Lia1p, a novel protein required during nuclear differentiation for genome-wide DNA rearrangements in Tetrahymena thermophila

Extensive genome-wide rearrangements occur during somatic macronuclear development in Tetrahymena thermophila. These events are guided by RNA interference-directed chromatin modification including histone H3 lysine 9 methylation, which marks specific germ line-limited internal eliminated sequences (IESs) for excision. Several genes putatively involved in these developmental genome rearrangements were identified based on their proteins' localization to differentiating somatic nuclei, and here we demonstrate that one, LIA1, encodes a novel protein that is an essential component of the genome rearrangement machinery. A green fluorescent protein-Lia1 fusion protein exhibited dynamic nuclear localization during development that has striking similarity to that of the dual chromodomain-containing DNA rearrangement protein, Pdd1p. Coimmunoprecipitation experiments showed that Lia1p associates with Pdd1p and IES chromatin during macronuclear development. Cell lines in which we disrupted both the germ line and somatic copies of LIA1 (DeltaLIA1) grew normally but were unable to generate viable progeny, arresting late in development just prior to returning to vegetative growth. These mutant lines failed to properly form Pdd1p-containing nuclear structures and eliminate IESs despite showing normal levels of H3K9 methylation. These data indicate that Lia1p is required late in conjugation for the reorganization of the Tetrahymena genome.     

Communication between parental and developing genomes during tetrahymena nuclear differentiation is likely mediated by homologous RNAs

Approximately 6000 DNA elements, totaling nearly 15 Mb, are coordinately excised from the developing somatic genome of Tetrahymena thermophila. An RNA interference (RNAi)-related mechanism has been implicated in the targeting of these germline-limited sequences for chromatin modification and subsequent DNA rearrangement. The excision of individual DNA segments can be inhibited if the homologous sequence is placed within the parental somatic nucleus, indicating that communication occurs between the parental and developing genomes. To determine how the DNA content of one nucleus is communicated to the other, we assessed DNA rearrangement occurring in wild-type cells that were mated to cells that contained the normally germline-limited M element within their somatic nuclei. M-element rearrangement was blocked in the wild-type cell even when no genetic exchange occurred between mating partners, a finding that is inconsistent with any genetic imprinting models. This inhibition by the parental somatic nucleus was rapidly established between 5 and 6 hr of conjugation, near or shortly after the time that zygotic nuclei are formed. M-element small RNAs (sRNAs) that are believed to direct its rearrangement were found to rapidly accumulate during the first few hours of conjugation before stabilizing to a low, steady-state level. The period between 5 and 6 hr during which sRNA levels stabilize correlates with the time after which the parental genome can block DNA rearrangement. These data lead us to suggest that homologous sRNAs serve as mediators to communicate sequence-specific information between the parental and developing genomes, thereby regulating genome-wide DNA rearrangement, and that these sRNAs can be effectively compared to the somatic genome of both parents.     

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.     

Mutations in Pdd1 Reveal Distinct Requirements for Its Chromodomain and Chromoshadow Domain in Directing Histone Methylation and Heterochromatin Elimination

Pdd1, a specialized HP1-like protein, is required for genome-wide DNA rearrangements that restructure a previously silent germ line genome into an active somatic genome during macronuclear differentiation of Tetrahymena thermophila. We deleted or otherwise mutated conserved regions of the protein to investigate how its different domains promote the excision of thousands of internal eliminated sequences (IESs). Previous studies revealed that Pdd1 contributes to recognition of IES loci after they are targeted by small-RNA-guided methylation of histone H3 on lysine 27 (H3K27), subsequently aids the establishment of H3K9 methylation, and recruits proteins that lead to excision. The phenotypes we observed for different Pdd1 alleles showed that each of the two chromodomains and the chromoshadow domain (CSD) have distinct contributions during somatic genome differentiation. Chromodomain 1 (CD1) is essential for conjugation as either its deletion or the substitution of two key aromatic amino acid residues (the W97A W100A mutant) is lethal. These mutations caused mislocalization of a cyan fluorescent protein (CFP)-tagged protein, prevented the establishment of histone H3 dimethylated on K9 (H3K9me2), and abolished IES excision. Nevertheless, the requirement for CD1 could be bypassed by recruiting Pdd1 directly to an IES by addition of a specific DNA binding domain. Chromodomain 2 (CD2) was necessary for producing viable progeny, but low levels of H3K9me2 and IES excision still occurred. A mutation in the chromoshadow domain (CSD) prevented Pdd1 focus formation but still permitted ∼17% of conjugants to produce viable progeny. However, this mutant was unable to stimulate excision when recruited to an ectopic IES, indicating that this domain is important for recruitment of excision factors.     

Small RNAs in genome rearrangement in Tetrahymena

Small RNAs produced by an RNAi-related mechanism are involved in DNA elimination during development of the somatic macronucleus from the germline micronucleus in Tetrahymena. The properties of these small RNAs can explain how the primary sequence of the parental macronucleus epigenetically controls genome rearrangement in the new macronucleus and provide the first demonstration of an RNAi-mediated process that directly alters DNA sequence organization. Methylation of histone H3 on lysine 9 and accumulation of chromodomain proteins, hallmarks of heterochromatin, also occur specifically on sequences undergoing elimination and are dependent on the small RNAs. These findings contribute to a new paradigm of chromatin biology: regulation of heterochromatin formation by RNAi-related mechanisms in eukaryotes.     

