Targeted transformation of Ascobolus immersus and de novo methylation of the resulting duplicated DNA sequences.

To develop a method to modify genomic sequences in Ascobolus immersus by precisely reintroducing defined DNA segments previously manipulated in vitro, we investigated the effect of transforming DNA conformation on recombination with chromosomal sequences. Circular single-stranded DNA carrying the met2 gene and double-stranded DNA linearized by cutting within the met2 gene both transformed protoplasts of a met2 mutant strain of A. immersus to prototrophy. In contrast to the equivalent circular double-stranded DNA, which chiefly integrated at nonhomologous chromosomal sites, single-stranded and double-stranded cut DNAs recombined primarily with the homologous chromosomal met2 sequence. Of the single-stranded DNA transformants, 65% resulted from replacement of the resident met2 mutation by the exogenous wild-type allele. In 70% of the double-stranded-cut DNA transformants, one or more copies of the transforming DNA had integrated at the met2 locus, leading to tandem duplications of the met2 target region separated by plasmid DNA. These duplicated sequences could recombine, leading to progeny containing only one copy of the met2 region. This resulted in a precise gene replacement if the wild-type allele had been retained. In addition, we show that newly duplicated sequences were most often de novo methylated at the cytosine residues during the sexual phase. Cytosine methylation was associated with inactivation of the integrated met2 gene(s) in segregants of crosses. However, methylation was not accurately maintained at each DNA replication cycle, so that Met- segregants recovered a wild-type phenotype through successive mitotic divisions. This finding indicated that met2 genes were silenced by methylation alone.     

How Does the Cell Count the Number of Ectopic Copies of a Gene in the Premeiotic Inactivation Process Acting in Ascobolus Immersus?

Repeated genes, artificially introduced in Ascobolus immersus by integrative transformation, are frequently inactivated during the sexual phase. Inactivation is observed in about 50% of meioses if duplicated genes are at ectopic chromosomal locations, and in 90% of meioses if genes are tandemly repeated. Inactivation is associated with extensive methylation of the cytosine residues of the duplicated sequences and is induced in the still haploid nuclei of the dikaryotic cell which will undergo karyogamy and subsequent meiosis. Only repeated sequences become methylated. This raises the intriguing question of how the premeiotic inactivation machinery is informed that a nucleus contains multiple copies of a gene. By using in crosses recombinant strains of A. immersus in which either one, two or three genetically independent copies of the exogenous amdS gene from Aspergillus nidulans had been introduced, we could follow the premeiotic inactivation of each one of the ectopic amdS copies. This led us to propose that a prerequisite for inactivation is a premeiotic pairing of repeated sequences and that each copy can undergo successive cycles of pairing. In fact, once methylated, a copy can pair with a still unmethylated copy, so that an uneven number of copies can be subject to inactivation.     

Methylation of DNA repeats of decreasing sizes in Ascobolus immersus.

In Ascobolus immersus, DNA duplications are subject to the process of methylation induced premeiotically (MIP), which methylates the cytosine residues within the repeats and results in reversible gene silencing. The triggering of MIP requires pairing of the repeats, and its detection requires maintenance of the resulting methylation. MIP of kilobase-size duplications occurs frequently and leads to the methylation of all C residues in the repeats, including those belonging to non-CpG sequences. Using duplications of decreasing sizes, we observed that tandem repeats never escaped MIP when larger than 630 bp and showed a sudden and drastic drop in MIP frequencies when their sizes decreased from 630 to 317 bp. This contrasted with the progressive decrease of MIP frequencies observed with ectopic repeats, in which apparently the search for homology influences the MIP triggering efficiency. The minimal size actually required for a repeat to undergo detectable MIP was found to be close to 300 bp. Genomic sequencing and Southern hybridization analyses using restriction enzymes sensitive to C methylation showed a loss of methylation at non-CpG sites in short DNA segments, methylation being restricted to a limited number of CpG dinucleotides. Our data suggest the existence of two distinct mechanisms underlying methylation maintenance, one responsible for methylation at CpG sites and the other responsible for methylation at non-CpG sites.     

Isolation of the Ascobolus Immersus Spore Color Gene B2 and Study in Single Cells of Gene Silencing by Methylation Induced Premeiotically

The ascomycete Ascobolus immersus has been extensively used as a model system for the genetic study of meiotic recombination. More recently, an epigenetic process, known as methylation induced premeiotically (MIP), that acts on duplicated sequences has been discovered in A. immersus and has raised a new interest in this fungus. To try and extend these studies, we have now cloned the A. immersus spore color gene b2, a well characterized recombination hot-spot. Isolation of the whole gene was verified by physical mapping of four large b2 alterations, followed by transformation and mutant rescue of a null b2 allele. Transformation was also used to duplicate b2 and subject it to MIP. As a result, we were able for the first time to observe gene silencing as early as just after meiosis and in single cells. Furthermore, we have found evidence for a modulating effect of MIP on b2 expression, depending on the region of the gene that is duplicated and hence subjected to MIP.     

