Interactions between newly developed macronuclei and maternal macronuclei in sexually immature multinucleate exconjugants of Paramecium caudatum

The macronucleus of Paramecium caudatum controls most cellular activities, including sexual immaturity after conjugation. Exconjugant cells have two macronuclear forms: (1) fragments of the maternal macronucleus, and (2) the new macronuclei that develop from the division products of a fertilization micronucleus. The fragments are distributed into daughter cells without nuclear division and persist for at least eight cell cycles after conjugation. Conjugation between heterokaryons revealed that the fragmented maternal macronuclei continued to express genetic information for up to eight cell cycles. When the newly developed macronucleus was removed artificially within four cell cycles after conjugation, the clones regenerated the macronuclear fragments (macronuclear regeneration; MR) and showed mating reactivity, because they were sexually mature. However, when the new macronucleus was removed during later stages, many MR clones did not show mating reactivity. In some extreme cases, immaturity continued for more than 50 fissions after conjugation, as seen with normal clones that had new macronuclei derived from a fertilization micronucleus. These results indicate that the immaturity determined by the new macronucleus is not annulled by the regenerated maternal macronucleus. Mature macronuclear fragments may be "reprogrammed" in the presence of the new macronucleus, resulting in their expression of "immaturity."     

Histone rearrangements accompany nuclear differentiation and dedifferentiation in Tetrahymena

Histone synthesis and deposition into specific classes of nuclei has been investigated in starved and conjugating Tetrahymena. During starvation and early stages of conjugation (between 0 and 5 hr after opposite mating types are mixed), micronuclei selectively lose preexisting micronuclear-specific histones α, β, γ, and H3^F. Of these histones, only α appears to accumulate in micronuclear chromatin through active synthesis and deposition during the mating process. Curiously, α is not observed (by stain or label) in young macronuclear anlagen (4C, 10 hr of conjugation). Thus, young macronuclear anlagen are missing all of the histones which are known to be specific to micronuclei of vegetative cells. By 14–16 hr of conjugation, we observe active synthesis and deposition of macronuclear-specific histones, hv1, hv2, and H1, into new macronuclear anlagen (8C). Thus macronuclear differentiation seems well underway by this time of conjugation. It is also in this time period (14–16 hr) that we first detect significant amounts of micronuclear-specific H1-like polypeptides β and γ in micronuclear extracts. These polypeptides do not seem to be synthesized during this period, which suggests that β and γ are derived from a precursor molecule(s). Since these micronuclear-specific histones do not appear in micronuclear chromatin until after other micronuclei have been selected to differentiate as macronuclei, we suspect that micronuclear differentiation is also an important process which occurs in 10–16 hr mating cells. Our results also suggest that proteolytic processing of micronuclear H3^S into H3^F (which occurs in a cell cycle dependent fashion during vegetative growth) is not operative during most if not all of conjugation. Thus micronuclei of mating cells contain only H3^S which also seems consistent with the fact that some micronuclei differentiate into new macronuclei (micronuclear H3^S is indistinguishable from macronuclear H3). Interestingly, the only H3 synthesized and deposited into the former macronucleus of mating cells is the relatively minor macronuclear-specific H3-like variant, hv2. These results demonstrate that significant histone rearrangements occur during conjugation in Tetrahymena in a manner consistent with the fact that during conjugation some micronuclei eventually differentiate into new macronuclei. Our results suggest that selective synthesis and deposition of specific histones (and histone variants) plays an important role in the nuclear differentiation process in Tetrahymena. The disappearance of specific histones also raises the possibility that developmentally regulated proteolytic processing of specific histones plays an important (and previously unsuspected) role in this system.     

