Localization of dihydrofolate reductase amplified genes in Chinese hamster cells resistant to methotrexate

New sublines of BFFR1 and BFFR3 cells were obtained as a result of prolonged cultivation of Chinese hamster cells of Blld-ii-FAF 28 line (clone 431) in the presence of increasing concentrations of methotrexate (MTX). The lines obtained were resistant to 200 and 300 mcM of MTX, respectively. Amplification of the gene for dihydrofolate reductase (DHFR), similar to normal DHFR gene in restriction patterns, was proved by blot-hybridization of the resistant cells' DNA with 32P-labeled plasmid DHFR-26. Correlation is shown between the extent of gene amplification and resistance of the cell lines. In situ hybridization of the metaphase chromosomes of resistant cells with 3H-DHFR-26 results in preferential binding of the label with the regions of marker chromosomes 2 and 5, containing long, so called differential staining regions which are known to be the places of localization of amplified genes.     

The presence of amplified regions affects the stability of chromosomes in drug-resistant Chinese hamster cells

The stability of chromosomes carrying amplified CAD (carbamyl phosphate synthetase-aspartate transcarbamylase-dihydroorotase) or DHFR (dihydrofolate reductase) genes was studied in V79 Chinese hamster cell derivatives resistant to PALA (N-phosphonacetyl-L-aspartate) and MTX (methotrexate), respectively. Cells were maintained in the presence of the selective drugs during the study. In both metaphase chromosomes and interphase nuclei, amplified regions were localized by in situ hybridization. In MTX-resistant cells, the amplification-bearing chromosome moved sluggishly at anaphase and gave rise to bud-shaped formations in interphase nuclei. It is suggested that these buds could eventually separate as micronuclei. In both MTX- and PALA-resistant cells, amplified DNA was observed in micronuclei in interphase and in displaced chromosomes in metaphase. Finally, amplification-bearing dicentric chromosomes were found in both drug-resistant cell lines. Cumulatively, these observations indicate that the presence of the amplified region in a chromosome renders it unstable: chromosomes bearing an amplified region tended to be excluded from cells, and rearrangements were more frequent than in normal chromosomes.     

Characterization of double minute chromosomes’ DNA content in a human high grade astrocytoma cell line by using comparative genomic hybridization and fluorescence in situ hybridization

The presence of double minute chromosomes (dmin) in cancer cells is known to be correlated with gene amplifications. In human high grade astrocytomas or glioblastomas, about 50% of cytogenetically characterized cases display dmin. G5 is a cell line which has been established from a human glioblastoma containing multiple dmin. In order to identify the DNA content of these dmin, three techniques were successively used: conventional cytogenetic analysis, comparative genomic hybridization (CGH), and fluorescent in situ hybridization (FISH). The karyotype of G5 cells showed numerical chromosome changes (hypertriploidy), several marker chromosomes, and multiple dmin. CGH experiments detected two strong DNA amplification areas located in 9p21-22 and 9p24, as well as an underrepresentation of chromosomes 6, 10, 11, 13, 14, and 18q. By using FISH with a chromosome 9-specific painting probe to metaphase chromosomes of the G5 cell line, dmin were shown to contain DNA sequences originating from chromosome 9. This study demonstrates the usefulness of a combination of classical karyotyping, CGH, and FISH to identify the chromosomal origin of amplified DNA sequences in dmin. Received: 30 October 1994 / Revised: 25 February 1996     

Characterization of chromosomal aberrations in diffuse large B-cell lymphoma (DLBL) by G-banding and spectral karyotyping (SKY)

Cytogenetic chromosome analysis by classical G-banding was supplemented by spectral karyotyping (SKY) in 12 cases of diffuse large B-cell lymphoma (DLBL). SKY is a fluorescence in-situ-based, genome-wide screening technique allowing identification of genetic material even in highly condensed metaphase chromosomes of poor morphology. By simultaneous hybridization of whole chromosome painting probes onto tumor chromosome spreads genetic rearrangements are visualized permitting the clarification of even complex karyotype alterations and the identification of genetic material of previously unknown origin, so-called marker chromosomes. Taking the SKY results into account, we reevaluated the G-banding karyotypes initially carried out, thus generating a more precise karyotype in ten of twelve (83%) cases investigated. In particular, thirteen chromosomal rearrangements not correctly recognized by classical cytogenetics were identified, the genetic origin of seven marker chromosomes was elucidated and three structural genetic rearrangements were redefined. We found SKY to be a valuable technique to establish a definite karyotype in addition to classical cytogenetics.     

