Transcriptional gene silencing mutants.

Genetic approaches to identify molecular components of transcriptional gene silencing (TGS) in plants have yielded several Arabidopsis thaliana mutants and identified the first genes involved. All mutations found affect the maintenance of silencing and reactivate silent genes in trans. The mutations fall into two categories: ddm1 and hog release silencing in association with decreased levels of DNA methylation, while sil and mom reactivate genes without changing the methylation state. While plants homozygous over several generations for hog, sil or mom exhibit no morphological changes, ddm1-type mutants accumulate developmental abnormalities. The mutants indicate that TGS in plants is controlled by several genetic components and possibly by multiple independent pathways. The DDM1 gene was assigned to the SWI2/SNF2 gene family of chromatin-remodelling proteins, the MOM gene is a novel protein and the other loci have not yet been characterized.

Endogenous targets of transcriptional gene silencing in Arabidopsis.

Transcriptional gene silencing (TGS) frequently inactivates foreign genes integrated into plant genomes but very likely also suppresses an unknown subset of chromosomal information. Accordingly, RNA analysis of mutants impaired in silencing should uncover endogenous targets of this epigenetic regulation. We compared transcripts from wild-type Arabidopsis carrying a silent transgene with RNA from an isogenic transgene-expressing TGS mutant. Two cDNA clones were identified representing endogenous RNA expressed only in the mutant. The synthesis of these RNAs was found to be released in several mutants affected in TGS, implying that TGS in general and not a particular mutation controls the transcriptional activity of their templates. Detailed analysis revealed that the two clones are part of longer transcripts termed TSI (for transcriptionally silent information). Two major classes of related TSI transcripts were found in a mutant cDNA library. They are synthesized from repeats present in heterochromatic pericentromeric regions of Arabidopsis chromosomes. These repeats share sequence homology with the 3' terminal part of the putative retrotransposon Athila. However, the transcriptional activation does not include the transposon itself and does not promote its movement. There is no evidence for a general release of silencing from retroelements. Thus, foreign genes in plants encounter the epigenetic control normally directed, at least in part, toward a subset of pericentromeric repeats.

Disruption of the plant gene MOM releases transcriptional silencing of methylated genes.

Epigenetic modifications change transcription patterns in multicellular organisms to achieve tissue-specific gene expression and inactivate alien DNA such as transposons or transgenes. In plants and animals, DNA methylation is involved in heritability and flexibility of epigenetic states, although its function is far from clear. We have isolated an Arabidopsis gene, MOM, whose product is required for the maintenance of transcriptional gene silencing. Mutation of this gene or depletion of its transcript by expression of antisense RNA reactivates transcription from several previously silent, heavily methylated loci. Despite this, the dense methylation at these reactivated loci is maintained even after nine generations, indicating that transcriptional activity and methylation pattern are inherited independently. The predicted MOM gene product is a nuclear protein of 2,001 amino acids containing a region similar to part of the ATPase region of the SWI2/SNF2 family, members of which are involved in chromatin remodelling. MOM is the first known molecular component that is essential for transcriptional gene silencing and does not affect methylation pattern. Thus, it may act downstream of methylation in epigenetic regulation, or be part of a new pathway that does not require methylation marks.

Rapid structural and epigenetic changes in polyploid and aneuploid genomes.

Recent work with plants has demonstrated that genome instability can be triggered by a change in chromosome number arising from either whole genome duplications (polyploidy) or loss/gain of individual chromosomes (aneuploidy). This genome instability is manifested as rapid structural and epigenetic alterations that can occur somatically or meiotically within a few generations after heteroploid formation. The intrinsic instability of newly formed polyploid and aneuploid genomes has relevance for genome evolution and human carcinogenesis, and points toward recombinational and epigenetic mechanisms that sense and respond to chromosome numerical changes.

Cytosine methylation at CG and CNG sites is not a prerequisite for the initiation of transcriptional gene silencing in plants, but it is required for its maintenance.