Internuclear control of DNA synthesis in exconjugant cells of Paramecium caudatum

An exconjugant cell of Paramecium caudatum has two kinds of macronuclei, fragmented prezygotic macronuclei and postzygotic new macronuclei (anlagen). Although the DNA synthesis in the fragmented prezygotic macronucleus continues until the third cell cycle after conjugation, selective suppression of the DNA synthesis in the prezygotic macronucleus takes place at the fourth cell cycle. The inhibition of DNA synthesis in prezygotic fragmented macronuclei is due to the presence of a postzygotic macronucleus (anlage) in the same cytoplasm because the inhibition does not occur when the postzygotic macronucleus (anlage) is removed by micromanipulation during the third or fourth cell cycle. Well-developed postzygotic macronuclei (anlagen) with full ability to divide have the ability to depress the DNA synthesis of prezygotic macronuclear fragments. The suppression of DNA synthesis in prezygotic macronuclear fragments seems to be irreversible. Competition for the limited amount of DNA precursors also plays an important role in the onset of the selective suppression of the DNA synthesis.     

Scheduled and unscheduled DNA synthesis during development in conjugating Tetrahymena

Autoradiography has been used to confirm and to extend previous microspectrophotometric studies (Doerder and DeBault, 1975) on the timing of DNA synthesis during conjugation in Tetrahymena thermophila. The majority of DNA synthesis occurs at the expected periods preceding gamete formation and the two postzygotic divisions and during macronuclear development. DNA in new macronuclei is endoreplicated in an extremely discontinuous fashion. Under starvation conditions, the first endoreplication (2C to 4C) occurs immediately after the second postzygotic division when both new macronuclei and new micronuclei replicate. The second endoreplication (4C to 8C) does not occur until after separation of conjugants. If mating cells are kept under prolonged starvation conditions (20-24 hr), refeeding induces a partially synchronous division, after which an unexpectedly high percentage of cells incorporate tritiated thymidine into both macro- and micronuclei. Two previously undescribed periods of DNA synthesis were observed in the micronuclei of conjugating Tetrahymena. The first occurs during the early stages of meiotic prophase, before full crescent elongation. The second takes place in an extended period corresponding to macronuclear anlagen development, before conjugants have separated. CsCl gradient analyses indicate that, in micronuclear fractions, only main band DNA is being synthesized in both of these periods. However, in macronuclear fractions from both stages, a significant fraction (approximately 20%) of the DNA being synthesized has the buoyant density of ribosomal DNA. The finding that macro- and micronuclear DNA can be synthesized simultaneously in a single cell, both during conjugation and after refeeding starved exconjugants, raises interesting questions of how macro- or micronuclear-specific histones are targeted to the appropriate nuclei.     

A Study of Odd Mating-Type Determination Factor by Transfer of Macronuclear Karyoplasm in PARAMECIUM TETRAURELIA

The unique feature of the "B system" of mating-type determination found in Paramecium tetraurelia is the existence of a cytoplasmic difference between odd (O) and even (E) cells created and maintained by the action of their macronuclei. Thus far, the presence of a determining factor that controls the differentiation of the developing zygotic macronucleus for O mating type has not been verified. Results of crosses between cells of differing clonal age and complementary mating type suggest that, for one to two fissions after autogamy, O cells produce some factor that determines the gametic nucleus (micronucleus) as mating type O. Direct evidence for the production of O-determining factor by the young O macronucleus was obtained by transplanting young O macronuclear karyoplasm (a part of the macronucleus) into E cells: 32-35% of E exautogamous clones transformed to O; transformation of E exautogamous clones to O reached as high as 72% by transfer of young O macronuclear karyoplasm from a conjugant, 3-4 hr after mixing. This indicates that O determinants produced by the O macronucleus can also act during the sensitive period of development of the new macronucleus. These O-determining factors may be produced or activated at the sexual stage and then decrease in activity in subsequent fissions after new macronuclear reorganization.     

