Segregation and rearrangement of coamplified genes in different lineages of mutant cells that overproduce adenylate deaminase

Mammalian recombination hot spot in a DNA loop anchorage region: a model for the study of common fragile sites

We analyzed the replication pattern and the topological organization of a 200 kb long Chinese hamster polygenic locus, which spans the boundary of two isochores. One of them is G + C rich while the second one is highly A + T rich. Previous analysis of mutants amplified for this locus had identified, within the A + T rich isochore, a mitotic recombination hotspot and a replication origin separated by some 7 kb. The recombination hotspot exhibits structural features repeatedly observed at common fragile sites, including a typical enrichment in peaks of enhanced DNA helix flexibility. By studying the replication pattern of the same locus in the non-amplified CHO cells, we confirm here the localization of the replication origin and show that the mitotic recombination hotspot does not correspond to a replicon junction. This finding makes questionable current hypotheses correlating replication termination regions with recombination prone sequences. Using topoisomerase II-mediated DNA cleavage at matrix attachment sites, we identified a 40 kb-long DNA anchorage region extending all along a transcription unit nested within the A + T rich isochore. Both the recombination hotspot and the replication origin lie within this topoisomerase II sensitive region, which suggests that features essential for initiation of recombination and initiation of DNA replication cluster within DNA anchorage regions. Features common to this region and to common fragile sites are discussed. J. Cell. Biochem. Suppl. 36: 170-178, 2001.

oriGNAI3: a narrow zone of preferential replication initiation in mammalian cells identified by 2D gel and competitive PCR replicon mapping techniques

The nature of mammalian origins of DNA replication remains controversial and this is primarily because two-dimensional gel replicon mapping techniques have identified broad zones of replication initiation whereas several other techniques, such as quantitative PCR, have disclosed more discrete sites of initiation at the same chromosomal loci. In this report we analyze the replication of an amplified genomic region encompassing the 3'-end of the GNAI3 gene, the entire GNAT2 gene and the intergenic region between them in exponentially growing Chinese hamster fibroblasts. These cells express GNAI3 but not GNAT2 . The replication pattern was first analyzed by two-dimensional neutral-alkaline gel electrophoresis. Surprisingly, the results revealed a small preferential zone of replication initiation, of at most 1.7 kb, located in a limited part of the GNAI3 - GNAT2 intergenic region. Mapping of this initiation zone was then confirmed by quantitative PCR. The agreement between the two techniques exploited here strengthens the hypothesis that preferred sites of replication initiation do exist in mammalian genomes.

Matrix attachment regions and transcription units in a polygenic mammalian locus overlapping two isochores

Eukaryotic chromosomes are ponctuated by specialized DNA sequences (MARs) characterized by their ability to bind the network of nonhistone proteins that form the nuclear matrix or scaffold. We previously described an amplifiable cluster of genes with different tissue-specific expression patterns, located on Chinese hamster chromosome 1q. This model is especially appropriate to study the relationships between MARs and transcription units. We show here that four attachment regions, with sequences exhibiting motifs specific to MARs, are present within the 100 kb of screened DNA. Three of them are relatively short sequences localized in intergenic regions. The last one extends over one of the transcription units and contains a region previously identified as a recombination hot spot. Moreover, the analysis of a DNA sequence extending over some 50 Kb of this region and spanning at least four genes, disclosed a strikingly sharp change in G + C content. This strongly suggests that the studied region contains the boundary of two isochores. We propose that the frequency and the size of MARs are correlated to their localization in G + C rich or poor domains.

GNAI3, GNAT2, AMPD2, GSTM are clustered in 120 kb of Chinese hamster chromosome 1q

We studied a polygenic region located on Chromosome (Chr) 1q in Chinese hamster cells that is coamplified along with the AMPD2 gene. Previous sequence analysis identified both members of the GSTM family and the GNAI3 gene within a cloned 120-kb region surrounding the AMPD2 locus. We show here that the GNAT2 gene, which is inactive in the fibroblastic cells, lies within the 20 kb separating the transcriptionally active GNAI3 and AMPD2 genes. We map most gene ends by sequence comparison with human homologs; one is inferred from the presence of an unmethylated CpG island. This Chinese hamster locus corresponds to a region of conserved linkage between human Chr 1 (locus 1p13) and mouse Chr 3 (position 52.5 cM), where Gnai-3 and Gnat-2 have been mapped. The AMPD2 gene is presently unlocalized in human genome; its proposed position on mouse Chr 3 is at 53.4 cM. Our results, obtained by physical mapping, strongly suggest that the order and possibly the tight linkage of these genes are conserved on all three genomes.

