A new chromosome type replacing the double minutes in a mouse tumor

Gene amplification in neoplasia: A cytogenetic survey of 80 131 cases

Gene amplification is a crucial process in cancer development, leading to the overexpression of oncogenes. It manifests cytogenetically as extrachromosomal double minutes (dmin), homogeneously staining regions (hsr), or ring chromosomes (r). This study investigates the prevalence and distribution of these amplification markers in a survey of 80 131 neoplasms spanning hematologic disorders, and benign and malignant solid tumors. The study reveals distinct variations in the frequency of dmin, hsr, and r among different tumor types. Rings were the most common (3.4%) sign of amplification, followed by dmin (1.3%), and hsr (0.8%). Rings were particularly frequent in malignant mesenchymal tumors, especially liposarcomas (47.5%) and osteosarcomas (23.4%), dmin were prevalent in neuroblastoma (30.9%) and pancreatic carcinoma (21.9%), and hsr frequencies were highest in head and neck carcinoma (14.0%) and neuroblastoma (9.0%). Combining all three amplification markers (dmin/hsr/r), malignant solid tumors consistently exhibited higher frequencies than hematologic disorders and benign solid tumors. The structural characteristics of these amplification markers and their potential role in tumorigenesis and tumor progression highlight the complex interplay between cancer-initiating gene-level alterations, for example, fusion genes, and subsequent amplification dynamics. Further research integrating cytogenetic and molecular approaches is warranted to better understand the underlying mechanisms of these amplifications, in particular, the enigmatic question of why certain malignancies display certain types of amplification. Comparing the present results with molecular genetic data proved challenging because of the diversity in definitions of amplification across studies. This study underscores the need for standardized definitions in future work.

Life of double minutes: generation, maintenance, and elimination

Advances in genome sequencing have revealed a type of extrachromosomal DNA, historically named double minutes (also referred to as ecDNA), to be common in a wide range of cancer types, but not in healthy tissues. These cancer-associated circular DNA molecules contain one or a few genes that are amplified when double minutes accumulate. Double minutes harbor oncogenes or drug resistance genes that contribute to tumor aggressiveness through copy number amplification in combination with favorable epigenetic properties. Unequal distribution of double minutes over daughter cells contributes to intratumoral heterogeneity, thereby increasing tumor adaptability. In this review, we discuss various models delineating the mechanism of generation of double minutes. Furthermore, we highlight how double minutes are maintained, how they evolve, and discuss possible mechanisms driving their elimination.

The architecture and evolution of cancer neochromosomes

We isolated and analyzed, at single-nucleotide resolution, cancer-associated neochromosomes from well- and/or dedifferentiated liposarcomas. Neochromosomes, which can exceed 600 Mb in size, initially arise as circular structures following chromothripsis involving chromosome 12. The core of the neochromosome is amplified, rearranged, and corroded through hundreds of breakage-fusion-bridge cycles. Under selective pressure, amplified oncogenes are overexpressed, while coamplified passenger genes may be silenced epigenetically. New material may be captured during punctuated chromothriptic events. Centromeric corrosion leads to crisis, which is resolved through neocentromere formation or native centromere capture. Finally, amplification terminates, and the neochromosome core is stabilized in linear form by telomere capture. This study investigates the dynamic mutational processes underlying the life history of a special form of cancer mutation.

MYCN gene amplification. Identification of cell populations containing double minutes and homogeneously staining regions in neuroblastoma tumors

Neuroblastoma is the second most common solid tumor occurring in children. Amplification of the MYCN oncogene is associated with poor prognosis. To identify neuroblastoma tumors with MYCN amplification, we studied the number of copies of MYCN in interphase cells by fluorescence in situ hybridization in 20 neuroblastoma patients. MYCN amplification appeared in 7 tumor specimens. Interphase and metaphase studies showed a tumor cell population with both forms of amplification, double minutes and homogeneously staining regions, in two patients. These patients showed a smaller tumor cell subpopulation with the presence of more than one homogeneously staining region, suggesting that gene amplification was undergoing karyotype evolution.