Molecular structure and evolution of double-minute chromosomes in methotrexate-resistant cultured mouse cells.

To determine whether microscopically visible double-minute chromosomes (DMs) are derived from submicroscopic precursors, we monitored the amplification of the dihydrofolate reductase (DHFR) gene in 10 independent isolates of methotrexate (MTX)-resistant mouse cells. At every other doubling in MTX concentration, the cells were examined both microscopically, to detect the presence of microscopically visible DMs, and by pulsed-field gel electrophoresis and hybridization to a DHFR-specific probe, to detect submicroscopic DMs. One of the cloned MTX-resistant isolates was examined in detail and was shown to originally contain amplified DHFR genes on circular DMs measuring 1 and 3 Mb in size; additionally, metaphase chromosome preparations from this cloned isolate were examined and were shown to contain microscopically visible DMs too large to enter a pulsed-field gel. During stepwise selection for increasing levels of MTX, the smaller DMs (not microscopically visible) were shown to be preferentially amplified, whereas the larger (microscopically visible) ones decreased in relative numbers. Rare-cutting NotI digestion patterns of total genomic DNA that includes the DMs containing the DHFR gene suggest that the DMs increase in copy number without any further significant rearrangements. We saw no evidence from any of the 10 isolates to suggest that microscopically visible DMs are formed from smaller submicroscopic precursors.     

Microcell-mediated cotransfer of genes specifying methotrexate resistance, emetine sensitivity, and chromate sensitivity with Chinese hamster chromosome 2.

Many selectable mutants of somatic Chinese hamster cells have been described, but very few of the mutations have been mapped to specific chromosomes. We have utilized the microcell-mediated gene transfer technique to establish the location of three selectable genetic markers on chromosome 2 of Chinese hamster. Microcells were prepared from the methotrexate-resistant MtxRIII line of Flintoff et al. (Somatic Cell Genet. 2:245-261, 1976) and fused to wild-type CHO cells, and microcell hybrids (transferants) were selected in medium containing methotrexate. All transferants were karyotyped and found to contain a marker chromosome from the donor MtxRIII line. This marker chromosome, called 2p-, consisted of a chromosome 2 with a reduced short arm resulting from a reciprocal translocation between 2p and 5q. In experiments utilizing emetine-resistant (Emtr) or chromate-resistant (Chrr) recipient cells it was found that the emt+ and chr+ wild-type genes were cotransferred with the 2p- chromosomes. Karyotype analysis of several transferants with rearranged or broken 2p- markers allowed regional localization of the emt and chr loci to the proximal third of the long arm and localization of the gene or genes conferring methotrexate resistance to the short arm. These results confirm our earlier assignment of the emt and chr loci to chromosome 2 in Chinese hamster.     

Assignment of two rat dihydrofolate (DHFR) genes to chromosomes 2 and 4

A panel of rat x mouse cell hybrids was used in the chromosomal mapping of the rat dihydrofolate reductase (DHFR) gene. It was determined that the probe hybridized to gene sequences on two different chromosomes (Nos. 2 and 4), possibly representing the active gene and a pseudogene. Hybridization of the DHFR probe to DNA from a methotrexate resistant rat cell line revealed that the gene on chromosome 2 was amplified, but not the gene on chromosome 4. This result was taken to suggest that the active DHFR gene is located on rat chromosome 2 and that the sequence on chromosome 4 is a pseudogene.     

