Transcription of three c-myc exons is enhanced in chicken bursal lymphoma cell lines

Regulation of RelB expression during the initiation of dendritic cell differentiation

The transcription factor RelB is required for proper development and function of dendritic cells (DCs), and its expression is upregulated early during differentiation from a variety of progenitors. We explored this mechanism of upregulation in the KG1 cell line model of a DC progenitor and in the differentiation-resistant KG1a subline. RelB expression is relatively higher in untreated KG1a cells but is upregulated only during differentiation of KG1 by an early enhancement of transcriptional elongation, followed by an increase in transcription initiation. Restoration of protein kinase CbetaII (PKCbetaII) expression in KG1a cells allows them to differentiate into DCs. We show that PKCbetaII also downregulated constitutive expression of NF-kappaB in KG1a-transfected cells and restores the upregulation of RelB during differentiation by increased transcriptional initiation and elongation. The two mechanisms are independent and sensitive to PKC signaling levels. Conversely, RelB upregulation was inhibited in primary human monocytes where PKCbetaII expression was knocked down by small interfering RNA targeting. Altogether, the data show that RelB expression during DC differentiation is controlled by PKCbetaII-mediated regulation of transcriptional initiation and elongation.

Transforming ability of Gag-Myc fusion proteins correlates with Gag-Myc protein stability and transcriptional repression

Avian retroviruses that have transduced c-myc are useful tools to study the conditions necessary for cellular transformation. FH3, one such retrovirus which encodes a Gag-Myc fusion protein, is not transforming in quail embryonic fibroblasts, but a late variant of FH3 that arose after passaging FH3-infected cells is transforming. Mutational analysis of FH3 revealed that the presence of a portion of the retroviral protease in FH3 inhibited transformation and that this inhibition was transferable to a more highly transforming retrovirus, MC29. Transforming and non-transforming FH3-derived and MC29-derived Gag-Myc proteins were used to further explore characteristics of Myc necessary for transformation. Gag-Myc proteins which were transforming were found to be the most stable in the cell. To distinguish whether transactivation and/or repression is correlated to transformation, the various Gag-Myc fusion proteins were tested for their ability to activate or repress c-Myc targets. Results indicated that a correlation exists between transforming Gag-Myc proteins and their ability to repress, whereas all Gag-Myc proteins could transactivate, regardless of their ability to transform. Taken together, these results suggest that protein stabilization of Myc and repression of target genes by Myc are important for cellular transformation.

The MYC dualism in growth and death

Over-expression of the transcription factor c-Myc immortalizes primary cells and transforms in co-operation with activated ras. Therefore, c-myc is considered a proto-oncogene. Since its discovery c-Myc has been shown to render cells growth factor independent, accelerates passage through G1 of the cell cycle, inhibits differentiation and elicits apoptosis. Whereas the effects on immortalization, proliferation and inhibition of differentiation are in conceivable accordance with gain of function, as it is defined for a proto-oncogene, its pro-apoptotic activity disables a straight forward explanation of the physiological role of c-Myc and suggests a highly complex contribution during development. The recent accomplishments in c-Myc research shed some light on the difficile regulatory network which keeps check on c-Myc activity such as by binding to proteins some of which are transcription factors for non-c-Myc targets. Moreover, it was shown that genes are targeted by c-Myc depending on the sequence of flanking regions adjacent to the E-box or in dependence on the availability of binding partners which is most probably specific to the cellular context. Cdc25A and ornithine decarboxylase, both described to be c-Myc targets, have been brought forward as downstream effectors in the induction of proliferation under serum rich conditions, or in the induction of apoptosis when serum factors are limited. These genes seem to be regulated by c-Myc in a cell type-specific manner. H-ferritin, IRP2 and telomerase are the most recently discovered direct targets of c-Myc. The regulation of H-ferritin and IRP2 might explain the potential of c-Myc to promote proliferation and the regulation of telomerase could be responsible for the immortalizing properties of c-Myc. In the future, H-ferritin and telomerase have to be analyzed whether or not these genes are also Myc targets in other cell systems. Although the intense research efforts regarding the function of c-Myc last already two decades the role of this gene is still enigmatic.