Transgenes integrated into plant chromosomes, and/or endogenous plant genes, may be subjected to epigenetic silencing at the transcriptional or post-transcriptional level. Transcriptional inactivation is correlated with hypermethylation of CG/CNG sites at the silent loci. It is not known whether local hypermethylation is part of the inactivation process, or just an outcome of the silent state. To address this issue, we generated transgenic tobacco lines containing a selectable marker gene controlled by a derivative of the 35S promoter of the cauliflower mosaic virus (CaMV) devoid of CG and CNG methylation acceptor sites. Silencing was triggered by crossing to the silencer locus of tobacco line 271. This line contains inactive and methylated copies of the 35S promoter and is able to silence homologous promoter copies at ectopic chromosomal positions. The mutated promoter lacking CG/CNG methylation acceptor sites was as susceptible to Trans-silencing as the unmodified 35S promoter control. Thus, methylation at CG and CNG sites is not a prerequisite for the initiation of epigenetic gene inactivation. Interestingly, while methylation of the remaining cytosines is usually only slightly affected by silencing, it was significantly increased in the absence of CG/CNG sequences. Since this sequence preference is the same as that of known methyltransferases, this may imply that silencing is accompanied or directly followed by recruitment of methyltransferase, which, in the absence of cytosines in the optimal sequence context, modifies other C residues in the affected area. However, silencing without CG/CNG methylation was immediately relieved in the absence of the silencer. Thus, CG/CNG methylation is probably essential for the maintenance of previously established epigenetic states.

Plant genes: the genetics of epigenetics.

The formation of silent epialleles is accompanied by local hypermethylation of the DNA template, and genetically altered, methylation-deficient Arabidopsis mutants generate an increased number of epimutations. But what came first--methylation or epigenetic change?

Release of epigenetic gene silencing by trans-acting mutations in Arabidopsis.

Gene silencing in plants inactivates trans-genes introduced into plants and/or endogenous homologous genes. This stable but potentially reversible loss of gene activity resembles epigenetic changes that occur in normal development. The stability of silencing implies the involvement of trans-acting components, although none of them have been identified so far. Here we report the finding of second-site mutations interfering with maintenance of the silent state. We mutagenized Arabidopsis thaliana plants carrying a silent transgene encoding hygromycin phosphotransferase (hpt) and therefore show a heritable hygromycin-sensitive phenotype. The M2 generation was screened for hygromycin resistance. Eight putative mutants (som1 to 8) were found that expressed the transgene and transmitted the expressed state to their progeny. All mutations were shown to reactivate a silent transgenic test locus in trans. The level of DNA methylation at the hpt locus and at centromeric repeats was found to be reduced in the som mutants. Complementation crosses indicated complex epigenetic interactions among the som mutant alleles and with the previously described ddm1 allele, which elicits DNA hypomethylation [Vongs, A., Kakutani, T, Martiensen, R.A. & Richards, E.J. (1993) Science 260, 1926-1928]. Som mutants can be classified into three groups: (i) allelic or interacting with ddm1 and with each other (som 1,4, and 5), (ii) nonallelic with ddm1 and som mutants of group A (som2), and (iii) mutants with slow resilencing after out-crosses, which hinders their classification (som 3, 6, 7 and 8).

Methylation of cytosines in nonconventional methylation acceptor sites can contribute to reduced gene expression.

Epigenetic silencing of gene expression is often correlated with extensive DNA methylation at cytosine residues in the promoter and the coding region of silenced genes. Increasing evidence indicates that, in such cases, DNA methylation can also occur in sequence contexts other than CG and CNG, resulting in genomic regions with almost complete modification of cytosines. Whether this nonconventional methylation at CNN sites also contributes to gene repression is not known. We constructed genes with a promoter and a coding region devoid of the conventional methylation acceptor sites CG and CNG in addition to constructs with the corresponding wild-type sequences containing these sites. We generated unmethylated and completely methylated DNA by the polymerase chain reaction and performed expression assays in plant protoplasts. Quantification of transcript levels by RNase protection assay demonstrated that DNA methylation at positions other than CG or CNG sites contributes to the reduction in gene expression.

A change of ploidy can modify epigenetic silencing.