Mutation affecting cell separation and macronuclear resorption during conjugation in Tetrahymena thermophila: Early expression of the zygotic genotype

A new recessive conjugation lethal mutation was found in Tetrahymena thermophila which was named mra for macronuclear resorption arrest. Other events affected by the mra mutations are separation of pairs, DNA replication in the macronuclear anlagen, and resorption of one of the two micronuclei. In wild-type crosses 50% of the pairs had separated by 12 hr after mixing two mating types and had completed resorption of the old macronucleus 1–2 hr later. In contrast most mra conjugants did not separate even by 24 hr after mixing and the old relic (condensed) macronucleus was seen in over 90% of them. After addition of 10mM calcium to the conjugation medium, the mra conjugants did separate but they still failed to complete resorption of the old macronucleus and to replicate macronuclear anlagen DNA in the exconjugants. The calcium induced separation of the mra conjugants occurred later than the separation of control pairs. During normal conjugation cell separation occurs before the first expression of known macronuclear genes and prior to processing of the macro-nuclear DNA. Therefore, the mra phenotype infers that separation of conjugants requires a signal which is produced by the macronuclear anlagen at an unusually early time. © 1992 Wiley-Liss, Inc.     

Nuclear Roles in the Post-Conjugant Development of the Ciliate Euplotes aediculatus II. Experimentally Induced Regeneration of Old Macronuclear Fragments1

Following conjugation in ciliates, the usual fate of the old pre-conjugant macronucleus is resorption. In some species, however, old macronuclei, or their fragments, have the ability to reform functional vegetative macronuclei when new macronuclear anlagen are defective. The present work on Euplotes shows that if anlagen are allowed to carry out their essential roles in early exconjugant development, including influence on cortical reorganization such that feeding can resume, they can then be permanently damaged by UV-microbeam irradiation and regeneration of old macronuclear fragments can occur. E. aediculatus exconjugants were anlage-irradiated at 40–60 hr of development and the irradiated cells cultured individually and fed. Squashes revealed enlargement and anteriorward migration of the persistent (posterior) macronuclear fragments. The first post-conjugant fission of such cells was delayed (times ranged 6–43 days) and did not seem to involve the damaged anlagen, which remained rudimentary, did not divide along with the cells, and were subsequently resorbed. It appeared that cell fission was supported by the fragments of the old macronuclei, which either divided or partitioned themselves between the two daughter cells. Mating tests performed on early clones derived from irradiated exconjugants revealed ample conjugation competence; intraclonal conjugation in such clones was also apparent. The absence of the immature period seen in normal exconjugants provides further evidence that the clones arose from cells with regenerated macronuclei.     

Mating type transformation by transfer of macronuclear chromatin in Paramecium tetraurelia

Macronuclear chromatin from vegetative cells of one mating type (O, or E) in Paramecium tetraurelia was transferred by micropipetting into the macronucleus of vegetative cells of the opposite mating type (E, or O). A few percent (<5%) of the recipient cells gave rise to, by asexual propagation, progenies amongst which some were found to have transformed their mating type in accordance with the donor chromatin. This demonstrates the transformation of mating type during asexual propagation of the cells. In the case of E chromatin transfer to O recipients, many asexual progenies of the recipients transformed from O to E mating type nevertheless remained O after one sexual cycle. Such results indicate two distinctive macronuclear activities in mating type determination: one determining mating type of vegetative cells and the other influencing the differentiation of the developing post-zygotic macronucleus for mating type. The results are interpreted by the hypothesis that the quantity of E macronuclear chromatin required for differentiation of the developing post-zygotic macronucleus from mating type is larger than required for mating type determination in vegetative cells.     

Mating type differentiation in Tetrahymena thermophila: Strong influence of delayed refeeding of conjugating pairs

Mating type differentiation in Tetrahymena thermophila is known to regularly involve stable hereditary alterations at a single chromosomal locus in the somatic (macro)nucleus. This differentiation is directionally affected by the temperature at which new macronuclei develop after fertilization. We now report large and predictable effects of delayed refeeding of conjugating pairs upon mating type differentiation, particularly among mat-2 homozygotes. The mating types whose frequency is affected the most are IV, VI, and VII, a set different from that most affected by temperature. We interpret our observations to reveal the existence of a second system which can participate in mating type differentiation, with different specificity from the system influenced by temperature under conditions of early refeeding of conjugating pairs. These observations enrich the phenomenology surrounding mating type differentiation in T thermophila and provide additional, easily controllable experimental conditions for the manipulation of mating type frequencies.     

