Anna Szeles

Horizontal transfer of oncogenes by uptake of apoptotic bodies

Tumor formation involves the accumulation of a series of genetic alterations that are required for malignant growth. In most malignancies, genetic changes can be observed at the chromosomal level as losses or gains of whole or large portions of chromosomes. Here we provide evidence that tumor DNA may be horizontally transferred by the uptake of apoptotic bodies. Phagocytosis of apoptotic bodies derived from H-rasV12- and human c-myc-transfected rat fibroblasts resulted in loss of contact inhibition in vitro and a tumorigenic phenotype in vivo. Fluorescence in situ hybridization analysis revealed the presence of rat chromosomes or of rat and mouse fusion chromosomes in the nuclei of the recipient murine cells. The transferred DNA was propagated, provided that the transferred DNA conferred a selective advantage to the cell and that the phagocytotic host cell was p53-negative. These results suggest that lateral transfer of DNA between eukaryotic cells may result in aneuploidy and the accumulation of genetic changes that are necessary for tumor formation.

De novo chromosome formations by large-scale amplification of the centromeric region of mouse chromosomes

Chromosomes formedde novo which originated from the centromeric region of mouse chromosome 7, have been analysed. These new chromosomes were formed by apparently similar large-scale amplification processes, and are organized into amplicons of ∼30 Mb. Centromeric satellite DNA was found to be the constant component of all amplicons. Satellite DNA sequences either bordered the large euchromatic amplicons (E-type amplification), or made up the bulk of the constitutive heterochromatic amplicons (H-type amplification). Detailed analysis of a heterochromatic megachromosome formedde novo by an H-type amplification revealed that it is composed of a tandem array of 10–12 large (∼30 Mb) amplicons each marked with integrated ‘foreign’ DNA sequences at both ends. Each amplicon is a giant palindrome, consisting of two inverted doublets of ∼7.5-Mb blocks of satellite DNA. Our results indicate that the building units of the pericentric heterochromatin of mouse chromosomes are ∼7.5-Mb blocks of satellite DNA flanked by nonsatellite sequences. We suggest that the formationde novo of various chromosome segments and chromosomes seen in different cell lines may be the result of large-scale E- and H-type amplification initiated in the pericentric region of chromosomes.

Stability of a functional murine satellite DNA-based artificial chromosome across mammalian species.

A 60-Mb murine chromosome consisting of murine pericentric satellite DNA and two bands of integrated marker and reporter genes has been generated de novo in a rodent/human hybrid cell line (mM2C1). This prototype mammalian artificial chromosome platform carries a normal centromere, and the expression of its β-galactosidase reporter gene has remained stable under selection for over 25 months. The novel chromosome was transferred by a modified microcell fusion method to mouse [L-M(TK−)], bovine (P46) and human (EJ30) cell lines. In all cases, the chromosome remained structurally and functionally intact under selection for periods exceeding 3 months from the time of transfer into the new host. In addition, the chromosome was retained in three first- generation tumours when L-M(TK−) cells containing the chromosome were xenografted in severe combined immunodeficiency mice. These data support that a murine satellite DNA-based artificial chromosome can be used as a functional mammalian artificial chromosome and can be maintained in vivo and in cells of heterologous species in vitro.

A 3p21.3 region is preferentially eliminated from human chromosome 3/mouse microcell hybrids during tumor growth in SCID mice

We have previously shown that four markers spanning the 3p24‐p21.3 region, THRB, AP20R, D3S1029, and D3S32, were regularly eliminated from three human chromosome 3 (chr3)/mouse microcell hybrids (MCHs) during tumor growth in SCID mice. In an attempt to narrow down the eliminated region, we have studied 22 new SCID mouse tumors derived from 5 MCH lines carrying human chr3. They were analyzed by fluorescence in situ hybridization (FISH), Southern blotting, and polymerase chain reaction (PCR). MCHs that carried human chr1, chr8, chr13, and chr17 were examined as controls. We could identify a common eliminated region (CER) at 3p21.3, bordered distally by D3S1260 and proximally by D3S643/D3F15S2. Eight of 53 chr3‐specific PCR markers, AP20R, D3S966, D3S3559, D3S1029, Wl‐7947, D3S2354, AFMb362wb9, and D3S32, were localized within the CER. This finding is consistent with the notion that a tumor suppressor gene may be located in this area, as suggested by frequent loss of heterozygosity (LOH) within this region observed in several types of solid tumors. Genes Chromosom. Cancer 18:200–211, 1997.

