The Mlvi-1 locus involved in the induction of rat T-cell lymphomas and the pvt-1/Mis-1 locus are identical

The 8q24 gene desert: an oasis of non-coding transcriptional activity

Understanding the functional effects of the wide-range of aberrant genetic characteristics associated with the human chromosome 8q24 region in cancer remains daunting due to the complexity of the locus. The most logical target for study remains the MYC proto-oncogene, a prominent resident of 8q24 that was first identified more than a quarter of a century ago. However, many of the amplifications, translocation breakpoints, and viral integration sites associated with 8q24 are often found throughout regions surrounding large expanses of the MYC locus that include other transcripts. In addition, chr.8q24 is host to a number of single nucleotide polymorphisms associated with cancer risk. Yet, the lack of a direct correlation between cancer risk alleles and MYC expression has also raised the possibility that MYC is not always the target of these genetic associations. The 8q24 region has been described as a "gene desert" because of the paucity of functionally annotated genes located within this region. Here we review the evidence for the role of other loci within the 8q24 region, most of which are non-coding transcripts, either in concert with MYC or independent of MYC, as possible candidate gene targets in malignancy.

Evolutionarily new sequences expressed in tumors

Background

Earlier we suggested the concept of the positive evolutionary role of tumors. According to this concept, tumors provide conditions for the expression of evolutionarily new and/or sleeping genes in their cells. Thus, tumors are considered as evolutionary proving ground or reservoir of expression. To support this concept we have previously characterized in silico and experimentally a new class of human tumor-related transcribed sequences.

Results

In this article we describe results of further studies of previously described tumor-related sequences. The results of molecular phylogeny studies, Southern hybridization experiments and computational comparison with genomes of other species are presented.

Conclusion

These results suggest that these previously described tumor-related human transcripts are also relatively evolutionarily new.

The c-myc locus is a common integration site in type B retrovirus-induced T-cell lymphomas

Type B leukemogenic virus (TBLV) induces rapidly appearing T-cell leukemias. TBLV insertions near the c-myc gene were detectable in 2 of 30 tumors tested, whereas 80% of the tumors showed c-myc overexpression. TBLV insertions on chromosome 15 (including a newly identified locus, Pad7) may cause c-myc overexpression by cis-acting effects at a distance.

The activated Mlvi-4 locus in Moloney murine leukemia virus-induced rat T-cell lymphomas encodes an env/Mlvi-4 fusion protein

A genomic DNA probe derived from the region immediately 3' of the clusters of integrated proviruses in the Mlvi-4 locus detects a 5.5-kb mRNA transcript which is specifically expressed in normal rat thymus and spleen. The same probe detects two tumor-specific mRNA transcripts 2.5 and 10 kb long, both of which are expressed only in tumors carrying a provirus in the Mlvi-4 locus. Sequence analysis of two cDNA clones (LE3a and B1.1) of the 2.5-kb tumor-specific mRNA, obtained from two independent tumors (6889 and B1), revealed that they are both derived from hybrid env/Mlvi-4 mRNA transcripts. The splicing of env to Mlvi-4 sequences linked a cryptic splice donor site at nucleotide position 6397 of the viral genome with a splice acceptor site in the region immediately 3' of the integrated provirus. The mRNA that gives rise to cDNA clone B1.1 terminates 1,005 bases 3' of the splice acceptor site without additional splicing. The mRNA that gives rise to cDNA clone LE3a terminates in the same site but undergoes differential splicing of an 81-base-long intron. The resulting mRNAs contain 247-amino-acid (clone B1.1) or 226-amino-acid (clone LE3a) open reading frames sharing 221 N-terminal amino acids, of which 207 are derived from the viral env gene and 14 are derived from Mlvi-4. RNase protection assays using 6889 tumor cell RNA and a probe derived from the cDNA clone LE3a detected both mRNA transcripts. More abundant of the two, however, was the one encoding the putative 247-amino-acid protein. Transient transfections of a construct expressing the RNA transcript defined by clone B1.1 into D17 cells led to the expression of an Env/Mlvi-4 fusion protein with an apparent molecular mass of 33 kDa. Given that cells with provirus insertions in the Mlvi-4 locus are selected and that retroviral env gene products may have profound effects in the biology of hematopoietic cells, we suggest that the detected fusion proteins may contribute to the growth of T-cell lymphomas.