Resistance to avian leukosis virus lymphomagenesis occurs subsequent to proviral c-myc integration

Most chicken strains are highly susceptible to avian leukosis virus (ALV) induction of bursal lymphoma, involving proviral integration within the c-myc proto-oncogene, while certain strains are genetically resistant to lymphomagenesis. A nested PCR assay was developed to analyse the appearance of proviral c-myc integrations after ALV infection of lymphoma-susceptible birds, and to determine whether these integrations arise in lymphoma-resistant birds. Proviral c-myc integrations are detected in bursa and other tissues from 6 day-old lymphoma-susceptible birds infected as embryos. The abundance of bursal cells carrying these integrations increases roughly 40-fold by 35 days of age, indicating that these cells hyperproliferate within the bursal environment. Bursal cells with proviral c-myc integrations also arise soon after infection of lymphoma-resistant embryos. However, these cells expand much more slowly than cells from lymphoma-susceptible birds. Both strains show the same rate of viral infection, so that resistance to lymphomagenesis occurs at a step subsequent to proviral c-myc integration. Proviral c-erbB gene integrations arise at the same frequency in bursa and other tissues of both strains, and they do not increase in abundance during development. These findings indicate that the mechanism of resistance to lymphomagenesis involves specific inhibition of cells with proviral c-myc integrations within the bursa.

Differential selection of cells with proviral c-myc and c-erbB integrations after avian leukosis virus infection

Avian leukosis virus (ALV) infection induces bursal lymphomas in chickens after proviral integration within the c-myc proto-oncogene and induces erythroblastosis after integration within the c-erbB proto-oncogene. A nested PCR assay was used to analyze the appearance of these integrations at an early stage of tumor induction after infection of embryos. Five to eight distinct proviral c-myc integration events were amplified from bursas of infected 35-day-old birds, in good agreement with the number of transformed bursal follicles arising with these integrations. Cells containing these integrations are remarkably common, with an estimated 1 in 350 bursal cells having proviral c-myc integrations. These integrations were clustered within the 3' half of c-myc intron 1, in a pattern similar to that observed in bursal lymphomas. Bone marrow and spleen showed a similar number and pattern of integrations clustered within 3' c-myc intron 1, indicating that this region is a common integration target whether or not that tissue undergoes tumor induction. While all tissues showed equivalent levels of viral infection, cells with c-myc integrations were much more abundant in the bursa than in other tissues, indicating that cells with proviral c-myc integrations are preferentially expanded within the bursal environment. Proviral integration within the c-erbB gene was also analyzed, to detect clustered c-erbB intron 14 integrations associated with erythroblastosis. Proviral c-erbB integrations were equally abundant in the bone marrow, spleen, and bursa. These integrations were randomly situated upstream of c-erbB exon 15, indicating that cells carrying 3' intron 14 integrations must be selected during induction of erythroblastosis.

A conditional self-inactivating retrovirus vector that uses a tetracycline-responsive expression system

We developed a novel conditional self-inactivating (C-SIN) vector, TL-SN, by replacement of the enhancer-promoter of the 3' long terminal repeat of Moloney murine leukemia virus with a synthetic tetracycline operator-cytomegalovirus promoter (tetP) from the tetracycline-responsive expression system (TRES). The other component of the TRES, a chimeric transactivator (tTA), was stably incorporated into PA317 amphotropic packaging cells, thus generating the packaging cell line PA317-tTA. C-SIN amphotropic G418-resistant virus particles were generated with a titer of 2 x 10(5) CFU/ml within 2 days of transinfection of PA317-tTA cells with TL-SN ecotropic virus particles. This titer was approximately 2 log units higher than that obtained by transinfection of parental PA317 cells and was due to the high level of viral transcripts originating from the tetP promoter at the 5' end of the transduced vector in the presence of tTA. Our C-SIN vector has the potential for use in human gene therapy since it incorporates the advantages of previous SIN vectors in having weak tetP promoter activity (in the absence of tTA in target cells) while at the same time achieving high viral titers with PA317-tTA packaging cells.

Improved self-inactivating retroviral vectors derived from spleen necrosis virus

Self-inactivating (SIN) retroviral vectors contain a deletion spanning most of the right long terminal repeat's (LTR's) U3 region. Reverse transcription copies this deletion to both LTRs. As a result, there is no transcription from the 5' LTR, preventing further replication. Many previously developed SIN vectors, however, had reduced titers or were genetically unstable. Earlier, we reported that certain SIN vectors derived from spleen necrosis virus (SNV) experienced reconstitution of the U3-deleted LTR at high frequencies. This reconstitution occurred on the DNA level and appeared to be dependent on defined vector sequences. To study this phenomenon in more detail, we developed an almost completely U3-free retroviral vector. The promoter and enhancer of the left LTR were replaced with those of the cytomegalovirus immediate-early genes. This promoter swap did not impair the level of transcription or alter its start site. Our data indicate that SNV contains a strong initiator which resembles that of human immunodeficiency virus. We show that the vectors replicate with efficiencies similar to those of vectors possessing two wild-type LTRs. U3-deleted vectors carrying the hygromycin B phosphotransferase gene did not observably undergo LTR reconstitution, even when replicated in helper cells containing SNV-LTR sequences. However, vectors carrying the neomycin resistance gene did undergo LTR reconstitution with the use of homologous helper cell LTR sequences as template. This supports our earlier finding that sequences within the neomycin resistance gene can trigger recombination.

