Early dihydrofolate reductase gene amplification events in CHO cells usually occur on the same chromosome arm as the original locus

DNA Double-Strand Breaks Affect Chromosomal Rearrangements during Methotrexate-Mediated Gene Amplification in Chinese Hamster Ovary Cells

Methotrexate (MTX)-mediated gene amplification has been widely used in Chinese hamster ovary (CHO) cells for the biomanufacturing of therapeutic proteins. Although many studies have reported chromosomal instability and extensive chromosomal rearrangements in MTX-mediated gene-amplified cells, which may be associated with cell line instability issues, the mechanisms of chromosomal rearrangement formation remain poorly understood. We tested the impact of DNA double-strand breaks (DSBs) on chromosomal rearrangements using bleomycin, a DSB-inducing reagent. Bleomycin-treated CHO-DUK cells, which are one of the host cell lines deficient in dihydrofolate reductase (Dhfr) activity, exhibited a substantial number of cells containing radial formations or non-radial formations with chromosomal rearrangements, suggesting that DSBs may be associated with chromosomal rearrangements. To confirm the causes of DSBs during gene amplification, we tested the effects of MTX treatment and the removal of nucleotide base precursors on DSB formation in Dhfr-deficient (i.e., CHO-DUK) and Dhfr-expressing (i.e., CHO-K1) cells. Immunocytochemistry demonstrated that MTX treatment did not induce DSBs per se, but a nucleotide shortage caused by the MTX-mediated inhibition of Dhfr activity resulted in DSBs. Our data suggest that a nucleotide shortage caused by MTX-mediated Dhfr inhibition in production cell lines is the primary cause of a marked increase in DSBs, resulting in extensive chromosomal rearrangements after gene amplification processes.

Mechanisms Generating Cancer Genome Complexity: Back to the Future

Understanding the mechanisms underlying cancer genome evolution has been a major goal for decades. A recent study combining live cell imaging and single-cell genome sequencing suggested that interwoven chromosome breakage-fusion-bridge cycles, micronucleation events and chromothripsis episodes drive cancer genome evolution. Here, I discuss the "interphase breakage model," suggested from prior fluorescent in situ hybridization data that led to a similar conclusion. In this model, the rapid genome evolution observed at early stages of gene amplification was proposed to result from the interweaving of an amplification mechanism (breakage-fusion-bridge cycles) and of a deletion mechanism (micronucleation and stitching of DNA fragments retained in the nucleus).

Role for RNA:DNA hybrids in origin-independent replication priming in a eukaryotic system

DNA replication initiates at defined replication origins along eukaryotic chromosomes, ensuring complete genome duplication within a single S-phase. A key feature of replication origins is their ability to control the onset of DNA synthesis mediated by DNA polymerase-α and its intrinsic RNA primase activity. Here, we describe a novel origin-independent replication process that is mediated by transcription. RNA polymerase I transcription constraints lead to persistent RNA:DNA hybrids (R-loops) that prime replication in the ribosomal DNA locus. Our results suggest that eukaryotic genomes have developed tools to prevent R-loop-mediated replication events that potentially contribute to copy number variation, particularly relevant to carcinogenesis.

RNA-dependent genome processing during nuclear differentiation: the model systems of stichotrichous ciliates

We introduce ciliated protozoa, and more specifically the stichotrichous ciliates Oxytricha and Stylonychia, as biological model systems for the analysis of programmed DNA-reorganization processes during nuclear differentiation. These include DNA excision, DNA elimination, reordering of gene segments and specific gene amplification. We show that small nuclear RNAs specify DNA sequences to be excised or retained, but also discuss the need for a RNA template molecule derived from the parental nucleus for these processes. This RNA template guides reordering of gene segments to become functional genes and determines gene copy number in the differentiated nucleus. Since the template is derived from the parental macronucleus, gene reordering and DNA amplification are inherited in a non-Mendelian epigenetic manner.

A mechanism of gene amplification driven by small DNA fragments

DNA amplification is a molecular process that increases the copy number of a chromosomal tract and often causes elevated expression of the amplified gene(s). Although gene amplification is frequently observed in cancer and other degenerative disorders, the molecular mechanisms involved in the process of DNA copy number increase remain largely unknown. We hypothesized that small DNA fragments could be the trigger of DNA amplification events. Following our findings that small fragments of DNA in the form of DNA oligonucleotides can be highly recombinogenic, we have developed a system in the yeast Saccharomyces cerevisiae to capture events of chromosomal DNA amplification initiated by small DNA fragments. Here we demonstrate that small DNAs can amplify a chromosomal region, generating either tandem duplications or acentric extrachromosomal DNA circles. Small fragment-driven DNA amplification (SFDA) occurs with a frequency that increases with the length of homology between the small DNAs and the target chromosomal regions. SFDA events are triggered even by small single-stranded molecules with as little as 20-nt homology with the genomic target. A double-strand break (DSB) external to the chromosomal amplicon region stimulates the amplification event up to a factor of 20 and favors formation of extrachromosomal circles. SFDA is dependent on Rad52 and Rad59, partially dependent on Rad1, Rad10, and Pol32, and independent of Rad51, suggesting a single-strand annealing mechanism. Our results reveal a novel molecular model for gene amplification, in which small DNA fragments drive DNA amplification and define the boundaries of the amplicon region. As DNA fragments are frequently found both inside cells and in the extracellular environment, such as the serum of patients with cancer or other degenerative disorders, we propose that SFDA may be a common mechanism for DNA amplification in cancer cells, as well as a more general cause of DNA copy number variation in nature.

