Variegated expression of a globin transgene correlates with chromatin accessibility but not methylation status.

There are now many mammalian examples in which single cell assays of transgene activity have revealed variegated patterns of expression. We have previously reported that transgenes in which globin regulatory elements drive the lacZ reporter gene exhibit variegated expression patterns in mouse erythrocytes, with transgene activity detectable in only a sub-population of circulating erythroid cells. In order to elucidate the molecular mechanism responsible for variegated expression in this system, we have compared the chromatin structure and methylation status of the transgene locus in expressing and non-expressing populations of erythrocytes. We find that there is a difference in the chromatin conformation of the transgene locus between the two states. Relative to active transgenes, transgene loci which have been silenced exhibit a reduced sensitivity to general digestion by DNase I, as well as a failure to establish a transgene-specific DNase I hypersensitive site, suggesting that silenced transgenes are situated within less accessible chromatin structures. Surprisingly, the restrictive chromatin structure observed at silenced transgene loci did not correlate with increased methylation, with transgenes from both active and inactive loci appearing largely unmethylated following analysis with methylation-sensitive restriction enzymes and by sequencing PCR products derived from bisulphite-converted genomic DNA.     

Tandemly repeated transgenes of the human minisatellite MS32 (D1S8), with novel mouse gamma satellite integration.

The human hypervariable minisatellite MS32 has a well characterised internal repeat unit array and high mutation rates have been observed at this locus. Analysis of MS32 mutants has shown that male germline mutations are polarised to one end of the array and frequently involve complex gene conversion-like events, suggesting that tandem repeat instability may be modulated by cis-acting sequences flanking the locus. In order to investigate the processes affecting MS32 mutation rate and mechanism, we have created transgenic mice harbouring an MS32 allele. Here we describe the organisation of eight transgenic insertions. Analysis of these transgenic loci by MVR-PCR and structural analysis of the junctions between mouse flanking DNA and the transgenic loci has shed light on mechanisms of integration and rearrangement of the tandem repeated transgenes. Sequence analysis of the mouse DNA flanking these transgenes has shown that 5 of the 8 insertions have integrated into mouse gamma satellite repeated sequence. This suggests a non-random integration of the MS32 transgene construct into the mouse genome.     

Co-silencing of homologous transgenes in tobacco

Two transgenes inserted into different genomic positions can co-inactivate each other when they share homologous sequences while each of the two homologous transgenes is stably expressed in the absence of a second homologous copy. To evaluate the efficiency of such homology-dependent gene silencing (HDGS) effects, we have produced 19 tobacco transformants that contained a stably expressed NPTII transgene inserted into a single genomic locus, and have analysed the stability of each transgene in the presence of a second stably expressed homologous transgene. All transformants shared the coding region of the NPTII gene but individual transformants differed in transgene copy number, expression levels and in the continuity of the transgene homology due to the insertion of introns into the NPTII region as well as the use of different promoters and terminators for the design of the transgene constructs. We generated 189 progeny populations representing all possible dual combinations among the 19 lines and analysed the kanamycin resistance of 400 seedlings of each cross. Our data show (1) that gene silencing occurs at a relative low frequency when transgenic loci sharing an homology at the coding sequence level are combined, and (2) that neither the variation of this homology by insertion of introns in the coding sequence, or by changing the promoter and terminator of the construct, nor the variation in the expression level of the transgene, are decisive parameters modifying the efficiency of co-silencing between two NPTII transgenes.     

Molecular and genetic analysis of nitrite reductase co-suppression in transgenic tobacco plants

Silencing ofNia host genes and transgenes (encoding nitrate reductase) was previously achieved by introducing into tobacco plants the tobaccoNia2 cDNA cloned downstream of the cauliflower mosaic virus (CaMV) 35S promoter. To check whetherNii host genes and transgenes (encoding nitrite reductase, the second enzyme of the nitrate assimilation pathway) were also susceptible to silencing, a transgene consisting of the tobaccoNii1 gene with two copies of the enhancer of the 35S promoter cloned 1 kb upstream of theNii promoter region was introduced into tobacco plants. Among nine independent transformants analysed, two showed silencing ofNii host genes and transgenes in some descendants after selfing, but never after back-crossing with wild-type plants, suggesting that silencing depends on the number of transgene loci and/or on certain allelic or ectopic combinations of transgene loci. In one transformant carrying a single transgene locus in a homozygous state, silencing was triggered in all progeny plants of each generation, 20 to 50 days after germination. Field trial analysis confirmed that silencing was not triggered when the transgene locus of this latter line was present in a hemizygous state. In addition, it was revealed that silencing can be triggered, albeit at low frequency and later during the development, when this transgene locus is brought into the presence of a non-allelic transgene locus by crossing, suggesting that a homozygous state is not absolutely required.     

External control of transgene expression in tobacco plastids using the bacterial lac repressor

Although several induction systems have been described for plants containing transgenes in the nucleus, to date there is only one method for controlling transgene expression in plastids. This consists of chemical induction of a nuclear gene and import of the gene product into plastids, so that transformation of two cellular compartments is required. Here we describe a system for external control of plastid gene expression which is based entirely on plastid components and can therefore be established in a single transformation step. Our system uses modified promoters containing binding sites for the bacterial lac repressor. Chemical induction can be made with intact plants or after harvesting, which provides ecological and economic benefits.     

