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.     

Methylation of adenine in the nuclear DNA of Tetrahymena is internucleosomal and independent of histone H1

There are about 50 copies of each chromosome in the somatic macronucleus of the ciliated protozoan Tetrahymena. Approximately 0.8% of the adenine residues in the macronuclear DNA of Tetrahymena are methylated to N⁶-methyladenine. The degree of methylation varies between sites from a very low percentage to >90%. In this study a correlation was found between nucleosome positioning and DNA methylation. Eight GATC sites with different levels of methylation were examined. There was a direct correlation between the degree of methylation and proximity to linker DNA at these sites. Although methylation occurs preferentially in linker DNA, the patterns and extent of methylation in a histone H1 knockout strain were virtually indistinguishable from those in wild-type cells.     

Dynamic nuclear reorganization during genome remodeling of Tetrahymena

The single-celled ciliate Tetrahymena thermophila possesses two versions of its genome, one germline, one somatic, contained within functionally distinct nuclei (called the micronucleus and macronucleus, respectively). These two genomes differentiate from identical zygotic copies. The development of the somatic nucleus involves large-scale DNA rearrangements that eliminate 15 to 20 Mbp of their germline-derived DNA. The genomic regions excised are dispersed throughout the genome and are largely composed of repetitive sequences. These germline-limited sequences are targeted for removal from the genome by a RNA interference (RNAi)-related machinery that directs histone H3 lysine 9 and 27 methylation to their associated chromatin. The targeting small RNAs are generated in the micronucleus during meiosis and then compared against the parental macronucleus to further enrich for germline-limited sequences and ensure that only non-genic DNA segments are eliminated. Once the small RNAs direct these chromatin modifications, the DNA rearrangement machinery, including the chromodomain proteins Pdd1p and Pdd3p, assembles on these dispersed chromosomal sequences, which are then partitioned into nuclear foci where the excision events occur. This DNA rearrangement mechanism is Tetrahymena's equivalent to the silencing of repetitive sequences by the formation of heterochromatin. The dynamic nuclear reorganization that occurs offers an intriguing glimpse into mechanisms that shape nuclear architecture during eukaryotic development.     

Single-strand and double-strand cleavage at half-modified and fully modified recognition sites for the restriction nucleases Sau3a and Taqi

The influence of cytosine methylation on the cleavage of DNA by the restriction nucleases Sau3A and TaqI has been investigated. Bovine satellite DNA fragments containing a GATCGA sequence, i.e. a Sau3A site overlapping with a TaqI site have been used in this study. The methylation of these fragments has been determined by sequence analysis. It has been found that a TaqI site (TCGA) methylated at cytosine in both DNA strands is still sensitive to double-strand cleavage. A Sau3A site (GATC), however, is rendered resistant to double-strand cleavage by methylation of a single cytosine. Fragments containing the "half-modified" Sau3A site are nicked in the unmethylated DNA strand. It has been shown by sequence analysis of nicked DNA that the single-strand break occurs at the same position which is cleaved in unmodified DNA.     

Molecular analysis of N6-methyladenine patterns in Tetrahymena thermophila nuclear DNA.

We have cloned two DNA fragments containing 5'-GATC-3' sites at which the adenine is methylated in the macronucleus of the ciliate Tetrahymena thermophila. Using these cloned fragments as molecular probes, we analyzed the maintenance of methylation patterns at two partially and two uniformly methylated sites. Our results suggest that a semiconservative copying model for maintenance of methylation is not sufficient to account for the methylation patterns we found during somatic growth of Tetrahymena. Although we detected hemimethylated molecules in macronuclear DNA, they were present in both replicating and nonreplicating DNA. In addition, we observed that a complex methylation pattern including partially methylated sites was maintained during vegetative growth. This required the activity of a methylase capable of recognizing and modifying sites specified by something other than hemimethylation. We suggest that a eucaryotic maintenance methylase may be capable of discriminating between potential methylation sites to ensure the inheritance of methylation patterns.     

Proximal recognition sites facilitate intrasite hopping by DNA adenine methyltransferase: mechanistic exploration of epigenetic gene regulation

The methylation of adenine in palindromic 5'-GATC-3' sites by Escherichia coli Dam supports diverse roles, including the essential regulation of virulence genes in several human pathogens. As a result of a unique hopping mechanism, Dam methylates both strands of the same site prior to fully dissociating from the DNA, a process referred to as intrasite processivity. The application of a DpnI restriction endonuclease-based assay allowed the direct interrogation of this mechanism with a variety of DNA substrates. Intrasite processivity is disrupted when the DNA flanking a single GATC site is longer than 400 bp on either side. Interestingly, the introduction of a second GATC site within this flanking DNA reinstates intrasite methylation of both sites. Our results show that intrasite methylation occurs only when GATC sites are clustered, as is found in gene segments both known and postulated to undergo in vivo epigenetic regulation by Dam methylation. We propose a model for intrasite methylation in which Dam bound to flanking DNA is an obligate intermediate. Our results provide insights into how intrasite processivity, which appears to be context-dependent, may contribute to the diverse biological roles that are carried out by Dam.     