RNA-dependent control of gene amplification

We exploit the unusual genome organization of the ciliate cell to analyze the control of specific gene amplification during a nuclear differentiation process. Ciliates contain two types of nuclei within one cell, the macronucleus and the micronucleus; and after sexual reproduction a new macronucleus is formed from a micronuclear derivative. During macronuclear differentiation, most extensive DNA reorganization, elimination, and fragmentation processes occur, resulting in a macronucleus containing short DNA molecules (nanochromosomes) representing individual genetic units and each being present in high copy number. It is believed that these processes are controlled by small nuclear RNAs but also by a template derived from the old macronucleus. We first describe the exact copy numbers of selected nanochromosomes in the macronucleus, and define the timing during nuclear differentiation at which copy number is determined. This led to the suggestion that DNA processing and copy number control may be closely related mechanisms. Degradation of an RNA template derived from the macronucleus leads to significant decrease in copy number, whereas injection of additional template molecules results in an increase in copy number and enhanced expression of the corresponding gene. These observations can be incorporated into a mechanistic model about an RNA-dependent epigenetic regulation of gene copy number during nuclear differentiation. This highlights that RNA, in addition to its well-known biological functions, can also be involved in the control of gene amplification.

Identification and analysis of specific chromosomal region adjacent to exogenous Dhfr-amplified region in Chinese hamster ovary cell genome

Chinese hamster ovary (CHO) cells are widely used for the stable production of recombinant proteins. Gene amplification techniques are frequently used to improve of protein production, and the dihydrofolate reductase (DHFR) gene amplification system is most widely used in the CHO cell line. We previously constructed a CHO genomic bacterial artificial chromosome (BAC) library from a mouse Dhfr-amplified CHO DR1000L-4N cell line and one BAC clone (Cg0031N14) containing the CHO genomic DNA sequence adjacent to Dhfr was selected. To identify the specific chromosomal region adjacent to the exogenous Dhfr-amplified region in the CHO cell genome, we performed further screening of BAC clones to obtain other Dhfr-amplified regions in the CHO genome. From the screening by high-density replica filter hybridization using a digoxigenin-labeled pSV2-dhfr/hGM-CSF probe, we obtained 8 new BAC clones containing a Dhfr-amplified region. To define the structures of the 8 BAC clones, Southern blot analysis, BAC end sequencing and fluorescence in situ hybridization (FISH) were performed. These results revealed that all the selected BAC clones contained a large palindrome structure with a small inverted repeat in the junction region. This suggests that the obtained amplicon structure in the Dhfr-amplified region in the CHO genome plays an important role in exogenous gene amplification.

Mechanisms of gene amplification and evidence of coamplification in drug-resistant human osteosarcoma cell lines

Gene amplification and copy number changes play a pivotal role in malignant transformation and progression of human tumor cells by mediating the activation of genes and oncogenes, which are involved in many different cellular processes including development of drug resistance. Since doxorubicin (DX) and methotrexate (MTX) are the two most important drugs for high-grade osteosarcoma (OS) treatment, the aim of this study was to identify genes gained or amplified in six DX- and eight MTX-resistant variants of the human OS cell lines U-2OS and Saos-2, and to get insights into the mechanisms underlying the amplification processes. Comparative genomic hybridization techniques identified amplification of MDR1 in all six DX-resistant and of DHFR in three MTX-resistant U-2OS variants. In addition, progressive gain of MLL was detected in the four U-2OS variants with higher resistance levels either to DX or MTX, whereas gain of MYC was found in all Saos-2 MTX-resistant variants and the U-2OS variant with the highest resistance level to DX. Fluorescent in situ hybridization revealed that MDR1 was amplified in U-2OS and Saos-2/DX-resistant variants manifested as homogeneously staining regions and double minutes, respectively. In U-2OS/MTX-resistant variants, DHFR was amplified in homogeneously staining regions, and was coamplified with MLL in relation to the increase of resistance to MTX. Gene amplification was associated with gene overexpression, whereas gene gain resulted in up-regulated gene expression. These results indicate that resistance to DX and MTX in human OS cell lines is a multigenic process involving gene copy number and expression changes.

Palindromic gene amplification--an evolutionarily conserved role for DNA inverted repeats in the genome

The clinical importance of gene amplification in the diagnosis and treatment of cancer has been widely recognized, as it is often evident in advanced stages of diseases. However, our knowledge of the underlying mechanisms is still limited. Gene amplification is an essential process in several organisms including the ciliate Tetrahymena thermophila, in which the initiating mechanism has been well characterized. Lessons from such simple eukaryotes may provide useful information regarding how gene amplification occurs in tumour cells.

In situ hybridization to metaphase chromosomes and interphase nuclei

In situ hybridization is used to determine the chromosomal map location and the relative order of genes and DNA sequences within a chromosomal band. It can also be used to detect aneuploidy, gene amplification, and subtle chromosomal rearrangements. Fluorescence in situ hybridization (FISH), probably the most widely used method, is described in the first basic protocol. Two support protocols are provided to amplify weak fluorescent signals obtained in FISH. Nonisotopic probes can also be detected by enzymatic reactions using horseradish peroxidase or alkaline phosphatase, as described in alternate protocols. Nonisotopic labeling of DNA probes by nick translation is described in a support protocol. The order of closely spaced FISH probes along chromosomes in interphase nuclei can be determined. A basic protocol for isotopic in situ hybridization (IISH) with (3)H is provided followed by a support protocol for preparation of autoradiographic emulsion.

Inverted duplication pattern in anaphase bridges confirms the breakage-fusion-bridge (BFB) cycle model for 11q13 amplification

The homogeneously staining region (hsr) involving chromosome band 11q13 includes amplified genes from this chromosome segment and carries a relatively poor prognosis in oral squamous cell carcinomas (OSCC), with shorter time to recurrence and reduced overall survival. We previously identified an inverted duplication pattern of genes within the 11q13 hsr in OSCC cells, supporting a breakage-fusion-bridge (BFB) cycle model for gene amplification. To validate our hypothesis that 11q13 gene amplification in OSCC occurs via BFB cycles, we carried out fluorescence in situ hybridization (FISH) using probes for band 11q13 on 29 OSCC cell lines. We demonstrate that all OSCC cell lines with 11q13 amplification express a significantly higher frequency of anaphase bridges containing 11q13 sequences compared to cell lines without amplification, providing further experimental evidence that 11q13 gene amplification in OSCC cells occurs via BFB cycles. Elucidation of mechanisms responsible for initiating and promoting gene amplification provides opportunities to identify new biomarkers to aid in the diagnosis and prognosis of oral cancer, and may be useful for developing novel therapeutic strategies for patients with OSCC.

