Genetic Characterization and Use of a Restriction Fragment Length Variant in the Hypotrichous Ciliate Euplotes crassus1

Two forms of a macronuclear DNA molecule differing in the presence or absence of a restriction endonuclease recognition site have been detected in the hypotrichous ciliate Euplotes crassus. Through a series of genetic crosses the two forms were shown to be allelic, being derived from a single micronuclear genetic locus. This restriction fragment length variant (RFLV) was used as a genetic marker to determine that the migratory and stationary pronuclei generated during mating can be genetically non-identical. In addition, the RFLV was used to investigate the efficiency of processing of the alternate alleles during macronuclear development and their subsequent transmission during vegetative growth. Little or no bias in the processing and/or amplification of the two alleles was observed during macronuclear development. During vegetative growth, however, changes in the relative amounts of the two alleles were observed.     

The processing of macronuclear-destined DNA sequences microinjected into the macronuclear anlagen of the hypotrichous ciliate Stylonchia lemnae.

We describe the construction of a vector carrying the micronuclear versions of two macronuclear DNA molecules, one of which was modified by the insertion of a polylinker sequence. This vector was injected into the polytene chromosomes of the developing macronucleus of Stylonychia and its processing during further macronuclear development and its fate in the mature macronucleus were analyzed. In up to 30% of injected cells the modified macronuclear DNA sequence could be detected. While the internal eliminated sequences (IES) present in the macronuclear precursor DNA sequence are still retained in the mature macronucleus, the modified macronuclear DNA sequence is correctly cut out from the vector, telomeres are added de novo and it is stably retained in the macronucleus during vegetative growth of the cells. This vector system represents an experimental system that allows the identification of DNA sequences involved in the processing of macronuclear DNA sequences during macronuclear development.     

Differential DNA amplification and copy number control in the hypotrichous ciliate Euplotes crassus

During macronuclear development in hypotrichous ciliated protozoans, several thousand macronuclear DNA molecules are amplified several-hundred fold. We investigated the regulation of this amplification by determining the copy numbers of three different macronuclear DNA molecules in the hypotrichous ciliate Euplotes crassus. Two of the macronuclear DNA molecules were present in approximately 1,000 copies per cell, while the third was present in approximately 6,500 copies per cell. These reiteration levels were achieved either during macronuclear development, or shortly thereafter, and were maintained during vegetative growth. The most abundant macronuclear DNA molecule is present as a single-copy sequence in the micronuclear genome. Thus, its high copy number results from differential amplification. These results indicate that DNA amplification during macronuclear development is regulated individually for each macronuclear DNA molecule.     

Variable copy number of macronuclear DNA molecules in Tetrahymena.

In Tetrahymena, the DNA of the macronucleus exists as very large (100 to 4,000-kb) linear molecules that are randomly partitioned to the daughter cells during cell division. This genetic system leads directly to an assortment of alleles such that all loci become homozygous during vegetative growth. Apparently, there is a copy number control mechanism operative that adjusts the number of each macronuclear DNA molecule so that macronuclear DNA molecules (with their loci) are not lost and aneuploid death is a rare event. In comparing Southern analyses of the DNA from various species of Tetrahymena using histone H4 genes as a probe, we find different band intensities in many species. These differences in band intensities primarily reflect differences in the copy number of macronuclear DNA molecules. The variation in copy number of macronuclear DNA molecules in some species is greater than an order of magnitude. These observations are consistent with a developmental control mechanism that operates by increasing the macronuclear copy number of specific DNA molecules (and the genes located on these molecules) to provide the relatively high gene copy number required for highly expressed proteins.     

RAD51 is required for propagation of the germinal nucleus in Tetrahymena thermophila

RAD51, the eukaryote homolog of the Escherichia coli recA recombinase, participates in homologous recombination during mitosis, meiosis, and in the repair of double-stranded DNA breaks. The Tetrahymena thermophila RAD51 gene was recently cloned, and the in vitro activities and induction of Rad51p following DNA damage were shown to be similar to that of RAD51 from other species. This study describes the pattern of Tetrahymena RAD51 expression during both the cell cycle and conjugation. Tetrahymena RAD51 mRNA abundance is elevated during macronuclear S phase during vegetative cell growth and with both meiotic prophase and new macronuclear development during conjugation. Gene disruption of the macronuclear RAD51 locus leads to severe abnormalities during both vegetative growth and conjugation. rad51 nulls divide slowly and incur rapid deterioration of their micronuclear chromosomes. Conjugation of two rad51 nulls leads to an arrest early during prezygotic development (meiosis I). We discuss the potential usefulness of the ciliates' characteristic nuclear duality for further analyses of the potentially unique roles of Tetrahymena RAD51.     

