T. malaccensis

Populations of Tetrahymena pyriformis and T. malaccensis were treated with insulin, then washed and treated again 24 h later. The ethograms of controls, treated, washed and retreated populations were drawn. Statistical analysis showed that T. pyriformis was affected by insulin more severely than T. malaccensis. In T. pyriformis the effects of the 'memory' of the first treatment seem to be more relevant than those of the first and second treatments themselves. On the contrary in T. malaccensis treatments with insulin per se seem to affect the behaviour more strongly than the memory of the first treatment itself. These results are discussed in detail in the context of previous work.

Tetrahymena: a model for growth, cell cycle and nutritional studies, with biotechnological potential

Tetrahymena has been used as a model cell system in many studies of morphogenesis, conjugation, gene mapping, cell division and growth kinetics. In this article, we consider some advances which have resulted from the successful development of a chemically defined medium (CDM), and how subsequent work has extended the contribution that this organism has made to our understanding of different aspects of growth, nutrition, cell cycle control, cytokinesis and intercellular signalling. Finally, we discuss the considerable potential that has arisen for the biotechnological exploitation of this big and rapidly growing eukaryotic cell.

Cytodifferentiation in Tetrahymena vorax is linked to glycosyl-phosphatidylinositol-anchored protein assembly

The role of glycosyl-PtdIns (GPI)-anchored proteins in the cytodifferentiation of Tetrahymena vorax was examined. Labelling of cells with [3H]myristate or [3H]palmitate followed by electrophoresis showed an array of proteins carrying covalently bound lipids. Electrophoresis of protein from cells labelled with the GPI-anchor components [3H]Ins and [14C]ethanolamine revealed three polypeptides on fluorograms which have apparent molecular masses of approx. 28, 50 and 82 kDa. Labelled lipid associated with these polypeptides was susceptible to release by in vitro exposure to Bacillus thuringiensis PtdIns-specific phospholipase C (PI-PLC). Using labelled fatty acids, cells induced to differentiate showed altered GPI-anchored protein-labelling patterns in comparison with undifferentiated control cells, with a heavily labelled 32 kDa band appearing upon differentiation. Pre-incubation of cells in 10 mM D-mannosamine, an inhibitor of GPI incorporation into protein, resulted in a reduction of the incorporation of label into the three GPI-anchored proteins, nearly complete inhibition of differentiation and a reduction in the rate of digestive vacuole formation. A 50% inhibition of differentiation was obtained using 500 microM mannosamine. The inhibitory impact of D-mannosamine on differentiation could be competitively and completely reversed by the inclusion of D-mannose, but not D-glucose. Neither glucosamine nor tunicamycin inhibited differentiation. Incubation of cells in PI-PLC (5 units/ml) plus the differentiation inducer resulted in an acceleration of differentiation and generally higher percentages of differentiated cells versus controls.

Oxytocin and vasopressin change the activity of the contractile vacuole in tetrahymena: Newer contributions to the phylogeny of hormones and hormone receptors

1. Primary interaction with oxytocin accounted for a significant prolongation of the time interval between two systolic contractions of the contractile vacuole in Tetrahymena, whereas primary interaction with vasopressin had no appreciable influence on that functional parameter. 2. Primary treatment (imprinting) with vasopressin increased sensitivity to vasopressin and reduced responsiveness to oxytocin. 3. Primary treatment (imprinting) with oxytocin did not increase cellular response either to oxytocin or to vasopressin on second exposure. 4. Oxytocin, which is chemically related to the antidiuretic hormone vasopressin, influences the water metabolism in protozoa; vasopressin develops a similar effect after imprinting. 5. The experimental observations allow conclusions on certain events involved in the phylogenesis of hormones and receptors.

Suicide is not the inevitable outcome of "perpetual" selfing in tetrahymenines collected from natural habitats