High-resolution mapping identifies a commonly amplified 11q13.3 region containing multiple genes flanked by segmental duplications

DNA amplification of the 11q13 region is observed frequently in many carcinomas. Within the amplified region several candidate oncogenes have been mapped, including cyclin D1, TAOS1 and cortactin. Yet, it is unknown which gene(s) is/are responsible for the selective pressure enabling amplicon formation. This is probably due to the use of low-resolution detection methods. Furthermore, the size and structure of the amplified 11q13 region is complex and consists of multiple amplicon cores that differ between different tumor types. We set out to test whether the borders of the 11q13 amplicon are restricted to regions that enable DNA breakage and subsequent amplification. A high-resolution array of the 11q13 region was generated to study the structure of the 11q13 amplicon and analyzed 29 laryngeal and pharyngeal carcinomas and nine cell lines with 11q13 amplification. We found that boundaries of the commonly amplified region were restricted to four segments. Three boundaries coincided with a syntenic breakpoint. Such regions have been suggested to be putatively fragile. Sequence comparisons revealed that the amplicon was flanked by two large low copy repeats known as segmental duplications. These segmental duplications might be responsible for the typical structure and size of the 11q13 amplicon. We hypothesize that the selection for genes through amplification of the 11q13.3 region is determined by the ability to form DNA breaks within specific regions and, consequently, results in large amplicons containing multiple genes.

The breakage-fusion-bridge (BFB) cycle as a mechanism for generating genetic heterogeneity in osteosarcoma

Osteosarcoma (OS) is characterized by chromosomal instability and high copy number gene amplification. The breakage-fusion-bridge (BFB) cycle is a well-established mechanism of genome instability in tumors and in vitro models used to study the origins of complex chromosomal rearrangements and cancer genome amplification. To determine whether the BFB cycle could be increasing the de novo rate of formation of cytogenetic aberrations in OS, the frequency of anaphase bridge configurations and dicentric chromosomes in four OS cell lines was quantified. An increased level of anaphase bridges and dicentrics was observed in all the OS cell lines. There was also a strong association between the frequencies of anaphase bridges, dicentrics, centrosomal anomalies, and multipolar mitotic figures in all the OS cell lines, indicating a possible link in the mechanisms that led to the structural and numerical instabilities observed in OS. In summary, this study has provided strong support for the role of the BFB cycle in generating the extensive structural chromosome aberrations, as well as cell-to-cell cytogenetic variation observed in OS, thus conferring the genetic diversity for OS tumor progression.

The origin of chromosome rearrangements at early stages of AMPD2 gene amplification in Chinese hamster cells

BACKGROUND

Gene amplification and chromosomal rearrangements are frequent properties of cancer cells, provoking considerable interest in the mechanism of gene amplification and its consequences - particularly its relationship to chromosomal rearrangements. We recently studied the amplification of the gene for adenylate deaminase 2 (AMPD2) in Chinese hamster cells. Using fluorescent in situ hybridization (FISH), we found that early amplification of the AMPD2 gene is based on unequal gene segregation at mitosis, rather than local over-replication. We observed large inverted repeats of the amplified sequences, consistent with an amplification mechanism involving cycles of chromatid breakage, followed by fusion after replication and, in mitosis, the formation of bridges between the fused sister chromatids that leads to further breaks - a process we refer to as chromatid breakage-fusion-bridge (BFB) cycles. Our previous work left open the question of how this mechanism of gene amplification is related, if at all, to the chromosomal rearrangements that generate the dicentric, ring and double-minute (DM) chromosomes observed in some AMPD2-amplified metaphase cells, which are not predicted intermediates of chromatid BFB cycles, although they could be generated by related chromosome BFB cycles.

RESULTS

We have addressed this question using FISH with probes for the AMPD2 gene and other markers on the same chromosome. Our results are not consistent with the chromosome BFB cycle mechanism, in which two chromatids break simultaneously and fuse to generate, after replication, a dicentric chromosome. Rather, they suggest that dicentric chromosomes are generated by secondary events that occur during chromatid BFB cycles. Our results also suggest that DM chromosomes are generated by the 'looping-out' of a chromosomal region, generating a circular DNA molecule lacking a centromere; in this case, gene amplification would result from the unequal segregation of DM chromosomes at mitosis.

CONCLUSION

We conclude that, at early stages of AMPD2 gene amplification, chromatid BFB cycles are a major source of both 'intrachromosomal' gene amplification and genomic rearrangement, which are first limited to a single chromosome but which can then potentially spread to any additional chromosome. It also seems that, occasionally, a DNA sequence including the AMPD2 gene can be excised, generating a DM chromosome and thus initiating an independent process of 'extrachromosomal' amplification.

When, where and how the bridge breaks: anaphase bridge breakage plays a crucial role in gene amplification and HSR generation

Amplified genes are frequently localized on extrachromosomal double minutes (DMs) or in chromosomal homogeneously staining regions (HSRs). We previously showed that a plasmid bearing a mammalian replication initiation region could efficiently generate DMs and HSRs after transfection into human tumor cell lines. The Breakage-Fusion-Bridge (BFB) cycle model, a classical model that explains how HSRs form, could also be used to explain how the transfected plasmids generate HSRs. The BFB cycle model involves anaphase bridge formation due to the presence of dicentric chromosomes, followed by the breakage of the bridge. In this study, we used our plasmid-based model system to analyze how anaphase bridges break during mitosis. Dual-color fluorescence in situ hybridization analyses revealed that anaphase bridges were most frequently severed in their middle irrespective of their lengths, which suggests that a structurally fragile site exists in the middle of the anaphase bridge. Breakage of the chromosomal bridges occurred prior to nuclear membrane reformation and the completion of cytokinesis, which indicates that mechanical tension rather than cytokinesis is primarily responsible for severing anaphase bridges. Time-lapse observation of living cells revealed that the bridges rapidly shrink after being severed. If HSR length was extended too far, the bridge could no longer be resolved and became tangled depending on the tension. The unbroken bridge appeared to inhibit the completion of cytokinesis. These observations strongly suggest that anaphase bridges are highly elastic and that the length of the spindle axis determines the maximal HSR length.