Lymphoma models for B cell activation and tolerance. X. Anti-mu-mediated growth arrest and apoptosis of murine B cell lymphomas is prevented by the stabilization of myc

Treatment of the WEHI-2131 or CH31 B cell lymphomas with anti-mu or transforming growth factor (TGF)-beta leads to growth inhibition and subsequent cell death via apoptosis. Since anti-mu stimulates a transient increase in c-myc and c-fos transcription in these lymphomas, we examined the role of these proteins in growth regulation using antisense oligonucleotides. Herein, we demonstrate that antisense oligonucleotides for c-myc prevent both anti-mu- and TGF-beta-mediated growth inhibition in the CH31 and WEHI-231 B cell lymphomas, whereas antisense c-fos has no effect. Furthermore, antisense c-myc promotes the appearance of phosphorylated retinoblastoma protein in the presence of anti-mu and prevents the progression to apoptosis as measured by propidium iodide staining. Northern and Western analyses show that c-myc message and the levels of multiple myc proteins were maintained in the presence of antisense c-myc, results indicating that myc species are critical for the continuation of proliferation and the prevention of apoptosis. These data implicate c-myc in the negative signaling pathway of both TGF-beta and anti-mu.

A model system for nonhomologous recombination between retroviral and cellular RNA

A current model for the generation of transforming retroviruses proposes that read-through RNAs, containing both viral and cellular sequences, are copackaged with viral genomic RNA. It is, however, possible that a cellular mRNA is occasionally encapsidated into a retroviral particle, even though viral packaging sequences are absent. We have generated recombinant proviruses following copackaging of an avian leukosis viral genomic RNA and a neo-containing RNA completely devoid of retroviral sequences. In these studies, we used the packaging cell line SE21Q1b, which has the unique ability to randomly package cellular mRNA into retroviral particles. We describe 10 recombinants obtained following copackaging of nonhomologous RNAs. Our data show that recombination is not occurring at the DNA level in the parental SE21Q1b cells but is occurring at the RNA level, during reverse transcription. These data further suggest that reverse transcriptase can preferentially jump between templates at short stretches of homology in otherwise unrelated RNAs. We conclude that retroviral sequences are not required for packaged mRNA to be reverse transcribed and to be included in integrated proviruses.

Overproduction of v-Myc in the nucleus and its excess over Max are not required for avian fibroblast transformation

The cellular proto-oncogene c-myc can acquire transforming potential by a number of different means, including retroviral transduction. The transduced allele generally contains point mutations relative to c-myc and is overexpressed in infected cells, usually as a v-Gag-Myc fusion protein. Upon synthesis, v-Gag-Myc enters the nucleus, forms complexes with its heterodimeric partner Max, and in this complex binds to DNA in a sequence-specific manner. To delineate the role for each of these events in fibroblast transformation, we introduced several mutations into the myc gene of the avian retrovirus MC29. We observed that Gag-Myc with a mutated nuclear localization signal is confined predominantly in the cytoplasm and only about 5% of the protein could be detected in the nucleus (less than the amount of endogenous c-Myc). Consequently, only a small fraction of Max is associated with Myc. However, cells infected with this mutant exhibit a completely transformed phenotype in vitro, suggesting that production of enough v-Gag-Myc to tie up all cellular Max is not needed for transformation. While the nuclear localization signal is dispensable for transformation, minimal changes in the v-Gag-Myc DNA-binding domain completely abolish its transforming potential, consistent with a role of Myc as a transcriptional regulator. One of its potential targets might be the endogenous c-myc, which is repressed in wild-type MC29-infected cells. Our experiments with MC29 mutants demonstrate that c-myc down-regulation depends on the integrity of the v-Myc DNA-binding domain and occurs at the RNA level. Hence, it is conceivable that v-Gag-Myc, either directly or circuitously, regulates c-myc transcription.

Overproduction of v-Myc in the nucleus and its excess over Max are not required for avian fibroblast transformation

The cellular proto-oncogene c-myc can acquire transforming potential by a number of different means, including retroviral transduction. The transduced allele generally contains point mutations relative to c-myc and is overexpressed in infected cells, usually as a v-Gag-Myc fusion protein. Upon synthesis, v-Gag-Myc enters the nucleus, forms complexes with its heterodimeric partner Max, and in this complex binds to DNA in a sequence-specific manner. To delineate the role for each of these events in fibroblast transformation, we introduced several mutations into the myc gene of the avian retrovirus MC29. We observed that Gag-Myc with a mutated nuclear localization signal is confined predominantly in the cytoplasm and only about 5% of the protein could be detected in the nucleus (less than the amount of endogenous c-Myc). Consequently, only a small fraction of Max is associated with Myc. However, cells infected with this mutant exhibit a completely transformed phenotype in vitro, suggesting that production of enough v-Gag-Myc to tie up all cellular Max is not needed for transformation. While the nuclear localization signal is dispensable for transformation, minimal changes in the v-Gag-Myc DNA-binding domain completely abolish its transforming potential, consistent with a role of Myc as a transcriptional regulator. One of its potential targets might be the endogenous c-myc, which is repressed in wild-type MC29-infected cells. Our experiments with MC29 mutants demonstrate that c-myc down-regulation depends on the integrity of the v-Myc DNA-binding domain and occurs at the RNA level. Hence, it is conceivable that v-Gag-Myc, either directly or circuitously, regulates c-myc transcription.