Evidence for long-range oncogene activation by hepadnavirus insertion

Insertional mutagenesis of host genes, a common oncogenic strategy of slow transforming retroviruses, has recently been described for a DNA virus of the hepadnavirus group: the woodchuck hepatitis virus. This virus causes insertional activation of myc genes, mainly the intronless N-myc2 oncogene, in > 50% of woodchuck liver tumours. In most remaining tumours, N-myc2 is overexpressed without any apparent genetic alteration. To elucidate the role of the virus in such cases, we have cloned and analysed single integration sites in four woodchuck tumours carrying wild-type myc alleles. All sites were clustered within < 20 kb in a single locus, in which scarce unique sequences showed no detectable transcriptional activity. By fluorescent in situ hybridization, N-myc2 and the new locus (win) were localized to the same region of the long arm of the woodchuck X chromosome, and a 150-180 kb intervening distance was deduced from pulse-field gel analysis. The detection of viral integrations in win in additional tumours that produced abundant N-myc2 transcripts further substantiates the link between these two loci in woodchuck tumorigenesis. We propose that efficient activation of the N-myc2 promoter by the hepadnavirus enhancer acting over a long distance might operate in liver cell transformation.

The Myb and Ahi-1 genes are physically very closely linked on mouse chromosome 10

Ahi-1 has previously been identified as a common helper provirus integration site on mouse Chromosome (Chr) 10 in 16% of Abelson pre-B-cell lymphomas and shown to be closely linked to the Myb protooncogene. By using long-range restriction mapping, we have mapped the Myb and Ahi-1 regions within a 120-kbp DNA fragment. The Ahi-1 region is located approximately 35 kbp downstream of the Myb gene. A further confirmation of this finding was obtained by screening a mouse YAC library. The three positive clones obtained contained both the Myb and Ahi-1 gene sequences. To test whether provirus integration in the Ahi-1 region enhances the expression of Myb by a cis-acting mechanism, we have also examined Myb gene expression in A-MuLV-induced pre-B-lymphomas. Our data have revealed that there is no clear evidence for such activation in the tumors we have tested, indicating that provirus insertion in the Ahi-1 region is activating a novel gene, apparently involved in tumor formation.

Variant translocations in two Burkitt's lymphoma cell lines are located in the MLV14 locus

The human MLV14 locus, located 20 kilobases 3' of MYC, is rearranged in two Burkitt's lymphoma cell lines with either a t(2;8)(p12;q24) or t(8;22)(q24;q11). Alterations of MLV14 may have prognostic significance in some types of B-cell malignancies.

Insertional mutagenesis of flvi-2 in tumors induced by infection with LC-FeLV, a myc-containing strain of feline leukemia virus

LC-FeLV is a myc-containing strain of feline leukemia virus (FeLV) which exhibits only partial transforming activity in vitro and in vivo. LC-FeLV infection in kittens may induce, but does not necessarily induce, thymic lymphosarcoma in viremic animals after a short latency. These observations suggest that infection with LC-FeLV is not sufficient to induce complete transformation and that another genetic event(s) is required. One possibility for such an event is that the integrating provirus acts as an insertional mutagen and thereby disrupts the structure or function of another proto-oncogene. Using a strategy of transposon tagging, this possibility was examined in eight feline T-cell lymphosarcomas, including four induced by experimental infection with LC-FeLV, three induced by natural infection with FeLV, and one FeLV-negative tumor. The analysis demonstrated one locus, termed flvi-2, to be structurally altered in six of the tumors examined, including three induced by LC-FeLV and three in which no activated myc oncogene is apparent. Inverse polymerase chain reaction was used to demonstrate the presence and transcriptional orientation of proviruses integrated at flvi-2 in five of these tumors. The flvi-2 locus does not hybridize to cloned probes representing 21 previously identified proto-oncogenes or common domains of retroviral integration. Thus, the data suggest that interruption of the flvi-2 locus cooperates with the myc oncogene in the induction of T-cell lymphomas by LC-FeLV; indeed, the observations indicate that the insertional mutagenesis of flvi-2 plays a role in T-cell lymphomagenesis even in the absence of feline v-myc.