An amplified insect dihydrofolate reductase gene contains a single intron

We have used methotrexate-resistant mosquito (Aedes albopictus) cells as the source of DNA for cloning an 8.5-kb EcoRI fragment containing an amplified dihydrofolate reductase (DHRF) gene. An estimated 1200 copies of the DHFR gene were represented in nuclear DNA from Mtx-5011-256 cells, which were 3000-fold more resistant to methotrexate than wild-type cells. Southern blot analysis indicated that all of the amplified DHFR genes were contained within a 1.8-kb AccI fragment represented in the cloned DNA. In contrast to mammalian DHFR genes which span approximately 30 kb, the complete amino acid coding sequence of the mosquito DHFR gene spanned 614 nucleotides, including a single 56-nucleotide intron that interrupted a conserved Arg codon at amino acid position 27. Additional introns characteristic of mammalian DHFR genes were absent; conservation of the first intron in the mosquito DHFR gene supports a regulatory role for this intron. The mosquito DHFR gene coded for a 186-amino-acid protein with 43-48% similarity to vertebrate DHFR.     

Loss and stabilization of amplified dihydrofolate reductase genes in mouse sarcoma S-180 cell lines.

We studied the loss and stabilization of dihydrofolate reductase genes in clones of a methotrexate-resistant murine S-180 cell line. These cells contained multiple copies of the dihydrofolate reductase gene which were associated with double minute chromosomes. The growth rate of these cells in the absence of methotrexate was inversely related to the degree of gene amplification (number of double minute chromosomes). Cells could both gain and lose genes as a result of an unequal distribution of double minute chromosomes into daughter cells at mitosis. The loss of amplified dihydrofolate reductase genes during growth in the absence of methotrexate resulted from the continual generation of cells containing lower numbers of double minute chromosomes. Because of the growth advantage of these cells, they became dominant in the population. We also studied an unstably resistant S-180 cell line (clone) that, after 3 years of continuous growth in methotrexate, generated cells containing stably amplified dihydrofolate reductase genes. These genes were present on one or more chromosomes, and they were retained in a stable state.     

Bivariate flow karyotyping of acute myelocytic leukemia in the BNML rat model

Univariate as well as bivariate flow karyotyping has been performed on chromosome suspensions obtained from the Brown Norway myelocytic leukemia (BNML), a rat model for human acute myelocytic leukemia (AML). Flow karyograms were obtained from both the in vivo transplantable parent line and from an in vitro established cell line. Density gradient centrifugation performed on cells arrested in mitosis resulted in an enrichment of mitotic cells. Furthermore, with this procedure leukemic and nonleukemic cells could be separated. Univariate analysis with propididum iodide (PI) as a DNA stain revealed the position of the several tumor-specific marker chromosomes in the in vitro cell line. Estimations of the peak position of the various chromosomes was done by comparing the univariate flow karyogram with a computer-simulated karyogram from the BNML that was derived from the mean length of the individual chromosomes in conventionally prepared metaphase slides. By comparing the bivariate flow karyogram of the in vivo BNML cells with the flow karyogram of normal BN cells, it was clearly demonstrated which peaks are involved in the altered chromosomal pattern of the BNML. No differences were found between the flow karyograms of the in vitro- and the ex vivo-derived chromosome suspensions in this rat leukemia model.     

Similarities between human ataxia fibroblasts and murine SCID cells: High sensitivity to γ rays and high frequency of methotrexate-induced DHFR gene amplification,but normal radiosensitivity to densely ionizing α particles

Two-ray hypersensitive cell lines, human ataxia telangiectasia (AT) and murine severe combined immune deficiency (SCID) cells, proved to be very competent in amplifying their dihydrofolate reductase (DHFR) gene under methotrexate selection stress. Over a period of months, methotrexate-resistant clones were obtained which were able to grow in progressively increasing methotrexate concentrations up to 1 mM. By then methotrexate-resistant AT and SCID cells had amplified their DHFR gene 6- and 30-fold, respectively, and showed very high DHFR mRNA expression. In contrast, related cells with normal radiosensitivity (human GM637 and mouse BALB/c fibroblasts) did not show DHFR gene amplification under comparable conditions. This correlation of the capacity of DHFR gene amplification and-ray hypersensitivity in AT and SCID cells suggests that gene amplification may have a mechanism(s) in common with those involved in repair of-radiation-induced damage. No difference in cell killing could be observed following exposure to densely ionizing particles: AT and SCID cells exhibited comparable survival rates to GM637 and BALB/c cells, respectively.     