Differential DNA Amplification and Copy Number Control in the Hypotrichous Ciliate Euplotes crassus

ABSTRACT. During macronuclear development in hypotrichous ciliated protozoans, several thousand macronuclear DNA molecules are amplified several-hundred fold. We investigated the regulation of this amplification by determining the copy numbers of three different macronuclear DNA molecules in the hypotrichous ciliate Euplotes crassus. Two of the macronuclear DNA molecules were present in approximately 1,000 copies per cell, while the third was present in approximately 6,500 copies per cell. These reiteration levels were achieved either during macronuclear development, or shortly thereafter, and were maintained during vegetative growth. The most abundant macronuclear DNA molecule is present as a single-copy sequence in the micronuclear genome. Thus, its high copy number results from differential amplification. These results indicate that DNA amplification during macronuclear development is regulated individually for each macronuclear DNA molecule.     

Variable copy number of macronuclear DNA molecules in Tetrahymena

In Tetrahymena, the DNA of the macronucleus exists as very large (100 to 4,000-kb) linear molecules that are randomly partitioned to the daughter cells during cell division. This genetic system leads directly to an assortment of alleles such that all loci become homozygous during vegetative growth. Apparently, there is a copy number control mechanism operative that adjusts the number of each macronuclear DNA molecule so that macronuclear DNA molecules (with their loci) are not lost and aneuploid death is a rare event. In comparing Southern analyses of the DNA from various species of Tetrahymena using histone H4 genes as a probe, we find different band intensities in many species. These differences in band intensities primarily reflect differences in the copy number of macronuclear DNA molecules. The variation in copy number of macronuclear DNA molecules in some species is greater than an order of magnitude. These observations are consistent with a developmental control mechanism that operates by increasing the macronuclear copy number of specific DNA molecules (and the genes located on these molecules) to provide the relatively high gene copy number required for highly expressed proteins. © 1992 Wiley-Liss, Inc.     

DNA intermediates and telomere addition during genome reorganization in Euplotes crassus

Three gene-sized molecules cloned intact from macronuclear DNA served as hybridization probes to study excision of these molecules from chromosomes and their processing during macronuclear development in the hypotrich Euplotes crassus. These molecules occur in integrated forms within polytene chromosomal DNA during macronuclear developmental. After transection of the polytene chromosomes, the three molecules occur in intermediate forms. One of the three molecules first appeared in a large intermediate that was subsequently replaced by a second intermediate, approximately 140 bp larger than the final molecule. The other two macronuclear molecules were detected only in intermediates approximately 140 bp larger than the mature form. These penultimate intermediates are larger by virtue of oversized telomeres, which are pared to yield the mature gene-sized molecules.     

Sequence characterization of Tetrahymena macronuclear DNA ends.

Tetrahymena is a ciliated protozoan which has two nuclei: a micronucleus, which maintains the genetic continuity of the cell, and the macronucleus which is derived from the micronucleus after sexual conjugation. A macronuclear DNA library was constructed to contain DNA ends. A probe containing C4A2 repeats which are known to be present at macronuclear DNA ends (1) was used to screen the library. Three clones were characterized by sequencing, restriction enzyme mapping and Bal 31 digestion. The data indicate that these three clones represent macronuclear DNA ends which were generated by DNA fragmentation during macronuclear formation. The sequencing data at the C4A2 repeat junction show a conserved sequence of five nucleotides, TTATT. Sequences further away show no obvious homologies except that they are highly enriched in AT. This structure is quite different from the subtelomeric sequences of other organisms.     

Detection of circular excised DNA deletion elements in Tetrahymena thermophila during development.

Extensive programmed DNA deletion occurs in ciliates during development. In this study we examine the excised forms of two previously characterized deletion elements, the R- and M-element, in Tetrahymena. Using divergently oriented primers in polymerase chain reactions we have detected the junctions formed by joining the two ends of these elements, providing evidence for the presence of circular excised forms. These circular forms were detected in developing macronuclear DNA from 12-24 h after mating began, but not in micronuclear or whole cell DNA of vegetative cells. They are present at very low abundance, detectable after PCR only through hybridization with specific probes. Sequence analysis shows that the circle junctions occur at or very near the known ends of the elements. There is sequence microheterogeneity in these junctions, which does not support a simple reciprocal exchange model for DNA deletion. A model involving staggered cuts and variable mismatch repair is proposed to explain these results. This model also explains the sequence microheterogeneity previously detected among the junction sequences retained in the macronuclear chromosome.     