The gene map of the Norway rat (Rattus norvegicus) and comparative mapping with mouse and man

The current status of the rat gene map is presented. Mapping information is now available for a total of 214 loci and the number of mapped genes is increasing steadily. The corresponding number of loci quoted at HGM10 was 128. Genes have been assigned to 20 of the 22 chromosomes in the rat. Some aspects of comparative mapping with mouse and man are also discussed. It was found that there is a good correlation between the morphological homologies detectable in rat and mouse chromosomes, on the one hand, and homology at the gene level on the other. For 10 rat synteny groups all the genes so far mapped are syntenic also in the mouse. For the remaining rat synteny groups it appears that the majority of the genes will be syntenic on specific (homologous) mouse chromosomes, with only a few genes dispersed to other members of the mouse karyotype. Furthermore, the data indicate that mouse chromosome 1 genetically corresponds to two rat chromosomes, viz., 9 and 13, equalizing the difference in chromosome number between the two species. Further mappings will show whether the genetic homology will prove to be as extensive as these preliminary results indicate. As might be expected from evolutionary considerations, rat synteny groups are much more dispersed in the human genome. It is clear, however, that many groups of genes have remained syntenic during the period since man and rat shared a common ancestor. One further point was noted. In two cases groups of genes were syntenic in the mouse but dispersed to two chromosomes in rat and man, whereas in a third case a group of genes was syntenic in the rat but dispersed to two chromosomes in mouse and man. This finding argues in favor of the notion that the original gene groups were on separate ancestral chromosomes, which have fused in one rodent species but remained separate in the other and in man.

Retroviral insertions 90 kilobases proximal to the Evi-1 myeloid transforming gene activate transcription from the normal promoter

The inappropriate production of the Evi-1 zinc finger protein occurs in retrovirus-induced murine myeloid leukemias and human acute myelogenous leukemias. In murine leukemias, expression of the Evi-1 gene is associated with retroviral insertions either in the Evi-1 locus, which is immediately 5' of the coding region of the gene, or in the genetically linked Cb-1/fim-3 locus. In these studies, we demonstrate by chromosomal walking and pulse field electrophoresis that the Cb-1/fim-3 locus is located 90 kb 5' of the Evi-1 locus. Primary structure analysis of Evi-1 cDNA clones from a Cb-1/fim-3 rearranged cell line (DA-3) demonstrates that transcription initiates 5' of the Evi-1 locus and that the first noncoding exon of the gene is 681 bp larger than previously defined. S1 nuclease protection studies reveal multiple transcription initiation sites within this region. Comparable transcriptional initiation sites were identified in RNA from kidney and ovary, in which the gene is normally expressed, suggesting that retroviral insertions in the Cb-1/fim-3 locus activate transcription from the normal promoter. In one myeloid cell line (DA-3), a single long terminal repeat (LTR) is present in the Cb-1/fim-3 locus. No stable transcripts were detectable from this LTR. In cells with retroviral insertions in the Cb-1/fim-3 locus, one allele of the Evi-1 locus becomes hypermethylated in the 5' region of the gene. Together, these results are most consistent with an LTR-mediated, long-range cis activation of Evi-1 gene expression.

