Novel DNA rearrangements are associated with dihydrofolate reductase gene amplification

We have employed the technique of chromosome "walking" to determine the structure of 240 kilobases of amplified DNA surrounding the dihydrofolate reductase gene in methotrexate-resistant mouse cell lines. Within this region, we have found numerous DNA rearrangements which occurred during the amplification process. DNA subclones from regions flanking the dihydrofolate reductase gene were also utilized as hybridization probes in other cell lines. Our results show that: 1) amplification-specific DNA rearrangements or junctions are unique to each cell line; 2) within a given cell line, multiple amplification-specific DNA sequence rearrangements are found; 3) the degree of amplification of sequences flanking the dihydrofolate reductase gene shows quantitative variation among and within cell lines; and 4) both the arrangement of amplified sequences as well as the magnitude of gene amplification may vary with prolonged culture even under maintenance selection conditions. These studies indicate that there is no static repetitive unit amplified in these cells. Rather, a dynamic and complex arrangement of the amplified sequences exists which is continually changing.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide exicision repair gene ERCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

Introduction of a long synthetic repetitive DNA sequence into cultured tobacco cells

Genome information has been accumulated for many species, and these genes and regulatory sequences are expected to be applied in plants by enhancing or creating new metabolic pathways. We hypothesized that manipulating a long array of repetitive sequences using tethered chromatin modulators would be effective for robust regulation of gene expression in close proximity to the arrays. This approach is based on a human artificial chromosome made of long synthetic repetitive DNA sequences in which we manipulated the chromatin by tethering the modifiers. However, a method for introducing long repetitive DNA sequences into plants has not yet been established. Therefore, we constructed a bacterial artificial chromosome-based binary vector in Escherichia coli cells to generate a construct in which a cassette of marker genes was inserted into 60-kb synthetic human centromeric repetitive DNA. The binary vector was then transferred to Agrobacterium cells and its stable maintenance confirmed. Next, using Agrobacterium-mediated genetic transformation, this construct was successfully introduced into the genome of cultured tobacco BY-2 cells to obtain a large number of stable one-copy strains. ChIP analysis of obtained BY-2 cell lines revealed that the introduced synthetic repetitive DNA has moderate chromatin modification levels with lower heterochromatin (H3K9me2) or euchromatin (H3K4me3) modifications compared to the host centromeric repetitive DNA or an active Tub6 gene, respectively. Such a synthetic DNA sequence with moderate chromatin modification levels is expected to facilitate manipulation of the chromatin structure to either open or closed.     

Differential repair of DNA damage in specific nucleotide sequences in monkey cells.

An immunological method was developed that isolates DNA fragments containing bromouracil in repair patches from unrepaired DNA using a monoclonal antibody that recognizes bromouracil. Cultured monkey cells were exposed to either UV light or the activated carcinogen aflatoxin B1 and excision repair of damage in DNA fragments containing the integrated and transcribed E. coli gpt gene was compared to that in the genome overall. A more rapid repair, of both UV and AFB1 damage was observed in the DNA fragments containing the E. coli gpt genes. The more efficient repair of UV damage was not due to a difference in the initial level of pyrimidine dimers as determined with a specific UV endonuclease. Consistent with previous observations using different methodology, repair of UV damage in the alpha sequences was found to occur at the same rate as that in the genome overall, while repair of AFB1 damage was deficient in alpha DNA. The preferential repair of damage in the gpt gene may be related to the functional state of the sequence and/or to alterations produced in the chromatin conformation by the integration of plasmid sequences carrying the gene.     

A promising genomic transfectant into Xeroderma pigmentosum group A with highly amplified mouse DNA and intermediate UV resistance turns revertant

Following transfection of genomic mouse DNA into an SV40 transformed fibroblast cell line from a patient with Xeroderma pigmentosum (complementation group A, XPA), a single UV resistant cell clone was isolated out of a total of 10(4) independent transfectants. The recipient XPA cell line has as yet not produced spontaneous revertants among 2.2 x 10(8) cells. The isolated cell clone contains 50-70 kb of mouse sequences which are heavily amplified (500-fold), and has acquired both intermediate resistance to UV killing and intermediate unscheduled DNA synthesis (UDS) capacity. By continued passage without selective pressure, cells were generated, which had lost both the dominant marker gene and repetitive mouse sequences. Single colonies of these cells were still intermediately resistant to UV suggesting that either undetected unique mouse DNA had segregated from the bulk of repetitive DNA, or, more likely, that the initially isolated transfectant was a spontaneous revertant. This documents that a persuasive clone isolated can still be a false positive (spontaneous revertant) and that an extremely laborious approach may lead into a dead end.     