Functional and defective components of avian endogenous virus long terminal repeat enhancer sequences

Oncogenic avian retroviruses, such as Rous sarcoma virus (RSV) and the avian leukosis viruses, contain a strong enhancer in the U3 portion of the proviral long terminal repeat (LTR). The LTRs of a second class of avian retroviruses, the endogenous viruses (ev) lack detectable enhancer activity. By creating ev-RSV hybrid LTRs, we previously demonstrated that, despite the lack of independent enhancer activity in the ev U3 region, ev LTRs contain sequences that are able to functionally replace essential enhancer domains from the RSV enhancer. A hypothesis proposed to explain these data was that ev LTRs contain a partial enhancer that includes sequences necessary but not sufficient for enhancer activity and that these sequences were complemented by RSV enhancer domains present in the original hybrid constructs to generate a functional enhancer. Studies described in this report were designed to define sequences from both the ev and RSV LTRs required to generate this composite enhancer. This was approached by generating additional ev-RSV hybrid LTRs that exchanged defined regions between ev and RSV and by directly testing the requirement for specific motifs by site-directed mutagenesis. Results obtained demonstrate that ev enhancer sequences are present in the same relative location as upstream enhancer sequences from RSV, with which they share limited sequence similarity. In addition, a 67-bp region from the internal portion of the RSV LTR that is required to complement ev enhancer sequences was identified. Finally, data showing that CArG motifs are essential for high-level activity, a finding that has not been previously demonstrated for retroviral LTRs, are presented.

Avian retroviral RNA encapsidation: reexamination of functional 5' RNA sequences and the role of nucleocapsid Cys-His motifs

RNA packaging signals (psi) from the 5' ends of murine and avian retroviral genomes have previously been shown to direct encapsidation of heterologous mRNA into the retroviral virion. The avian 5' packaging region has now been further characterized, and we have defined a 270-nucleotide sequence, A psi, which is sufficient to direct packaging of heterologous RNA. Identification of the A psi sequence suggests that several retroviral cis-acting sequences contained in psi+ (the primer binding site, the putative dimer linkage sequence, and the splice donor site) are dispensable for specific RNA encapsidation. Subgenomic env mRNA is not efficiently encapsidated into particles, even though the A psi sequence is present in this RNA. In contrast, spliced heterologous psi-containing RNA is packaged into virions as efficiently as unspliced species; thus splicing per se is not responsible for the failure of env mRNA to be encapsidated. We also found that an avian retroviral mutant deleted for both nucleocapsid Cys-His boxes retains the capacity to encapsidate RNA containing psi sequences, although this RNA is unstable and is thus difficult to detect in mature particles. Electron microscopy reveals that virions produced by this mutant lack a condensed core, which may allow the RNA to be accessible to nucleases.

CArG, CCAAT, and CCAAT-like protein binding sites in avian retrovirus long terminal repeat enhancers

A strong enhancer element is located within the long terminal repeats (LTRs) of exogenous, oncogenic avian retroviruses, such as Rous sarcoma virus (RSV) and the avian leukosis viruses. The LTRs of a second class of avian retroviruses, the endogenous viruses (evs), lack detectable enhancer function, a property that correlates with major sequence differences between the LTRs of these two virus groups. Despite this lack of independent enhancer activity, we previously identified sequences in ev LTRs that were able to functionally replace essential enhancer domains from the RSV enhancer with which they share limited sequence similarity. To identify candidate enhancer domains in ev LTRs that are functionally equivalent to those in RSV LTRs, we analyzed and compared ev and RSV LTR-specific DNA-protein interactions. Using this approach, we identified two candidate enhancer domains and one deficiency in ev LTRs. One of the proposed ev enhancer domains was identified as a CArG box, a motif also found upstream of several muscle-specific genes, and as the core sequence of the c-fos serum response element. The RSV LTR contains two CArG motifs, one at a previously identified site and one identified in this report at the same relative location as the ev CArG motif. A second factor binding site that interacts with a heat-stable protein was also identified in ev LTRs and, contrary to previous suggestions, appears to be different from previously described exogenous virus enhancer binding proteins. Finally, a deficiency in factor binding was found within the one inverted CCAAT box in ev LTRs, affirming the importance of sequences that flank CCAAT motifs in factor binding and providing a candidate defect in the ev enhancer.

