Preconjugant cell interaction and cell cycle in the ciliate Euplotes crassus. Switching from the vegetative to the sexual stage.

Cells of Euplotes crassus can mate during the entire extent of G₁ as well in the very early macronuclear S phase. An arrest to cell cycling that occurs during mating is triggered by the ciliary agglutination that takes place between complementary cells, after a waiting period and before the cell bodies fuse into conjugal pairs. Cycling arrest is reversible. Sexually developing cells returned to nutrient conditions are able to reinitiate macronuclear DNA synthesis, although after a lag period. The synchronous reinitiation of synthesis is interpreted as a consequence of reprogramming events that occur as cells switch from the vegetative to the sexual stage of the life cycle.     

Recombination and Assortment in the Macronucleus of TETRAHYMENA THERMOPHILA: A Theoretical Study by Computer Simulation

The compound nature of the macronucleus of Tetrahymena thermophila presents multiple opportunities for recombination between genes on the same macronuclear chromosome. Such recombinants should be detectable through their assortment at subsequent amitotic macronuclear divisions. Thus, a macronucleus that is initially AB/ab should produce recombinant assortees of the genotypes Ab/aB. Computer simulation shows that, when the recombination frequency is two or fewer times per cell cycle, recombinant assortees are produced at experimentally measurable frequencies of less than 40%. At higher recombination frequencies, linked genes appear to assort independently. The simulations also show that recombination during macronuclear development can be distinguished from recombination in subsequent cell cycles only if the first appearance of recombinant assortees is 100 or more fissions after conjugation. The use of macronuclear recombination and assortment as a means of mapping macronuclear genes is severely constrained by the large variances in assortment outcomes; with experimentally small sample sizes, such mapping is impossible.     

Cell cycle mutation in Paramecium tetraurelia discriminates between sexual and vegetative functions

The temperature-sensitive mutation cc1 blocks a number of cell cycle processes in Paramecium including macronuclear DNA synthesis, oral morphogenesis, and the later stages of micronuclear mitosis. Oral morphogenesis and micronuclear mitosis also occur in the sexual pathway. This study shows that cc1 cells can proceed through conjugation or autogamy under restrictive conditions; neither stomatogenesis nor micronuclear mitosis is blocked. Fertilization and macronuclear determination occur normally, but DNA synthesis in macronuclear anlagen is blocked. Therefore, this mutation discriminates between oral replacement during meiosis and vegetative prefission stomatogenesis, and between mitotic spindle elongation during the pregamic and postzygotic divisions and spindle elongation during the vegetative cell cycle. These results point to a fundamental regulatory difference between morphogenesis in the vegetative and sexual pathways. © 1994 Wiley-Liss, Inc.     

Nuclear Behavior During Reconjugation in Euplotes patella (Ciliophora,Hypotrichida)1

Nuclear behavior during reconjugation and the ultimate fate of the ex-reconjugants were followed after induction of reconjugation in Euplotes patella. An exconjugant could reconjugate with a vegetative cell or with another exconjugant. Exconjugants at an early stage of macronuclear development (oval macronuclear anlagen) did not reconjugate frequently whereas exconjugants at a late stage of macronuclear development (rod-like macronuclear anlagen) reconjugated frequently. In all cases, the micronucleus underwent normal meiosis and other nuclear changes. After reconjugation, a new macronuclear anlage and a new micronucleus were formed normally, so that there were two kinds of macronuclear anlagen in the exconjugants, an old and a new. The old rod-shaped anlage did not disappear after the differentiation of a new one, but it was broken up into several fragments. While the survival rate after normal conjugation was 78%, it was 0–20% after reconjugation. These results suggest that the micronuclei of exconjugants can act as germ nuclei even at a very early stage and that reconjugation, unlike conjugation, is harmful to the cell.     

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.     