Nuclear differentiation and nucleic acid synthesis in well-fed exconjugants of Paramecium aurelia

Paramecium aurelia exconjugants contain new macronuclear anlagen and numerous fragments of the old pre-zygotic macronucleus. Macronuclear anlagen develop during the first two cell cycles after conjugation. During this time their volume increases from about 11 m³ to about 3700 m³ and more than 10 doublings of DNA content occur. The rate of DNA synthesis is between two and three times as great as in the vegetative macronucleus. — In macronuclear fragments, however, DNA synthesis is suppressed. The rate of DNA synthesis in macronuclear fragments during the extended first cell cycle after conjugation (11 1/2 hr. vs. 5 1/2 hr. for the vegetative cell cycle) is only about one-third of the rate in vegetative macronuclei and there is only a 65% increase in the mean DNA content of fragments. The rate of fragment DNA synthesis continues to decrease during each of the subsequent two cell cycles. — Unlike the rate of DNA synthesis, the rate of RNA synthesis per unit of DNA is similar in macronuclear anlagen, macronuclear fragments and fully developed macronuclei. Macronuclear fragments continue to synthesize RNA at the normal rate long after the new macronuclei are fully developed. Fragments contribute about 80% of all RNA synthesized during the first two cell cycles after conjugation. RNA synthesis begins very early in the development of macronuclear anlagen and nucleolar material appears during the first half-hour of anlage development. — Chromosome-like structures were never observed during anlage development and there was no evidence of two periods of DNA synthesis separated by a DNA poor stage as has been observed in several hypotrichous Ciliates.     

Analysis of mating type determination by transplantation of O macronuclear karyoplasm in Paramecium tetraurelia

The odd (O) or even (E) mating type in Paramecium tetraurelia is determined during the first cell cycle after new macronuclear development. The present paper demonstrates that mating type E is irreversibly determined at the end of the first cell cycle. Direct evidence comes from transplanting O macronuclear karyoplasm containing O-determining factor into E autogamous cells during a new postzygotic macronuclear development. Transplantation of O macronuclear karyoplasm into E autogamous cells at 7–8 hr after the origin of the macronucleus from a product of the synkaryon produces nearly 100% O mating type among the exautogamous cell lines but almost none 10–11 hr after the origin of the macronucleus (around the end of the first cell cycle). The macronuclear anlagen at the stage at which mating type E seems to be fixed contains about 20 times as much DNA as the vegetative G1 micronucleus. The O-determining factor shifting E cells toward O mating type by transplanting O macronuclear karyoplasm is also produced by the newly developed macronucleus in an effective concentration at 10–11 hr after the sensitive period and produced at full levels by the third cell cycle. The level of O factor in the macronucleus then gradually declines with subsequent repeated rounds of DNA synthesis and is finally lost by the eighth cell cycle.     

A Nuclear Protein Involved in Apoptotic-like DNA Degradation in Stylonychia: Implications for Similar Mechanisms in Differentiating and Starved Cells

Ciliates are unicellular eukaryotic organisms containing two types of nuclei: macronuclei and micronuclei. After the sexual pathway takes place, a new macronucleus is formed from a zygote nucleus, whereas the old macronucleus is degraded and resorbed. In the course of macronuclear differentiation, polytene chromosomes are synthesized that become degraded again after some hours. Most of the DNA is eliminated, and the remaining DNA is fragmented into small DNA molecules that are amplified to a high copy number in the new macronucleus. The protein Pdd1p (programmed DNA degradation protein 1) from Tetrahymena has been shown to be present in macronuclear anlagen in the DNA degradation stage and also in the old macronuclei, which are resorbed during the formation of the new macronucleus. In this study the identification and localization of a Pdd1p homologous protein in Stylonychia (Spdd1p) is described. Spdd1p is localized in the precursor nuclei in the DNA elimination stage and in the old macronuclei during their degradation, but also in macronuclei and micronuclei of starved cells. In all of these nuclei, apoptotic-like DNA breakdown was detected. These data suggest that Spdd1p is a general factor involved in programmed DNA degradation in Stylonychia.     

