Godeleine Faugeron

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.

A Gene Essential for De Novo Methylation and Development in Ascobolus Reveals a Novel Type of Eukaryotic DNA Methyltransferase Structure

Molecular mechanisms determining methylation patterns in eukaryotic genomes still remain unresolved. We have characterized, in Ascobolus, a gene for de novo methylation. This novel eukaryotic gene, masc1, encodes a protein that has all motifs of the catalytic domain of eukaryotic C5-DNA-methyltransferases but is unique in that it lacks a regulatory N-terminal domain. The disruption of masc1 has no effect on viability or methylation maintenance but prevents the de novo methylation of DNA repeats, which takes place after fertilization, through the methylation induced premeiotically (MIP) process. Crosses between parents harboring the masc1 disruption are arrested at an early stage of sexual reproduction, indicating that the activity of Masc1, the product of the gene, is crucial in this developmental process.

Histone H1 Is Dispensable for Methylation-Associated Gene Silencing in Ascobolus immersus and Essential for Long Life Span

ABSTRACT 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, namedH1, 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 thatAscobolus 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.

The MET2 gene of Saccharomyces cerevisiae: molecular cloning and nucleotide sequence

A 5.1-kb DNA fragment from Saccharomyces cerevisiae, which complements a yeast met2 mutant strain, has been cloned. This fragment contains the wild-type MET2 gene which codes for the homoserine O-transacetylase, one of the methionine biosynthetic enzymes. The presence of the MET2 gene has been shown by integrative transformation experiments and genetic analyses of the resulting transformants. The complete nucleotide sequence of a 2826-bp DNA fragment carrying the MET2 gene has been determined. The sequence contains one major open reading frame of 438 codons, giving a calculated Mr of 48,370 for the encoded protein. We have identified the transcriptional product of the MET2 gene and estimated its size at 1650 nucleotides.

Molecular cloning and characterization of the met2 gene from Ascobolus immersus

We have cloned the met2 gene from Ascobolus immersus by heterologous hybridization with the MET2 gene of Saccharomyces cerevisiae. This gene codes for the homoserine O-transacetylase, one of the methionine biosynthetic enzymes. The complete nucleotide sequence of a 2910-bp DNA fragment carrying the met2 gene has been determined. The gene contains a 165-bp intron which is similar in structure to other fungal introns. The deduced amino acid (aa) sequence (518 aa residues; Mr of 57726) shows three domains with a significant level of homology with the corresponding yeast protein. Northern-blot analysis reveals at least two transcripts (2.4 and 2.1 kb) probably due to transcription termination heterogeneity, as suggested by S1-mapping experiments. Polymorphism has been observed in the met2 gene flanking regions of Ascobolus strains from two different stocks.

Stable allele replacement and unstable non-homologous integration events during transformation of Ascobolus immersus.

An homologous transformation system for the filamentous fungus Ascobolus immersus has been developed, based on the complementation of a met2 mutation by the wild-type (wt) allele gene encoding homoserine O-transacetylase. Transformation of A. immersus met2 mutants occurs with moderate frequencies (about 50 transformants per microgram input DNA). Analysis of the DNA of the met2+ transformants showed that transformation resulted either in a single integration of the donor DNA into the genome by many different nonhomologous recombination events or in the substitution of the endogenous met2 mutation by the wt transforming allele. The relative frequencies of both events depended on the vector sequences carrying the cloned met2 gene. Whereas the substitution event led, as expected, to genetically stable transformants, the non-homologous integration was always associated with a strong instability when transformants were crossed and underwent meiosis.

Clustering of multiple transgene integrations in highly-unstable Ascobolus immersus transformants

A large proportion of Ascobolus immersus transformants are highly unstable in crosses: the phenotype conferred by the transgene is not transmitted to the progeny, irrespective of the endogenous or foreign origin of the transgene. They all have integrated multiple transgene copies, clustered at a single chromosomal site or at tightly-linked sites. Clustered non-homologous integrations are always rearranged. Yet they never escape the “methylation induced premeiotically” (MIP) process. This always results in gene silencing, even when the transgene is partially repeated, accounting for the high instability of these transformants.