Mutants of Sexual Maturity in PARAMECIUM CAUDATUM Selected by Erythromycin Resistance

Cells of Paramecium caudatum, syngen 3 usually become sexually mature about 50 fissions after conjugation. In order to study the genetic mechanisms that control fission-dependent expression of maturity, an attempt was made to obtain early mature mutants by treatment with N-methyl-N'-nitro-N-nitro-soguanidine. A new cytoplasmic marker, erythromycin resistance, was used to eliminate nonconjugant and macronuclear regeneration clones. Twenty early mature clones were obtained from five different mutagenized cultures. Three of them were genetically analyzed by crosses to wild-type stocks. The results show all three mutants to be controlled by incompletely dominant genes, i.e., the homozygotes became mature 20-25 fissions and the heterozygotes 15 fissions earlier than the wild-type clones. At least two different loci are suggested for the early maturity.     

Accessory gland size influences time to sexual maturity and mating frequency in the stalk-eyed fly, Cyrtodiopsis dalmanni

Age at first reproduction is an extremely important life-historytrait. Several factors such as nutritional state and age-specificfecundity have been shown to influence time to sexual maturity;however, little work has been done in insects. We addressedthis in a stalk-eyed fly (Cyrtodiopsis dalmanni), by testingthe hypothesis that time to sexual maturity is associated withthe development of male internal reproductive structures. Wefound that sexual maturity was attained after an increased rateof growth in the accessory glands, several days after maturesperm bundles, and motile sperm were observed in the testes.Although testis development is essential, the results suggestthat accessory gland growth is more closely associated withthe time taken to reach sexual maturity than is testis growth.When we manipulated the growth of testes and accessory glandsvia a dietary manipulation, we found that delayed growth ratesincreased the time taken to reach sexual maturity. Among thedelayed individuals, sexually mature males had larger accessoryglands, but not testes, than did immature males. In adult males,mating frequency was significantly positively correlated withaccessory gland size, but not with testis length or body size.We conclude that accessory gland size is a critical determinantof sexual maturity and male mating frequency in this species.     

Induction of Blocks in Nuclear Divisions and Overcondensation of Meiotic Chromosomes with Cycloheximide During Conjugation of Tetrahymena thermophila

During conjugation, the micronucleus of Tetrahymena thermophila undergoes five consecutive nuclear divisions: meiosis, third prezygotic division (pregamic mitosis) and two postzygotic mitoses of the synkaryon. The four products of the synkaryon differentiate into macronuclear anlagen and new micronuclei and the old macronucleus is resorbed. The protein synthesis inhibitor cycloheximide, applied during conjugation, induced several developmental blocks. Pairs shifted to the drug during early meiotic prophase (stages I–III) were arrested at prophase. Cycloheximide applied to cells at pachytene (stages IV-VI) to metaphase arrested the conjugants at the stage of modified prometaphase/metaphase with overcondensed, swollen bivalents. In contrast to other systems, in the presence of cycloheximide, separation of chromatids, decondensation of chromosomes and exit from metaphase I were inhibited in both diploid and haploid cells. Pairs shifted to the drug after metaphase I were arrested at postmeiotic interphase after completing one nuclear cycle. The same rule applied to the subsequent cycle; then cells were arrested at the stage of pronuclei, and those pairs with functional pronuclei and synkarya were arrested at the stage of two products of the first postzygotic division (pronuclei were not arrested in nuclear transfer and karyogamy). Only pairs with two products of the first postzygotic division were arrested at the same stage after the cycloheximide treatment. Pairs shifted to cycloheximide during the second postzygotic division were arrested in development of macronuclear anlagen and resorption of old macronuclei. The postmeiotic conjugants pulse-treated with cycloheximide (2 h) yielded heterokaryons retaining parental macronuclei (i.e. they exhibited macronuclear retention).     

Mating Types, Breeding System, Conjuàtion and Nuclear Phenomena in the Marine Ciliate Euplotes cristatus Kahl from the Gulf of Naples