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.     

Lack of expression of micronuclear genes determining two different enzymatic activities in Tetrahymena thermophila

Abstract. Several (albeit indirect) lines of evidence indicate that the 2n germline micronucleus of the ciliate protozoans is not expressed during vegetative growth, even though it resides in the same cytoplasm and in close physical proximity to the actively expressed large somatic macronucleus (45n). To test this hypothesis more directly and quantitatively at the level of biochemically assayable specific enzyme activities, special heterokaryon strains of Tetrahymena thermophila have been constructed which carry the wild-type alleles specifying galactokinase ( galA ⁺) and phenylalanine hydroxylase ( tyrC ⁺) in the micronucleus only. The heterokaryons were assayed for these two enzyme activities using in vitro radiometric assays. No galactokinase or phenylalanine hydroxylase attributable to the micronuclear genes was observed in such heterokaryons. These results extend the observation of lack of micronuclear gene expression to at least two specific genes, i.e., galA and tyrC , as well as extending previous phenotypic observations on heterokaryons and autoradiographic studies of micronuclear RNA synthesis. By conjugating two of these heterokaryons to each other, it is now possible to determine precisely and unambiguously at what point during macronuclear differentiation the genes in the new macronucleus begin to be actively expressed relative to the timing of the extensive molecular changes that accompany the differentiation of the new macronucleus. These heterokaryons thus provide an excellent model system for the investigation of fundamental genetic regulatory mechanisms in operation during the differentiation of an entire eukaryotic genome.     

Mutants Affecting Processing of DNA in Macronuclear Development in Paramecium

In Paramecium tetraurelia, stock 51, the A surface protein is coded by the wild type A51 gene, present in micronuclei in two copies and in macronuclei in about 1500 copies. DNA processing, comprised of DNA cleavage, copy number amplification and telomere addition occurs at autogamy and conjugation when old macronuclei degrade and new macronuclei are formed from micronuclei. In this paper we characterize mutants with macronuclear A gene deletions. These mutants are notable in three respects. First, the mutants do not appear to be simple micronuclear deletions. Although genetic analysis shows that the d12 mutant d12(-1300) is homozygous for the allele A-1300 and the mutant d12(+1) for A+1, analysis by the polymerase chain reaction indicates that the micronuclei in these two mutants contain intact, but presumably altered, micronuclear A genes. They undergo deletion during DNA processing when new macronuclei are formed. Second, the position of the deletions in these alleles has been shown to change. The deficiency present in the d12 allele A-1300 was originally determined to extend from position -1300 (relative to the start of translation of the A gene) to the end of the chromosome. Later, a derivative of this strain, homozygous for the d12 allele A+1 was isolated in which the start site of the deletion was found to have moved from -1300 to +1. Third, a surprising interaction occurs in crosses between a line homozygous for the d12 allele and one homozygous for the wild-type A51 allele. Previous work on the non-Mendelian d48 mutant (which has intact A51 genes in its micronucleus, but has truncated A51 genes in its macronucleus) has shown that intact A51 alleles must be present in the old macronucleus in order for A51 alleles to undergo proper processing. We find that d12 alleles act on A51 alleles in heterozygotes such that intact macronuclear A genes are no longer required for proper processing of A51. Thus, in crosses of 51 x d12 (either +1 or -1300) d12 exconjugants, as well as 51 exconjugants, give rise to clones carrying both intact A51 and truncated d12 alleles. Remarkably the d12 alleles, which are themselves deleted during processing, are capable in the heterozygote of fostering normal processing of the A51 allele.     

不同生理状态下膜状急纤虫大核DNA和线粒体DNA的多态性比较

为探索纤毛虫在营养及休眠条件下两套遗传系统的作用关系,对膜状急纤虫(Tachysomapellionella)营养细胞和休眠包囊大核DNA、线粒体DNA进行了RAPD比较。结果显示,在所选用的34条随机引物中,大核DNA共扩增出203条片段,其中以休眠包囊大核DNA为模板扩增出45条特有片段,以营养细胞大核DNA为模板扩增出36条特有片段,两者存在40%的差异。在所选用的32条随机引物中,线粒体DNA共扩增出216条片段,其中以休眠包囊线粒体DNA为模板扩增出35条特有片段,以营养细胞线粒体DNA为模板扩增出47条特有片段,两者有38%的差异。结果表明,膜状急纤虫休眠包囊与营养期的大核DNA结构存在显著的差异;两者的线粒体DNA结构也存在较大差异。这表明,膜状急纤虫在包囊形成过程中,大核及线粒体DNA结构可能都发生了一定的变化,并且这些变化可能与包囊形成过程中的形态结构和代谢活动等剧烈变化以及休眠状态下的生理生化变化密切相关。     

