Alternate Junctions and Microheterogeneity of Tlr1, a Developmentally Regulated DNA Rearrangement in Tetrahymena thermophila

ABSTRACT. A large number of developmentally regulated DNA rearrangements occur during the development of the macronucleus in Tetrahymena thermophila , Tlr1 is a deletion element which has large inverted repeats near the rearrangement junctions and deletes more than 13 kbp of internal DNA. Previous analysis of caryonidal lines revealed alternate left junctions for the Tlr1 rearrangement in B strain cells. We show here that C2 strain Tetrahymena also use alternate rearrangement junctions. We have mapped and sequenced two additional rearrangement variants and find that both the left and right can vary over a range of approximately 200 bp. We also demonstrate the presence of sequence microheterogeneity in the most commonly found Tlr1 rearrangement product.     

DNA synthesis, methylation and degradation during conjugation in Tetrahymena thermophila.

We have investigated the timing of DNA synthesis, methylation and degradation during macronuclear development in the ciliate, Tetrahymena thermophila. DNA synthesis was first detected in the anlagen early in macronuclear development, but the majority of DNA synthesis occurred later, after pair separation. Anlagen DNA was first detectably methylated at GATC sites 3-5 hours after its synthesis. Once initiated, de novo methylation was rapid and complete, occurring between 13.5 and 15 hours of conjugation. The level of methylation of GATC sites was constant throughout the remainder of conjugation, and was similar to that in mock-conjugated cells. Degradation of DNA in the old macronucleus and DNA synthesis in the anlagen began at about the same time. Upon pair separation, less than 20% of old macronuclear DNA remained. A small percentage of nucleotides prelabeled prior to conjugation were recycled in the developing anlagen.     

Effects of Nullisomic Chromosome Deficiencies on Conjugation Events in Tetrahymena Thermophila: Insufficiency of the Parental Macronucleus to Direct Postzygotic Development

Conjugation fails postzygotically after mating of Tetrahymena cells that have wild-type parental macronuclei but harbor noncomplementing nullisomic parental germline deficiencies. Failures begin shortly after formation of the new macronuclear precursor (anlage) and completion of the first step in elimination of the parental macronucleus (pycnosis). Conjugants fail to complete pair separation, to eliminate one new micronucleus, and to amplify anlage DNA, and they eventually die. Some deficiencies block resorption of the pycnotic parental macronucleus, but we find no evidence for its regeneration. Some deficiencies cause aberrant anlage DNA loss. Those that do not cause DNA loss are epistatic to those that do, indicating that normal anlage development requires the dependent function of at least two types of genes. The possibility that these genes are involved in developmentally regulated anlage DNA rearrangements is discussed. Each observed conjugation defect indicates insufficiency of the parental macronucleus to direct postzygotic development and can be explained by the deficiency of essential conjugation genes that are expressed from the anlage. The failure of nullisomic conjugants to complete pair separation indicates a requirement for gene products, expressed from the early anlage or its precursors, soon after anlage first differentiate.     

Developmentally programmed DNA rearrangement in Tetrahymena thermophila: Isolation and sequence characterization of three new alternative deletion systems

Extensive developmentally programmed DNA rearrangements, including thousands of internal deletions, occur in the differentiating somatic macronucleus in Tetrahymena thermophila. Some deletion systems involve the use of multiple alternative deletion sites. We report here the cloning and the sequences of three new alternative deletion systems (RR, RP and B) obtained using genomic subtraction. The RP and RR deletion systems are 2 kb apart on chromosome IR, and both involve the removal of < 2 kb of micronuclear sequences. The B deletion system is on chromosome 5 and involves a deletion of > 5 kb. All three deleted regions are very AT rich (∼ 80%) and do not appear to encode any protein. Sequences of the regions flanking the deletion junctions of all three systems revealed no sequence similarity among them nor with any previously reported deletion systems, suggesting that different cis-acting elements are involved for rearrangement. Unlike other deletion systems in ciliates, the B deletion system lacks short terminal direct repeats. Our results suggest an average of at least one alternative deletion system per 134 kb of micronuclear DNA and lead to an estimate that at least 25% of all deletion systems in Tetrahymena utilize alternative ends. The genomic subtraction method employed in this study could prove useful for the isolation of alternatively deleted DNA in special-purpose cases in Tetrahymena and other ciliates. The hybridization parameters for genomic subtraction worked out here for highly AT-rich DNA may have wider usefulness.     