Use of hydroxyurea to alter drug resistance of human tumor cells

Tumor cell resistance to cancer chemotherapeutic agents is a well-recognized problem for clinicians. Efforts are being made to develop agents that are not affected by cross-resistance to other drugs, as observed with the mdr phenotype. Other efforts are focused on reversing drug resistance to enhance chemotherapeutic intervention. Gene amplification accounts for one mechanism through which tumor cells develop drug resistance. Since amplified genes may be unstable, the elimination of these genes is likely to be a promising new target for cancer chemotherapy. The use of HU at low concentrations either to reestablish tumor sensitivity to chemotherapeutic agents or to decrease tumorigenicity, accomplished by the reduction of oncogene copy number, continues to be investigated. Studies thus far all report similar effects of noncytotoxic concentrations of HU on unstably amplified genes (EC DNA elimination), regardless of what gene is harbored on the EC DNA. The next essential step in the evaluation of HU-induced EC DNA elimination is to study the phenomena in vivo. In spite of extensive tissue distribution, HU appears to have pharmacokinetic properties, due to its short half-life, that may limit investigators' ability to study its use in prototype animal tumor models such as the nude mouse. In contrast, HU's half-life in humans (3.5 to 4.5 hours) [122] is comparatively longer, and therefore clinical trials may prove less troublesome.

Recombination between separate MYC amplification structures in COLO320 cells

Cytogenetically visible gene amplification structures can consist of arrays of amplicons presumably formed by secondary "rearrangements" following amplicon formation. The structural evolution of gene amplification sites in tumor cells suggests that complex secondary structures may have some selective advantage in the tumor cell environment. Although secondary amplicon rearrangements are a hallmark of the gene amplification process, little is known about the mechanics of this process. COLO320 neuroendocrine tumor cells carry two different types of amplified MYC oncogene sequences, one type with an intact MYC gene and the other with a rearranged "chimeric" MYC gene. We have studied various clonal subpopulations of COLO320 cells and identified regions within and downstream of the MYC locus that are unique to each amplicon type. Using double-label fluorescence in situ hybridization with DNA probes unique to each amplicon type, we have observed that both chromosomal and extrachromosomal MYC amplicon arrays in COLO320 cells frequently consist of heterogeneous mixtures of each MYC amplicon type. Our results suggest that the two MYC amplicon types of COLO320 cells were formed simultaneously but independently, and that double minute chromosomes observed in COLO320 cells were formed by intermolecular homologous recombination secondary to amplicon formation.

Double minute chromosomes and a homogeneously staining chromosome region in C3H10T1/2 murine cells transformed "in vitro" by proton radiation

Four foci (type II or type III) of transformed cells, isolated from the murine line C3H10T1/2 after exposure to proton radiations, were expanded and cytogenetically examined. While the overall numerical chromosome distributions were similar, there were some differences between the various cell lines with regard to the presence and frequency of specific-marker chromosomes and to the colony-forming efficiency in soft-agarose medium. No association between any of these markers and the transformed phenotype could be established. However, in the line F4, derived from a type II focus, numerous double-minute chromosomes (DM) were observed after passage 22, and the phenomenon became more pronounced in the subclone C2. The finding of DMs in radiation-transformed cells is unusual. The DMs were observed in long-term subcultures, and in one of them they were partially replaced by a homogeneously staining chromosome region (HSR). DNAs from transformed cells of the line F4 and subclone C2 was digested with restriction enzymes and analyzed by Southern blotting with probes for seven oncogenes commonly amplified in cancer cells (c-myc, N-myc, N-ras, Ki-ras, Ha-ras, c-myb, c-abl) and with probes for the mouse MHC class I region. None of the regions tested was structurally altered or amplified in these transformed cells. The origin of the genetic material carried by DMs or homogeneously staining intrachromosomal regions (HSR) in cells of the line F4 and subclone C2, where it is believed to provide a selective advantage for in vitro growth, remains unknown.