A significant fraction of the Tetrahymena clones isolated from natural habitats self (mating occurs within a clone). Early attempts to study such clones failed because stable subclones were rarely, if ever, observed, and isolated pairs all died. Isozyme analysis revealed that these wild selfers were a diverse group; some were very similar to T. australis, a species with synclonal mating type determination and to T. elliotti, shown recently to have a karyonidal mating type system. One originally stable clone of T. australis included some selfing clones after a few years in our laboratory. Other clones manifested unique zymograms. Subclones isolated from 18 selfer strains were heterogeneous. All subclones of several selfers mated massively at each transfer through 100 fissions. Selfing among subclones of other selfers was highly variable or not observed. Although 77% of the pairs isolated died, and 9% of the pair cultures selfed, 15 selfers yielded some viable nonselfing "immature" progeny. Additional immature progeny were obtained by isolating pairs from macronuclear retention synclones. Although some "immature" progeny eventually selfed, most remained stable. Giemsa staining revealed macronuclear anlagen in nearly all mating pairs and some anomalies. Crosses among the F1 progeny clones of the T. elliotti selfers yield viability data comparable to those from crosses among normal strains. Perhaps perpetual selfing is a mechanism of getting rid of deleterious combinations of genes and uncovering better combinations in homozygous state by playing genetic roulette.

DNA elimination and its relation to quantities in the macronucleus of Tetrahymena

The macronucleus of Tetrahymena contains a large number of DNA molecules of subchromosomal size. They belong to about 270 species each one occurring at an average number of 45 copies. Macronuclei divide unequally and nothing is known of segregation control. This and the elimination and degradation of DNA during macronuclear amitosis make the clonal stability of macronuclei a problem of qualitative and quantitative control on a subchromosomal level. We studied the contribution of DNA elimination to the quantitative composition of the macronucleus cytophotometrically in single cells of different strains. This was done under standard conditions and under conditions known to influence the amount of macronuclear DNA. The following results were found: Elimination of DNA occurs at almost every division. The size of the elimination body is highly variable but still positively correlated with the macronuclear DNA content. In T. thermophila the amount of eliminated DNA is 2.5% of the G2 content and is not dependent on the growth state. It varies with species, amounting to as much as 8% in T. pigmentosa. During conditions which increase the macronuclear DNA content, very little DNA is eliminated. On the other hand, large amounts are eliminated under other conditions causing the macronuclear DNA content to decrease. DNA to be eliminated at division is synthesized at the same time as bulk DNA. We developed a computer program which helps us study the effects of DNA elimination and unequal divisions upon the copy numbers of subchromosomal DNA classes.(ABSTRACT TRUNCATED AT 250 WORDS)

Macronuclear differentiation in conjugating pairs of Tetrahymena treated with the antitubulin drug nocodazole

During Tetrahymena conjugation gamic nuclei (pronuclei) are produced, reciprocally exchanged, and fused in each mate. The synkaryon divides twice; the two anterior nuclei develop into new macronuclei while the two posterior nuclei become micronuclei. The postzygotic divisions were blocked with the antitubulin drug nocodazole (ND). Then pronuclei (gamic nuclei) developed directly into macronuclear anlagen (primordial macronuclei), inducing amicronucleate cells with two anlagen, or, rarely, cells with one anlagen and one micronucleus. ND had a similar effect on cells that passed the first postzygotic division inducing amicronucleate cells with two anlagen, while cells treated with ND at the synkarya stage produced only one large anlage. Different intracytoplasmic positioning of the nuclei treated with ND (pronuclei, synkarya and two products of the first division) shows that most of cell cytoplasm is competent for inducing macronuclear development. Only posteriorly positioned nuclei--products of the second postzygotic division--remain micronuclei. The total cell DNA content, measured cytophotometrically in control and in ND-induced amicronucleate conjugant cells with one and two anlagen, was similar in all three samples at 12 h of conjugation. Eventually, at 24 h this content was about 2 pg (8 C) per anlagen both in nonrefed control and in amicronucleate exconjugants. Therefore "large" nuclei developing in the presence of ND were true macronuclear anlagen.

A cdc2-like kinase phosphorylates histone H1 in the amitotic macronucleus of Tetrahymena

Genetic and biochemical studies have shown that cdc2 protein kinase plays a pivotal role in a highly conserved mechanism controlling the entry of cells into mitosis. It is generally believed that one function of cdc2 kinase is to phosphorylate histone H1 which in turn promotes mitotic chromosome condensation. However, direct evidence linking H1 phosphorylation to mitotic chromatin condensation is limited and the exact cellular function(s) of H1 phosphorylation remains unclear. In this study, we show that mammalian cdc2 kinase phosphorylates H1 from the amitotic macronucleus of Tetrahymena with remarkable fidelity. Furthermore, we demonstrate that macronuclei from Tetrahymena contain a growth-associated H1 kinase activity which closely resembles cdc2 kinase from other eukaryotes. Using polyclonal antibodies raised against yeast p34cdc2, we have detected a 36 kd immunoactive polypeptide in macronuclei which binds to Suc1 (p13)-coated beads and closely follows H1 kinase activity. Since macronuclei divide without mitotic chromosome condensation, these data demonstrate that H1 phosphorylation by cdc2 kinase may be necessary, but is not sufficient to promote mitotic chromatin condensation. The fact that an activity which strongly resembles mammalian cdc2 kinase is active during cell growth in a nucleus which does not undergo mitosis and chromosome condensation suggests that other factors are needed for a true mitotic division to occur. These data also reinforce the notion that H1 phosphorylation has important functions outside mitosis both in Tetrahymena and in mammalian cells.