Relationship of ultraviolet light-induced DNA-protein cross-linkage to chromatin structure

The production of banding patterns in metaphase chromosomes by restriction enzymes is inhibited by ultraviolet (UV) irradiation. Irradiation of fixed chromatin produces a 15-fold decrease in DNA extraction by restriction enzymes in comparison with that observed by irradiation before fixation. Alcohol-acid fixation of chromatin produces two major changes, the extraction of histones and dehydration. The effect of UV light is probably the result of a net increase in the yield of DNA-protein cross-links at comparable fluences of UV light and of the stabilization of the structural changes in the fixed chromatin fibril induced by the photoadducts. The X-irradiation of cells before fixation, as well as the rehydration of fixed chromatin, increases the extraction of DNA from fixed chromatin irradiated with UV light to levels similar to or even higher than those obtained with living cells. The effect of UV light before and after fixation on the extraction of DNA by restriction enzymes and proteinase K can be related to changes in chromatin structure and DNA conformation.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide excision repair gene FRCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

Increased sensitivity of subtelomeric regions to DNA double-strand breaks in a human cancer cell line

We previously reported that a single DNA double-strand break (DSB) near a telomere in mouse embryonic stem cells can result in chromosome instability. We have observed this same type of instability as a result of spontaneous telomere loss in human tumor cell lines, suggesting that a deficiency in the repair of DSBs near telomeres has a role in chromosome instability in human cancer. We have now investigated the frequency of the chromosome instability resulting from DSBs near telomeres in the EJ-30 human bladder carcinoma cell line to determine whether subtelomeric regions are sensitive to DSBs, as previously reported in yeast. These studies involved determining the frequency of large deletions, chromosome rearrangements, and chromosome instability resulting from I-SceI endonuclease-induced DSBs at interstitial and telomeric sites. As an internal control, we also analyzed the frequency of small deletions, which have been shown to be the most common type of mutation resulting from I-SceI-induced DSBs at interstitial sites. The results demonstrate that although the frequency of small deletions is similar at interstitial and telomeric DSBs, the frequency of large deletions and chromosome rearrangements is much greater at telomeric DSBs. DSB-induced chromosome rearrangements at telomeric sites also resulted in prolonged periods of chromosome instability. Telomeric regions in mammalian cells are therefore highly sensitive to DSBs, suggesting that spontaneous or ionizing radiation-induced DSBs at these locations may be responsible for many of the chromosome rearrangements that are associated with human cancer.     

Normal reconstruction of DNA supercoiling and chromatin structure in cockayne syndrome cells during repair of damage from ultraviolet light.

The chromatin of human cells undergoes structural rearrangements during excision repair of ultraviolet damage in DNA that were detected by transient relaxation of DNA supercoiling and increased staphylococcal nuclease digestibility of repaired sites. Inhibition of polymerization and/or ligation of repaired regions with inhibitors of DNA polymerase alpha (cytosine arabinoside and aphidicolin) resulted in the accumulation of single-strand breaks, delayed reconstruction of DNA supercoiling, and maintenance of the staphylococcal nuclease digestibility. These observations suggest that reconstruction of the native chromatin state requires completion of repaired regions with covalent ligation into the DNA strands. Although previous claims have been made that a late stage associated with ligation of repaired regions may be defective in cells from patients with Cockayne syndrome, complete reconstruction of the native chromatin occurred in cells from three unrelated patients after ultraviolet irradiation. No abnormality in repair was therefore detected in Cockayne syndrome cells. The hypersensitivity of cell survival and semiconservative DNA replication to damage by ultraviolet light in this human disorder must therefore be regarded as features of a primary defect in DNA metabolism unrelated to DNA repair.     