Double minutes arise from circular extrachromosomal DNA intermediates which integrate into chromosomal sites in human HL-60 leukemia cells

Amplification of oncogenes has been found to be an important prognostic factor in behavior of patients' malignancies. In this study we have used new gel electrophoresis techniques to follow the location of amplified c-myc oncogene sequences in HL-60 promyelocytic leukemia cells. In passages 46-62 of the cells, the cells contain amplified c-myc sequences on submicroscopic circular extrachromosomal DNA (episomes). With increased passages in culture (passages 63-72) the cells lose the episome c-myc sequences with a shift of those sequences to double minutes. With additional passage in culture, the c-myc shifts from the double minutes to a chromosomal site der(5)t(5;17)(q11.2;q?11.2). Concomitant with the shift of the c-myc sequences into the chromosomal compartment is a phenotypic change of a shortened cell-doubling time. These studies provide the first molecular evidence of a progression from a submicroscopic location for amplified oncogene sequences to a chromosomal location for the amplified sequences. This molecularly documented model can now be used to test various strategies to prevent incorporation of extrachromosomally located oncogene sequences into chromosomal sites. Prevention of integration of the oncogene sequences into chromosomal sites could modulate progression of patients' tumors.

Cytogenetic findings in a primary malignant fibrous histiocytoma of bone and the lung metastasis

Cytogenetic studies were performed on a malignant fibrous histiocytoma of bone and its metastasis to lung. Numerical chromosome abnormalities were described for all chromosomes except chromosomes 2, 4 and 16. Structural abnormalities in the primary tumor involved chromosomes 1, 3, 5, 10, 11, 13, 15, 16 and 17. The chromosomal rearrangements seen both in the primary tumor and its metastasis involved chromosomes 13, 15 and 17. Two X chromosomes contained large homogeneously staining regions (HSRs) in the primary tumor which were replaced by multiple double minutes (DMs) in the metastatic tumor.

Involvement of unstable chromosomal regions containing C-heterochromatin and fragile sites in the integration of amplified dhfr domains

A 10(-3) M methotrexate (MTX)-resistant variant (H2), selected from the murine fibrosarcoma line B77-3T3/AA12, was characterized after 5 (H2 MTXRes I) and 9 (H2 MTXRes II) months of in vitro propagation in the presence of the drug. Southern blot hybridization of wild-type and H2 MTXRes DNAs confirmed amplification of the dhfr gene without apparent rearrangements in its structure. Cytogenetic analysis revealed that double minutes (DMs) predominated in H2 MTXRes I, whereas homogeneously staining regions (HSRs) were the main feature of H2 MTXRes II cells. HSRs, shown to contain dhfr sequences by in situ chromosome hybridization, were localized within two rearranged chromosomes, designated as m1 and m2 because of their derivation from the marker chromosome m of AA12 cells. This chromosome, characterized by two interstitial C bands adjacent to two nonstaining gaps, was no longer observed in H2 MTXRes II cells. A role for nonrandom involvement of chromosome m in the integration of amplified DNA is suggested by the finding of another HSR-chromosome, m3, derived from m, in an independent MTXRes clone (B1). Rearrangement in one of the unstable C-band/gap regions of chromosome m is proposed as the unifying mechanism that may account for the outcome of the three HSR chromosomes observed.

Analysis of the replication mode of double minutes using the PCC technique combined with BrdUrd labeling

A cultured line of neuroblastoma cells (NB) was found to contain double minute chromosomes (DMs) DMs have been reported to be acentric and, therefore, to be segregated randomly into daughter cells without separating their sister elements. When NB cells were fused with Chinese hamster metaphase cells, prematurely condensed chromosomes (PCCs) were induced. DMs seen together with G2 PCCs appeared to be closely paired, dot-like structures resembling DMs observable in metaphase cells. In contrast, DMs in G1 cells showed a tendency to become single as the stage progressed so that the majority of DMs in late G1 cells were actually no longer double. DMs in S-phase cells, however, again appeared double. These results clearly indicate why DMs are invariably double and never assume a quadruple configuration in metaphase cells in spite of their non-disjunctional segregation at anaphase. Such a characteristic mode of DM replication was further confirmed by a 5-bromo-2'-deoxyuridine (BrdUrd) labeling experiment: when NB cells were exposed to BrdUrd for two successive rounds of DNA replication prior to PCC induction, half of the resulting single G1 minutes as well as G1 PCCs stained dark and the other half stained light after staining for sister chromatid differentiation.

Formation of double minutes by breakdown of a homogeneously staining region in a refractory anemia with excess blasts

A patient suffering from refractory anemia with excess blasts in transformation had four different bone marrow karyotypes. These were 46,XY; 45,X,-Y; 45,X,-Y, 5q-,19q+; and 43,X,-Y,-9,-17,5q-,+dmin. The most plausible explanation for this is proposed to be formation of a homogeneously staining region on chromosome #19, followed by its breakdown into double minutes.