Reversion in Chinese hamster lines amplified at the AMPD2 locus: spontaneous and benzamide-stimulated gradual loss of amplified alleles of marker genes

The HC47 and HC474 cell lines of Chinese hamster fibroblasts resist coformycin through the intrachromosomal amplification of the AMP deaminase 2 (AMPD2) gene. Due to the coamplification of a mu glutathione S-transferase (GST) gene, these mutant lines are more sensitive than GMA32 wild-type parental cells to buthionine sulfoximine (BSO), an inhibitor of glutathione biosynthesis. This property was exploited to select revertants of amplification from HC474 cells. Reversion in that line is frequently a gradual process that does not involve extrachromosomal intermediates. The terminal products of this process are commonly cells with a complete deletion of the amplified allele of marker genes and are therefore haploid for these loci on the homologous chromosome. Exposing HC474 cells to benzamide (BA), an inhibitor of polyADP-ribosylation, increased the recovery of revertants to an extent allowing the detection of reverting cells without BSO selection. This effect of BA was used to isolate revertant cells from the HC47 line that is extremely stable and to demonstrate that the mechanism of gradual reversion also occurs in this line. The gradual deletion of amplified copies within the chromosomes suggests that breakage-fusion-bridge (BFB) cycles drive this process.

A glutathione depletion selectively imposed on mu glutathione S-transferase overproducing cells increases nitrogen mustard toxicity

Glutathione (GSH) contributes to the detoxification of anticancer drugs through the operation of specific glutathione S-transferases (GST) and innate, or acquired, overexpression of this enzyme family has been frequently observed in tumor cell lines. In the GMA32 line of Chinese hamster fibroblasts, we showed that GSH starvation produced by exposing cells to buthionine sulfoximine (BSO) increased the toxicity of chlorambucil and melphalan, but not that of N,N'-bis(2-chloroethyl)-N-nitrosourea (BCNU), cisplatine and doxorubicin. This indicates that efficient mechanisms of detoxification using GSH operate for chlorambucil and melphalan, but not for the other drugs in these cells. We then showed that GSH depletion could be selectively and transiently induced in the mu GST overexpressing cell line derived from GMA32, HC474, by exposing cells to substrates specific to the overexpressed isozyme. Exposing cells to such a substrate, trans-stilbene oxide, does not alter the sensibility of GMA32 cells to melphalan and chlorambucil, but increases that of HC474 cells to these drugs, to an extent comparable to that obtained with BSO. This observation highlights the possibility of exploiting GST overexpression, a frequent feature of tumor cells, to selectively sensitize these undesirable cells to anticancer drugs.

Amplification of the murine mdr2 gene and a reconsideration of the structure of the murine mdr gene locus

A common feature of cells selected in vitro for the multidrug resistance (MDR) phenotype is the amplification and concomitant overexpression of the mdr genes. In murine macrophage-like J774.2-derived MDR cell lines, there is a good correlation between levels of amplification and expression for the mdr1b gene, but not for the other two gene family members, mdr1a and mdr2. To understand this phenomenon better, a study of the amplification and expression of the mdr2 gene was undertaken. Southern blotting of genomic DNAs from a series of six MDR cell lines revealed that five of these lines had 5'-end amplification of mdr2, whereas only three contained 3'-end amplification. The analysis also suggested the involvement of a recombination hot-spot in this phenomenon. Despite the observation that the ratio between the number of copies of the 5' and 3' ends of the gene differs among cell lines, the ratio of 5' to 3' end transcription of mdr2 was approximately 1 in all cell lines. An analysis of promoter methylation in MDR cell lines demonstrated that this mechanism may play a role in regulating the transcription of mdr2, but not of mdr1b. Long-range mapping of the mdr locus in parental and amplified cell lines suggested that the three mdr genes are oriented in the same direction, and also revealed the presence of a number of rearrangement events. Models for the murine mdr gene locus in wild-type cells and in a cell line containing a rearrangement are presented.