Telomere dysfunction and chromosome instability

The ends of chromosomes are composed of a short repeat sequence and associated proteins that together form a cap, called a telomere, that keeps the ends from appearing as double-strand breaks (DSBs) and prevents chromosome fusion. The loss of telomeric repeat sequences or deficiencies in telomeric proteins can result in chromosome fusion and lead to chromosome instability. The similarity between chromosome rearrangements resulting from telomere loss and those found in cancer cells implicates telomere loss as an important mechanism for the chromosome instability contributing to human cancer. Telomere loss in cancer cells can occur through gradual shortening due to insufficient telomerase, the protein that maintains telomeres. However, cancer cells often have a high rate of spontaneous telomere loss despite the expression of telomerase, which has been proposed to result from a combination of oncogene-mediated replication stress and a deficiency in DSB repair in telomeric regions. Chromosome fusion in mammalian cells primarily involves nonhomologous end joining (NHEJ), which is the major form of DSB repair. Chromosome fusion initiates chromosome instability involving breakage-fusion-bridge (B/F/B) cycles, in which dicentric chromosomes form bridges and break as the cell attempts to divide, repeating the process in subsequent cell cycles. Fusion between sister chromatids results in large inverted repeats on the end of the chromosome, which amplify further following additional B/F/B cycles. B/F/B cycles continue until the chromosome acquires a new telomere, most often by translocation of the end of another chromosome. The instability is not confined to a chromosome that loses its telomere, because the instability is transferred to the chromosome donating a translocation. Moreover, the amplified regions are unstable and form extrachromosomal DNA that can reintegrate at new locations. Knowledge concerning the factors promoting telomere loss and its consequences is therefore important for understanding chromosome instability in human cancer.     

Local action of the chromatin assembly factor CAF-1 at sites of nucleotide excision repair in vivo

DNA damage and its repair can cause both local and global rearrangements of chromatin structure. In each case, the epigenetic information contained within this structure must be maintained. Using the recently developed method for the localized UV irradiation of cells, we analysed responses that occur locally to damage sites and global events triggered by local damage recognition. We thus demonstrate that, within a single cell, the recruitment of chromatin assembly factor 1 (CAF-1) to UV-induced DNA damage is a strictly local phenomenon, restricted to damage sites. Concomitantly, proliferating cell nuclear antigen (PCNA) locates to the same sites. This localized recruitment suggests that CAF-1 participates directly in chromatin structural rearrangements that occur in the vicinity of the damage. Use of nucleotide excision repair (NER)-deficient cells shows that the NER pathway--specifically dual incision--is required for recruitment of CAF-1 and PCNA. This in vivo demonstration of the local role of CAF-1, depending directly on NER, supports the hypothesis that CAF-1 ensures the maintenance of epigenetic information by acting locally at repair sites.     

UV Damage in DNA Promotes Nucleosome Unwrapping

The association of DNA with histones in chromatin impedes DNA repair enzymes from accessing DNA lesions. Nucleosomes exist in a dynamic equilibrium in which portions of the DNA molecule spontaneously unwrap, transiently exposing buried DNA sites. Thus, nucleosome dynamics in certain regions of chromatin may provide the exposure time and space needed for efficient repair of buried DNA lesions. We have used FRET and restriction enzyme accessibility to study nucleosome dynamics following DNA damage by UV radiation. We find that FRET efficiency is reduced in a dose-dependent manner, showing that the presence of UV photoproducts enhances spontaneous unwrapping of DNA from histones. Furthermore, this UV-induced shift in unwrapping dynamics is associated with increased restriction enzyme accessibility of histone-bound DNA after UV treatment. Surprisingly, the increased unwrapping dynamics is even observed in nucleosome core particles containing a single UV lesion at a specific site. These results highlight the potential for increased “intrinsic exposure” of nucleosome-associated DNA lesions in chromatin to repair proteins.     

Jumping translocations in spontaneous abortions

Chromosome translocations involving one donor chromosome and multiple recipient chromosomes have been referred to as jumping translocations (JTs). Acquired JTs are commonly observed in cancer patients, mainly involving chromosome 1. Constitutional forms of JTs mostly involve the acrocentric chromosomes and their satellites and have been reported in patients with clinical abnormalities. Recognizable phenotypes resulting from these events have included Down, Prader-Willi, and DiGeorge syndromes. The presence of JTs in spontaneous abortions has not been previously described. The breakpoints of all JTs occur in areas rich in repetitive DNA (telomeric, centromeric, and nucleolus organizing regions). We report two different unstable chromosome rearrangements in samples derived from spontaneous abortions. The first case involved a chromosome 15 donor. The recipient chromosomes were 1, 9, 15, and 21, and the respective breakpoints were in either the heterochromatic regions or the centromeres. FISH studies confirmed that the breakpoints of the jumping 15 rearrangement did not involve the Prader-Willi region but originated at the centromere or in the proximal short arm. A second case of instability was observed with a rearrangement resulting from a presumed de novo 8;21 translocation. Three JT cell lines were observed. They consisted of a deleted 8p chromosome, a dicentric 8;21 translocation, and an 8q isochromosome. The instability regions appeared to be at the pericentromeric region of chromosome 8 and the satellite region of chromosome 21. Both cases proved to be de novo events. The unstable nature of the JT resulting in chromosomal imbalance most likely contributed to the fetal loss. It appears that JT events may predispose to chromosomal imbalance via nondisjunction and chromosomal rearrangement and, therefore, may be an unrecognized cause of fetal loss.     