Nucleus-specific and temporally restricted localization of proteins in Tetrahymena macronuclei and micronuclei

Labeled nuclear proteins were microinjected into the cytoplasm of Tetrahymena thermophila. Macronuclear H1, calf thymus H1, and the SV40 large T antigen nuclear localization signal linked to BSA accumulated specifically in macronuclei, even if cells were in micronuclear S phase or were nonreplicating. The way in which histone H4 localized to either the macronucleus or the micronucleus suggested that it accumulates in whichever nucleus is replicating. The inability of the micronucleus to accumulate Tetrahymena H1 or heterologous nuclear proteins, even at a period in the cell cycle when it is accumulating H4, suggests that it has a specialized transport system. These studies demonstrate that although the mechanism for localizing proteins to nuclei is highly conserved among eukaryotes, it can differ between two porecontaining nuclei lying in the same cytoplasm.

Histone acetylation in conjugating Tetrahymena thermophila

We have monitored histone acetylation during conjugation of the ciliated protozoan Tetrahymena thermophila using antibodies against the tetraacetylated form of H4 histone (Pfeffer, U., N. Ferrari, and G. Vidali. 1986. J. Biol. Chem. 261:2496-2498). During meiosis, the three prezygotic divisions, fertilization, and the first postzygotic division, micronuclei, do not contain highly acetylated forms of H4 histone. However, after the second postzygotic division, when anteriorly located micronuclei begin to develop into new macronuclei, they are strongly stained by the anti-tetraacetylated H4 histone antibody. In the old macronucleus, histones are actively deacetylated when it has ceased to transcribe but before it is eliminated. Histone acetylation processes analyzed here appear to be correlated to the commitment to transcription rather than to the transcription process itself. This is in good correlation with evidence we have obtained in chick erythrocyte nuclei during reactivation upon fusion with mammalian cells (Pfeffer, U., N. Ferrari, F. Tosetti, and G. Vidali. 1988. Exp. Cell Res. 178:25-30). Furthermore, it becomes clear from our data that histone acetylation occurs in close correlation to the position of nuclei within the cytoplasm of T. thermophila. Mechanisms that control differential histone acetylation and deacetylation are discussed.

Lipid modification during cytodifferentiation of Tetrahymena vorax. Whole cell phospholipids and triacylglycerols of microstomal and macrostomal phenotypes

Microstomal cells of the ciliate Tetrahymena vorax V2S can be induced to undergo cytodifferentiation to form an alternate phenotype known as the macrostomal cell; however, sublines of T. vorax exist that respond differently to methods that induce macrostomal cell formation. The phospholipid- and triacylglycerol-bound fatty acid compositions of microstomal and macrostomal cells of a high-transforming subline (designated 3-C) were determined and compared to similar data from cells of a low-transforming subline (designated Ala). Differences in fatty acid composition were found between the two phenotypes as well as between the different sublines. Some change in the distribution of radioactive acetate and lauric acid into phospholipid classes of the different subline was observed, and evidence was also obtained that indicated changes in the relative amounts of the sterol-like pentacyclic triterpenoid tetrahymanol. A limited analysis of the lipid composition of stomatin revealed the presence of small amounts of tetrahymanol, phospholipid and free fatty acid. Stomatin is the naturally produced material obtained from T. pyriformis that triggers differentiation in T. vorax. The existence of a low-transforming subline provides a powerful experimental tool for elucidating the underlying biochemical and molecular mechanisms that control cytodifferentiation in T. vorax and possibly in other eukaryotic cells.

Egestion of asbestos fibers in Tetrahymena results in early morphological abnormalities. A step in the induction of heterogeneous cell lines?