Unstable and stable CAD gene amplification: importance of flanking sequences and nuclear environment in gene amplification

We analyzed the amplification of the CAD gene in independently isolated N-(phosphonacetyl)-L-aspartate-resistant clones derived from single parental clones in two mouse cell lines. We report for the first time that the CAD gene is amplified unstably in mouse cells, that the degree of instability varies greatly between clones, and that minute chromosomes and highly unstable chromosomelike structures contain the amplified sequences. These data are most consistent with the idea that the amplified unit in each clone consists of different flanking DNA and that such differences engender amplified sequences with unequal stability. We also introduced the mouse chromosome containing the CAD gene into hamster cells by microcell-mediated chromosome transfer to determine whether the propensity for unstable extrachromosomal amplification of the mouse CAD gene would prevail in the hamster cell nuclear environment. We report that the mouse CAD gene was amplified stably in expanded chromosomal regions in each of seven hybrids that were analyzed. This observation is consistent with the idea that the nuclear environment influences whether mutants containing intra- or extrachromosomally amplified sequences will be isolated.

Rings and double minutes in a case with blastic phase of chronic myelocytic leukemia

The patient studied was a 33-year-old female in the blastic phase of chronic myelocytic leukemia resistant to busulfan. The results of cytogenetic studies of bone marrow cells were as follows: The abnormal chromosomes were double Ph1, +19, +6, +B, ring D, double ring D, double minutes (DM) of various sizes, etc. The mean number of DM per cell was increased in 4-day culture compared with that in 1-day culture.

Double minutes and other chromosomal aberrations in malignant cell line of Shionogi carcinoma 115

G-banded karyotypes and structural abnormalities of chromosomes are described in two clones of the mouse mammary carcinoma SC 115 cell line. The cells showed multiple numerical and structural abnormalities. Structural anomalies, such as double minutes, acentric fragments, gaps or breaks, radials, ring chromosomes, endoreduplications, dicentrics, and elongated chromosomes were observed in varying proportions. Unstable chromosomal aberrations, such as breaks, gaps, fragments, and radials, frequently appeared without any particular pretreatment. Increased numbers of double minutes per cell correlated positively with the presence of elongated chromosomes, which did not contain homogeneously staining regions by the G-band technique.

Unstable and stable CAD gene amplification: importance of flanking sequences and nuclear environment in gene amplification

We analyzed the amplification of the CAD gene in independently isolated N-(phosphonacetyl)-L-aspartate-resistant clones derived from single parental clones in two mouse cell lines. We report for the first time that the CAD gene is amplified unstably in mouse cells, that the degree of instability varies greatly between clones, and that minute chromosomes and highly unstable chromosomelike structures contain the amplified sequences. These data are most consistent with the idea that the amplified unit in each clone consists of different flanking DNA and that such differences engender amplified sequences with unequal stability. We also introduced the mouse chromosome containing the CAD gene into hamster cells by microcell-mediated chromosome transfer to determine whether the propensity for unstable extrachromosomal amplification of the mouse CAD gene would prevail in the hamster cell nuclear environment. We report that the mouse CAD gene was amplified stably in expanded chromosomal regions in each of seven hybrids that were analyzed. This observation is consistent with the idea that the nuclear environment influences whether mutants containing intra- or extrachromosomally amplified sequences will be isolated.

Cloning of a non-c-myc DNA fragment from the double minutes of a human colon carcinoid cell line