Multicolor spectral karyotyping of rat chromosomes

Rat and mouse have become important animal models to study various human diseases such as cancer. Cytogenetic analysis of the respective karyotypes is frequently required to investigate the causative genetic defects and especially neoplastic cells often show complex chromosome aberrations and many different marker chromosomes. However, structural homogeneity of the chromosomes in these species as well as less pronounced differences in banding patterns make it difficult to assign genetic abnormalities to certain chromosomes by conventional banding techniques. Here we report for the first time the successful application of multicolor spectral karyotyping (SKY) to rat chromosomes, which allows unequivocal identification of all rat chromosomes with the exception of chromosomes 13 and 14 in different colors, thus enabling the elucidation of even complex rearrangements in the rat karyotype. Flow-sorted chromosome specific painting probes for all 22 rat chromosomes (20 autosomes, X, and Y) were combinatorially labeled by a set of five different fluorochromes and hybridized in situ to metaphase spreads of a healthy rat, to diakineses from testicular material, and to cells from a rat FAO hepatoma cell line. Measuring the complete spectrum at each image point by using the SpectraCube((R)) spectral imaging system and respective computer software allowed identification of the individual rat chromosomes by their specific emission spectra. Classification algorithms in the analysis software can then display the rat chromosomes in specific pseudo-colors and automatically order them in a karyotype table. After its successful application to human and mouse chromosomes, spectral karyotyping of rat chromosomes now also allows cytogenetic screening of the complete rat genome by a single hybridization.     

Unusual case of 18p- syndrome: diagnosis using a cloned DNA fragment

The patient with atypical clinic picture of 18p- syndrome is described. The in situ hybridization technique was used to localize chromosome 18-specific cloned sequence to metaphase chromosomes of the proband. The predominant hybridization was found in pericentromeric regions of homologous chromosome 18. The amount of pericentromeric DNA measured by in situ hybridization was different in homologous chromosomes and the number of radioactive grains was statistically greater in the normal chromosome 18 than in the chromosome 18p-. The cause of asymmetrical hybridization of probes to homologous chromosomes 18 is discussed. The results obtained indicate that this probe may be useful in clinical cytogenetics for identification of chromosome 19 in metaphase and interphase cells, determination of breakpoints or studies of pericentromeric DNA polymorphisms.     

Reverse chromosome painting for the identification of marker chromosomes and complex translocations in leukemia.

BACKGROUND: Chromosome banding techniques and in situ hybridization reveal the majority of chromosomal aberrations. However, difficulties remain in cases of highly contracted chromosomes, poor quality of the metaphases or the presence of markers with the involvement of several chromosomes. Here, it is demonstrated that reverse painting can be applied successfully starting with bone marrow cells from primary acute myelocytic leukemias (AML). METHODS: This was accomplished by culturing the leukemic cells with a cocktail of various growth factors, which yielded sufficient numbers of cells in cycle to harvest chromosomes for sorting. Aberrant chromosomes were flow-sorted and amplified by degenerate oligonucleotide-primed PCR. The resulting products were labeled by nick-translation and hybridized on normal metaphase spreads. RESULTS: Two patients with marker chromosomes in their leukemia cells were analyzed in detail. The hybridization pattern displayed the composition of the aberrant sorted chromosome. Results were compared with conventional cytogenetic analyses that were performed on material obtained from the same aspirate. The reverse-painting technique enabled identification of aberrations that were not detected by conventional cytogenetic analysis. CONCLUSIONS: Primary AML cells can be cultured in vitro, using optimal culture conditions, facilitating the production of high quality flow karyotypes, suitable for sorting of marker chromosomes to produce DOP-PCR derived chromosome painting probes for reverse painting. Valuable additional cytogenetic information can thus be obtained about complex chromosomal rearrangements or structural aberrations that could not be completely resolved by conventional cytogenetic analysis.