Amplified extrachromosomal elements containing c-Myc and Pvt 1 in a mouse plasmacytoma

Allele-specific loss or imbalance of chromosomes 9, 15, and 16 in B-cell tumors from interspecific F1 hybrid mice carrying Emu-c-myc or N-myc transgenes

Mice carrying an immunoglobulin enhancer (Emu-) linked c- or N-myc transgene develop fatal monoclonal or oligoclonal pre-B or B-cell lymphomas. This indicates that, beside the Emu-activated myc gene, additional genetic changes are required for tumor development. To trace these additional changes, we carried out a genome-wide search for loss of heterozygosity (LOH) and allelic imbalance (AI). This was done at 53 microsatellite markers in a panel of 34 lymphomas and four plasmacytomas from c- or N-myc transgene carrying (BALB/c x Mus spretus)F1 hybrids. An additional 43 lymphomas and three plasmacytomas from non-transgenic F1 mice were also investigated. Losses of one or more spretus-derived chromosome 9 markers were detected in 19 of 23 (83%) of the lymphomas, but in none of the four plasmacytomas that developed in N-myc F1 mice. No LOH-9 was found in any of the 11 lymphomas from Emu-c-myc F1 mice and only in 1 of 46 (2%) tumors derived from non-transgenic (BALB/c x spretus)F1 hybrid controls. These results suggest that a gene on spretus chromosome 9 confers resistance to the development of N-myc but not c-myc-induced lymphomas. AI of chromosome 15 markers (AI-15) was detected in 57 of 77 (74%) lymphomas and in 5 of 7 (72%) plasmacytomas, independently of the transgenic status and the mode of induction. All of the lymphomas and plasmacytomas with AI-15 revealed a relative gain of the spretus-derived D15Mit6 allele (located at 13.7 cM from the centromere), together with a gain of the BALB/c allele of the more distal (29.6 cM) D15Mit64 marker, suggesting somatic recombination. LOH in the region close to c-myc was detected in a proportion of tumors with AI-15. The observation of complex genetic alterations includes somatic recombination, AI and LOH involving chromosome 15 in tumors induced by a myc transgene. This indicates that at least two genes in addition to c-myc on this chromosome can be involved in lymphoma development.

Deregulated expression of c-Myc in a translocation-negative plasmacytoma on extrachromosomal elements that carry IgH and myc genes

The induced expression of c-Myc in plasmacytomas in BALB/c mice is regularly associated with nonrandom chromosomal translocations that juxtapose the c-myc gene to one of the Ig loci on chromosome 12 (IgH), 6 (IgK), or 16 (IgL). The DCPC21 plasmacytoma belongs to a small group of plasmacytomas that are unusual in that they appear to be translocation-negative. In this paper, we show the absence of any c-myc-activating chromosomal translocation for the DCPC21 by using fluorescent in situ hybridization, chromosome painting, and spectral karyotyping. We find that DCPC21 harbors c-myc and IgH genes on extrachromosomal elements (EEs) from which c-myc is transcribed, as shown by c-myc mRNA tracks and extrachromosomal gene transfer experiments. The transcriptional activity of these EEs is supported further by the presence of the transcription-associated phosphorylation of histone H3 (H3P) on the EEs. Thus, our data suggest that in this plasmacytoma, c-Myc expression is achieved by an alternative mechanism. The expression of the c-Myc oncoprotein is initiated outside the chromosomal locations of the c-myc gene, i.e., from EEs, which can be considered functional genetic units. Our data also imply that other "translocation-negative" experimental and human tumors with fusion transcripts or oncogenic activation may indeed carry translocation(s), however, in an extrachromosomal form.

Chromosomal and extrachromosomal instability of the cyclin D2 gene is induced by Myc overexpression

We examined the expression of cyclins D1, D2, D3, and E in mouse B-lymphocytic tumors. Cyclin D2 mRNA was consistently elevated in plasmacytomas, which characteristically contain Myc-activating chromosome translocations and constitutive c-Myc mRNA and protein expression. We examined the nature of cyclin D2 overexpression in plasmacytomas and other tumors. Human and mouse tumor cell lines that exhibited c-Myc dysregulation displayed instability of the cyclin D2 gene, detected by Southern blot, fluorescent in situ hybridization (FISH), and in extrachromosomal preparations (Hirt extracts). Cyclin D2 instability was not seen in cells with low levels of c-Myc protein. To unequivocally demonstrate a role of c-Myc in the instability of the cyclin D2 gene, a Myc-estrogen receptor chimera was activated in two mouse cell lines. After 3 to 4 days of Myc-ER activation, instability at the cyclin D2 locus was seen in the form of extrachromosomal elements, determined by FISH of metaphase and interphase nuclei and of purified extrachromosomal elements. At the same time points, Northern and Western blot analyses detected increased cyclin D2 mRNA and protein levels. These data suggest that Myc-induced genomic instability may contribute to neoplasia by increasing the levels of a cell cycle-regulating protein, cyclin D2, via intrachromosomal amplification of its gene or generation of extrachromosomal copies.

Amplification of the translocated c-myc genes in three Burkitt lymphoma cell lines

Translocations of the coding exons of the human c-myc gene are consistent features of human Burkitt lymphomas (BL). In the BL cell lines CA46, JD40, and ST486, the second and third c-myc exons have been translocated into the immunoglobulin heavy chain locus. In addition to this rearrangement, in all three cell lines, we have found that the translocated c-myc exons show low-level amplification relative to restriction fragments from the germ-line c-myc gene. The patterns of hybridization of an IgM switch region probe suggest that immunoglobulin heavy chain sequences have been co-amplified with the translocated c-myc sequences. Differential sedimentation was used to determine whether the amplified sequences reside in high-molecular-weight chromosomes or low-molecular-weight extrachromosomal DNA. In JD40 and ST486 cells, the amplified c-myc sequences were found on high-molecular-weight chromosomes ST486 cells also contained translocated C-myc sequences in low-molecular-weight, extrachromosomal DNA, as did CA46 cells. These conclusions were corroborated by fluorescence in-situ hybridization (FISH) of HeLa, CA46, ST486 and JD40 metaphase chromosomes. These results suggest that there is ongoing selection for cells containing amplified copies of the expressed c-myc sequences. and that there is continuous generation of extrachromosomal copies of the translocated c-myc sequences in ST486 and CA46 cells.

c-Myc dependent initiation of genomic instability during neoplastic transformation

The dihydrofolate reductase (DHFR) gene is a target of c-Myc in genomic instability. The induced overexpression of c-Myc in cell lines is followed by the amplification and rearrangement of the DHFR gene. Furthermore, the constitutive upregulation of c-Myc protein coincides with genomic instability of the DHFR gene in lymphoid, non-lymphoid and in tumor lines. The amplification of the DHFR gene is locus-specific and independent of species origins. We have now addressed the question whether inducible deregulation of c-Myc is followed by DHFR gene amplification in vivo. We show that the DHFR gene is a target of c-Myc-dependent neoplasia in vivo and propose a role for genomic instability during the initiation of neoplastic transformation.