In Tetrahymena populations exposed to crocidolite asbestos fibers, many cells develop morphological abnormalities within 1-2 hours. The abnormalities are mainly large or small protrusions or indentations, or flattened parts of the cell surface and most often located in the posterior part of the cell. They are formed repeatedly in all cells but are also continuously repaired so that the fraction of cells affected represents an equilibrium between these two processes. Their formation is connected with egestion of the large bundles of fibers formed by phagocytosis. Such effects of egestion of fibers do not seem to have been reported previously. Egestion of a bundle of fibers is much slower than for other types of undigestible residues. In contrast to normal exocytosis occurring invariably at the cytoproct, egestion of asbestos often occurs in the posterior part of the cell outside the cytoproct. To my knowledge this is the first reported case of either very slow or extra-cytoproctal egestion in Tetrahymena. Cells with large abnormalities have a greater tendency to develop into "early heterogeneous" cells than the average abnormal cell. Some of these give rise to hereditarily stable heterogeneous cell lines of Tetrahymena. The morphological abnormalities are probably caused by mechanical action of the crocidolite fibers resulting in local damage of the cytoskeletal elements responsible for normal cell shape. The heterogenous cell lines may arise when cellular structures carrying non-genic cytotactically inherited information are modified. The relevance of these ideas to the induction of cancer by asbestos is briefly discussed.

Cell volume and dry weight of cultured Tetrahymena

Cultures of Tetrahymena pyriformis, T. hegewishi and T. malaccensis have been studied with regard to control of cell volume and cellular dry weight. Cell volume was measured on cells suspended in 0.9% sodium chloride + 0.1% sodium azide using a Multisizer cell counter (Coulter). Tetrahymena were grown at different temperatures and under various up- or downshift conditions. In all cases the changes in cell volume are paralleled by changes in cellular dry weight. The volume and the dry weight of a Tetrahymena cell are determined by the particular medium and the growth temperature. Large cells are seen in concentrated media and at low growth temperatures resulting in cell volumes up to 17,000 microns 3, whereas starving cells decrease gradually towards 700 microns 3 or even smaller sizes. It is proposed that lag phase observed at up- and downshift is to a large extent due to the necessary adjustment of the cell volume to the new conditions.

A conditional mutant having paralyzed cilia and a block in cytokinesis is rescued by cytoplasmic exchange in Tetrahymena thermophila

Nineteen mutants that are conditional for both the ability to regain motility following deciliation and the ability to grow were isolated. The mutations causing slow growth were placed into five complementation groups. None of the mutations appears to affect energy production as all mutants remained motile at the restrictive temperature. In three complementation groups protein synthesis and the levels of mRNA encoding alpha-tubulin or actin were largely unaffected at the restrictive temperature, consistent with the hypothesis that mutations in these three groups directly affect the assembly of functional cilia and growth. Complementation group 1 was chosen for further characterization. Both phenotypes were shown to be linked, suggesting they are caused by a single mutation. Group 1 mutants regenerated cilia at the restrictive temperature, but the cilia were nonmotile. This mutation also caused a block in cytokinesis at the restrictive temperature but did not affect nuclear divisions or DNA synthesis. The block in cell division was transiently rescued by wild-type cytoplasm exchanged when mutants were paired with wild-type cells during conjugation (round 1 of genomic exclusion). Thus, at least one mutation has been isolated that affects assembly of some microtubule-based structures in Tetrahymena (cilia during regeneration) but not others (nuclei divide at 38 degrees), and the product of this gene is likely to play a role in both ciliary function and in cytokinesis.

Localization and expression of mRNA for a macronuclear-specific histone H2A variant (hv1) during the cell cycle and conjugation of Tetrahymena thermophila

hv1 is a histone H2A variant found in the transcriptionally active Tetrahymena macronucleus but not in the transcriptionally inert micronucleus. This, along with a number of other lines of evidence, suggests that hv1 is associated with active genes. We have used a cDNA clone as a probe to study hv1 mRNA accumulation throughout the cell cycle and during conjugation. In situ hybridization to glutaraldehyde-fixed growing cells, whose position in the cell cycle was determined by size and morphology, showed that hv1 message is present throughout the cell cycle. The message was uniformly distributed in these vegetative cells. Compared with four other Tetrahymena histone genes studied to date (S. -M. Yu, S. Horowitz, and M. A. Gorovsky, Genes Dev., 1:683, 1987; M. Wu, C. D. Allis, and M. A. Gorovsky, Proc. Natl. Acad. Sci. USA 85:2205, 1988), hv1 mRNA is the only one that does not show a pattern of accumulation during the cell cycle that could explain the nuclear localization of its encoded protein. Thus, either hv1 or some molecule with which it associates contains a macronuclear-specific targeting sequence or there exists a cell cycle-regulated event that restricts its translation to the macronuclear S phase. In situ hybridization to conjugating cells revealed that hv1 message amounts increase just prior to macronuclear development and decline precipitously after the cells separate. The hv1 message showed no marked subcellular localization and is, therefore, unlikely to play a role in the cytoplasmic determination known to occur during macronuclear development.