Gene amplification and tumor progression

Proto-oncogenes are the genes which are most frequently found amplified in human tumor cells. Acquisition of a drug-resistant phenotype by gene amplification is frequent for in-vitro cultured cells but is very rare in human tumors. Proto-oncogenes amplified in human tumors belong essentially to one of three families (erbB, ras, myc) or to the 11q13 locus. Amplification is always specific for the tumor cells and is not found in constitutional DNA of the patient, indicating that amplification of the gene is selected for during tumor growth. For genes of the first three families, amplification results in overexpression in most of the cases. These are strong arguments in favor of a role of this amplification in tumor progression. The gene whose overexpression is the driving force for the selection of the amplification of the 11q13 locus is not known. The prad1 gene is presently a good candidate. Amplification of one type of proto-oncogene is generally not restricted to one tumor type. However, the N-myc gene is amplified mainly in tumors of neuronal or neuroendocrine origin and L-myc amplification is restricted to lung carcinomas. To understand the role of proto-oncogene amplification and overexpression in tumor progression it is necessary to know the function of the corresponding protein in the cell. erbB proteins are transmembrane receptors for growth factors. ras genes encode small GTP-binding proteins which are possibly involved in signal transduction. The myc proteins are transcription factors. The expression of the c-myc gene is induced a few hours after cells of various types have been induced to proliferate. The genes of these three families therefore encode proteins which appear to be involved in signal transduction. It is possible that overexpression of one of them, as a result of gene amplification, makes the cell a better responder to low levels of growth stimuli. For several genes which are found amplified in human tumors, it was shown that overexpression of the normal protein could confer a transformed or tumorigenic phenotype to in-vitro cultured cells. In addition, several studies on animal and human tumor-derived cell lines with an amplified proto-oncogene have established a relationship between proto-oncogene amplification and the tumorigenic phenotype. In neuroblastomas, it was proposed that down-modulation of MHC Class I antigens is a consequence of N-myc amplification and that this could be important in the progression toward a metastatic phenotype.(ABSTRACT TRUNCATED AT 400 WORDS)

The evolution of the amplified adenylate deaminase 2 domains in Chinese hamster cells suggests the sequential operation of different mechanisms of DNA amplification

Fluorescent in situ hybridization was used to localize the adenylate deaminase 2 (AMPD2) genes and flanking sequences on the chromosomes of the Chinese hamster line GMA32 and to study the distribution of additional copies of these genetic sequences in amplified mutants selected at several early stages of the amplification process. The synteny of AMPD2 genes and MDR1 genes, located on chromosomes 1, was demonstrated; in GMA32 the existence of a rearrangement positioning the two AMPD2 genes at different distances from the telomeres was disclosed. Using this structural marker, we showed that the amplified copies distribute along only one of the chromosomes 1. Their organization in different cells of clonal mutant populations at a very early stage of amplification was extremely heterogeneous; classes of organization could be recognized however. Their quantitative distribution at this stage and in cells which went through 10 more division cycles suggests an evolution pathway common to the mutant clones under study: as a rule, tandems of few units of identical and very large size (47 Mb) appear to be the first detected product of amplification; this organization is progressively overtaken by structures with more units of reduced and irregular size, while, in a growing number of cells, clusters of much shorter units can be observed. The nature of segregative amplification mechanisms operating in these processes and the possible involvement of replicative ones are discussed.

Mammalian drug resistant mutants with multiple gene amplifications: genes encoding the M1 component of ribonucleotide reductase, the M2 component of ribonucleotide reductase, ornithine decarboxylase, p5-8, the H-subunit of ferritin and the L-subunit of ferritin

Hydroxyurea was used to select two very highly drug resistant cell lines, designated HR-15 and HR-30. Both drug resistant lines contained elevated levels of ribonucleotide reductase activity. Northern and Southern blot analysis indicated that the two drug resistant lines contained increased levels of mRNA for the two components, M1 and M2, of ribonucleotide reductase, and M1 and M2 gene amplifications. Alterations in M1 and M2 protein levels were also evident in Western blot analysis. Further studies of HR-15 and HR-30 cells by Northern and Southern blot analysis showed that the drug resistant cell lines had elevated levels of ornithine decarboxylase mRNA and p5-8 mRNA, as well as increased ornithine decarboxylase and p5-8 gene copy numbers, respectively. Furthermore, characterization of HR-15 and HR-30 drug-resistant cell lines revealed increased mRNA levels for both H- and L-ferritin. Both cell lines exhibited by Southern blot analysis, amplification of the H- and L-ferritin genes. Increases in the cellular levels of H- and L-ferritin subunit proteins were also observed in both HR-15 and HR-30 cells, by Western blot analysis. This is the first description of mutant cell lines containing this complex combination of modified gene expressions and gene amplifications. The alterations exhibited by these lines confirm and extend present models of hydroxyurea resistance, are in agreement with and help substantiate models of ribonucleotide reductase regulation and provide interesting links between the expressions of several cellular activities important in proliferation.