Retroviral insertions 90 kilobases proximal to the Evi-1 myeloid transforming gene activate transcription from the normal promoter

The inappropriate production of the Evi-1 zinc finger protein occurs in retrovirus-induced murine myeloid leukemias and human acute myelogenous leukemias. In murine leukemias, expression of the Evi-1 gene is associated with retroviral insertions either in the Evi-1 locus, which is immediately 5' of the coding region of the gene, or in the genetically linked Cb-1/fim-3 locus. In these studies, we demonstrate by chromosomal walking and pulse field electrophoresis that the Cb-1/fim-3 locus is located 90 kb 5' of the Evi-1 locus. Primary structure analysis of Evi-1 cDNA clones from a Cb-1/fim-3 rearranged cell line (DA-3) demonstrates that transcription initiates 5' of the Evi-1 locus and that the first noncoding exon of the gene is 681 bp larger than previously defined. S1 nuclease protection studies reveal multiple transcription initiation sites within this region. Comparable transcriptional initiation sites were identified in RNA from kidney and ovary, in which the gene is normally expressed, suggesting that retroviral insertions in the Cb-1/fim-3 locus activate transcription from the normal promoter. In one myeloid cell line (DA-3), a single long terminal repeat (LTR) is present in the Cb-1/fim-3 locus. No stable transcripts were detectable from this LTR. In cells with retroviral insertions in the Cb-1/fim-3 locus, one allele of the Evi-1 locus becomes hypermethylated in the 5' region of the gene. Together, these results are most consistent with an LTR-mediated, long-range cis activation of Evi-1 gene expression.

Identification of a common viral integration region in Cas-Br-E murine leukemia virus-induced non-T-, non-B-cell lymphomas

The Cas-Br-E murine leukemia virus is a nondefective retrovirus that induces non-T-, non-B-cell lymphomas in susceptible NIH/Swiss mice. By using a DNA probe derived from Cas-Br-E provirus-flanking sequences, we identified a DNA region, originally called Sic-1, rearranged in 16 of 24 tumors analyzed (67%). All proviruses were integrated in a DNA segment smaller than 100 bp and were in the same 5'-to-3' orientation. Ecotropic as well as mink cell focus-forming virus types were found integrated in that specific DNA region. On the basis of Southern blot analysis of somatic cell hybrids and progeny of an interspecies backcross, the Sic-1 region was localized on mouse chromosome 9 near the previously described proto-oncogenes or common viral integration sites: Ets-1, Cbl-2, Tpl-1, and Fli-1. Restriction map analysis shows that this region is identical to the Fli-1 locus identified in Friend murine leukemia virus-induced erythroleukemia cell lines and thus may contain sequences also responsible for the development of mouse non-T-, non-B-cell lymphomas.

Pvt-1 transcripts are found in normal tissues and are altered by reciprocal(6;15) translocations in mouse plasmacytomas

The mouse Pvt-1 (for plasmacytoma variant translocation) region maps to a chromosome 15 breakpoint region that is frequently interrupted by "variant" reciprocal chromosome translocations, rcpt(6;15), in plasmacytomas. This region lies several hundred kilobases (kb) 3' of the mouse c-myc gene (Myc) which is deregulated in both rcpt(6;15) and rcpt(12;15) plasmacytomas. rcpt(12;15) translocations apparently activate c-myc directly by interrupting the gene itself, but the mechanism causing c-myc deregulation in tumors bearing rcpt(6;15) translocations remains unknown. The indirect activation of c-myc by Pvt-1 interruption has remained an appealing possibility, but heretofore it has not been possible to establish such a connection. Furthermore, no genes from the Pvt-1 locus have been shown to be transcribed in normal tissues or in tumors with rcpt(6;15) translocations. We report the isolation of a cDNA clone, Pvt-1-1, from mouse spleen mRNA that is specific to the Pvt-1 region. This cDNA probe detects low levels of large (ca. 14 kb) RNA transcripts in normal mouse tissues. In plasmacytomas with rcpt(6;15) translocations, the Pvt-1 transcripts are elevated in abundance and truncated in size. Both changes are apparently induced by the chromosomal translocation. Expression of 14-kb Pvt-1 RNA is elevated in B-cell tumor lines that express immunoglobulin light chain genes; thus, we postulate that these translocations are facilitated by the increased DNA accessibility of immunoglobulin kappa light chain and Pvt-1 genes when they are simultaneously expressed at certain times during B-cell ontogeny.