Phosphorylation of the SQ H2A.X motif is required for proper meiosis and mitosis in Tetrahymena thermophila

Phosphorylation of the C terminus SQ motif that defines H2A.X variants is required for efficient DNA double-strand break (DSB) repair in diverse organisms but has not been studied in ciliated protozoa. Tetrahymena H2A.X is one of two similarly expressed major H2As, thereby differing both from mammals, where H2A.X is a quantitatively minor component, and from Saccharomyces cerevisiae where it is the only type of major H2A. Tetrahymena H2A.X is phosphorylated in the SQ motif in both the mitotic micronucleus and the amitotic macronucleus in response to DSBs induced by chemical agents and in the micronucleus during prophase of meiosis, which occurs in the absence of a synaptonemal complex. H2A.X is phosphorylated when programmed DNA rearrangements occur in developing macronuclei, as for immunoglobulin gene rearrangements in mammals, but not during the DNA fragmentation that accompanies breakdown of the parental macronucleus during conjugation, correcting the previous interpretation that this process is apoptosis-like. Using strains containing a mutated (S134A) SQ motif, we demonstrate that phosphorylation of this motif is important for Tetrahymena cells to recover from exogenous DNA damage and is required for normal micronuclear meiosis and mitosis and, to a lesser extent, for normal amitotic macronuclear division; its absence, while not lethal, leads to the accumulation of DSBs in both micro- and macronuclei. These results demonstrate multiple roles of H2A.X phosphorylation in maintaining genomic integrity in different phases of the Tetrahymena life cycle.     

Analysis of a piwi-related gene implicates small RNAs in genome rearrangement in tetrahymena

During development of the somatic macronucleus from the germline micronucleus in ciliates, chromosome rearrangements occur in which specific regions of DNA are eliminated and flanking regions are healed, either by religation or construction of telomeres. We identified a gene, TWI1, in Tetrahymena thermophila that is homologous to piwi and is required for DNA elimination. We also found that small RNAs were specifically expressed prior to chromosome rearrangement during conjugation. These RNAs were not observed in TWI1 knockout cells and required PDD1, another gene required for rearrangement, for expression. We propose that these small RNAs function to specify sequences to be eliminated by a mechanism similar to RNA-mediated gene silencing.     

Role of histone deacetylation in developmentally programmed DNA rearrangements in Tetrahymena thermophila

In Tetrahymena, as in other ciliates, development of the somatic macronucleus during conjugation involves extensive and reproducible rearrangements of the germ line genome, including chromosome fragmentation and excision of internal eliminated sequences (IESs). The molecular mechanisms controlling these events are poorly understood. To investigate the role that histone acetylation may play in the regulation of these processes, we treated Tetrahymena cells during conjugation with the histone deacetylase inhibitor trichostatin A (TSA). We show that TSA treatment induces developmental arrests in the early stages of conjugation but does not significantly affect the progression of conjugation once the mitotic divisions of the zygotic nucleus have occurred. Progeny produced from TSA-treated cells were examined for effects on IES excision and chromosome breakage. We found that TSA treatment caused partial inhibition of excision of five out of the six IESs analyzed but did not affect chromosome breakage at four different sites. TSA treatment greatly delayed in some cells and inhibited in most the excision events in the developing macronucleus. It also led to loss of the specialized subnuclear localization of the chromodomain protein Pdd1p that is normally associated with DNA elimination. We propose a model in which underacetylated nucleosomes mark germ line-limited sequences for excision.     

Role of micronucleus-limited DNA in programmed deletion of mse2.9 during macronuclear development of Tetrahymena thermophila

Extensive programmed DNA rearrangements occur during the development of the somatic macronucleus from the germ line micronucleus in the sexual cycle of the ciliated protozoan Tetrahymena thermophila. Using an in vivo processing assay, we analyzed the role of micronucleus-limited DNA during the programmed deletion of mse2.9, an internal eliminated sequence (IES). We identified a 200-bp region within mse2.9 that contains an important cis-acting element which is required for the targeting of efficient programmed deletion. Our results, obtained with a series of mse2.9-based chimeric IESs, led us to suggest that the cis-acting elements in both micronucleus-limited and macronucleus-retained flanking DNAs stimulate programmed deletion to different degrees depending on the particular eliminated sequence. The mse2.9 IES is situated within the second intron of the micronuclear locus of the ARP1 gene. We show that the expression of ARP1 is not essential for the growth of Tetrahymena. Our results also suggest that mse2.9 is not subject to epigenetic regulation of DNA deletion, placing possible constraints on the scan RNA model of IES excision.     