Structure of a palindromic amplicon junction implicates microhomology-mediated end joining as a mechanism of sister chromatid fusion during gene amplification

Amplification of the copy number of oncogenes is frequently associated with tumor progression. Often, the amplified DNA consists of large (tens to hundreds of kilobases) 'head-to-head' inverted repeat palindromes (amplicons). Several mechanisms have been proposed to explain palindrome formation but their relative contributions in nature have been difficult to assess without precise knowledge of the sequences involved at the junction of natural amplicons. Here, we have sequenced one such junction and compared this sequence to the un-rearranged structure, allowing us to pinpoint the site of sister chromatid fusion. Our results support a novel model, consistent with all described sister chromatid fusions, in which sister chromatid fusion is initiated by microhomology-mediated end joining of double strand breaks.

Induction of multiple double-strand breaks within an hsr by meganucleaseI-SceI expression or fragile site activation leads to formation of double minutes and other chromosomal rearrangements

Gene amplification is frequently associated with tumor progression, hence, understanding the underlying mechanisms is important. The study of in vitro model systems indicated that different initial mechanisms accumulate amplified copies within the chromosomes (hsr) or on extra-chromosomal elements (dmin). It has long been suggested that formation of dmin could also occur following hsr breakdown. In order to check this hypothesis, we developed an approach based on the properties of the I-SceI meganuclease, which induces targeted DNA double-strand breaks. A clone containing an I-SceI site, integrated by chance close to an endogenous dhfr gene locus, was used to select for methotrexate resistant mutants. We recovered clones in which the I-SceI site was passively co-amplified with the dhfr gene within the same hsr. We show that I-SceI-induced hsr breakdown leads to the formation of dmin and creates different types of chromosomal rearrangements, including inversions. This demonstrates, for the first time, a direct relationship between double-strand breaks and inversions. Finally, we show that activation of fragile sites by aphidicolin or hypoxia in hsr-containing cells also generates dmin and a variety of chromosomal rearrangements. This may constitute a valuable model to study the consequences of breaks induced in hsr of cancer cells in vivo.

Gamma-ray and hydrogen peroxide induction of gene amplification in hamster cells deficient in DNA double strand break repair

To investigate the role of DNA double strand breaks (DSBs) and of their repair in gene amplification, we analyzed this process in the V3 Chinese hamster cell line and in the parental line AA8, after exposure to gamma-rays and to hydrogen peroxide (H2O2). V3 is defective in DSB repair because of a mutation in the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) gene, a gene involved in the non-homologous end-joining pathway. As a measure of gene amplification we used the frequency of colonies resistant to N-(phosphonacetyl)-L-aspartate (PALA), since in rodent cells PALA resistance is mainly achieved through the amplification of the CAD (carbamyl-P-synthetase, aspartate transcarbamylase, dihydro-orotase) gene. After treatment with different doses of gamma-rays and of H2O2, we found a dose related increase in the frequency of gene amplification and of chromosome aberrations. When the same doses of damaging agents were used, these increments were higher in V3 than in AA8. These results indicate that DSBs that are not efficiently repaired can be responsible for the induction of gene amplification. H2O2 stimulates gene amplification as well as gamma-rays, however, at similar levels of amplification induction, chromosome damage was about 50% lower. This suggests that gene amplification can be induced by H2O2 through pathways alternative to a direct DNA damage. Stimulation of gene amplification by H2O2, which is one of the products of the aerobic metabolism, supports the hypothesis that cellular metabolic products themselves can be a source of genome instability.

Amplification of the human dihydrofolate reductase gene via double minutes is initiated by chromosome breaks

DNA sequence amplification is one of the most frequent manifestations of genomic instability in human tumors. We have shown previously that amplification of the dihydrofolate reductase (DHFR) gene in Chinese hamster cells is initiated by chromosome breaks, followed by bridge-breakage-fusion cycles that generate large intrachromosomal repeats; these are ultimately trimmed by an unknown process to smaller, more homogenous units manifested as homogenously staining chromosome regions (HSRs). However, in most human tumor cells, amplified DNA sequences are borne on unstable, extrachromosomal double minutes (DMs), which suggests the operation of a different amplification mechanism. In this study, we have isolated a large number of independent methotrexate-resistant human cell lines, all of which contained DHFR-bearing DMs. Surprisingly, all but one of these also had suffered partial or complete loss of one of the parental DHFR-bearing chromosomes. Cells in a few populations displayed what could be transient intermediates in the amplification process, including an initial HSR, its subsequent breakage, the appearance of DHFR-containing fragments, and, finally, DMs. Our studies suggest that HSRs and DMs both are initiated by chromosome breaks, but that cell types differ in how the extra sequences ultimately are processed and/or maintained.

Late onset of CAD gene amplification in unamplified PALA resistant Chinese hamster mutants

In rodent cells, resistance to PALA (N-phosphonacetyl-L-aspartate) has always been found associated with amplification of the CAD gene (carbamyl-P synthetase, aspartate transcarbamylase, dihydro-orotase). We describe two PALA resistant Chinese hamster mutant cell lines in which amplification of the CAD gene was not present. The PALA resistant phenotype was stable when the cells were grown in non-selective medium. However, after prolonged growth in the presence of the same drug concentration used for selection, cells with increased CAD gene copy number and higher levels of resistance overrode the original population. In these cell populations, a heterogeneous organization of the CAD genes was revealed by fluorescence in situ hybridization on mitotic chromosomes indicating that the additional copies of the gene were generated in several ways, such as non-disjunction and breakage-fusion-bridge cycles. The clastogenic effect of PALA, evidenced as chromosomal aberrations in the cells grown in the presence of the drug, could have favored the late onset of the amplified mutants. It is tempting to speculate that, during the expansion of tumor populations, different drug resistance mechanisms, including gene amplification, could occur in succession and lead to the generation of cells highly resistant to chemotherapeutic agents.