Evidence for a megareplicon covering megabases of centromeric chromosome segments.

We have analysed the replication of the heterochromatic megachromosome that was formedde novo by a large-scale amplification process initiated in the centromeric region of mouse chromosome 7. The megachromosome is organized into amplicons ∼30 Mb in size, and each amplicon consists of two large inverted repeats delimited by a primary replication initiation site. Our results suggest that these segments represent a higher order replication unit (megareplicon) of the centromeric region of mouse chromosomes. Analysis of the replication of the megareplicons indicates that the pericentric heterochromatin and the centromere of mouse chromosomes begin to replicate early, and that their replication continues through approximately three-quarters of the S-phase. We suggest that a replication-directed mechanism may account for the initiation of large-scale amplification in the centromeric regions of mouse chromosomes, and may also explain the formation of new, stable chromosome segments and chromosomes.

Human/mouse microcell hybrid based elimination test reduces the putative tumor suppressor region at 3p21.3 to 1.6 cM.

We have previously identified an approximately 7 cM long common eliminated region (CER), involving the 3p21.3 markers AP20R, D3S966, D3S3559, D3S1029, WI‐7947, D3S2354, AFMb362wb9, and D3S32, in human chromosome 3/A9 mouse fibrosarcoma microcell hybrid (MCH) derived SCID mouse tumors. We now report the results of our more detailed analysis on 24 SCID mouse tumors derived from two MCH lines that originally carried intact human chromosomes 3. They were analyzed by fluorescence in situ hybridization (FISH) painting and PCR, using 24 markers covering the region between D3S1611 and D3S1235 at 3p22‐p21.2. D3S32 and D3S2354 were regularly eliminated during in vivo tumor growth, whereas the other 22 markers, D3S1611, ACAA, D3S1260, WI‐692, AP20R, D3S3521, D3S966, D3S1029, D3S643, WI‐2420, MST1, GNAI2, D3S1235, D3S1298, GLB1, WI‐4193, D3S3658, D3S3559, D3S3678, WI‐6400, WI‐7947, and WI‐10865, were regularly retained. We have defined a common eliminated region of approximately 1.6 cM (designated as CER1) inside the 7 cM CER described earlier. CER1 is flanked distally by D3S1029 and proximally by D3S643. Genes Chromosomes Cancer 20:329–336, 1997.

Differential elimination of 3p and retention of 3q segments in human/mouse microcell hybrids during tumor growth

We have previously found that human chromosome 3 was fragmented in the course of in vivo tumor growth of monochromosomal human/mouse (A9 fibrosarcoma parent) microcell hybrids in SCID mice. Marker analysis of tumor cell lines has identified a regularly eliminated 7 cM segment on 3p21.3 referred to as the common eliminated region (CER). The same region is frequently affected by LOH in a variety of human carcinomas. The present study is a comparative chromosome painting, reverse painting, and PCR marker analysis of microcell hybrids (MCHs) that originally contained an intact chromosome 3 from two alternative donors, during and after four passages in SCID mice. We found regular elimination of 3p in parallel with preferential retention of 3q. In addition to CER on 3p, we can now define a common retained region (CRR) on 3q. It includes eight markers between D3S1282 (3q25‐q26) and D3S1265 (3q27‐qter) and spans approximately 43 cM. These observations are concordant with the frequent loss of corresponding 3p regions and the frequent retention, with occasional amplification, of 3q in several types of human tumors. Genes Chromosomes Cancer 20:224–233, 1997.

6;7 chromosomal translocation in spontaneously arising rat immunocytomas: evidence for c-myc breakpoint clustering and correlation between isotypic expression and the c-myc target.