Homology-dependent gene silencing in transgenic plants: epistatic silencing loci contain multiple copies of methylated transgenes

Previous work has shown that two homologous, unlinked transgene loci can interact in plant nuclei, leading to non-reciprocal trans-inactivation and methylation of genes at one locus. Here, we report the structure and methylation of different transgene loci that contain the same construct but are variably able to inactivate and methylate a partially homologous, unlinked target locus. Silencing loci comprised multiple, methylated copies of the transgene construct, whereas a non-silencing locus contained a single, unmethylated copy. The correspondence between strength of silencing activity and copy number/degree of methylation was further demonstrated by producing novel alleles of a strong silencing locus: reducing the transgene copy number and methylation within this silencing locus decreased its ability to inactivate the target locus. The strong silencing locus, which was located close to a telomere, trans-inactivated various structural variants of the original target construct, regardless of their location in the genome. This suggests that the silencing locus can scan the entire genome for homologous regions, a process possibly aided by its telomeric location. Our data support the idea that epistatic trans-inactivation of unlinked, homologous transgenes in plants results from a pre-existing epigenetic difference between transgene loci, which is subsequently equalized by epigene conversion involving DNA-DNA pairing.     

Sleeping Beauty transposition in the mouse genome is associated with changes in DNA methylation at the site of insertion

The Sleeping Beauty (SB) transposon (Tn) system is a nonviral gene delivery tool that has widespread application for transfer of therapeutic genes into the mammalian genome. To determine its utility as a gene delivery system, it was important to assess the epigenetic modifications associated with SB insertion into the genome and potential inactivation of the transgene. This study investigated the DNA methylation pattern of an SB Tn as well as the flanking genomic region at insertion sites in the mouse genome. The ubiquitous ROSA26 promoter and an initial part of the eGFP coding sequence in the SB Tn exhibited high levels of CpG methylation in transgenic mouse lines, irrespective of the chromosomal loci of the insertion sites. In contrast, no detectable CpG methylation in the endogenous mouse ROSA26 counterpart was observed in the same animals. Furthermore, significant hypomethylation was detected in neighboring chromosomal sequences of two unique SB Tn insertions compared to wild-type patterns. Taken together, these results suggest that SB Tn insertions into the mouse genome can be discriminated by DNA methylation machinery from an identical endogenous DNA sequence and can profoundly alter the DNA methylation status of the transgene cargo as well as flanking host genomic regions.     

Influence of a nonfragile FHIT transgene on murine tumor susceptibility

FHIT, at a constitutively active chromosome fragile site, is often a target of chromosomal aberrations and deletion in a large fraction of human tumors. Inactivation of murine Fhit allelessignificantly increases susceptibility of mice to spontaneous and carcinogen-induced tumorigenesis. In this study, transgenic mice, carrying a human FHIT cDNA under control of the endogenous promoter, were produced to determine the effect of Fhit expression, from a nonfragile cDNA transgene outside the fragile region, on carcinogen-induced tumor susceptibility of wildtype and Fhit heterozygous mice. Mice received sufficient oral doses of N-nitrosomethybenzylamine (NMBA) to cause forestomach tumors in >80% of nontransgenic control mice. Although the level of expression of the FHIT transgene in the recombinant mouse strains was much lower than the level of endogenous Fhit expression, the tumor burden in NMBA-treated male transgenic mice was significantly reduced, while female transgenic mice were not protected. To determine if the difference in protection could be due to differences in epigenetic changes at the transgene loci in male versus female mice, we examined expression, hypermethylation and induced re-expression of FHIT transgenes in male and female mice or cells derived from them. The transgene was methylated in male and female mice and in cell lines established from male and female transgenic kidneys, the FHIT locus was both hypermethylated and deacetylated. It is likely that the FHIT transgene is more tightly silenced in female transgenic mice, leading to a lack of protection from tumor induction.     

Structure of the rhsA locus from Escherichia coli K-12 and comparison of rhsA with other members of the rhs multigene family.

The complete nucleotide sequence of the rhsA locus and selected portions of other members of the rhs multigene family of Escherichia coli K-12 have been determined. A definition of the limits of the rhsA and rhsC loci was established by comparing sequences from E. coli K-12 with sequences from an independent E. coli isolate whose DNA contains no homology to the rhs core. This comparison showed that rhsA comprises 8,249 base pairs (bp) in strain K-12 and that the Rhs0 strain, instead, contains an unrelated 32-bp sequence. Similarly, the K-12 rhsC locus is 9.6 kilobases in length and a 10-bp sequence resides at its location in the Rhs0 strain. The rhsA core, the highly conserved portion shared by all rhs loci, comprises a single open reading frame (ORF) 3,714 bp in length. The nucleotide sequence of the core ORF predicts an extremely hydrophilic 141-kilodalton peptide containing 28 repeats of a motif whose consensus is GxxxRYxYDxxGRL(I or T). One of the most novel aspects of the rhs family is the extension of the core ORF into the divergent adjacent region. Core extensions of rhsA, rhsB, rhsC, and rhsD add 139, 173, 159, and 177 codons to the carboxy termini of the respective core ORFs. For rhsA, the extended core protein would have a molecular mass of 156 kilodaltons. Core extensions of rhsB and rhsD are related, exhibiting 50.3% conservation of the predicted amino acid sequence. However, comparison of the core extensions of rhsA and rhsC at both the nucleotide and the predicted amino acid level reveals that each is highly divergent from the other three rhs loci. The highly divergent portion of the core extension is joined to the highly conserved core by a nine-codon segment of intermediate conservation. The rhsA and rhsC loci both contain partial repetitions of the core downstream from their primary cores. The question of whether the rhs loci should be considered accessory genetic elements is discussed but not resolved.     