Are linker histones (histone H1) dispensable for survival?

In the multicelled filamentous ascomycete Ascolobus immersus, the single copy gene for histone H1 can be silenced by methylation in the process known as methylation-induced premeiotically (MIP). The results of a recent paper using this unique system(1) have shown that histone H1 silencing results in an enhanced DNA accessibility to nucleases and an increase in the overall extent of DNA methylation. Interestingly, while none of these effects appear to decrease the immediate viability of this fungus, silencing of histone H1 results in a significant decrease in its overall life span. These results suggest that while linker histones may be dispensable for the relatively short life span of an individual cell, they are most likely indispensable for survival of higher eukaryote organisms.     

Histone H1 is dispensable for methylation-associated gene silencing in Ascobolus immersus and essential for long life span

A gene encoding a protein that shows sequence similarity with the histone H1 family only was cloned in Ascobolus immersus. The deduced peptide sequence presents the characteristic three-domain structure of metazoan linker histones, with a central globular region, an N-terminal tail, and a long positively charged C-terminal tail. By constructing an artificial duplication of this gene, named H1, it was possible to methylate and silence it by the MIP (methylation induced premeiotically) process. This resulted in the complete loss of the Ascobolus H1 histone. Mutant strains lacking H1 displayed normal methylation-associated gene silencing, underwent MIP, and showed the same methylation-associated chromatin modifications as did wild-type strains. However, they displayed an increased accessibility of micrococcal nuclease to chromatin, whether DNA was methylated or not, and exhibited a hypermethylation of the methylated genome compartment. These features are taken to imply that Ascobolus H1 histone is a ubiquitous component of chromatin which plays no role in methylation-associated gene silencing. Mutant strains lacking histone H1 reproduced normally through sexual crosses and displayed normal early vegetative growth. However, between 6 and 13 days after germination, they abruptly and consistently stopped growing, indicating that Ascobolus H1 histone is necessary for long life span. This constitutes the first observation of a physiologically important phenotype associated with the loss of H1.     

Activity of the transposon Tam3 in Antirrhinum and tobacco: possible role of DNA methylation.

The transposon Tam3 from Antirrhinum majus can transpose in a heterologous host (Nicotiana tabacum); thus the element is autonomous, probably encoding the specific information required for its own transposition. In transgenic tobacco Tam3 rapidly becomes methylated at its ends whilst adjacent flanking sequences remain hypomethylated. This methylation may account for our failure to detect Tam3 transposition in the progeny of transgenic tobacco. Treatment with the inhibitor of cytosine methylation, 5 aza-cytosine appeared to induce transposon related activity at a low level. In Antirrhinum methylation also appears to be associated with inactivation of Tam3 copies.     

Gene inactivation in Arabidopsis thaliana is not accompanied by an accumulation of repeat-induced point mutations

Chromosomal integration of multicopy transgene inserts in higher plants is often followed by loss of expression. We have analysed whether this inactivation can trigger repeat-induced point mutations (RIP) as has been observed in Neurospora crassa. We have previously characterized transgenic lines of Arabidopsis thaliana containing the hygromycin phosphotransferase (hpt) gene either as a unique sequence in plants expressing the gene, or as multimeric, closely linked repeats in clones that were resistant to hygromycin directly after transformation but exhibited gene inactivation in the subsequent generation. At the sequence level, we have determined the mutation frequencies in the promoter and coding regions of active and inactive copies of transgene inserts after passage through three sexual generations. No RIP-like mutations were found in inactivated genes. Comparison of our data with those from Neurospora suggest that sequence divergence within plant repetitive DNA is either much slower than in Neurospora or is generated by a different mechanism.     

Gene inactivation in Arabidopsis thaliana is not accompanied by an accumulation of repeat-induced point mutations

Chromosomal integration of multicopy transgene inserts in higher plants is often followed by loss of expression. We have analysed whether this inactivation can trigger repeat-induced point mutations (RIP) as has been observed in Neurospora crassa. We have previously characterized transgenic lines of Arabidopsis thaliana containing the hygromycin phosphotransferase (hpt) gene either as a unique sequence in plants expressing the gene, or as multimeric, closely linked repeats in clones that were resistant to hygromycin directly after transformation but exhibited gene inactivation in the subsequent generation. At the sequence level, we have determined the mutation frequencies in the promoter and coding regions of active and inactive copies of transgene inserts after passage through three sexual generations. No RIP-like mutations were found in inactivated genes. Comparison of our data with those from Neurospora suggest that sequence divergence within plant repetitive DNA is either much slower than in Neurospora or is generated by a different mechanism.     

Novel pattern of DNA methylation in Neurospora crassa transgenic for the foreign gene hph.