Coamplification of mu class glutathione S-transferase genes and an adenylate deaminase gene in coformycin-resistant Chinese hamster fibroblasts

In Chinese hamster fibroblasts, we previously detected an expressed gene located near the AMP deaminase gene. This gene was named Y1. Upon selection for resistance to coformycin, an inhibitor of AMP deaminase activity, both genes were amplified in several mutants. We have determined the complete nucleotide sequence of Y1 cDNA and identified the Y1 gene as a mu class glutathione S-transferase gene by comparison with sequences present in a data bank. Accordingly, Y1-amplified mutants express an increased glutathione S-transferase activity toward 1-chloro-2,4-dinitrobenzene; this activity, as well as the abundance of the corresponding RNA, appears, however, to reach a limit despite further increase in the Y1 gene copy number during successive amplification steps. Southern blot experiments showed that Y1 belongs to a multigene family, all or part of which has been amplified in mutant lines. These data provide a method to amplify and to overexpress the mu class of the glutathione S-transferase gene family on the basis of its linkage with the AMP deaminase gene.

Structural organization and expression of amplified chromosomal sequences, which include the rudimentary gene, in cultured Drosophila cells resistant to N-(phosphonacetyl)-L-aspartate

We have used 160 kilobases of cloned Drosophila genomic DNA from the rudimentary (r) region to examine the organization of amplified DNA in Drosophila cells resistant to 10 mM N-(phosphonacetyl)-L-aspartate (PALAr cells) obtained by stepwise selection. Evidence for the direct tandem linkage of the amplified sequences is presented. The pattern and intensity of amplified bands as well as the presence of novel junctions in the DNA sequence of PALAr cells indicate that there are two types of units of 150 and 120 kilobases long. The sequence of the smaller unit is entirely included within the larger one. The longer of the two units is present twice while the shorter one is amplified eightfold as compared to the level of the relevant DNA sequences in the wild-type. These data are consistent with a model in which successive crossing-over events over several cell cycles lead to amplification of the selected r gene and flanking sequences. However, these data can also be accounted for by a totally different mechanism in which multiple copies of DNA are generated by rolling circle replication. Transcription units other than the r gene are present within the 150 kilobase region of amplified DNA. These are found to be overexpressed in PALAr cells, though some transcripts are underrepresented relative to the copy number of the corresponding coding sequences.

Structure of four amplified DNA novel joints

The structures of four novel joints present in the amplified DNA of a Syrian hamster cell line highly resistant to N-(phosphonacetyl)-L-aspartate were analyzed. Novel joints J1, J2, and J4 were formed by recombination between two regions of wild-type DNA, whereas joint J3 is the end point of an inverted duplication. A fraction of the J3 copies displays a cruciform structure in the purified genomic DNA. The formation of J1 and J2 apparently involved a simple breakage and joining of the two wild-type sequences, whereas extra nucleotides are present at the junction point of J3 and J4. The two regions of the wild-type DNA which have recombined to form J1, J2, and J4 show few sequence similarities, indicating that these joints probably resulted from nonhomologous recombination. AT-rich regions are present in the vicinity of the breakpoint for the four joints and eight of 10 crossover points could be associated with putative topoisomerase I cleavage sites. Our results indicate that different types of novel joints are present in the amplified DNA of this cell line, which was isolated after several steps of selection.

Relationships between reversion of hydroxyurea resistance in hamster cells and the co-amplification of ribonucleotide reductase M2 component, ornithine decarboxylase and P5-8 genes

Hydroxyurea is a specific inhibitor of ribonucleotide reductase, which is a rate-limiting enzyme activity in DNA synthesis. Cells selected for resistance to hydroxyurea contain alterations in ribonucleotide reductase activity. An unstable hydroxyurea resistant population of hamster cells has been used to isolate a stable drug resistant cell line, and two stable revertant lines with different sensitivities to hydroxyurea cytotoxicity and different ribonucleotide reductase activity levels. We show for the first time that a decrease in hydroxyurea resistance is accompanied by a parallel decline in gene copies for the M2 component of ribonucleotide reductase, ornithine decarboxylase and a gene of unknown function called p5-8, indicating that the co-amplification of the three genes is associated with drug resistance, and supporting the concept that M2, ornithine decarboxylase and p5-8 are closely linked, and form part of a single amplicon in hamster cells.