Our previous studies have shown that spontaneously arising immunocytomas in the LOU/Ws1 strain of rats contain a t(6;7) chromosomal translocation in all seven tumors studied (F. M. Babonits, J. Spira, G. Klein, and H. Bazin, Int. J. Cancer 29:431-437, 1982). We have also shown that the c-myc is located on chromosome 7 (J. Sümegi, J. Spira, H. Bazin, J. Szpirer, G. Levan, and G. Klein, Nature (London) 306:497-499, 1983) and the immunoglobulin H cluster on chromosome 6 (W.S. Pear, G. Wahlström, J. Szpirer, G. Levan, G. Klein, and J. Sümegi, Immunogenetics 23:393-395, 1986). We now report a detailed cytogenetic and molecular analysis of nine additional rat immunocytomas. The t(6;7) chromosomal translocation is found in all tumors. Mapping of the c-myc breakpoints showed that in 10 of 14 tumors, the c-myc breakpoints are clustered in a 1.5-kilobase region upstream of exon 1. In contrast with sporadic Burkitts lymphoma and mouse plasmacytoma, only 1 of 14 tumors contains the c-myc breakpoints in either exon 1 or intron 1. Analysis of the sequences juxtaposed to the c-myc show that immunoglobulin H switch regions are the targets in at least five tumors and that there is a strong correlation between the secreted immunoglobulin and the c-myc target. Unlike sporadic Burkitts lymphoma and mouse plasmacytoma, at least two rat immunocytomas show recombination of the c-myc with sequences distinct from immunoglobulin switch regions.

A group of notI jumping and linking clones cover 2.5 Mb in the 3p21–p22 region suspected to contain a tumor suppressor gene

The chromosomal region 3p21.2-p22 has been shown to be involved in the development of several forms of solid tumors. Such deletions, translocations, and rearrangements presumably result in the disturbance or loss of a critical gene function. Pulsed-field gel electrophoresis (PFGE), using NotI linking clones as a probe represent a powerful tool for analyzing such rearrangements. A NotI linking clone, AP20 (D3S1641), was localized by in situ hybridization to 3p21.3-p22. Two NotI jumping clones adjacent to this clone were isolated, clone J32-612 covering 0.5 Mb and clone J31-611 covering approximately 1 Mb. Clone J31-611 crosses the border of the deletion present in hybrid cell line MCH939.2, which contains a deleted 3p21 region. For these jumping clones, corresponding NotI linking clones, NLJ3 (D3S1642) and NL3-003, were isolated. Altogether, linking and jumping clones from the AP20 locus hybridize to NotI fragments totaling 2.5 Mb in length. These NotI-containing clones detect expressed sequences in several human tissues. Clone NLJ3 possesses homology to the human platelet-derived endothelial cell growth factor gene and may represent a new member of this gene family. Another clone (AP20) revealed 66% sequence similarity to rat skeletal muscle voltage-sensitive sodium channel subtype 2. Therefore, this group of clones will be useful not only for analyzing rearrangements in tumors, but also for the isolation of new genes from the 3p21.3-p22 region.

B-CLL cells with unusual properties

In studies concerning the interaction of B‐CLL cells and Epstein‐Barr virus (EBV), we encountered one patient whose cells had several unusual properties. In addition to the B‐cell markers, the CLL cells expressed the exclusive T‐cell markers CD3 and CD8 and carried a translocation t(18,22)(q21;q11), involving the bcl‐2 and Igλ loci. The patient represents the 4th reported CLL case with this translocation. The CLL cells could be infected and immortalized by the indigenous and by the prototype B958 virus in vitro. The T‐cell markers were not detectable on the established lines. In all experiments the immortalized lines originated from the CLL cells. Their preferential emergence over virus‐infected normal B cells may be coupled to the high expression of the bcl‐2 gene due to the translocation. In spite of the sensitivity of CLL cells to EBV infection in vitro, no EBNA‐positive cells were detected in the ex vivo population. In vitro, we could generate cytotoxic function in T‐lymphocyte cultures which acted on autologous EBV‐infected CLL cells. Therefore we assume that if such cells emerged in vivo they were eliminated by the T‐cell response.