SYNOPSIS. The marine ciliate Euplotes cristatus Kahl (Ciliophora, Hypotrichida), collected off Capri, Gulf of Naples, is described in detail. From populations, 6 different mating types, representing 1 variety or syngen, have been isolated. The breeding relations revealed a multiple mating type system characteristic of other members of the Hypotrichida that have been investigated. Presumably a 7th mating type was found which does not mate with any of the others. Although this may belong to another syngen, it could represent a mating type which has not yet reached sexual maturity or 1 which may be in a period of decline. Animals of different mating type do not mate immediately after being mixed but usually 3 or more hours later. An agglutination reaction involving many specimens is absent. Instead, 2 ciliates engage in a “pairing play” before joining firmly in conjugation. Well-fed or actively feeding and dividing ciliates do not mate; mating occurs only after the food becomes gradually depleted or when the food supply is sharply cut off. All mating types appear to be extremely stable. Neither selfing pairs (intraclonal conjugation) nor autogamy have been observed within any clonal culture during the several years under investigation. Cell-free filtrates from 1 mating type do not elicit mating or induce conjugation with specimens of a different mating type. The general pattern of nuclear events in conjugation and exconjugant reorganization is as follows: 1 preliminary division, 3 pregamic (prezygotic) divisions, fertilization, and generally 1 or occasionally 2 postzygotic divisions. The fate of micronuclear products may be determined by their size and location. Those which are larger and close to the cell membranes of the joined conjugants persist and/or divide. Those which are smaller are carried by cyclosis toward the center of each ciliate and degenerate. The degenerating macronucleus of each conjugant becomes segmented in a more or less uniform manner resulting in 4 subspherical masses. Two become localized in the anterior end of a conjugant and 2 in the posterior end. Those in the posterior end are always the first to degenerate completely and disappear. In nuclear reorganization of the exconjugant, fusion of the macronuclear anlage with parts of the old macronucleus does not occur.     

Genomic exclusion in Tetrahymena thermophila: A cytogenetic and cytofluorimetric study

Genomic exclusion is an aberrant form of conjugation of Tetrahymena thermophila in which the genome of a defective conjugant is excluded from the genotype of the exconjugant progeny. This paper is concerned with the cytogenetic and nucleocytoplasmic events of genomic exclusion in senescent clones A*III and C*. In crosses between A*III or C* and strain B, functional, haploid gametic nuclei are formed only in the strain B cell. In some instances one of the gametic nuclei divides prior to transfer of the migratory gametic nucleus, and both products then undergo DNA synthesis. Two alternative cytogenetic pathways are followed after transfer of the migratory nucleus. In the first, the conjugants separate without further micronuclear divisions. This pathway was most common in A*III genomic exclusion. In exconjugants the former gametic nuclei undergo both DNA synthesis and (presumably) intranuclear separation of centromeres to restore micronuclear diploidy. The old macronucleus of each exconjugant is retained without autolysis. This class of exconjugant survives and contributes genes to future sexual progeny. In the second cytogenetic pathway the gametic nuclei divide and macronuclear anlagen are formed, as in normal conjugation. This pathway was more common in C* genomic exclusion. The initial DNA content of the anlagen ranges from haploid to diploid. Following two to three rounds of DNA synthesis, further macronuclear development ceases and the anlagen appear to undergo autolysis. The old macronucleus condenses and also undergoes autolysis, as in normal conjugation. Except for rare C* exconjugants, in which macronuclear development is completed, anlagen-bearing genomic exclusion exconjugants die. Death may be caused by aneuploidy, errors in the timing or receptivity to signals for autolysis, or the inability of anlagen-bearing exconjugants to feed. Anlagenbearing conjugants are frequently abnormal with respect to the number of anlagen and micronuclei. Most of the anomalies can be explained by postulating errors in the timing of both developmental signals and nuclear divisions. Rare conjugants in which gametic nuclei divide but do not give rise to macronuclear anlagen are also observed. In these instances, the old macronuclei condense and undergo autolysis. Destruction of the old macronucleus therefore is independent of the presence of macronuclear anlagen and requires cell pairing in order to be initiated.     