It has previously been reported that multiple copies of the hph gene integrated into the genome of Neurospora crassa are methylated at Hpa II sites (CCGG) during the vegetative life cycle of the fungus, while hph genes integrated as single copies are not methylated. Furthermore, methylation is correlated with silencing of the gene. We report here the methylation state of cytosine residues of the major part of the promoter region of the hph gene integrated into the genome of the multiple copy strain HTA5.7 during the vegetative stage of the life cycle. Cytosine methylation is sequence dependent, but the sequence specificity is complex and is different from the sequence specificity known for mammals and plants (CpG and CpNpG). The pattern of DNA methylation reported here is very different from that measured after meiosis in Neurospora or in Ascobulus . After the sexual cycle in those two fungi all the cytosines of multiple stretches of DNA are heavily methylated. This indicates that the still unknown methyltransferase in Neurospora has a different specificity in the sexual and the vegetative stages of the life cycle or that there are different methyltransferases. The pattern of methylation reported here is also different from the pattern of cytosine methylation of transgenes of Petunia , the only pattern published until now in plants that has DNA methylation at cytosines which are not in the canonical sequences CpG and CpNpG.     

Fragile X syndrome and the (CGG)n mutation: two families with discordant MZ twins.

The fragile X phenotype has been found, in the majority of cases, to be due to the expansion of a CGG repeat in the 5'-UTR region of the FMR-1 gene, accompanied by methylation of the adjacent CpG island and inactivation of the FMR-1 gene. Although several important aspects of the genetics of fragile X have been resolved, it remains to be elucidated at which stage in development the transition from the premutation to the full mutation occurs. We present two families in which discordance between two sets of MZ twins illustrates two important genetic points. In one family, two affected MZ brothers differed in the number of CGG repeats, demonstrating in vivo mitotic instability of this CGG repeat and suggesting that the transition to the full mutation occurred postzygotically. In the second family, two MZ sisters had the same number of repeats, but only one was mentally retarded. When the methylation status of the FMR-1 CpG island was studied, we found that the majority of normal chromosomes had been inactivated in the affected twin, thus leading to the expression of the fragile X phenotype.     

Wolbachia prophage DNA adenine methyltransferase genes in different Drosophila-Wolbachia associations

Wolbachia is an obligatory intracellular bacterium which often manipulates the reproduction of its insect and isopod hosts. In contrast, Wolbachia is an essential symbiont in filarial nematodes. Lately, Wolbachia has been implicated in genomic imprinting of host DNA through cytosine methylation. The importance of DNA methylation in cell fate and biology calls for in depth studying of putative methylation-related genes. We present a molecular and phylogenetic analysis of a putative DNA adenine methyltransferase encoded by a prophage in the Wolbachia genome. Two slightly different copies of the gene, met1 and met2, exhibit a different distribution over various Wolbachia strains. The met2 gene is present in the majority of strains, in wAu, however, it contains a frameshift caused by a 2 bp deletion. Phylogenetic analysis of the met2 DNA sequences suggests a long association of the gene with the Wolbachia host strains. In addition, our analysis provides evidence for previously unnoticed multiple infections, the detection of which is critical for the molecular elucidation of modification and/or rescue mechanism of cytoplasmic incompatibility.     

De Novo Methylation of Repeated Sequences in Coprinus Cinereus

We have examined the stability of duplicated DNA sequences in the sexual phase of the life cycle of the basidiomycete fungus, Coprinus cinereus. We observed premeiotic de novo methylation in haploid nuclei containing either a triplication, a tandem duplication, or an ectopic duplication. Methylation changes were not observed in unique sequences. Repeated sequences underwent methylation changes during the dikaryotic stage. In one cross, 27% of the segregants exhibited methylation-directed gene inactivation. However, all auxotrophs eventually reverted to prototrophy. C to T transition mutations were not observed in this study. Our studies also revealed one inversion that occurred in 50% of the segregants in a single triplication cross, and a single pop-out event that occurred during vegetative growth. These alterations were similar to changes reported in experiments with duplicated sequences in Neurospora crassa and Ascobolus immersus. However, significant differences were also noted. First, the extent of methylation was much less in C. cinereus than in the other two fungi. Second, CpG sequences appeared to be the preferred targets of methylation.     

DNA methylation inhibits propagation of tomato golden mosaic virus DNA in transfected protoplasts

The effects of methylation on plant viral DNA replication have been studied inNicotiana tabacum protoplasts transfected with DNA of the geminivirus tomato golden mosaic virus (TGMV). The transfected cells were also used to determine whether experimentally introduced methylation patterns are maintained in extrachromosomal viral DNA. Replacement of cytosine residues with 5-methylcytosine (m⁵C) reduced the amount of viral DNA which accumulated in transfected protoplasts. The reduction was observed whether m⁵C residues were substituted for cytosine residuesin vitro in either the viral strand or the complementary strand of double-stranded circular inoculum DNAs containing tandemly repeated copies of the A component of the TGMV genome. Both limited and extensive cytosine methylation of TGMV DNA sequencesin vitro was not propagated in progeny viral DNA. The absence of detectable maintenance-type methylation of the transfecting TGMV DNA sequences may be related to the lack of methylation observed in double-stranded TGMV DNA isolated from infected plants.