The cell line COLO 320 DM, derived from an untreated human colon carcinoid tumor, was subcloned to obtain a population (Cl 11) with an average of 37 double minutes (DM) per cell. Fractionation of the chromosomes by differential centrifugation yielded a fraction enriched in DM. DNA isolated from the DM-enriched fraction was inserted into the Pst I site of pBR322. One clone, p446, representative of a number of similar clones, contained a region complementary to genomic unique sequences (region p446U). Southern blot analysis using COLO 320 DNA, and DNA from two other cell lines derived from the same biopsy, COLO 320 HSR and COLO 321 HSR, demonstrated amplification and rearrangement of sequences complementary to p446U when compared with 28 different tumor and normal cell lines, some of which contained DM or homogeneously staining regions (HSR). COLO 320 DM Cl 11 had approximately 110 copies per cell of the p446U sequence, or three copies per DM. COLO 320 HSR, which contained one HSR, had 35 copies per cell, while COLO 321 HSR, which contained two HSR, had 700 copies. In addition, p446U did not hybridize with insert sequences of recombinant plasmid pHM(E + H), which includes the human c-myc coding region, 3 kb of upstream flanking sequences and 0.5 kb of downstream flanking sequences, or with an exon 3 probe, pMYC RI-CLA. Amplification of p446U was also not seen in cell lines containing amplified c-myc or N-myc genes. These results indicate that more than one sequence may be amplified in DM or HSR containing tumor cells, but that they need not be amplified together in other tumors.

Expression of phenotypic traits following modulation of colchicine resistance in J774.2 cells

Development of resistance to colchicine in the mouse macrophage-like cell line J774.2 coincides with the expression of a variety of phenotypic traits. A cloned subline (J7/CLC-20), maintained in 20 microM colchicine, exhibits reduced steady-state association with drug, increased presence of a 140,000-145,000 dalton (140-145 kD) phosphoglycoprotein associated with the plasma membrane, double minute chromosomes and cross-resistance to other drugs. While similar phenotypic traits are observed in J774.2 cells resistant to taxol and vinblastine, differences in the electrophoretic mobilities of the resistance-specific glycoproteins in each of the three sublines suggest that multi-drug resistant sublines exhibit specificity for individual drugs. In an attempt to elucidate the relationships between the phenotypic traits associated with colchicine resistance, the degree of colchicine resistance in J7/CLC-20 cells was modulated and the levels of expression of the phenotypic traits were quantitated. In the absence of colchicine in the growth medium, J7/CLC-20 cells reverted to drug sensitivity within 35 days. A decrease in the level of resistance coincided with coordinate changes in both the quantity of the resistance-specific glycoprotein and the average number of double minute chromosomes. We propose that the emergence and disappearance of the resistance-specific glycoprotein and double minute chromosomes may be closely linked. However, J7/CLC-20 cells which had regained their drug sensitivity after growth in drug-free medium maintained a reduced level of steady-state drug association. The persistence of reduced drug association in cells that have reverted to a drug-sensitive state suggests that this phenomenon, although related to colchicine resistance, need not be the primary or only mechanism of drug resistance.

Patterns of BrdU incorporation in homogeneously staining regions and double minutes

The replication chronology of two structural chromosome abnormalities linked to the amplification phenomenon of DNA sequences was investigated. Three cell lines containing homogeneously staining region (HSR) chromosomes (IMR-32, MK42, and COLO-320) and one line with double minutes (DM) (SW-613) were examined. Using a bromodeoxyuridine-Hoechst 33258-Giemsa method, the HSR in the three cell lines were shown to be composed of subunits that replicated their DNA throughout all portions of the S-phase of the cell cycle. The double minute chromosomes were observed to replicate randomly throughout the entire S-phase, with no pattern evident. These results are consistent with the suggestion that DNA from HSR and DM are structurally and functionally related. Moreover, this observation that these amplified regions replicate their DNA throughout the entire S-phase favors the idea that, during amplification processes, both early and late replicating sequences are included. The apparent discordance between staining characteristics and replication behavior exhibited by some HSR and DM are also discussed.

Homogeneously staining regions (HSRs) of a rat hepatoma cell line are not early replicating

The rat hepatoma cell line H4-IIE-C3 (H4) has homogeneously staining regions (HSRs) which contain multiple, tandemly repeated copies of ribosomal RNA (rRNA) genes. We determined the time of replication of the DNA within these HSRs autoradiographically after incorporation of [3H]thymidine and by Hoechst 33258 and Giemsa staining after 5-bromodeoxyuridine (5-BrdU) incorporation. The DNA within the H4 HSRs is not early replicating, unlike that in other HSRs. It begins replicating later than much of the other nuclear DNA, continues replicating throughout most of the S phase, and is completed 1-2 h before mitosis.