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.     

The condensin complex is essential for amitotic segregation of bulk chromosomes, but not nucleoli, in the ciliate Tetrahymena thermophila

The macronucleus of the binucleate ciliate Tetrahymena thermophila contains fragmented and amplified chromosomes that do not have centromeres, eliminating the possibility of mitotic nuclear division. Instead, the macronucleus divides by amitosis with random segregation of these chromosomes without detectable chromatin condensation. This amitotic division provides a special opportunity for studying the roles of mitotic proteins in segregating acentric chromatin. The Smc4 protein is a core component of the condensin complex that plays a role in chromatin condensation and has also been associated with nucleolar segregation, DNA repair, and maintenance of the chromatin scaffold. Mutants of Tetrahymena SMC4 have remarkable characteristics during amitosis. They do not form microtubules inside the macronucleus as normal cells do, and there is little or no bulk DNA segregation during cell division. Nevertheless, segregation of nucleoli to daughter cells still occurs, indicating the independence of this process and bulk DNA segregation in ciliate amitosis.     

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.     

Lysosomal enzymes in the macronucleus of Tetrahymena during its apoptosis-like degradation

A key characteristic of apoptosis is its regulated nuclear degradation. Apoptosis-like nuclear degradation also occurs in the ciliated unicellular organism, Tetrahymena thermophila. Chromatin of the macronucleus undergoes massive condensation, a process that can be blocked by caspase inhibitors. The nucleus becomes TUNEL-positive, and its DNA is cleaved into nucleosome-sized fragments. In a matter of hours the macronucleus is completely degraded, and disappears. The condensed nucleus sequesters acridine orange, which means that it might become an acidic compartment. We therefore asked whether lysosomal bodies fuse with the condensed macronucleus to form an autophagosome. We monitored acid phosphatase (AP) activity, which is associated with lysosomal bodies but is not found in normal nuclei. We find that after the macronucleus condenses AP activity is localized in cap-like structures at its cortex. Later, after the degrading macronucleus loses much of its DNA, acid phosphatase deposits appear deeper within the nucleus. We conclude that although macronuclear elimination is initiated by an apoptosis-like mechanism, its final degradation may be achieved through autophagosomy.     

Polytene chromosomes and nucleic acid metabolism during macronuclear development in Euplotes

Polytene chromosomes in two species of Euplotes, E. woodruffi and E. eurystomus, have been described during the macronuclear development following conjugation. In these two species, the giant chromosomes appear briefly in the macronuclear anlagen and disappear completely later. DNA synthesis begins concomitantly with the appearance of the giant chromosomes and reaches a peak at the maximum stage of polyteny. Shortly thereafter DNA begins to break down and the breakdown products leave the macronuclear anlagen, reducing the DNA content in the anlagen to the amount present at the earlier stages of the polytene development of the chromosomes. A later phase of DNA synthesis occurs in the anlagen with the appearance of replication bands comparable to the bands which double the DNA in the somatic macronucleus. These replication bands initiate several rounds of DNA synthesis which finally lead to the development of the vegetative macronucleus. RNA synthesis occurs uniformly on the giant chromosomes and no special RNA producing puffs or other regions are noticed on them.Research supported by American Cancer Society grant E 434 to David M. Prescott and by the Deutsche Forschungsgemeinschaft to Dieter Ammermann.     

Elimination of DNA sequences during macronuclear differentiation in Tetrahymena thermophila,as detected by in situ hybridization

Previous studies have indicated that certain sequences in the micronuclear genome are absent from the somatic macronucleus of Tetrahymena (Yao and Gorovsky, 1974; Yao and Gall, 1979; Yao, submitted). The present study used in situ hybridization to follow the elimination process during the formation of the new macronucleus. Micronuclear-specific DNA cloned in recombinant plasmids was labelled with ³H and hybridized to cytological preparations of T. thermophila at various stages of conjugation. Despite a smaller size and lower DNA content, the micronucleus has more hybridization than the mature macronucleus. Hybridization initially increased in the anlage (newly developing macronucleus) to reach a maximal level right after the old macronuclei had disappeared. The hybridization in the anlage then decreased to a significant extent prior to the first cell division. The results suggest that the micronuclear-specific sequence is first replicated a few rounds before it is eliminated from the anlage, and the elimination process occurs without nuclear division.     