Internal micronuclear DNA regions which include sequences homologous to macronuclear telomeres are deleted during development in Tetrahymena

C4A2 repeats are present in multiple clusters in both the macronucleus and micronucleus of Tetrahymena. Although the macronucleus is generated from the micronucleus after sexual conjugation, the repeats are telomeric sequences in the macronucleus but are internally located in the micronucleus (1). This study investigates the fate of the sequences adjacent to the micronuclear C4A2 repeats. Southern blot analyses of 21 C4A2-containing micronuclear clones show that extensive elimination of the adjacent sequences occurs during the formation of the macronucleus. Comparison of one C4A2-containing micronuclear clone with its derived macronuclear segment indicates that approximately 4.5 kb of DNA, which includes the C4A2 repeats and adjacent sequences on both sides is deleted from the macronucleus. The two regions adjoining the deletion are joined together to form a contiguous segment in the macronucleus. This excision of C4A2 repeats and surrounding sequences and the rejoining of the retained segments is probably the mechanism by which all or most of the other C4A2 adjacent sequences are eliminated.     

A possible role of mitochondria in the apoptotic-like programmed nuclear death of Tetrahymena thermophila

The ciliated protozoan Tetrahymena has a unique apoptosis-like process, which is called programmed nuclear death (PND). During conjugation, the new germinal micro- and somatic macro-nuclei differentiate from a zygotic fertilized nucleus, whereas the old parental macronucleus degenerates, ensuring that only the new macronucleus is responsible for expression of the progeny genotype. As is the case with apoptosis, this process encompasses chromatin cleavage into high-molecular mass DNA, oligonucleosomal DNA laddering, and complete degradation of the nuclear DNA, with the ultimate outcome of nuclear resorption. Caspase-8- and caspase-9-like activities are involved in the final resorption process of PND. In this report, we show evidence for mitochondrial association with PND. Mitochondria and the degenerating macronucleus were colocalized in autophagosome using two dyes for the detection of mitochondria. In addition, an endonuclease with similarities to mammalian endonuclease G was detected in the isolated mitochondria. When the macronuclei were incubated with isolated mitochondria in a cell-free system, DNA fragments of 150-400 bp were generated, but no DNA ladder appeared. Taking account of the present observations and the timing of autophagosome formation, we conclude that mitochondria might be involved in Tetrahymena PND, probably with the process of oligonucleosomal laddering.     

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.     

Centromeric histone H3 is essential for vegetative cell division and for DNA elimination during conjugation in Tetrahymena thermophila

The Tetrahymena thermophila CNA1 gene encodes the centromeric H3, Cna1p. Green fluorescent protein (GFP)-tagged Cna1p localizes in micronuclei in dots whose number and behavior during mitosis and conjugation are consistent with centromeres. During interphase, Cna1p-GFP localizes in peripheral dots, suggesting centromeres are associated with the nuclear envelope. Newly synthesized Cna1p-GFP enters micronuclei in mitosis and accumulates in the nucleoplasm. Its deposition at centromeres starts at early S phase and continues through most of S phase. CNA1 is required for vegetative cell growth. Knockdown of CNA1 genes in the somatic macronucleus results in micronuclear DNA loss and delayed chromosome segregation during mitosis. During conjugation, Cna1p-GFP disappears from the centromeres in the developing macronucleus, consistent with centromeric sequences being internal eliminated sequences. Surprisingly, zygotic CNA1 is required for efficient elimination of germ line-specific sequences during development of the new macronuclei but not for the RNA interference pathway, through which sequences are targeted for elimination. Zygotically expressed Cna1p localizes in the spherical structures in which the later stages of DNA elimination occur, and these structures cannot be formed in the absence of zygotic CNA1, suggesting that, in addition to functioning in centromeres, Cna1p may also play a role in organizing the formation of the DNA elimination structures.     

抗沉默因子Asf1调控嗜热四膜虫细胞核的稳定性

组蛋白H3/H4的分子伴侣Asf1(anti-silencing factor 1),参与依赖DNA复制及不依赖DNA复制的核小体装配,同时参与转录调控、基因沉默以及DNA损伤修复等过程. 在不同生物中,Asf1具有功能的保守性和多样性．嗜热四膜虫ASF1（TTHERM_00442300）基因编码的蛋白质含有保守的N端结构域和酸性的C端结构域．N端结构域同源序列进化树分析表明,Asf1进化与物种进化一致．实时荧光定量PCR表明,ASF1在四膜虫营养生长、饥饿及有性生殖时期均有表达,且在有性生殖4～6 h转录水平达到最高．免疫荧光定位分析表明,HA-Asf1在营养生长时期以及有性生长时期定位于功能大核和小核中,而在凋亡的大核中信号消失．过表达ASF1导致大核及小核变大,抑制细胞增殖．敲减ASF1后会导致大核形态异常,小核缺失．结果表明,ASF1表达对细胞核的形态和结构维持发挥重要的调控作用．     