Double minutes in the HeLa cell line

Metaphase preparations of three sublines of the HeLa line showed the presence of double minutes (DM) in varying frequencies. In two sublines (S3 and TCH-3753), the size of the DM was variable, whereas in the Fe-1000 subline, they were uniform. Giemsa banding preparations revealed typical HeLa marker chromosomes in all sublines.

Regular pattern of karyotypic alterations accompanying gene amplification in Djungarian hamster cells: study of colchicine, adriablastin, and methotrexate resistance

Chromosomal analysis of 26 Djungarian hamster cell lines obtained from 11 independent clones and possessing different levels of resistance to colchicine or adriablastin as a consequence of gene amplification revealed regular patterns in the karyotypic changes that accompanied the development of drug resistance. Usually the sequence of karyotypic changes was as follows: first an additional chromosome 4 appeared: then single unpaired small chromatin bodies (SCBs) arose; later in the middle part of the long arm of one of three chromosomes 4 long homogeneously staining regions (HSRs) and double minute chromosomes (DMs) were formed; and finally in the most resistant variants large clusters of SCBs appeared. The emergence of the clusters of the SCBs correlated well with the occurrence of autonomously replicating, amplified DNA sequences. In contrast to DNA of the HSRs the DNA of the SCBs could replicate outside the S-phase of the cell cycle. When kept in a non-selective medium, the cells gradually lost their resistance to colchicine: 1%-4% of the cells lost the capacity to form colonies in the selective medium independently of the pattern of location in them of amplified genes (in chromosomal HSRs. SCBs, or DMs). Loss of drug resistance was accompanied by disappearance of the chromosomal HSRs, SCBs, and DMs. Chromosomal analysis of the set of methotrexate-resistant Djungarian hamster cell lines indicated the following karyotypic evolution: first the additional material on the distal part of one of two chromosomes 3 appeared; then the light HSRs were formed on the distal part of one of two chromosomes 4; later clusters of SCBs and HSRs arose on the distal part of the short arm of chromosome 3. Probably the amplification of different genes is characterized by specific patterns of karyotypic alterations.

Incidence of double minutes, cytogenetic equivalents of gene amplification, in human carcinoma cells

Screening of the occurrence of double minutes (DM) was performed in more than 1,000 metaphases obtained from a total of 22 solid human breast tumours and more than 3,600 metaphases from a total of 55 malignant effusions (45 patients with different types of carcinomas). DM were observed in 15 of these breast tumor cases and in 34 of the effusions (obtained from 29 cancer patients). The percentage of cells exhibiting DM as well as the number of DM per respective cell varied widely. It could be seen that metastatic cells from malignant effusions exhibited on the average more DM per cell than did cells of primary breast carcinomas. Differences in the incidence of DM could be observed between different carcinomas as well as between different age groups. In addition, it did not appear that DM could be induced by mutagenic tumor therapy. DM are thus not a rare finding in human solid tumors but, as cytogenetic equivalents of gene amplification, they rather represent a fundamental biological characteristic of tumor development.

Karyotype analysis of carcinogen-treated Chinese hamster cells in vitro evolving from a normal to a malignant phenotype

The relationship of cytogenetic changes with the acquisition of an indefinite life span in vitro, the ability of cells to grow in soft agar and their tumourigenicity in syngeneic animals has been studied in control, trans-7,8-dihydrodiolbenzo(a)pyrene and 7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydrobenzo(a)-pyrene-treated secondary cultures derived from Chinese hamster embryonic lung. Karyotype analysis revealed a sequence of chromosome changes as the cells progressed through culture. Aneuploidy, namely trisomy of chromosome 4, the long arm in particular, was an early dominant change. The possible association of this trisomy with the acquisition of immortality in vitro is implicated, although the involvement of other nonrandom chromosome changes cannot be eliminated, implying that there may be several genomic sites in the Chinese hamster which may potentially be involved with the acquisition of unlimited growth potential. Neither the ability of cells to grow in soft agar nor as tumours could be associated with any specific chromosome(s). Double minutes were observed in metaphases from the cell lines, agar colonies and tumours; their possible relationship with growth advantage is discussed.