Proviral insertions within the int-2 gene can generate multiple anomalous transcripts but leave the protein-coding domain intact

We examined the effects of mouse mammary tumor virus integration on the multiple RNA transcripts expressed from the int-2 proto-oncogene in virally induced breast tumors. Proviral insertion either upstream or downstream of the gene could simultaneously activate transcription from three dissimilar int-2 promoters. In some tumors, the activating provirus lies within the transcription unit and disrupts the structures of the various RNAs. Insertions in the 5' region of the gene had complex effects depending on the orientation and position of the provirus relative to the three promoters and intron-exon boundaries. RNase protection experiments identified transcripts initiated in the viral long terminal repeat, at normal and cryptic sites in the int-2 sequences, and from cryptic promoters in an inverted provirus. AT the 3' end, insertions occurred within the untranslated trailer and provided alternative termination signals that substituted for one or both of the normal the poly(A) addition sites. However, in no instance, of the 20 tumors analyzed in detail, did a provirus perturb the presumed open reading frame of the gene. These data strongly implicate the normal product of the int-2 gene, which is related to the fibroblast growth factor family, as a contributory factor in virally induced mammary tumors.

FH3, a v-myc avian retrovirus with limited transforming ability

We have isolated a new acute avian transforming virus which contains the oncogene myc. This virus, designated FH3, was isolated after injection of a 10-day-old chick embryo with avian leukosis virus. While FH3 shares many properties with other v-myc-containing avian retroviruses, it also has several unique properties. The primary target for transformation in vitro is chicken macrophages; infection of chicken fibroblasts does not lead to complete morphological transformation. FH3 also exhibits a limited host range, in that Japanese quail macrophages and fibroblasts are infected but are not completely transformed. FH3 induces in vivo a limited tumor type if injected into 10-day-old chick embryos; only a cranial myelocytoma, which does not appear to be metastatic, can be detected. The v-myc gene of FH3 is expressed predominantly as a P145 Gag-Myc protein which is encoded by a ca. 8-kilobase genomic RNA. This FH3-encoded polyprotein is localized in the nucleus of all infected cells, whether or not they are transformed.

Avian proto-myc genes promoted by defective or nondefective retroviruses are single-hit transforming genes in primary cells

Lymphomas of certain strains of chickens infected by retroviruses frequently contain recombinant transforming genes in which the promoter of the cellular proto-myc gene is replaced by that of a defective rather than an intact retrovirus. Here we ask whether the resulting hybrid genes are sufficient for tumorigenic transformation like viral myc genes. Further, we ask whether retroviruses must be defective in order to mutate proto-myc to a transforming gene or whether the defectiveness plays a transformation-independent function in tumorigenesis. For this purpose the defective provirus of proviral-proto-myc recombinants from lymphomas were repaired, or intact proviruses were recombined with proto-myc genes in vitro, and then compared to recombinant proto-myc genes with defective proviruses for transforming function in quail embryo fibroblasts. It was found that a single copy of a provirus-proto-myc recombinant gene with an intact provirus is sufficient to transform a quail embryo cell in vitro. Moreover, our analyses showed that multiple internal retroviral deletions [corrected] eliminate or inhibit provirus expression. The effect of these deletions [corrected] was detectable only because the inactive proviruses were linked to the selectable, transforming proto-myc gene marker. It is consistent with our results that proviral defectiveness of recombinant proto-myc genes is necessary in vivo for the clonal growth of a transformed cell into a tumor to escape antiviral immunity. The large discrepancy between the probabilities of provirus insertion and tumorigenesis is suggested to reflect the low probabilities of spontaneous deletion of the provirus and of rare, strain-specific defects of tumor-resistance genes of the host.

The myc family of nuclear proto-oncogenes

Several members of the myc family of proto-oncogenes have been described, and some (c-, N-, and L-myc) have been characterized in considerable detail. They are united by a common gene structure and nucleotide homologies that were used to identify some of them initially. Their protein products also have scattered regions of amino acid identity or homology. Although the cellular activities of the various proteins are unknown, some members may play a role in regulating cell growth and differentiation. They share the ability to cooperate with an activated ras gene and cotransform embryonic rodent cells. In naturally occurring tumors, the members of the myc family of oncogenes appear to be activated by genetic changes (proviral insertion, chromosomal translocation, and gene amplification) that augment or otherwise disrupt normally regulated expression. The members of this family of genes differ markedly in their tissue specificity and developmental regulation of expression. This may account in part for the frequent appearance of activated c-myc genes in a wide variety of neoplasms and the limited appearance of activated N- and L-myc genes in tumors of embryonic or neural origin. The c-myc gene may be activated in tumors by a variety of mechanisms, whereas N- and L-myc appear to be activated only by gene amplification. Regulation of expression of the different myc genes also appears to occur by different mechanisms. Finally, the products of the different genes differ in may regions of the protein, and this divergence probably reflects their specific and individual functions.