Heterochromatin,gene position effect and gene silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

DNA Damage Leaves its Mark on Chromatin

DNA organization into chromatin has a major influence on the cellular response to DNA damage. Recent studies in various systems ranging from yeast to human cells stress the importance of chromatin not simply as a barrier to DNA repair processes but also as an active contributor to the DNA damage response. Indeed, modulations of chromatin organization involving various degrees of rearrangements, such as histone modifications and even nucleosome displacement, can promote efficient repair and also participate in checkpoint signaling. Here, we survey recent progress in delineating how chromatin rearrangements provide crosstalk with the DNA damage response. In particular, we highlight new data on histone dynamics at damage sites and discuss their functional importance for the stable propagation of specific chromatin states.     

Heterochromatin, Position Effect, and Genetic Silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

DNA methylation and chromosome instability in lymphoblastoid cell lines

In order to gain more insight into the relationships between DNA methylation and genome stability, chromosomal and molecular evolutions of four Epstein-Barr virus-transformed human lymphoblastoid cell lines were followed in culture for more than 2 yr. The four cell lines underwent early, strong overall demethylation of the genome. The classical satellite-rich, heterochromatic,juxtacentromeric regions of chromosomes 1, 9, and 16 and the distal part of the long arm of the Y chromosome displayed specific behavior with time in culture. In two cell lines, they underwent a strong demethylation, involving successively chromosomes Y, 9, 16, and 1, whereas in the two other cell lines, they remained heavily methylated. For classical satellite 2-rich heterochromatic regions of chromosomes 1 and 16, a direct relationship could be established between their demethylation, their undercondensation at metaphase, and their involvement in non-clonal rearrangements. Unstable sites distributed along the whole chromosomes were found only when the heterochromatic regions of chromosomes 1 and 16 were unstable. The classical satellite 3-rich heterochromatic region of chromosomes 9 and Y, despite their strong demethylation, remained condensed and stable. Genome demethylation and chromosome instability could not be related to variations in mRNA amounts of the DNA methyltransferases DNMT1, DNMT3A, and DNMT3B and DNA demethylase. These data suggest that the influence of DNA demethylation on chromosome stability is modulated by a sequence-specific chromatin structure.     

DNA damage processing and aberration formation in plants

Various types of DNA damage, induced by endo- and exogenous genotoxic impacts, may become processed into structural chromosome changes such as sister chromatid exchanges (SCEs) and chromosomal aberrations. Chromosomal aberrations occur preferentially within heterochromatic regions composed mainly of repetitive sequences. Most of the preclastogenic damage is correctly repaired by different repair mechanisms. For instance, after N-methyl-N-nitrosourea treatment one SCE is formed per >40,000 and one chromatid-type aberration per approximately 25 million primarily induced O6-methylguanine residues in Vicia faba. Double-strand breaks (DSBs) apparently represent the critical lesions for the generation of chromosome structural changes by erroneous reciprocal recombination repair. Usually two DSBs have to interact in cis or trans to form a chromosomal aberration. Indirect evidence is at hand for plants indicating that chromatid-type aberrations mediated by S phase-dependent mutagens are generated by post-replication (mis)repair of DSBs resulting from (rare) interference of repair and replication processes at the sites of lesions, mainly within repetitive sequences of heterochromatic regions. The proportion of DSBs yielding structural changes via misrepair has still to be established when DSBs, induced at predetermined positions, can be quantified and related to the number of SCEs and chromosomal aberrations that appear at these loci after DSB induction. Recording the degree of association of homologous chromosome territories (by chromosome painting) and of punctual homologous pairing frequency along these territories during and after mutagen treatment of wild-type versus hyperrecombination mutants of Arabidopsis thaliana, it will be elucidated as to what extent the interphase arrangement of chromosome territories becomes modified by critical lesions and contributes to homologous reciprocal recombination. This paper reviews the state of the art with respect to DNA damage processing in the course of aberration formation and the interphase arrangement of homologous chromosome territories as a structural prerequisite for homologous rearrangements in plants.