Gene amplification in a mouse embryo? Double minutes in cell lines independently derived from a Mus musculus X M. caroli fetus

Double minutes (DM) were found to be present in six of seven clones derived from a 16-day female Mus musculus X M. caroli fetus. The DM-positive clones derived from three primary populations independently set up from the fetus, and included clones with an active M. caroli X chromosome as well as clones with an active M. musculus X. The simplest explanation of these findings is that DM were already present in cells of the M. musculus X M. caroli embryo at the time of X chromosome inactivation and persisted during in vivo development and in vitro culture. This suggests that gene amplification occurred in the early embryo, or even the fertilized egg, perhaps because of interactions between components of germ cells contributed by the M. musculus and M. caroli parents. Alternatively, induction may have occurred independently in these lines, requiring that amplification is an unusually common occurrence in cells from interspecific hybrids.

Somatic cell fusion as a source of genetic rearrangement leading to metastatic variants

Tumor cell populations displaying metastatic properties often have higher gene dosage than their less malignant progenitor tumors, as shown by increased ploidy levels, chromosome duplication and gene amplification. The acquisition by tumor cells of high chromosome numbers may be due to endoreduplication or somatic hybridization either between tumor cells or between tumor and host cells. All such mechanisms increase genetic variability and instability in tumor cells since they trigger a polyploidization-segregation cycle. Among the wide variety of segregants which may emerge from high-ploidy cells, variants with increased malignancy can be positively selected in vivo. Evidence for in vivo fusion of tumor and normal host cells has been reported in different tumor systems. However the attainment by tumor-host hybrids of a higher degree of malignancy has only been observed following substantial chromosome segregation. The involvement of a cell of bone marrow origin as preferential host partner in the fusion process has been proved both by studies on tumor-host hybrids in bone marrow radiation chimeras and in vitro hybridization experiments between non-metastatic tumors and normal lymphoreticular cells which have led to the establishment of metastatic variants. Several different segregational mechanisms may bring about homozygosity or hemizygosity of recessive alleles in tumor-host hybrids, leading to their expression. The marked chromosome dynamics of tumor-host hybrids are also responsible for extensive chromosome rearrangements. At the molecular level these may represent mechanisms causing altered oncogene activity. The activation of new oncogenes by transposition or amplification as well as the amplification of previously activated oncogenes are the mechanisms most likely to be responsible for transition from low to high malignancy, occurring through ploidy changes, such as those produced by somatic mating.

Association of amplified oncogene c-myc with an abnormally banded chromosome 8 in a human leukaemia cell line

Several unusual chromosome structures have been described in drug-resistant cell lines and in certain tumours. These structures include elongated homogeneously staining regions (HSRs), small extrachromosomal paired chromatin bodies (double minutes, DMs) and abnormally banded regions (ABRs) with strong but anomalous band patterns. There is evidence that these are alternative forms of gene amplification, with HSRs breaking down to form DMs, and DMs integrating into the chromosome to generate HSRs and ABRs. Recently, it was demonstrated that, compared with several normal and leukaemia human cells, DNA sequences representing the human homologue of the onc gene of the avian myelocytomatosis virus (MC29), the so-called c-myc gene, were amplified in HL-60 cells. This is a human promyelocytic leukaemia cell line established in the laboratory of one of us (R.C.G.) at the National Cancer Institute (Bethesda, Maryland) in 1977, and widely used for studies on myeloid and monocytic differentiation. Amplification of the gene was present in primary leukaemic cells of the patient, and DMs were noted in some of these cells as well as in early passages of the HL-60 line. No structure resembling HSRs or ABRs were noted in karyotypic studies at this early stage and there were no alterations involving the long arm of chromosome 8 (8q), to which the c-myc gene has recently been mapped. We have now re-examined the karyotype of the HL-60 line, using cells frozen at various times during its continuous passage at the Wistar Institute (Philadelphia, Pennsylvania) to look for chromosomal abnormalities that might be associated with the amplification of c-myc. We find that, beginning in 1979, HL-60 cells at the Wistar Institute no longer had DMs, but did show an abnormal 8q+ chromosome, replacing a normal chromosome 8, and representing an ABR reflecting the site of myc gene amplification.