Lability of leukosis virus enhancer-binding proteins in avian hematopoeitic cells

Bursal lymphomas induced by avian leukosis virus (ALV) are characterized by integration of long terminal repeat (LTR) enhancer sequences next to the myc proto-oncogene and by subsequent myc hyperexpression. Nuclear runoff transcription analyses have shown that protein synthesis inhibition specifically decreases transcription of LTR-enhanced genes in bursal lymphoma cell lines (M. Linial, N. Gunderson, and M. Groudine, Science 230:1126-1132, 1985). Here, we show that LTR-enhanced transcription is also labile in nontransformed bursa, bone marrow, and spleen but not in other ALV-infected tissues from lymphoma-susceptible chickens. The bursal cells demonstrated this lability of LTR-enhanced transcription only at an early stage of development, when chickens are susceptible to ALV-induced lymphomagenesis. Mature bursal cells show stable LTR transcription enhancement (unaffected by inhibition of protein synthesis) and are not susceptible to lymphomagenesis. In lymphoma-resistant chicken strains, LTR-enhanced transcription was stable in all tissues during development. These data suggest that lability of LTR transcription enhancement in hematopoietic cells is involved in susceptibility to lymphomagenesis, and we propose a model for the action of these labile enhancing factors. Gel shift analysis of nuclear proteins from lymphoma cells indicated that four or more binding proteins specifically interact with the three LTR enhancer regions. These proteins can be separated by their differential sensitivity to heat treatment or protein synthesis inhibition. The lability of a subset of these binding proteins correlates with lability of LTR-enhanced transcription in certain lymphoid cell types, suggesting that these proteins are essential for LTR transcription enhancement.

myc protooncogene linked to retroviral promoter, but not to enhancer, transforms embryo cells

To define conditions under which the chicken protooncogene p-myc is converted to a viral and possibly to a cellular transforming gene, we assayed transforming function of hybrid genes put together from cloned retroviral and p-myc elements and of p-myc genes isolated from spontaneous viral lymphomas. Transforming function was measured in quail embryo cells transfected with cloned myc genes. We found that only myc genes with a promoter of a retroviral long terminal repeat (LTR) located between the native p-myc promoter and the second p-myc exon have transforming function. Transforming efficiencies decreased with increasing lengths of unspliced sequences between the LTR and p-myc exon 2. p-myc DNAs with LTRs downstream of the coding region or upstream but in the opposite transcriptional orientation failed to transform embryo cells. Likewise, only those retroviral-p-myc combinations from chicken B-cell lymphomas with a LTR positioned as promoter upstream of p-myc exon 2 had transforming function. We conclude that substitution of a retroviral LTR for the promoter and for as yet poorly defined, untranscribed regulatory elements of p-myc is sufficient to convert chicken p-myc to a transforming gene. However, retroviral LTRs can only convert p-myc genes to embryo-cell-transforming genes from a limited number of positions, and not as position-independent enhancers. Further, we deduce that there are two classes of viral chicken B-cell lymphomas, those with and those without embryo-cell-transforming p-myc genes.

5' long terminal repeats of myc-associated proviruses appear structurally intact but are functionally impaired in tumors induced by avian leukosis viruses

B-cell lymphomas induced in chickens infected with avian leukosis viruses are characterized by integration of the virus within the cellular myc locus and alteration of c-myc expression. Although avian leukosis viruses are intact, replication-competent retroviruses, the structures of many myc-associated proviruses are altered by deletions, raising the possibility that proviral defectiveness plays an essential role in oncogenesis. We found that all myc-associated proviruses in 21 independent tumors had deletions, which were confined to the viral genome and did not extend into adjacent cellular sequences. Deletions were not random but, in at least 85% of the myc-associated proviruses, involved a region near the 5' end of the proviral genome where elements implicated in control of viral gene expression have been localized. A second class of deletions involved sequences in the 3' half of the viral genome and included the splice acceptor site used in generating viral env mRNA. Both the 5' and 3' long terminal repeats of myc-associated proviruses appeared to be structurally intact in most tumors, although the 5' long terminal repeats were not involved in expression of either U5-myc transcripts or detectable steady-state viral RNAs. A complex array of repeated sequence elements surrounded the junctions of the internal deletions in two myc-associated proviruses. The organization of the deleted proviruses was similar to that of deleted unintegrated viral molecules, consistent with a model in which deletions occurred prior to integration.