A silent transgene in Arabidopsis thaliana was reactivated in an outcross but not upon selfing of hemizygous plants. This result could only be explained by assuming a genetic difference between the transgene-free gametes of the wild-type and hemizygous transgenic plants, respectively, and led to the discovery of ploidy differences between the parental plants. To investigate whether a change of ploidy by itself can indeed influence gene expression, we performed crosses of diploid or tetraploid plants with a strain containing a single copy of a transgenic resistance gene in an active state. We observed reduced gene expression of the transgene in triploid compared with diploid hybrids. This led to loss of the resistant phenotype at various stages of seedling development in part of the population. The gene inactivation was reversible. Thus, an increased number of chromosomes can result in a new type of epigenetic gene inactivation, creating differences in gene expression patterns. We discuss the possible impact of this finding for genetic diploidization in the light of widespread, naturally occurring polyploidy and polysomaty in plants.

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.

Cytosine methylation inhibits replication of African cassava mosaic virus by two distinct mechanisms.

Extrachromosomally replicating viral DNA is usually free of cytosine methylation and viral templates methylated in vitro are poor substrates when used in replication assays. We have investigated the mechanism of inhibition of viral replication by DNA methylation using as a model the DNA A of African cassava mosaic virus. We have constructed two component helper systems which allow for separation of the transcriptional inhibition of viral genes necessary for replication from replication inhibition due to altered interaction between the replication complex and methylated viral DNA. Our results suggest that methylation-mediated reduction of viral replication is due to both repression mechanisms and that this provides two independent selection pressures for the maintenance of methylation-free replicons in infected cells.

Expression of a downstream gene from a bicistronic transcription unit in transgenic tobacco plants.

We have constructed a set of plasmids carrying an artificial compact stop-start codon sequence, TGATGTAACATGA, between an upstream open reading frame, terminating at one of the stop codons, and a downstream kanamycin-resistance (KmR)-encoding gene (nptII) initiating at the second ATG. These plasmids were introduced into tobacco protoplasts by direct gene transfer. The efficiency of expression of the downstream nptII gene was measured by scoring the number of KmR transformants. With a closer distance between the functional stop and start codons, a tendency to less efficient expression of nptII was found. The integration and expression of both genes as a bicistronic transcription unit were verified by Southern- and Northern-blot analyses. A possible application of the compact stop-start codon sequence for insertional mutagenesis is discussed.

Lack of in vivo transcription of Acetabularia mediterranea 1175 bp ctDNA fragment homologous to the Drosophila per locus.

The period (per) locus of Drosophila melanogaster has a fundamental role in the expression of biological rhythms. A DNA sequence homologous to a short region of the Drosophila per locus was detected in the chloroplast of Acetabularia mediterranea. A 1175 bp DNA fragment containing the sequence was used as a probe in 'Northern' hybridization experiments. It was found that this DNA was not transcribed or only marginally transcribed in A. mediterranea, at least at the developmental stage just prior to cap formation. It seems that the 1175 bp ctDNA fragment is not involved in the Acetabularia biological rhythm mechanism.

Reversible inactivation of a transgene in Arabidopsis thaliana.

Fifty percent of Arabidopsis thaliana plants transgenic for a hygromycin resistance gene failed to transmit the resistance phenotype to the progeny. The complete transgene was, however, inherited in all cases according to Mendelian laws as observed by Southern analysis. This discrepancy between genotype and phenotype was the result of a reduced level of transcript in the sensitive transformants. The gene inactivation occurred in plants with multicopy integration of the foreign DNA. No definite correlation was found between gene inactivity and methylation of cytidine residues in the transgene sequence. Explants from several sensitive transformed plants regained a low level of hygromycin resistance on callus induction medium. Subsequent generations obtained by self-pollination were sensitive. In contrast, spontaneous restoration of hygromycin tolerance was observed in seedlings originating from out-crosses with wild-type plants or a different sensitive transformant. A reduction of the copy number was not a prerequisite for spontaneous reactivation. The resistance was often lost again in the next generation. Inactivation and reactivation of the transgene are therefore reversible.

Direct gene transfer to protoplasts of Arabidopsis thaliana.

We performed a series of direct gene transfer experiments with protoplasts of Arabidopsis thaliana ecotype Zürich. An average of more than 100 transformants were selected per 10(6)6 treated protoplasts. Stable transformation was confirmed by integration of the marker gene into high molecular weight DNA and by its genetic transmission to subsequent offspring generations.