Formation of circular amplifications in Saccharomyces cerevisiae by a breakage-fusion-bridge mechanism

Primary gene amplification, the mutation from one gene copy per genome to two or more copies per genome, is a major mechanism of oncogene overexpression in human cancers. Analysis of the structures of amplifications can provide important evidence about the mechanism of amplification formation. We report here the analysis of the structures of four independent spontaneous circular amplifications of ADH4:CUP1 in the yeast Saccharomyces cerevisiae. The structures of all four amplifications are consistent with their formation by a breakage-fusion-bridge (BFB) mechanism. All four of these amplifications include a centromere as predicted by the BFB model. All four of the amplifications have a novel joint located between the amplified DNA and the telomere, which results in a dicentric chromosome, and is adjacent to all the copies of the amplified DNA as predicted by the BFB model. In addition we demonstrated that two of the amplifications contain most of chromosome VII in an unrearranged form in a 1:1 ratio with the normal copy of chromosome VII, again consistent with the predictions of the BFB model. Finally, all four amplifications are circular, one stable endpoint for molecules after breakage- fusion-bridge.

The tumor suppressor p53 can reduce stable transfection in the presence of irradiation

The tumor suppressor p53 is believed to play an essential role in maintaining genome stability. Although it is currently unknown how p53 is involved in this important biological safeguard, several previous publications indicate that p53 can help to maintain genome integrity through the recombination-mediated DNA repair process. The integration of linearized plasmid DNA into the host chromosome utilizes the same repair process, and the frequency can be measured by clonogenic assays in which cells that were stably transfected by plasmid integration can be scored by their colony-forming abilities. To gain insight into whether p53 has a direct role in plasmid integration into the host chromosome, we determined the frequency of stable transfection with CHO cells expressing either wild-type or mutant p53 in the presence and absence of irradiation. We found that low-dose irradiation ( approximately 50 to 100 cGy) increased stable transfection frequencies in CHO cells regardless of their p53 status. However, the increase of transfection frequency was significantly lower in CHO cells expressing wild-type p53. Our data thus suggest that wild-type p53 can suppress plasmid DNA integration into the host genome. This p53 function may play a direct and significant role in maintaining genome stability.

Gene amplification mechanisms: the role of fragile sites

We studied the early stages of gene amplification in a Chinese hamster cell line and identified two distinct amplification mechanisms, both relying on an unequal segregation of gene copies at mitosis. In some cases, a sequence containing the selected gene is looped out, generating an acentric circular molecule, and amplification proceeds through unequal segregation of such extrachromosomal elements in successive cell cycles. In other cases, the accumulation of intrachromosomally amplified copies is driven by cycles of chromatid breakage, followed by fusion of sister chromatids devoid of a telomere, which leads to bridge formation and further break in mitosis (BFB cycles). We showed that some clastogenic drugs specifically trigger the intrachromosomal amplification pathway and strictly correlated this induction of BFB cycles to the ability of these drugs to activate fragile sites. In three model systems, we also established, that the location of centromeric and telomeric fragile sites relative to the selected genes determines the size and sequence content of the early amplicons.

Distinct chromosomal alterations associated with TP53 status of LoVo cells under PALA selective pressure: a parallel with cytogenetic pathways of colorectal cancers

This study investigates the chromosomal alterations involved in the acquisition of PALA resistance of LoVo colorectal cancer cells homozygous for wild-type TP53 before and after transfection with a 143Ala-mutated TP53 gene. PALA resistance was always associated with an increased number of CAD gene copies, but gene amplification sensu stricto was rarely observed. Interestingly, distinct chromosome patterns were found in relation to the TP53 status of the cells. In parental LoVo cells, the CAD copy number was increased through gains of normal chromosome 2 whereas in transfectant clones, resistance mostly occurred through chromosome rearrangements. The relationship with the two different cytogenetic patterns described in colorectal tumors is discussed.

Chromosome breakpoints near CpG islands in double minutes

Double minute chromosomes (DMs) are the principal genetic vehicles for amplifying oncogenes in human tumors and drug resistance genes in cultured mouse cells. Mouse EMT-6 cells resistant to methotrexate (MTX) generally contain circular DMs, approximately 1 megabase (Mb) in size, that amplify the dihydrofolate reductase (DHFR) gene. The 1 Mb DMs generally have CpG islands located 500 kb upstream of the DHFR gene. The purpose of this study was to determine the relationship between CpG islands and chromosomal breakpoints giving rise to the DM. We show that EMT-6 cells growing in very low levels of MTX that do not yet contain the 1 Mb DHFR-amplifying DM, develop a NotI/EagI site 500 kb upstream of the DHFR gene. This NotI site is close to, if not identical with, one of the chromosomal breakpoints giving rise to the DM. We show that 500 kb of DM DNA from upstream of the DHFR gene is derived from 500 kb of chromosomal DNA upstream of the chromosomal DHFR gene. The downstream breakpoint maps to a region approximately 200 kb downstream of the DHFR gene near a chromosomal SstII/EagI site. Therefore, approximately 700 kb of DM DNA was derived from the genomic region surrounding the DHFR gene. To confirm the organization of the DM DNA, we isolated DNA probes from the 1 Mb DM. Using pulsed field gel electrophoresis and Southern hybridization, we determined the approximate location of each probe with respect to the CpG island in both the DM and the chromosome. Approximately 300 kb of chimeric DNA from a region unrelated to the DHFR gene was incorporated during DM formation. Implications for the mechanism of DM formation are discussed.

CpG islands and double-minute chromosomes

Double-minute chromosomes (DMs) amplify oncogenes in human tumors. The organization of genomic DNA in four independently isolated DMs amplifying the DHFR (dihydrofolate reductase) gene has been compared by mapping locations of CpG islands. When cleaved with methylation-sensitive rare-cutting restriction endonucleases, three hypomethylated GC-rich DNA sequences were frequently found in specific regions in these DMs. One such zone was in the CpG island containing the divergently transcribed promoter separating the DHFR and the Rep-3 genes. The other two sites were approximately 500 kb upstream and 300 kb downstream of the DHFR gene. An approximately 800-kb amplified core genomic region containing the DHFR gene using DM-specific probes has been identified in this study. All the DMs consisted of the core amplified region combined with additional DNA fragments. These additional fragments are different for each DM. Therefore, while the DNAs in each of the DMs are different, they have common hypomethylated regions in similar locations. These results suggest a role for the location of hypomethylated GC-rich sites such as the CpG islands in genesis of DMs.