Stage-specific changes in protein synthesis during conjugation in Tetrahymena thermophila

Conjugation in the free-living ciliate Tetrahymena thermophila is an inducible developmental system which results in a synchronized reorganization of the genetic material in both mates of a pair. The cytological events were followed by Feulgen stainings of simultaneously mating cells and protein synthesis was revealed using [³⁵S]methionine pulse labelling and two-dimensional gel electrophoresis. At least 33 proteins, including 24 conjugation-specific proteins, with apparent molecular weights (M_r) between 61 and 200 × 10³ are stimulated during conjugation. Two slightly acidic proteins (M_r 89 and 73 × 10³, respectively) are stimulated shortly after mixing of mating-competent cells and mainly before tight pairs are formed. Ten proteins are stimulated during meiosis, and two of these (M_r 90 and 78 × 10³, respectively) are particularly interesting, since they are highly stimulated and more basic (pI values around 8.5) than most other proteins detected. Twelve proteins are stimulated essentially between pairing and early macronuclear development, three are stimulated from shortly before zygote formation and during the postzygotic divisions, and six are stimulated during late conjugation, at various parts of macronuclear development. The functions of the conjugation-stimulated proteins are discussed.     

A Transmissible developmental block in Tetrahymena thermophila

When the amicronucleate mutant BI3840 of Tetrahymena thermophila is mated with normal micronucleate cells, it receives a pronucleus from its partner but there is no further nuclear development and the conjugants separate, retaining their original macronuclei. Both of these sexually mature exconjugants and any cells with which they are mated show an unconditional block in macronuclear development. Although prezygotic nuclear divisions, nuclear transfer and post-zygotic nuclear divisions appeared normal upon cytological analysis of Giemsa-stained conjugants, macronuclear development was invariably aborted. Since the original macronucleus was resorbed, the cells were rendered amacronucleate and they died. When no macronuclear development was initiated, as in crosses with the aneuploid strain A* (III), the exconjugants were viable and retained their original macronuclei. This pattern was invariant with three different strains serving as the original micronuclear source, and in the case of one non-BI3840 exconjugant, persisted for over 200 cell generations. Exconjugants from a cross of one of the micronuclear donors with strain A* (III) did not show arrested development when crossed. It thus appears likely that there is conjugal transfer of non-nuclear information originating in BI3840 which is self-replicating and which causes an arrest in macronuclear development.     

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.     

LIA4 Encodes a Chromoshadow Domain Protein Required for Genomewide DNA Rearrangements in Tetrahymena thermophila

Extensive DNA elimination occurs as part of macronuclear differentiation during Tetrahymena sexual reproduction. The identification of sequences to excise is guided by a specialized RNA interference (RNAi) machinery that targets the methylation of histone H3 lysine 9 (K9) and K27 on chromatin associated with these internal eliminated sequences (IESs). This modified chromatin is reorganized into heterochromatic subnuclear foci, which is a hallmark of their subsequent elimination. Here, we demonstrate that Lia4, a chromoshadow domain-containing protein, is an essential component in this DNA elimination pathway. LIA4 knockout (ΔLIA4) lines fail to excise IESs from their developing somatic genome and arrest at a late stage of conjugation. Lia4 acts after RNAi-guided heterochromatin formation, as both H3K9 and H3K27 methylation are established. Nevertheless, without LIA4, these cells fail to form the heterochromatic foci associated with DNA rearrangement, and Lia4 accumulates in the foci, indicating that Lia4 plays a key role in their structure. These data indicate a critical role for Lia4 in organizing the nucleus during Tetrahymena macronuclear differentiation.     

Macronuclear Regeneration and Cell Division in Paramecium caudatum

SYNOPSIS. In Paramecium caudatum , occurrence of macronuclear regeneration is closely related to the time of feeding after conjugation. Macronuclear regeneration is induced with a high frequency when conjugating pairs are transferred into fresh culture medium. Feeding immediately after conjugation induces early cell division and 3 or more fissions occur without macronuclear division because of the inability of the macronuclear anlagen to divide. In the cells lacking normal macronuclear anlagen, old macronuclear fragments undergo regeneration and form vegetative macronuclei.     

Temperature Effects on Maturity Periods in Tetrahymena pyriformis Syngen 1*

Cells of Tetrahymena pyriformis syngen 1 grown at 30 C after conjugation achieve sexual maturity more quickly than do cells grown at 19 C, whether time is measured in numbers of cell divisions or in terms of absolute time. This result is achieved regardless of the temperature at which conjugation and nuclear reorganization occur. These observations differ from those of other workers investigating Paramecium, and suggest that the long term “chronometer” is more tightly coupled to cell division in Paramecium multimicronucleatum and Paramecium caudatum than in Tetrahymena pyriformis.     