Association of transgene integration sites with chromosome rearrangements in hexaploid oat

Transgene loci in 16 transgenic oat (Avena sativa L.) lines produced by microprojectile bombardment were characterized using phenotypic and genotypic segregation, Southern blot analysis, and fluorescence in situ hybridization (FISH). Twenty-five transgene loci were detected; 8 lines exhibited single transgene loci and 8 lines had 2 or 3 loci. Double FISH of the transgene and oat C- and A/D-genome-specific dispersed and clustered repeats showed no preferences in the distribution of transgene loci among the highly heterochromatic C genome and the A/D genomes of hexaploid oat, nor among chromosomes within the genomes. Transgene integration sites were detected at different locations along individual chromosomes, although the majority of transformants had transgenes integrated into subtelomeric and telomeric regions. Transgene integration sites exhibited different levels of structural complexity, ranging from simple integration structures of two apparently contiguous transgene copies to tightly linked clusters of multiple copies of transgenes interspersed with oat DNA. The size of the genomic interspersions observed in these transgene clusters was estimated from FISH results on prometaphase chromosomes to be megabases long, indicating that some transgene loci were significantly larger than previously determined by Southern blot analysis. Overall, 6 of the 25 transgene loci were associated with rearranged chromosomes. These results suggest that particle bombardment-mediated transgene integration may result from and cause chromosomal breakage and rearrangements. Received: 29 July 1999 / Accepted: 9 November 1999     

Targeting the Escherichia coli lac repressor to the mammalian cell nucleus

We have previously shown that about 90% of total Escherichia coli lac repressor synthesized in mammalian cells is located in the cytoplasm [Hu and Davidson, Cell 48 (1987) 555-566]. To target a functional lac repressor to the nucleus, we mutated 10 nucleotides at the 3' end of the coding sequence, thus adding the nuclear localization signal of the simian virus 40 large-T antigen to the C terminus of the repressor. The mutant lacI gene and the wild-type (wt) gene, both in standard animal cell expression vectors, driven by the promoter of the Rous sarcoma virus long terminal repeat, were stably transfected into three rodent cell lines. In confirmation of our previous results, only about 10% of the wt repressor, but all of the mutant protein, was localized in the nucleus. DNase I footprint analyses showed that the mutant repressor retained the same operator DNA-binding specificity as wt repressor. Furthermore, both repressor-operator complexes could be dissociated by addition of isopropyl-beta-D-thiogalactopyranoside in vitro. However, the ratio of number of repressor molecules per nucleus that, by in vitro assay, could bind to the operator sequence to the number of monomer repressor polypeptides per nucleus, as determined by Western blotting, was about 1:4 for the wt repressor and about 1:30 for the mutant repressor. This suggests that: (a) the mutant repressor assembles into tetramers inefficiently; and/or (b) it has reduced binding affinity to the operator sequence; and/or (c) it has higher binding affinity to nonspecific DNA.     

The physiological functions of prion protein

Foreign DNA can be readily integrated into the genomes of mammalian embryonic cells by retroviral infection, DNA microinjection, and transfection protocols. However, the transgenic DNA is frequently not expressed or is expressed at levels far below expectation. In a number of organisms such as yeast, plants, Drosophila, and nematodes, silencing of transfected genes is triggered by the interaction between adjacent or dispersed copies of genes of identical sequence. We set out to determine whether a mechanism similar to repeat-induced gene silencing (RIGS) is responsible for the silencing of transgenes in murine embryonal carcinoma stem cells. We compared the expression of identical reporter gene constructs in cells carrying single or multiple copies and found that the level of expression per integrated copy was more than 10-fold higher in single-copy integrants. In cells carrying tandem copies of the transgene, many copies were methylated and clones frequently failed to express both copies of near-identical integrated alleles. Addition of extra copies of the reporter gene coding sequence reduced the level of expression from the same reporter driven by a eukaryotic promoter. We also found that inhibitors of histone deacetylase such as trichostatin A forestall the silencing of multicopy transgenes, suggesting that chromatin mediates the silencing of transfected genes. This evidence is consistent with the idea that RIGS does occur in mammalian embryonic stem cells although silencing of single-copy transgenes also occurs, suggesting that RIGS is only one of the mechanisms responsible for triggering transgene silencing.