B-lymphoma induction by reticuloendotheliosis virus: characterization of a mutated chicken syncytial virus provirus involved in c-myc activation

Nondefective reticuloendotheliosis virus induces chicken bursal lymphoma in a manner similar to that of avian leukosis virus. The provirus integrates in the c-myc locus and uses a promoter insertion mechanism to activate c-myc expression. We cloned a provirus involved in c-myc activation from a B lymphoma. Detailed structural characterization of this clone, including sequence determination, revealed proviral insertion at 512 base pairs preceding the second c-myc exon. The provirus has a deletion of 80% of the viral genes but retains two intact long terminal repeats (LTRs). A segment of the viral env sequence is present in an inverted orientation. Elevated expression of c-myc, apparently directed by the 3' LTR, was detected. However, despite the presence of an intact 5' LTR, no viral transcripts were detected. Thus, the internal proviral rearrangement can affect 5' LTR transcription or stability of the message or both. This finding is in consonance with the view that proviral deletion plays an important role in the induction of bursal lymphomas by nonacute retroviruses.

An aberrant avian leukosis virus provirus inserted downstream from the chicken c-myc coding sequence in a bursal lymphoma results from intrachromosomal recombination between two proviruses and deletion of cellular DNA

A chicken bursal lymphoma, LL6, contains avian leukosis virus DNA integrated 3' of the c-myc coding sequences, unlike all other examined bursal lymphomas, which have integrations 5' to c-myc. To better understand this unusual mutation, we examined a molecular clone containing the LL6 c-myc gene and determined the structure of the proviral insertion by DNA sequencing. Viral DNA begins 575 base pairs downstream of the c-myc coding sequences within the untranslated region, disrupting the use of the normal polyadenylation signal. An internal deletion of the provirus extends from within U3 in the 5' long terminal repeat to within the gp37-coding region of the env gene, disabling virus replication and protein synthesis. Both host-virus boundaries appear normal with respect to the site in viral DNA which is joined to host DNA; both long terminal repeats lack the terminal dinucleotide found in unintegrated DNA. However, in contrast to normal integrations, the six bases of cellular sequence at the 5' junction are not repeated at the 3' junction. The DNA sequences immediately downstream of the LL6 recombinant provirus are not part of the c-myc gene; they originate from the same chromosome as c-myc, but at least 15 kilobases (kb) away. In addition, DNA sequences normally residing 3' of c-myc are deleted in LL6. In summary, these results imply that the LL6 provirus is the result of recombination between two proviruses; that both proviruses were originally downstream of c-myc in the same orientation and separated by at least 15 kb; and that the recombination event was preceded, accompanied, or followed by an internal proviral deletion. No transcript could be detected within a 20-kb region downstream of the LL6 provirus, leaving unresolved the question of whether the additional chromosomal alterations make a specific contribution to LL6 tumorigenesis.

Features of the chicken c-myc gene that influence the structure of c-myc RNA in normal cells and bursal lymphomas

The chicken c-myc gene is the target for proviral insertion mutations in bursal lymphomas and has been transduced to generate several viral oncogenes, but the boundaries of its exons have not been securely established. To define the landmarks of the chicken c-myc gene necessary to produce its mRNA, we used an RNase protection assay and a cDNA clone to analyze the c-myc mRNAs from normal chicken embryos and from two bursal lymphomas: LL6, which contains an avian leukosis virus provirus downstream of the c-myc coding region, and LL7, which contains an avian leukosis virus provirus upstream of the c-myc coding region. Two initiation sites for normal c-myc mRNA are less than 7 bases apart, downstream of a GC-rich region lacking canonical TATA and CAAT sequences. The first exon has two open reading frames for the entire length but no initiator methionine codons. The splice donor and acceptor sites at the boundary of the first intron were assigned by comparing a sequence of an LL6 c-myc cDNA clone with a genomic DNA sequence and confirmed by RNase protection of labeled RNA probes by normal and LL6-derived mRNAs. Two potential polyadenylation signals are located approximately 250 and 400 bases downstream of the c-myc coding region in the third exon, but only the more distal signal is utilized in both normal cells and the LL7 tumor. The proviral integration in the LL6 tumor occurred upstream of the authentic c-myc polyadenylation signal accounting for polyadenylation of this transcript in the proviral long terminal repeat.

Somatic rearrangement of the c-myc oncogene in primary human diffuse large-cell lymphoma

Chromosome translocations involving 8q24, the band to which c-myc has been mapped (Dalla-Favera et al., 1982), are a uniform finding in Burkitt's lymphoma (Bernheim et al., 1981). However, in only a minority of the tumors is the rearrangement of the c-myc locus sufficiently close to the gene to be detected with currently available probes (Dalla-Favera et al., 1983). Approximately 25% of diffuse large-cell lymphomas have also been reported to have translocations involving 8q24 (Mitelman, 1985), but there have been no reports of c-myc rearrangements in this form of non-Hodgkin's lymphoma. We have examined the structure of the c-myc locus in primary tumor tissue of 10 cases of diffuse large-cell lymphoma. In one patient, Southern blot analysis revealed additional c-myc fragments in the tumor DNA but not in the germ-line DNA. Southern blot analysis using probes from both the heavy- and light-chain immunoglobin loci showed that the myc rearrangement was unlikely to involve the immunoglobulin loci in this patient.