De novo cytosine methylation in the differentiating macronucleus of the stichotrichous ciliate Stylonychia lemnae

Dramatic DNA reorganization and elimination processes occur during macronuclear differentiation in ciliates. In this study we analyzed whether cytosine methylation of specific sequences plays a functional role during DNA rearrangement. Three classes of sequences, macronuclear-destined sequences (MDSs, pCE7), members from a large family of transposon-like elements and micronuclear-specific sequences (pLJ01), differing in their structure and future destiny during nuclear differentiation, were studied in the micronucleus, the developing macronucleus and, when present, in the mature macronucleus. While the MDSs become processed to a 1.1 and 1.3 kb gene-sized macronuclear DNA molecule, the family of transposon-like elements represented by MaA81 becomes removed late in the course of polytene chromosome formation. The micronuclear-specific sequence pLJ01 is eliminated together with bulk micronuclear DNA during degradation of polytene chromosomes. No methylated cytosine could be detected in the vegetative macronucleus and no difference in methylation pattern was observed either between micronucleus and developing macronucleus in MDSs or in a micronuclear-specific sequence. However, a significant percentage of the cytosines contained in the transposon-like element becomes methylated de novo in the course of macronuclear differentiation. This is the first demonstration that cytosine methylation in specific sequences occurs during macronuclear differentiation and may provide a first step towards understanding epigenetic factors involved in DNA processing.     

Trichocyst phenotype transformation induced by macronuclear transplantation in Paramecium tetraurelia

A portion of the macronucleus of wild-type cells of Paramecium tetraurelia was removed and was injected into cells homozygous for the ftA mutation. The ftA mutants make defective trichocysts and are unable to perform normal trichocyst exocytosis. After injection, approx. 30% of the surviving cells show a phenotype shift from mutant to wild-type. This shift is stable during subsequent vegetative growth until clonal death. If, however, the hybrid cell lines are brought to autogamy (which discards the existing macronucleus and forms a new one from sexual products derived from a micronucleus), then the lines revert to the ftA phenotype. Since micronuclei were not transplanted, the phenotypic reversion after autogamy is to be expected, and demonstrates that the transformation affects the macronucleus only. A second series of injections involved transfer of a portion of the macronucleus from cells homozygous for the trichocyst ptA mutation into ftA host cells. These two mutations are genetically complementary, so the injection should be genetically equivalent to forming a double heterozygote. Approx. 20% of the injection survivors shift to wild-type. This shift is also vegetatively stable unless autogamy occurs; after autogamy, reversion to the ftA phenotype is seen. These results show that a portion of a macronucleus can be successfully transplanted from one cell to another and that, in the host cytoplasmic environment, normal gene expression and replication of a transplanted macronucleus does occur. The technique of macronuclear transplantation is significant to studies of the macronuclear contribution to clonal aging, and to studies on genetic control over trichocyst development.     

Sequence-specific epigenetic effects of the maternal somatic genome on developmental rearrangements of the zygotic genome in Paramecium primaurelia.

In ciliates, the germ line genome is extensively rearranged during the development of the somatic macronucleus from a mitotic product of the zygotic nucleus. Germ line chromosomes are fragmented in specific regions, and a large number of internal sequence elements are eliminated. It was previously shown that transformation of the vegetative macronucleus of Paramecium primaurelia with a plasmid containing a subtelomeric surface antigen gene can affect the processing of the homologous germ line genomic region during development of a new macronucleus in sexual progeny of transformed clones. The gene and telomere-proximal flanking sequences are deleted from the new macronuclear genome, although the germ line genome remains wild type. Here we show that plasmids containing nonoverlapping segments of the same genomic region are able to induce similar terminal deletions; the locations of deletion end points depend on the particular sequence used. Transformation of the maternal macronucleus with a sequence internal to a macronuclear chromosome also causes the occurrence of internal deletions between short direct repeats composed of alternating thymines and adenines. The epigenetic influence of maternal macronuclear sequences on developmental rearrangements of the zygotic genome thus appears to be both sequence specific and general, suggesting that this trans-nucleus effect is mediated by pairing of homologous sequences.