The temperature-dependent change in methylation of the Antirrhinum transposon Tam3 is controlled by the activity of its transposase

The Antirrhinum majus transposon Tam3 undergoes low temperature-dependent transposition (LTDT). Growth at 15 degrees C permits transposition, whereas growth at 25 degrees C strongly suppresses it. The degree of Tam3 DNA methylation is altered somatically and positively correlated with growth temperature, an exceptional epigenetic system in plants. Using a Tam3-inactive line, we show that methylation change depends on Tam3 activity. Random binding site selection analysis and electrophoretic mobility shift assays revealed that the Tam3 transposase (TPase) binds to the major repeat in the subterminal regions of Tam3, the site showing the biggest temperature-dependent change in methylation state. Methylcytosines in the motif impair the binding ability of the TPase. Proteins in a nuclear extract from plants grown at 15 degrees C but not 25 degrees C bind to this motif in Tam3. The decrease in Tam3 DNA methylation at low temperature also requires cell division. Thus, TPase binding to Tam3 occurs only during growth at low temperature and immediately after DNA replication, resulting in a Tam3-specific decrease in methylation of transposon DNA. Consequently, the Tam3 methylation level in LTDT is regulated by Tam3 activity, which is dependent on the ability of its TPase to bind DNA and affected by growth temperature. Thus, the methylation/demethylation of Tam3 is the consequence, not the cause, of LTDT.     

The Role of Macronuclear DNA Sequences in the Permanent Rescue of a Non-Mendelian Mutation in Paramecium Tetraurelia

The Paramecium tetraurelia mutant called d48 has a complete copy of the A surface protein gene in its micronuclei, but lacks the A gene in the macronucleus. Previous experiments have shown that microinjection of a plasmid containing the entire A gene or a large portion of the gene into the macronucleus of d48 rescued the cell line after formation of a new macronucleus (autogamy). Here we show that several different regions of the A gene can rescue d48, but 100% of the activity cannot be localized to a single, defined region. Inversion of a sequence contained within an A gene plasmid had no measurable effect on rescue efficiency and co-injection of two different plasmids results in enhancement of rescue activity despite the non-contiguous form of the DNA sequences. Both these results suggest that no specific product (RNA or protein) with defined end points is made from the rescuing fragment. A unique restriction site was created in the A gene and used to demonstrate that the injected DNA does not serve as a direct template for the synthesis of the new macronuclear DNA. Models to explain the action of the injected DNA are discussed.     

DNA Digestion and Chromatin Condensation during Nuclear Death inTetrahymena

DNA fragmentation and nuclear condensation are key features in the regulated cell death of higher animal cells. Nuclear death also occurs as part of a developmentally programmed process during the sexual life cycle of the unicellular organismTetrahymena.We examined the regulation of nuclear death and the relationship between DNA fragmentation and chromatin condensation in this model system. Nuclear death is accompanied by DNA digestion to low-molecular-weight oligonucleosomal-length fragments, in agree- ment with a previous study [17], indicating an endonuclease-like activity typical of apoptosis in higher organisms. Actinomycin D and cycloheximide block DNA digestion as well as nuclear condensation suggesting that nuclear death is under genetic regulation. DNA digestion is completely blocked by aurin, a general nuclease inhibitor. In addition, when DNA fragmentation is blocked, nuclear condensation also fails to occur. Moreover, a kinetic analysis of DNA breakdown, using agarose gels, shows that some DNA digestion occurs before nuclear condensation has taken place. Thus the initiation of DNA digestion may provide conditions necessary for nuclear condensation. Temporary inhibition of nuclear death aborts the death program since after removal of inhibitors cells revert to a vegetative pathway without having eliminated the old or developed the new macronucleus. Zn²⁺and EGTA, both of which inhibit apoptosis in some cell types, fail to prevent nuclear condensation or DNA digestion inTetrahymena,suggesting a requirement here for an endonuclease which is Ca²⁺-independent and Zn²⁺-insensitive. With the TUNEL assay, DNA breakdown is detected exclusively in the condensed macronucleus (and occasional micronuclei identified as degenerating haploid products of meiosis), but not in precondensed macronuclei. These studies show that apoptotic-like DNA fragmentation occurs after condensation of the degenerating macronucleus. However, early DNA digestion may be critical for nuclear condensation and subsequent degeneration.     

Deoxyribonucleic Acid Synthesis and Distribution During Growth and Amitosis of the Macronucleus of Euplotes

SYNOPSIS. Short sections of deoxyribonucleic acid (DNA) in the elongated macronucleus of Euplotes eurystomus were labeled by means of a short exposure to tritiated (H³-) thymidine to follow by autoradiography the fate of the labeled DNA during amitotic reorganization of the macronucleus. During amitosis the radioactive DNA that was restricted during interphase to short sections of the nucleus is dispersed and becomes evenly distributed throughout each daughter macronucleus.
Although the reorganization bands normally originate only at the ends of the macronucleus, additional bands can start at other places on the macronuclear surface. Bands of the same macronucleus originate with a high degree of synchrony. DNA synthesis is a constant feature of the rear zone of every reorganization band.