The Oxytricha trifallax Macronuclear Genome: A Complex Eukaryotic Genome with 16,000 Tiny Chromosomes

The macronuclear genome of the ciliate Oxytricha trifallax displays an extreme and unique eukaryotic genome architecture with extensive genomic variation. During sexual genome development, the expressed, somatic macronuclear genome is whittled down to the genic portion of a small fraction (∼5%) of its precursor “silent” germline micronuclear genome by a process of “unscrambling” and fragmentation. The tiny macronuclear “nanochromosomes” typically encode single, protein-coding genes (a small portion, 10%, encode 2–8 genes), have minimal noncoding regions, and are differentially amplified to an average of ∼2,000 copies. We report the high-quality genome assembly of ∼16,000 complete nanochromosomes (∼50 Mb haploid genome size) that vary from 469 bp to 66 kb long (mean ∼3.2 kb) and encode ∼18,500 genes. Alternative DNA fragmentation processes ∼10% of the nanochromosomes into multiple isoforms that usually encode complete genes. Nucleotide diversity in the macronucleus is very high (SNP heterozygosity is ∼4.0%), suggesting that Oxytricha trifallax may have one of the largest known effective population sizes of eukaryotes. Comparison to other ciliates with nonscrambled genomes and long macronuclear chromosomes (on the order of 100 kb) suggests several candidate proteins that could be involved in genome rearrangement, including domesticated MULE and IS1595-like DDE transposases. The assembly of the highly fragmented Oxytricha macronuclear genome is the first completed genome with such an unusual architecture. This genome sequence provides tantalizing glimpses into novel molecular biology and evolution. For example, Oxytricha maintains tens of millions of telomeres per cell and has also evolved an intriguing expansion of telomere end-binding proteins. In conjunction with the micronuclear genome in progress, the O. trifallax macronuclear genome will provide an invaluable resource for investigating programmed genome rearrangements, complementing studies of rearrangements arising during evolution and disease.     

Positional control of nuclear differentiation in paramecium

Nuclear reorganization, which results in the differentiation between macronuclear anlagen and micronuclei during autogamy or conjugation in Paramecium tetraurelia, was compared in wild-type cells and in two mutants, mic44 and kin241, which form abnormal numbers of macronuclear anlagen and micronuclei. Our observations show that all macronuclear anlagen derive from the nuclei positioned at the posterior pole of the cell at the second postzygotic division. This posterior localization is transient and correlated with a marked change in cell shape and decrease of cell length. These results suggest that cytoplasmic or cortical factors precisely located in the posterior pole are essential to trigger macronuclear differentiation and that the control of nuclear positioning is dependent upon precise modifications of cell shape.     

Maternal effect mutations affecting macronuclear determination and development in Paramecium tetraurelia

Gene mutations that interfere with macronuclear development in Paramecium were obtained by selecting lines that failed to produce normal macronuclear anlagen following the second autogamy after mutagenesis. The mutants fell into several complementation groups. There was one case of apparent intragenic noncomplementation among the eight mutants examined. In the stronger mutants, macronuclear anlagen were not formed, and all four mitotic products of the posfzygotic divisions of the synkaryon remained as micronuclei. Under semirestrictive conditions, cells often contained a single anlage, suggesting that determination of anlagen was a discrete event for each nucleus. The missing anlagen trait was recessive and associated with a strong maternal effect. The phenocritical period of one of the stronger alleles, aal^a, began at the second postzygotic division and ended with the first morphological differentiation of macronuclear anlagen. Nuclear migration in this mutant was abnormal. Under restrictive conditions, the posterior products of the second postzygotic division reached a posterior-most position, which was 8% of cell length more anterior than that of the most posterior nuclei in wild-type cells. Under permissive conditions, the pattern of migration was intermediate between that of wild-type cells and mutants under fully restrictive conditions. The patterns of nuclear migration were consistent with the nuclear growth kinetics.     

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 10 mM 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 macronuclear 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.