Chromosomal fragile sites and DNA amplification in drug-resistant cells

It has been well established that DNA amplification is one of the important mechanisms by which cultured cells acquire resistance to many cytotoxic compounds. Amplification of important genes including those encoding oncoproteins, growth factors, their receptors and cell-cycle regulators has been reported in human neoplasms. Yet, despite intensive research since the first description of DNA amplification in cultured cells about 20 years ago, the mechanisms of DNA amplification remain largely unknown. Many models have been proposed to account for the diverse manifestations of amplified DNA in many different cell sources. It is not the intention of this commentary to review these many different models. Rather, we wil focus on the recent advances in this area of research, made mainly via the fluorescence in situ hybridization technique, that have revealed a fairly common chromosomal manifestation of amplified DNA in the drug-resistant hamster cell lines and have demonstrated the association of chromosomal fragile site breakage with early events in DNA amplification. These new developments underscore the importance of future research toward understanding the molecular bases of chromosomal fragile sites, including mechanisms involved in DNA strand breakage and repair, chromosomal translocations, and deletions, which may, in turn, provide important new insights into genomic plasticity and neoplastic transformation.

Structural analysis of the amplified IFN-beta and DHFR genes in a Chinese hamster ovary cell line using multicolour FISH analysis

Multicolour FISH was used to get insight into the structural arrangement of a homogeneously staining region which bears the co-transfected and subsequently co-amplified IFN-beta and DHFR genes in a CHO cell line. On metaphase chromosomes an arrangement of multiple bands with regular spacing is revealed. On extended chromatin fibres a cluster of directly repeated and interspersed IFN-beta and DHFR genes is visible. Up to three clusters were found arranged in tandem. The different chromosomal mechanisms leading to gene amplification are discussed.

Mini- and microsatellites

While the faithful transmission of genetic information requires a fidelity and stability of DNA that is involved in translation into proteins, it has become evident that a large part of noncoding DNA is organized in repeated sequences, which often exhibit a pronounced instability and dynamics. This applies both to longer repeated sequences, minisatellites (about 10-100 base pairs), and microsatellites (mostly 2-4 base pairs). Although these satellite DNAs are abundantly distributed in all kinds of organisms, no clear function has been discerned for them. However, extension of trinucleotide microsatellite sequences has been associated with several severe human disorders, such as Fragile X syndrome and Huntington's disease. Rare alleles of a minisatellite sequence have been reported to be associated with the ras oncogene leading to an increased risk for several human cancers. A dynamic behavior of repeated DNA sequences also applies to telomeres, constituting the ends of the chromosomes. Repeated DNA sequences protect the chromosome ends from losing coding sequences at cell divisions. The telomeres are maintained by the enzyme telomerase. Somatic cells, however, lose telomerase function and gradually die. Cancer cells have activated telomerase and therefore they acquire immortality.

Multiple mechanisms of N-phosphonacetyl-L-aspartate resistance in human cell lines: carbamyl-P synthetase/aspartate transcarbamylase/dihydro-orotase gene amplification is frequent only when chromosome 2 is rearranged

Rodent cells resistant to N-phosphonacetyl-L-aspartate (PALA) invariably contain amplified carbamyl-P synthetase/aspartate transcarbamylase/dihydro-orotase (CAD) genes, usually in widely spaced tandem arrays present as extensions of the same chromosome arm that carries a single copy of CAD in normal cells. In contrast, amplification of CAD is very infrequent in several human tumor cell lines. Cell lines with minimal chromosomal rearrangement and with unrearranged copies of chromosome 2 rarely develop intrachromosomal amplifications of CAD. These cells frequently become resistant to PALA through a mechanism that increases the aspartate transcarbamylase activity with no increase in CAD copy number, or they obtain one extra copy of CAD by forming an isochromosome 2p or by retaining an extra copy of chromosome 2. In cells with multiple chromosomal aberrations and rearranged copies of chromosome 2, amplification of CAD as tandem arrays from rearranged chromosomes is the most frequent mechanism of PALA resistance. All of these different mechanisms of PALA resistance are blocked in normal human fibroblasts.

Cloning and characterization of Chinese hamster p53 cDNA

We have cloned and sequenced Chinese hamster p53 cDNA and have compared the p53 sequence in different Chinese hamster cell lines to several relevant phenotypes. Our results indicate that a mutation in CHO cells that changes Thr211 to Lys211 abrogates the ability to arrest in G1 and apparently renders cells capable of amplifying DNA. However, this mutation has no effect on the G2 checkpoint or on acute down-regulation of DNA replication after a radiation challenge.

Patterns of oncogene activation in human neuroblastoma cells

Human neuroblastoma is the most frequent solid tumor in children. Recent studies suggest that a multiplicity of genomic alterations contributes to neuroblastoma, the most frequent and well studied being deletion of the short arm of chromosome 1 and amplification of N-MYC. We here present and discuss different patterns of oncogene activation including, amplification of N-MYC, duplication of N-MYC and amplification of MDM2.

FISH technology in chromosome and genome research

Fluorescent in situ hybridization technology is one of the most exciting and versatile research tools to be developed in recent years. It has enabled research to progress at a phenomenal rate in diverse areas of basic research as well as in clinical medicine. Fluorescent in situ hybridization has applications in physical mapping, the study of nuclear architecture and chromatin packaging, and the investigation of fundamental principles of biology such as DNA replication, RNA processing, gene amplification, gene integration and chromatin elimination. This review highlights some of these areas and provides source material for the reader who seeks more information on a specific field.