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.     

Diverse sequences within Tlr elements target programmed DNA elimination in Tetrahymena thermophila

Tlr elements are a novel family of ~30 putative mobile genetic elements that are confined to the germ line micronuclear genome in Tetrahymena thermophila. Thousands of diverse germ line-limited sequences, including the Tlr elements, are specifically eliminated from the differentiating somatic macronucleus. Macronucleus-retained sequences flanking deleted regions are known to contain cis-acting signals that delineate elimination boundaries. It is unclear whether sequences within deleted DNA also play a regulatory role in the elimination process. In the current study, an in vivo DNA rearrangement assay was used to identify internal sequences required in cis for the elimination of Tlr elements. Multiple, nonoverlapping regions from the ~23-kb Tlr elements were independently sufficient to stimulate developmentally regulated DNA elimination when placed within the context of flanking sequences from the most thoroughly characterized family member, Tlr1. Replacement of element DNA with macronuclear or foreign DNA abolished elimination activity. Thus, diverse sequences dispersed throughout Tlr DNA contain cis-acting signals that target these elements for programmed elimination. Surprisingly, Tlr DNA was also efficiently deleted when Tlr1 flanking sequences were replaced with DNA from a region of the genome that is not normally associated with rearrangement, suggesting that specific flanking sequences are not required for the elimination of Tlr element DNA.     

DNA hypomethylation circuit of the mouse oocyte-specific histone H1foo gene in female germ cell lineage

The oocyte-specific subtype of the linker histone H1 is H1FOO, which constitutes a major part of oocyte chromatin. H1foo is expressed in growing oocytes, through fertilization, up until the two-cell embryo stage, when it is subsequently replaced by somatic H1 subtypes. To elucidate whether an epigenetic mechanism is involved in the limited expression of H1foo, we analyzed the dynamics of the DNA methylation status of the H1foo locus in germ and somatic cells. We identified a tissue-dependent and differentially methylated region (T-DMR) upstream of the H1foo gene, which was hypermethylated in sperm, somatic cells, and stem cell lines. This region was specifically unmethylated in the ovulated oocyte, where H1foo is expressed. 5-Aza-2'-deoxycytidine treatments and luciferase assays provided in vitro evidence that DNA methylation plays a role in repressing H1foo in nonexpressing cells. DNA methylation analyses of fetal germ cells revealed the T-DMR to be hypomethylated in female and male germ cells at Embryonic Day 9.5 (E9.5), whereas it was highly methylated in somatic cells at this stage. Intriguingly, the unmethylated status was continuously observed throughout oogenesis at E9.5, E12.5, E15.5, E18.5, in mature oocytes, and after fertilization, in E3.5 blastocysts. In comparison, male germ cells acquired methylation beyond E18.5. These data demonstrate a continuously unmethylated circuit at the H1foo locus in the female germline.     

Keeping the soma free of transposons: programmed DNA elimination in ciliates

Many transposon-related sequences are removed from the somatic macronucleus of ciliates during sexual reproduction. In the ciliate Tetrahymena, an RNAi-related mechanism produces small noncoding RNAs that induce heterochromatin formation, which is followed by DNA elimination. Because RNAi-related mechanisms repress transposon activities in a variety of eukaryotes, the DNA elimination mechanism of ciliates might have evolved from these types of transposon-silencing mechanisms. Nuclear dimorphism allows ciliates to identify any DNA that has invaded the germ-line micronucleus using small RNAs and a whole genome comparison of the micronucleus and the somatic macronucleus.     

Mouse Dnmt3a preferentially methylates linker DNA and is inhibited by histone H1

In mammals, DNA methylation is crucial for embryonic development and germ cell differentiation. The DNA methylation patterns are created by de novo-type DNA methyltransferases (Dnmts) 3a and 3b. Dnmt3a is crucial for global methylation, including that of imprinted genes in germ cells. In eukaryotic nuclei, genomic DNA is packaged into multinucleosomes with linker histone H1, which binds to core nucleosomes, simultaneously making contacts in the linker DNA that separates adjacent nucleosomes. In the present study, we prepared oligonucleosomes from HeLa nuclei with or without linker histone H1 and used them as a substrate for Dnmt3a. Removal of histone H1 enhanced the DNA methylation activity. Furthermore, Dnmt3a preferentially methylated the linker between the two nucleosome core regions of reconstituted dinucleosomes, and the binding of histone H1 inhibited the DNA methylation activity of Dnmt3a towards the linker DNA. Since an identical amount of histone H1 did not inhibit the activity towards naked DNA, the inhibitory effect of histone H1 was not on the Dnmt3a catalytic activity but on its preferential location in the linker DNA of the dinucleosomes. The central globular domain and C-terminal tail of the histone H1 molecule were indispensable for inhibition of the DNA methylation activity of Dnmt3a. We propose that the binding and release of histone H1 from the linker portion of chromatin may regulate the local DNA methylation of the genome by Dnmt3a, which is expressed ubiquitously in somatic cells in vivo.     

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.