flvi-1, a common integration domain of feline leukemia virus in naturally occurring lymphomas of a particular type

A locus in feline DNA, termed flvi-1, which may play an important role in the natural induction of lymphomas by feline leukemia virus (FeLV) was identified. Examination of a bank of 21 naturally occurring FeLV-positive feline lymphomas revealed that FeLV proviral integration occurs at flvi-1 in four independent tumors (19%). Independent integrations occurred within a 2.4-kilobase region of flvi-1, the probability of which by random chance can be estimated as 10(-16). Several lines of evidence, including sequence analysis of the long terminal repeat, demonstrated that proviruses integrated at flvi-1 are exogenously acquired and are oriented in the same transcriptional direction with respect to the locus. Molecularly cloned flvi-1 did not hybridize with probes representing several previously described proviral integration domains or with probes representing 10 oncogenes. The natural feline lymphomas examined in this study were heterogeneous with respect to tissue of origin, cell type, and number of monoclonal proviral integrations. The four tumors in which flvi-1 is interrupted were classified as members of a phenotypic subgroup containing seven lymphomas, i.e., at least four (57%) of seven lymphomas of this type contained FeLV proviral integration at flvi-1. Members of this phenotypic subgroup are non-T-cell lymphomas isolated from the spleen and contain an average of three proviruses, compared with an average of eight among all of the tumors examined. The small number of proviral integrations in tumors of this subgroup suggests that an early proviral integration event into flvi-1 can induce malignant change.

Activation of multiple genes by provirus integration in the Mlvi-4 locus in T-cell lymphomas induced by Moloney murine leukemia virus

Moloney murine leukemia virus-induced rat T-cell lymphomas harbor proviruses integrated near c-myc and near Mlvi-1/Mis-1/Pvt-1, another locus of common integration which maps 270 kilobases 3' of c-myc. In this report, we present the characterization of a new locus of common integration in Moloney murine leukemia virus-induced T-cell lymphomas (Mlvi-4) which maps 30 kilobases 3' of c-myc, between c-myc and Mlvi-1. The Mlvi-4 locus, whose chromosomal map location is conserved in rats, mice, and humans, is also the target of chromosomal rearrangements in a variety of animal and human tumors. Evidence presented elsewhere shows that provirus integration in Mlvi-4 enhances the expression of c-myc and Mlvi-1 by cis-acting mechanisms operating over long distances of genomic DNA. In this manuscript, we show that provirus integration in the Mlvi-4 locus activates, by promoter insertion, one additional gene which maps immediately 3' to the cluster of the Mlvi-4 proviruses and which is transcribed in the same orientation as c-myc, giving rise to 3- and 10-kilobase mRNA transcripts. The Mlvi-4 gene is also expressed in normal thymus and spleen at very low levels, giving rise to 3- and 5.5-kilobase messages. Although Mlvi-4 is expressed in normal thymus, it is not expressed in Moloney murine leukemia virus-induced T-cell lymphomas corresponding to several stages of T-cell differentiation, but lacking a provirus in this locus. This suggests that Mlvi-4 may be expressed only in a subpopulation of T cells. We conclude that provirus insertion in Mlvi-4 activates c-myc and two additional genes, Mlvi-1 and Mlvi-4, whose expression is restricted to, and may be developmentally regulated in, T cells. Since Mlvi-4 is the target of genetic changes in a great variety of human and animal neoplasms, these results are critical for our understanding of oncogenesis.