Clonal analysis of delayed karyotypic abnormalities and gene mutations in radiation-induced genetic instability

Many tumors exhibit extensive chromosomal instability, but karyotypic alterations will be significant in carcinogenesis only by influencing specific oncogenes or tumor suppressor loci within the affected chromosomal segments. In this investigation, the specificity of chromosomal rearrangements attributable to radiation-induced genomic instability is detailed, and a qualitative and quantitative correspondence with mutagenesis is demonstrated. Chromosomal abnormalities preferentially occurred near the site of prior rearrangements, resulting in complex abnormalities, or near the centromere, resulting in deletion or translocation of the entire chromosome arm, but no case of an interstitial chromosomal deletion was observed. Evidence for chromosomal instability in the progeny of irradiated cells also included clonal karyotypic heterogeneity. The persistence of instability was demonstrated for at least 80 generations by elevated mutation rates at the heterozygous, autosomal marker locus tk. Among those TK- mutants that showed a loss of heterozygosity, a statistically significant increase in mutation rate was observed only for those in which the loss of heterozygosity encompasses the telomeric region. This mutational specificity corresponds with the prevalence of terminal deletions, additions, and translocations, and the absence of interstitial deletions, in karyotypic analysis. Surprisingly, the elevated rate of TK- mutations is also partially attributable to intragenic base substitutions and small deletions, and DNA sequence analysis of some of these mutations is presented. Complex chromosomal abnormalities appear to be the most significant indicators of a high rate of persistent genetic instability which correlates with increased rates of both intragenic and chromosomal-scale mutations at tk.

Sequence and context effects on origin function in mammalian cells

Jacob and Brenner proposed a model for control of DNA replication in which a trans-acting initiator protein binds to a cis-acting replicator to effect initiation of nascent DNA chains at a fixed locus. Although replicators have been identified in prokaryotic and simple eukaryotic genomes, it has been much more difficult to demonstrate their presence in mammalian chromosomes. Owing to the lack of genetic approaches for identifying mammalian replicators, investigators have directed attention to localizing nascent strand start sites, which should lie close to replicators. Toward this end, a variety of clever techniques have been invented for analyzing replication intermediates, but only rarely have more than one of these techniques been applied to a single locus. However, virtually all have been used to analyze the dihydrofolate reductase locus in CHO cells. The picture that has developed in this locus is that initiation can occur at any of a large number of sites scattered throughout a broad zone, but somewhat more frequently near two sites that may correspond to true genetic replicators. Furthermore, it appears that local transcriptional activity, as well as appropriate torsional stress (as imparted by local attachment to the nuclear matrix), may have profound effects on origin activity.

Inefficient growth arrest in response to dNTP starvation stimulates gene amplification through bridge-breakage-fusion cycles

Cells often acquire resistance to the antiproliferative agents methotrexate (MTX) or N-phosphonacetyl-L-aspartate (PALA) through amplification of genes encoding the target enzymes dihydrofolate reductase or carbamylphosphate synthetase/aspartate transcarbamylase/dihydroorotase (CAD), respectively. We showed previously that Syrian hamster BHK cells resistant to selective concentrations of PALA (approximately 3 x ID50) arise at a rate of approximately 10(-4) per cell per generation and contain amplifications of the CAD gene as ladder-like structures on one of the two B9 chromosomes, where CAD is normally located. We now find that BHK cells resistant to high concentrations of PALA (approximately 15 x ID50) appear only after prior exposure to selective concentrations of PALA for approximately 72 h. Furthermore, in contrast to untreated cells, BHK cells pretreated with selective concentrations of MTX give colonies in high concentrations of PALA, and cells pretreated with selective concentrations of PALA give colonies in high concentrations of MTX or 5-fluorouracil. As judged by measuring numbers of cells and metaphase cell pairs, BHK cells do not arrest completely when starved for pyrimidine nucleotides by treatment with selective concentrations of PALA for up to 72 h. We propose that DNA damage, caused when cells fail to stop DNA synthesis promptly under conditions of dNTP starvation, stimulates amplification throughout the genome by mechanisms--such as bridge-breakage-fusion cycles--that are triggered by broken DNA. Amplified CAD genes were analyzed by fluorescence in situ hybridization both in cells where amplification was induced by PALA pretreatment and in cells in which the amplification occurred spontaneously, before selection with PALA. The ladder-like structures that result from bridge-breakage-fusion cycles were observed in both cases.

Quantification of C-ERB-B2 gene amplification in breast cancer cells using fluorescence in situ hybridization and digital image analysis

Fluorescence in situ hybridization (FISH) allows detection of the intercellular heterogeneity of C-ERB-B2 gene amplification in uncultured breast cancer cells. Nevertheless, because high levels of amplification result in coalescence of signals, direct microscopy quantification is restricted to cells wih low levels of amplification or with dispersed signals. A methodology of digital image analysis, using surface and grey-level FISH signals as parameters that permit a rapid, objective, and accurate estimation of gene copy number, is presented. This procedure is independent of the signal overlapping and results in a more accurate quantification and characterization of tumor cell heterogeneity.

Origins of replication and the nuclear matrix: the DHFR domain as a paradigm

The eukaryotic genome appears to be organized in a loopwise fashion by periodic attachment to the nuclear matrix. The proposal that a chromatin loop corresponds to a functional domain has stirred interest in the properties of the DNA sequences at the bases of these loops, the matrix-attached regions (MARs). Evidence has been presented suggesting that certain MARs act as boundary elements isolating domains from their chromosomal context. MARs have also been found in the vicinity of promoters and enhancers and they could act by displacing these cis-regulatory elements into the proper nuclear subcompartment. Attachment to the matrix might also play a role in DNA replication. A large body of evidence indicates that replication occurs on the nuclear matrix. This implies that any DNA sequence will be attached to the matrix at a certain time during the cell cycle. This transient mode of attachment contrasts with the proposed permanent attachment of origins of DNA replication with the nuclear matrix. While some data exist that support this suggestion, the current lack of understanding of the mammalian replication origin precludes definitive conclusions regarding the role of MARs in the initiation process.