Gigantic macroautophagy in programmed nuclear death of Tetrahymena thermophila

Programmed nuclear death (PND) in Tetrahymena is a unique process during conjugation, in which only the parental macronucleus is degraded and then eliminated from the progeny cytoplasm, but other co-existing nuclei such as new micro- and macronuclei are unaffected. PND through autophagic elimination is expected to be strictly controlled, considering the significant roles in ciliates such as turnover of disused organelles and production of the next generation. Here we demonstrate that PND in Tetrahymena involves peculiar aspects of autophagy, which differ from mammalian or yeast macroautophagy. Drastic change of the parental macronucleus occurs when differentiation of new macronuclei is initiated. Combined use of monodansylcadaverine and a lysosome indicator LysoTracker Red showed that prior to nuclear condensation, the envelope of the parental macronucleus changed its nature as if it is an autophagic membrane, without the accumulation of a pre-autophagosomal structure from the cytoplasm. Subsequently, lysosomes approached only to the parental macronucleus and localized at the envelope until a final resorption stage. In addition, we found that the parental macronucleus exhibits certain sugars and phosphatidylserine on the envelope, which are possible "attack me" signals, that are not found on other types of nuclei. These findings suggest that PND is a highly elaborated process, different from the typical macroautophagy seen in other systems, and is executed through interaction between specific molecular signals on the parental macronuclear envelope and autophagic/lysosomal machineries.     

Developmental regulation of gene expression in Tetrahymena

The onset of gene expression in Tetrahymena thermophila during macronuclear differentiation was investigated by assay of galactokinase in conjugating deoxygalactose-resistant heterokaryons. Our results distinguish three successive states of galactokinase gene expression for cells developing a new macronucleus: stage 0, refractory to induction; stage 1, inducible by refeeding; and stage 2, induced. The refractory period ends at 12 to 13 hr after the onset of conjugation; this corresponds to the time of pair separation, and occurs several hours after the new macronuclei have become morphologically distinguishable. Stage 1 cells behave indistinguishably from mature starved cells. Inhibitor studies suggest that galactokinase synthesis is induced coincidentally with the induction of bulk protein synthesis during conjugation: thus it behaves developmentally like a typical protein; and that galactokinase mRNA is probably transcribed within 1 hr prior to its translation. Thus, when conjugating cells are refed during the refractory period, some developmental condition prevents the swift induction of protein (and galactokinase) synthesis observed upon refeeding starved (nonmating) cells. The possible nature of this developmental phenomenon is discussed.     

Studies on the Macronuclei of Doublet Paramecium tetraurelia: Distribution of Macronuclei and DNA at Fission*

SYNOPSIS. Doublet Paramecium tetraurelia would be expected to contain 2 macronuclei if their nuclear complement were strictly analogous to that of singlets. However, most doublets are unimacronucleate. It is shown in this study that dimacronucleate cells are present only in young clones. Unimacronucleate cells arise either through abnormalities in the determination and distribution of macronuclear anlagen during the first cell cycle after conjugation, or from dimacronucleate cells through abnormal division and segregation of macronuclei during the fission process. When a change in the number of macronuclei occurs through abnormalities in the division and segregation of daughter macronuclei, the daughter cells produced typically have DNA contents more similar than those expected from either random segregation of daughter macronuclei, or from the normal segregation pattern in ciliates in which changes in the number of macronuclei in progeny cells do not occur. This suggests that part of the regulation process of macronuclear DNA content in Paramecium may occur through control of the segregation pattern of daughter macronuclei.