A temperature-sensitive mutation affecting cilia regeneration, nuclear development, and the cell cycle of Tetrahymena thermophila is rescued by cytoplasmic exchange

A temperature-sensitive mutation was isolated that blocks cilia regeneration and arrests growth in Tetrahymena thermophila. Protein and RNA synthesis and ATP production appeared to be largely unaffected at the restrictive temperature, suggesting that the mutation is specific for cilia regeneration and growth. At the restrictive temperature, mutant cells arrested at a specific point in the cell cycle, after macronuclear S phase and shortly before micronuclear mitosis. Arrested cells did not undergo nuclear divisions, DNA replication, or cytokinesis, so the mutation appears to cause true cell cycle arrest. Surprisingly, the mutation does not appear to affect micronuclear mitosis directly but rather some event(s) prior to micronuclear mitosis that must be completed before cells can complete the cell cycle. The cell cycle arrest was transiently complemented by wild-type cytoplasm exchanged during conjugation with a wild-type cell. Each starved, wild-type cell apparently contained enough rescuing factor to support an average of six cell divisions. Thus, this mutation affects assembly and/or function of at least one but not all of the microtubule-based structures in T. thermophila.

Cell-cycle regulation as a mechanism for targeting proteins to specific DNA sequences in Tetrahymena thermophila

Transcriptionally active macronuclei and transcriptionally inert micronuclei of the ciliated protozoan Tetrahymena thermophila contain similar DNA sequences but have very different histones associated with the linker regions of chromatin. In situ hybridization showed that a gene coding for micronuclear linker histone is expressed only in association with micronuclear DNA replication, whereas the gene for macronuclear H1 histone is expressed during macronuclear (but not during micronuclear) S phase. These results indicate that cell-cycle regulation plays an important role in directing proteins to the appropriate nucleus in Tetrahymena and that the replication-expression model [Gottesfeld, J. & Bloomer, L. S. (1982) Cell 28, 781-791; Wormington, W. M., Schlissel, M. & Brown, D. D. (1983) Cold Spring Harbor Symp. Quant. Biol. 47, 879-884] for establishing appropriate transcriptionally active or repressed chromatin complexes during DNA replication is generally applicable.

Induction of cybrid strains of Tetrahymena thermophila by electrofusion

In this paper, the electrofusion of the ciliated protozoan, Tetrahymena thermophila, is described. Deciliated cells were brought into close membrane contact by dielectrophoresis in a weakly conductive medium. Then cell fusion was induced by application of repeated electric pulses. Up to 20 prestarved, logarithmic or stationary phase cells of the same or different mating types may form a single giant cell. The polykaryons are fully able to regenerate cilia and became motile. After an initial process of partial integration the polykaryons yield viable clones by separation of components. Cytoplasmic exchange between fused components occurs before separation. Cytoplasmically inherited chloramphenicol resistance was transmitted from one strain to another by electrofusion and drug-resistant cybrid strains were generated.

Parameters affecting the maximum cell concentration of Tetrahymena

In cultures with efficient aeration a maximum cell concentration (MCC) of 6 X 10(5) cells/ml (defined medium) and 5.5 X 10(6) cells/ml (broth) can be reached. By culturing within Millicells with excess supply of medium and efficient removal of waste products a physical limit for MCC of about 13 X 10(6) cells/ml is reached.

The abundance of alpha-tubulin mRNA increases during ciliary regeneration in Tetrahymena, and this occurs independently of the soluble tubulin content

Control mechanisms of tubulin synthesis are analyzed during ciliary regeneration of the ciliate Tetrahymena. Titration of the alpha-tubulin mRNA concentrations during the regeneration period reveal that enhancement of tubulin synthesis is preceded and accompanied by increased concentrations of tubulin mRNA molecules. Stimulation of tubulin synthesis is independent of the pool size of soluble tubulin molecules, as suggested by at least two independent lines of evidence: First, like cells of normal phenotype a temperature sensitive size mutant enhances tubulin synthesis as well as tubulin mRNA concentration during ciliary regeneration, although these large mutant cells have a much higher concentration and amount of soluble tubulin molecules in the cytoplasm. Second, slowly regenerating cells of normal phenotype shift-up their concentration of tubulin mRNA molecules already before a time, when ciliary outgrowth might cause a significant depletion of the pool of soluble tubulin molecules. Thus, neither an induction of tubulin synthesis nor an increase in tubulin mRNA molecules is mediated via changes in the pool size of soluble tubulin molecules.