A preliminary model of double-minute-mediated gene amplification

A mathematical model of double minute (dm) population dynamics has been developed based upon current concepts of the saltatory replication, random partitioning, nuclear exclusion and loss, and cellular growth inhibition of these extrachromosomal elements. A highly accurate approximate analytical solution has been obtained for the dm frequency distribution at steady state and preliminary analysis of transient states has been performed. The steady state solution has been fit to experimental frequency data of the SW527N carcinoma line, the excellent goodness of fit (X2 = 2.6, d.f. = 29) providing preliminary evidence for the consistency of this set of mechanisms. Two special cases are examined in which extrareplicative dms are produced on both the chromosome and existing dms at equal rates or on the chromosome alone. The model predicts that the population--average rate of extrareplicative dm production is 0.039 +/- S.E. 0.009 dms/hr/cell in the first case and is tenfold higher than when such replication occurs on the chromosome alone (0.0043 +/- S.E. 0.0004 dms/hr/cell). Allowable ranges of the extent of dm-related growth inhibition and dm loss are determined for the SW527N cell line. It is found that dm-related growth inhibition can be nearly as high as that observed for the S180 sarcoma lines (on the order of 0.5% per dm lengthening of the doubling time) or as low as zero.

Double minutes in mouse neuroblastoma cells and their hybrids

Cytogenetic studies were carried out on three clones of mouse neuroblastoma cells and six interspecific hybrid cells derived from the mouse neuroblastoma cells with either rat glioma cells and liver cells or Chinese hamster brain cells. The hybrid cells possessed characteristic karyotypes with marker chromosomes originating from the neuroblastoma cells. The parental chromosome constitution in the hybrid cells was clone-specific, even in the clones derived from the same parental cells. Double minutes (DMs) were demonstrated in the neuroblastoma cells and in all the hybrid cells studied. In addition other chromosome aberrations, such as microchromosomes and chromosome pulverization, were also observed in these cells. DMs varied in number and morphology among the cells. The number of DMs per cell correlated positively with the level of ploidy and with the karyological constitution contributed by the parental neuroblastoma cells. The results indicate that DMs have a chromosome nature and that the DMs of neuroblastoma chromosomes were transferred into the hybrid cells.

On the possibility of metabolic control of replicon "misfiring": relationship to emergence of malignant phenotypes in mammalian cell lineages

Constraints of a multireplicon chromosomal organization and of the necessity to maintain constant gene dosages demand that each origin of replication in a eukaryotic cell "fire" (initiate replication) only once per cell cycle. The central idea of this work is that a low probability of an extra ("illegitimate") round of DNA replication (called below "replicon misfiring") within any given chromosomal domain could be increased by certain substances of either intra- or extracellular origin. The term " "firone" is proposed for such a substance. It is shown that existence of firones could greatly speed up evolution of cellular systems under selection pressure, a developing tumor being one example of such a system. Experimentally testable predictions of the firone hypothesis are discussed.

Stability of C-banded and C-bandless microchromosomes in clonal sublines of the RVP3 mouse tumor grown serially in vivo

Karylogic studies were performed on three monocellular clones derived from mouse RVP3 cells, which had been originally transformed with the Prague strain of Rous sarcoma virus. All clones that had originally contained a stable number of microchromosomes, continues to retain them after prolonged passage in vivo. Centromeric heterochromatin was absent in 32% of the microchromosomes as revealed by C-banding technique. The stability of microchromosomes either positive or negative for centromeric heterochromatin is discussed in relation to double-minute chromatin bodies found in early passages of RVP3 tumor cells.

Chromosome studies in mycosis fungoides

G-banded chromosome analysis was performed on peripheral blood lymphocytes after phytohaemagglutinin stimulation from sixteen patients with mycosis fungoides. A number of chromosome abnormalities were observed in a low proportion of blood lymphocytes in seven patients in later stages of the disease. In four patients similar marker chromosomes in multiple copies were present, some of them without a clearly visible centromere. We conclude that a correlation exists between the presence of chromosome abnormalities in circulating blood lymphocytes and the course of the disease.

Ultrastructure of double minutes from a human tumor cell line

Double minutes (dm) have been isolated from human tumor cells by zonal centrifugation and by differential pelleting of chromosome suspsension. These methods allowed collection of dm in sufficient quantity and purity for visualization with electron microscopy. Ultrastructurally, the chromatin fibers in dm resemble thrance fragments was found. When the two isolation protocols were compared, differential pelleting was shown to increase purity twofold to 85% dm by mass. The differential pelleting procedure enables easy collection of dm in sufficient quantity and purity for chemical analysis.