Differences in c-myc and pvt-1 amplification in SEWA sarcoma sublines selected for adherent or non-adherent growth

Conversion of solid sarcomas and carcinomas into ascites tumors depends on the in vivo selection of phenotypically altered tumor cell variants that can grow in the dissociated form. Once selected, they retain this property even after prolonged s.c. growth as solid tumors. From an s.c.-passaged subline of an ascites-converted murine sarcoma (SEWA-AS12), we were able to separate cells adapted to the ascites form of growth from cells that can only grow in the solid form on the basis of their differential adherence to plastic. Both c-myc and pvt-1 were amplified approximately 63- to 77-fold in the nonadherent subline (SEWA-AS12-NA), but only 5- to 8-fold in the adherent subline (SEWA-AS12-ADH). This suggests that c-myc and/or pvt-1 amplification may provide a selective advantage to cells that can grow in the dissociated form.

Long-distance activation of the Myc protooncogene by provirus insertion in Mlvi-1 or Mlvi-4 in rat T-cell lymphomas

T-cell lymphomas induced by Moloney murine leukemia virus frequently have proviruses integrated at the Mlvi-4 and Mlvi-1 loci, which map approximately 30 and 270 kilobases 3' of the promoter region of the Myc protooncogene, respectively. Provirus insertion in these loci is responsible for the activation of adjacent genes. To determine whether Myc expression was also affected by these provirus insertions, we constructed T-cell hybrids between two rat thymic lymphomas containing a provirus in Mlvi-4 or Mlvi-1 and the murine T-cell lymphoma line BW5147. These hybrids segregated the provirus-containing rearranged alleles from the normal nonrearranged alleles of Mlvi-4 and Mlvi-1, and they carried an intact copy of rat Myc. Using an S1 nuclease protection assay, we observed that the expression of the rat Myc cosegregated with the rearranged Mlvi-4 or Mlvi-1 locus. However, provirus insertion in these loci had no effect on promoter utilization or on the expression of the murine Myc locus. We conclude that provirus insertion exerts a long-range cis effect on the expression of Myc. Therefore, provirus integration in a single locus may affect the expression of multiple genes, some of which may be located a long distance from the site of integration.

Activation of the Mlvi-1/mis1/pvt-1 locus in Moloney murine leukemia virus-induced T-cell lymphomas

The Mlvi-1/mis-1/pvt-1 locus, located approximately 270 kilobase pairs 3' of the c-myc protooncogene, was originally discovered as a common region of provirus integration in Moloney murine leukemia virus-induced rat T-cell lymphomas. The same locus was shown subsequently to be coamplified with c-myc and to be involved in chromosomal translocations in a variety of human and animal neoplasms. Provirus integration in Mlvi-1 in Moloney murine leukemia virus-induced rat T-cell lymphomas activates the c-myc protooncogene. The studies reported here were aimed to determine whether, in addition to the activation of c-myc, provirus integration affected the expression of other neighboring genes. Provirus integration was shown to occur in three clusters separated by regions of uninterrupted DNA. The proviruses in all three clusters had integrated in a single-transcriptional orientation, and they appeared intact. Systematic hybridization of Mlvi-1 clones to rat, mouse, and human genomic DNA revealed three patches of evolutionarily conserved sequences. Two of them were mapped in regions targeted by the provirus, and the third was mapped immediately 5' to the provirus clusters. A probe derived from the conserved sequences 5' of the integrated proviruses detected a tumor-specific RNA transcript in tumors carrying a provirus in Mlvi-1 or in the neighboring Mlvi-4 and c-myc loci. The highest level of RNA transcript expression, however, was seen in a CD4+ CD8+ tumor cell line that was not carrying a provirus in this region. We conclude that provirus insertion in this region activates both c-myc and another gene that is located in the immediate vicinity of the integrated Mlvi-1 proviruses and may be developmentally regulated in T cells.