Unidirectional co-stimulation by a non-mating strain of Tetrahymena thermophila

We report that a fatty acid auxotroph of Tetrahymena thermophila (RH179E1) fails to mate, yet retains the ability to co-stimulate normal cells unidirectionally. Thus, co-stimulation can be analyzed experimentally in the absence of pair formation. We show that the co-stimulation of normal cells of one mating type is sufficient to shorten the waiting period for pair formation of those cells with initiated cells. This is the first evidence that co-stimulation causes a hyperinduction of mating reactivity in T. thermophila, generating in turn a positive feedback mechanism for (presumably) gamone production. Co-stimulation by the variant strain is at a maximum after 3-4 h of exposure when the variant and wild-type cells are at a ratio of 1:1. When mixed with wild-type cells, RH179E1 induces the formation of progeny (at low frequency) which inherit exclusively genetic material of the wild-type cells.

Yeast centromere sequences do not confer mitotic stability on circular plasmids containing ARS elements of Tetrahymena thermophila rDNA

We have previously demonstrated that a 657 bp TaqI-XbaI and a 427 bp XbaI-XbaI fragment from the 5' non-transcribed spacer of the extrachromosomal ribosomal DNA of Tetrahymena thermophila function as autonomously replicating sequences (ARS) in Saccharomyces cerevisiae. These fragments are adjacent to each other in a region that encompasses the in vivo origin of bidirectional replication of rDNA. The presence of a yeast centromere (CEN) fragment does not confer mitotic stability on these plasmids. A sensitive yeast colony colour assay (Hieter et al. 1985a) has been used to evaluate the cis-acting effect of each ARS segment on the pattern of inheritance of a plasmid containing CEN5:URA3:SUP4. Colonies of transformed cells obtained both in the presence and absence of selection were red with no detectable white or pink sectors. The lack of sectoring indicates that both plasmids are lost at an extremely high rate, likely due to 1:0 segregation events. We conclude that while these ARS elements confer a high frequency transformation phenotype, they lack a function which is required in cis for the maintenance of mitotic stability in the presence of a centromere. This missing cis-acting function may result in the inability of the plasmids to be brought under the control of cell-cycle regulated replication.

Positional reorganization in compound janus cells of Tetrahymena thermophila

The janus mutations of Tetrahymena thermophila convert the large-scale organization of the dorsal surface of the cell into a mirror-image of the ventral surface, which is characterized by a second, abnormal, oral apparatus and by contractile vacuole pores to the left of the second oral area rather than the usual right. This conversion could be due either to a local change in the response to an unaltered positional system or to a more global reorganization of the system itself. janus homopolar doublets were used to distinguish between these two alternatives. Homopolar doublets can be made by fusing two similarly oriented cells in side-by-side parabiosis. Non-janus homopolar doublets typically possess two sets of normal oral structures with contractile vacuole pores to the right of each of them. In janus doublets, there are up to four sets of oral structures, with the abnormal oral structures located between the two sets of normal oral structures; contractile vacuole pores are situated to the right of the normal oral areas and to the left of the abnormal oral structures. Non-janus homopolar doublets are known to propagate their compound condition for a number of cell divisions, but also to regulate toward the singlet state through a progressive reduction in number of ciliary rows followed by loss of one of the two sets of major cell surface structures. janus homopolar doublets go through a corresponding regulation. As a consequence, the location of the abnormal oral structures relative to the normal ones is more variable in janus doublets than in janus singlets. Sometimes the abnormal oral structures shift to a position close to their normal counterparts and then the intervening CVP sets disappear. There is evidence for occasional fusion of an abnormal oral area with an adjacent normal oral apparatus, a condition that may be transitional to the singlet state. These observations are inconsistent with the idea of a fixed positional system and strongly suggest a global reorganization of the surface pattern in a manner consistent with predictions of an intercalation model that was first proposed to explain the regulation of non-janus doublets to singlets.