Ribosomal RNA gene amplification in Tetrahymena may be associated with chromosome breakage and DNA elimination

The chromosomal DNA sequence adjacent to one end of the single ribosomal RNA gene (rDNA) in the micronucleus of Tetrahymena has been isolated by cloning. Using this sequence as a hybridization probe the organization of the same sequence in the somatic macronucleus has been examined. The restriction enzyme digestion maps of this sequence in the two nuclei are very different. Detailed mapping studies suggest that a chromosome break has occurred near the junction between the rDNA and the neighboring sequence during the formation of the macronucleus. As a result the flanking sequence is located near a free chromosome end in the macronucleus. The existence of such a linear DNA end has also been shown by digestion with the exonuclease Bal 31. In addition to the breakage, some sequences at this junction are found to be eliminated from the macronucleus. This observation has been interpreted in relation to the mechanism of rDNA amplification, which in Tetrahymena generates extrachromosomal rDNA molecules during macronucleus development.     

Molecular genetic analysis of an SNF2/brahma-related gene in Tetrahymena thermophila suggests roles in growth and nuclear development

We used a reverse genetic approach to identify three members of the SNF2 superfamily of chromatin remodeling genes in the ciliated protozoan Tetrahymena thermophila in order to investigate possible functions of ATP-dependent chromatin remodeling factors in growth and nuclear development. Comparative sequence analysis of the gene product of the Tetrahymena brahma-related gene (TtBRG1) indicates it is a member of the SNF2/BRM subgroup of the SNF2 superfamily. Northern analysis suggests that TtBRG1 has roles in growth and nuclear development in Tetrahymena. Indirect immunofluorescence analysis during nuclear development indicates that TtBrg1p localizes to both the parental and developing macronucleus of Tetrahymena during the time period corresponding to genome rearrangements. We generated germ line knockout heterokaryons for TtBRG1 and demonstrated that expression of the gene is required to complete nuclear development of Tetrahymena. In addition, the formation of distinct Pdd1p-containing structures is disturbed during the late stages of conjugation in TtBRG1 germ line knockout heterokaryons. We discuss these results in light of possible roles of SNF2-related proteins in growth and nuclear development of Tetrahymena.     

Death harmony played by nucleus and mitochondria: nuclear apoptosis during conjugation of tetrahymena

Tetrahymena programmed nuclear death or nuclear apoptosis is a unique process during conjugation in which only the parental macronucleus is eliminated from the progeny cytoplasm, and other nuclei such as new micro- and macronuclei are unaffected. The nuclear death process consists of three successive steps: chromatin cleavage into high-molecular mass DNA, oligonucleosomal laddering concomitant with nuclear condensation, and complete degradation of the nuclear DNA. Following the first step of the death process, the parental macronucleus is engulfed by a large autophagosome in which many mitochondria are incorporated. Those sequestered mitochondria simply break down and release endonuclease similar to mammalian endonuclease G that is responsible for the generation of the DNA ladder, leading to the conclusion that mitochondria play a crucial role in the execution of the death program. Thus, the parental macronucleus is subject to final death by autophagy in collaboration with caspase-like enzymes, resulting in the ultimate outcome of nuclear resorption.     

四膜虫接合过程中旧大核内基因的彻底降解

形态学和遗传学方法早巳证明四膜虫接合过程中旧大核退化消失,其基因型对接合后代不发生影响。本文以1种具有强大复制优势而且是抗药性的rDNA分子,rdna-A3,为指标,证明在接合过程中旧大核内上万个rDNA分子没有1个能进入新大核,从而在基因分子水平上证明旧大核的退化是极为彻底的。同时检测了接合过程中旧大核内DNA发生降解的时间。     

Death Harmony Played by Nucleus and Mitochondria: Nuclear Apoptosis During Conjugation of Tetrahymena

Tetrahymena programmed nuclear death or nuclear apoptosis is a unique process during conjugation in which only the parental macronucleus is eliminated from the progeny cytoplasm, and other nuclei such as new micro- and macronuclei are unaffected. The nuclear death process consists of three successive steps: chromatin cleavage into high-molecular mass DNA, oligonucleosomal laddering concomitant with nuclear condensation, and complete degradation of the nuclear DNA. Following the first step of the death process, the parental macronucleus is engulfed by a large autophagosome in which many mitochondria are incorporated. Those sequestered mitochondria simply break down and release endonuclease similar to mammalian endonuclease G that is responsible for the generation of the DNA ladder, leading to the conclusion that mitochondria play a crucial role in the execution of the death program. Thus, the parental macronucleus is subject to final death by autophagy in collaboration with caspase-like enzymes, resulting in the ultimate outcome of the nuclear resorption.