Ribonucleotide reductase M2 subunit sequences mapped to four different chromosomal sites in humans and mice: functional locus identified by its amplification in hydroxyurea-resistant cell lines

The sites of sequences homologous to a murine cDNA for ribonucleotide reductase (RR) subunit M2 were determined on human and murine chromosomes by Southern blot analysis of interspecies somatic cell hybrid lines and by in situ hybridization. In the human genome, four chromosomal sites carrying RRM2-related sequences were identified at 1p31----p33, 1q21----q23, 2p24----p25, and Xp11----p21. In the mouse, M2 sequences were found on chromosomes 4, 7, 12, and 13 by somatic cell hybrid studies. By Southern analysis of human hydroxyurea-resistant cells that overproduce M2 because of gene amplification, we have identified the amplified restriction fragments as those that map to chromosome 2. To further confirm the site of the functional RRM2 locus, two other cDNA clones, p5-8 and S7 (coding for ornithine decarboxylase; ODC), which are coamplified with RRM2 sequences in human and rodent hydroxyurea-resistant cell lines, were mapped by Southern and in situ hybridization. Their chromosomal map positions coincided with the region of human chromosome 2 (p24----p25) that also contains one of the four RRM2-like sequences. Since this RRM2 sequence and p5-8 and ODC are most likely part of the same amplification unit, the RRM2 structural gene can be assigned to human chromosome 2p24----p25. This region is homologous to a region of mouse chromosome 12 that also carries one of numerous ODC-like sequences. In an RRM2-overproducing mouse cell line, we found amplification of the chromosome 12-specific restriction fragments. Thus, we conclude that mouse chromosome 12 carries the functional locus for RRM2.

Hamster cells with increased rates of DNA amplification, a new phenotype

Baby hamster kidney (BHK) cells selected simultaneously with N-phosphonacetyl-L-aspartate (PALA) and methotrexate (MTX) gave rise to doubly resistant colonies at frequencies 20 to 260 times greater than the product of the independent frequencies found with PALA or MTX alone. Double resistance was due to amplification of both target genes, CAD and DHFR. Four independent doubly resistant "MP" lines were selected and characterized. Cells resistant to coformycin, pyrazofurin, or ouabain were generated from all four MP lines at rates up to 25 times greater than the rates for BHK cells. These three drugs select cells that have amplified the genes for their target enzymes. Therefore, we conclude that the four MP lines have an amplificator phenotype. All four grew much more slowly than BHK cells, indicating that the amplificator phenotype may be linked to significant defects in metabolism or cell division.

New RNA species is produced by alternate polyadenylation following rearrangement associated with CAD gene amplification

Mammalian cells selected to resist N-(phosphonacetyl)-L-aspartate (PALA) contain amplified copies of the CAD gene. While a single 7.9-kb mRNA species is detected in PALA-sensitive and most PALA-resistant cell lines, two RNA species (7.9 and 10.2 kb) are detected in two related drug-resistant mutants presumably derived from the same parental cell. In this report we show that the 10.2-kb RNA is produced as a direct consequence of a sequence rearrangement adjacent to the 3' end of the CAD gene in these cell lines. A CAD gene containing the sequence rearrangement was cloned from one of these lines and found to produce both RNA species when transfected into CAD-deficient cells. DNA sequencing and S1 analysis demonstrate that the 10.2-kb RNA is produced by alternative polyadenylation rather than by alternative splicing. Sequence analysis also reveals that several consensus poly(A) addition signals (AATAAA) were brought into close proximity to the CAD gene by virtue of the rearrangement. While sequences adjacent to each of the polyadenylation signals contain additional features postulated to be important for the selection of the site of poly(A) addition, S1 mapping analysis indicates that only one of the polyadenylation signals is used. A comparison of all of these sites suggests that multiple sequence motifs are required to form a functional polyadenylation and cleavage signal.