Plasmid amplification-promoting sequences from the origin region of Chinese hamster dihydrofolate reductase gene do not promote position-independent chromosomal gene amplification

Initiation of DNA synthesis occurs with high frequency at oribeta, a region of DNA from the amplified dihydrofolate reductase (DHFR) domain of Chinese hamster CHOC 400 cells that contains an origin of bidirectional DNA replication (OBR). Recently, sequences from DHFR oribeta/OBR were shown to stimulate amplification of cis-linked plasmid DNA when transfected into murine cells. To test the role of oribeta/OBR in chromosomal gene amplification, linearized plasmids containing these sequences linked to a DHFR expression cassette were introduced into DHFR- CHO DUKX cells. After selection for expression of DHFR, cell lines that contain a single integrated, unrearranged copy of the linearized expression plasmid were identified and exposed to low levels of the folate analog, methotrexate (MTX). Of seven clonal cell lines containing the vector control, three gained resistance to MTX by 5 to 15-fold amplification of the integrated marker gene. Of 16 clonal cell lines that contained oribeta/OBR linked to a DHFR mini-gene, only 6 gained resistance to MTX by gene amplification. Hence, sequences from the DHFR origin region that stimulate plasmid DNA amplification do not promote amplification of an integrated marker gene in all chromosomal contexts. In addition to showing that chromosomal position has a strong influence on the frequency of gene amplification, these studies suggest that the mechanism that mediates the experiment of episomal plasmid DNA does not contribute to the early steps of chromosomal gene amplification.

Site-specific initiation of DNA replication in Xenopus egg extract requires nuclear structure

Previous studies have shown that Xenopus egg extract can initiate DNA replication in purified DNA molecules once the DNA is organized into a pseudonucleus. DNA replication under these conditions is independent of DNA sequence and begins at many sites distributed randomly throughout the molecules. In contrast, DNA replication in the chromosomes of cultured animal cells initiates at specific, heritable sites. Here we show that Xenopus egg extract can initiate DNA replication at specific sites in mammalian chromosomes, but only when the DNA is presented in the form of an intact nucleus. Initiation of DNA synthesis in nuclei isolated from G1-phase Chinese hamster ovary cells was distinguished from continuation of DNA synthesis at preformed replication forks in S-phase nuclei by a delay that preceded DNA synthesis, a dependence on soluble Xenopus egg factors, sensitivity to a protein kinase inhibitor, and complete labeling of nascent DNA chains. Initiation sites for DNA replication were mapped downstream of the amplified dihydrofolate reductase gene region by hybridizing newly replicated DNA to unique probes and by hybridizing Okazaki fragments to the two individual strands of unique probes. When G1-phase nuclei were prepared by methods that preserved the integrity of the nuclear membrane, Xenopus egg extract initiated replication specifically at or near the origin of bidirectional replication utilized by hamster cells (dihydrofolate reductase ori-beta). However, when nuclei were prepared by methods that altered nuclear morphology and damaged the nuclear membrane, preference for initiation at ori-beta was significantly reduced or eliminated. Furthermore, site-specific initiation was not observed with bare DNA substrates, and Xenopus eggs or egg extracts replicated prokaryotic DNA or hamster DNA that did not contain a replication origin as efficiently as hamster DNA containing ori-beta. We conclude that initiation sites for DNA replication in mammalian cells are established prior to S phase by some component of nuclear structure and that these sites can be activated by soluble factors in Xenopus eggs.

p53-dependent growth arrest of REF52 cells containing newly amplified DNA

The rat cell line REF52 is not permissive for gene amplification. Simian virus 40 tumor (T) antigen converts these cells to a permissive state, as do dominant negative mutants of p53, suggesting that the effect of T antigen is due mainly to its ability to bind to p53. To manipulate permissivity, we introduced a temperature-sensitive mutant of T antigen (tsA58) into REF52 cells and selected for resistance to N-(phosphonacetyl)-L-aspartate (PALA). Most freshly isolated PALA-resistant colonies, each of approximately 200 cells, selected at a permissive temperature, arrested when shifted to a nonpermissive temperature. Growth arrest was stable, with no evidence of apoptosis, as long as T antigen was absent but was reversed when T antigen was restored. In contrast, PALA-resistant clones grown to approximately 10(7) cells at a permissive temperature did not arrest when shifted to a nonpermissive temperature. All PALA-resistant clones examined had amplified carbamoyl-phosphate synthetase-aspartate transcarbamoylase-dihydroorotase (CAD) genes, present in structures consistent with a mechanism involving bridge-breakage-fusion (BBF) cycles. We propose that p53-mediated growth arrest operates only early during the complex process of gene amplification, when newly formed PALA-resistant cells contain broken DNA, generated in BBF cycles. During propagation under permissive conditions, the broken DNA ends are healed, and, even though the p53-mediated pathway is still intact at a nonpermissive temperature and the cells contain amplified DNA, they are not arrested in the absence of broken DNA. The data support the hypothesis that BBF cycles are an important mechanism of amplification and that the broken DNA generated in each cycle is a key signal that regulates permissivity for gene amplification.

A role for genomic instability in cellular radioresistance?

Inherent cellular radioresistance plays a critical role in the failure of radiotherapy. Although the consequences of radioresistance are well known, the molecular, biological, and cellular bases of radioresistance remain a mystery. We propose that genomic instability, the increased rate of acquisition of alterations in the mammalian genome, can directly modulate cells' sensitivity to radiation. In particular, destabilization of chromosomes occurring as a consequence of genomic instability may result in enhanced 'plasticity of the genome'. This increased plasticity of the genome allows cells to better adapt to changes in local environment(s) during tumor progression, or improve cell survival following exposure to DNA damage encountered during radiotherapy protocols, thereby contributing to radioresistant cell populations found in tumors both before and after radiotherapy.

Overexpression of c-myc precedes amplification of the gene encoding dihydrofolate reductase

An experimentally inducible model system was generated in which Chinese hamster ovary cells (CHO-9) were stably transfected with an inducible c-myc cDNA. The induction of c-myc in these transfectants is followed by the enhanced binding of c-Myc/Max-containing protein complexes to 5'flanking E-box sequences of the gene encoding dihydrofolate reductase (DHFR). Moreover, DHFR is transiently amplified. The inappropriate overproduction of the oncoprotein, therefore, seems to plays a role in induced DHFR amplification.