Sequence-specific DNA-binding proteins which interact with (G + C)-rich sequences flanking the chicken c-myc gene

The interaction of nuclear sequence-specific DNA-binding proteins from definitive chicken erythrocytes, thymus and proliferating transformed erythroid precursor (HD3) cells with the 700-base-pair (700-bp) DNA 5'-flanking region of the chicken c-myc gene was investigated by in vitro footprint analysis. The major HD3 protein-binding activity binds to a site (site V) 200 bp upstream from the 'cap' site but, after further fractionation, a second distinct binding activity is detected to a site (site VIII) which contains both the 'CAAT' and 'SP1-binding' consensus sequences. Protein from thymus and erythrocyte cells which express c-myc at lower levels, bind to seven and eight sites respectively. In common with HD3 cell protein, they both bind to site VIII and, although binding to the sequence at site V is also detected, the footprint protection pattern is sufficiently different (site V') to suggest the involvement of different proteins in terminally differentiated and proliferating cells. The DNA-binding activities were partially fractionated by high-performance liquid chromatography gel filtration and include an erythrocyte-specific protein which binds to a c-myc gene poly(dG) homopolymer sequence similar to that found upstream of the chicken beta A-globin gene.

Features of the chicken c-myc gene that influence the structure of c-myc RNA in normal cells and bursal lymphomas

The chicken c-myc gene is the target for proviral insertion mutations in bursal lymphomas and has been transduced to generate several viral oncogenes, but the boundaries of its exons have not been securely established. To define the landmarks of the chicken c-myc gene necessary to produce its mRNA, we used an RNase protection assay and a cDNA clone to analyze the c-myc mRNAs from normal chicken embryos and from two bursal lymphomas: LL6, which contains an avian leukosis virus provirus downstream of the c-myc coding region, and LL7, which contains an avian leukosis virus provirus upstream of the c-myc coding region. Two initiation sites for normal c-myc mRNA are less than 7 bases apart, downstream of a GC-rich region lacking canonical TATA and CAAT sequences. The first exon has two open reading frames for the entire length but no initiator methionine codons. The splice donor and acceptor sites at the boundary of the first intron were assigned by comparing a sequence of an LL6 c-myc cDNA clone with a genomic DNA sequence and confirmed by RNase protection of labeled RNA probes by normal and LL6-derived mRNAs. Two potential polyadenylation signals are located approximately 250 and 400 bases downstream of the c-myc coding region in the third exon, but only the more distal signal is utilized in both normal cells and the LL7 tumor. The proviral integration in the LL6 tumor occurred upstream of the authentic c-myc polyadenylation signal accounting for polyadenylation of this transcript in the proviral long terminal repeat.

Structure and transforming function of transduced mutant alleles of the chicken c-myc gene

A small retroviral vector carrying an oncogenic myc allele was isolated as a spontaneous variant (MH2E21) of avian oncovirus MH2. The MH2E21 genome, measuring only 2.3 kilobases, can be replicated like larger retroviral genomes and hence contains all cis-acting sequence elements essential for encapsidation and reverse transcription of retroviral RNA or for integration and transcription of proviral DNA. The MH2E21 genome contains 5' and 3' noncoding retroviral vector elements and a coding region comprising the first six codons of the viral gag gene and 417 v-myc codons. The gag-myc junction corresponds precisely to the presumed splice junction on subgenomic MH2 v-myc mRNA, the possible origin of MH2E21. Among the v-myc codons, the first 5 are derived from the noncoding 5' terminus of the second c-myc exon, and 412 codons correspond to the c-myc coding region. The predicted sequence of the MH2E21 protein product differs from that of the chicken c-myc protein by 11 additional amino-terminal residues and by 25 amino acid substitutions and a deletion of 4 residues within the shared domains. To investigate the functional significance of these structural changes, the MH2E21 genome was modified in vitro. The gag translational initiation codon was inactivated by oligonucleotide-directed mutagenesis. Furthermore, all but two of the missense mutations were reverted, and the deleted sequences were restored by replacing most of the MH2E21 v-myc allele by the corresponding segment of the CMII v-myc allele which is isogenic to c-myc in that region. The remaining two mutations have not been found in the v-myc alleles of avian oncoviruses MC29, CMII, and OK10. Like MH2 and MH2E21, modified MH2E21 (MH2E21m1c1) transforms avian embryo cells. Like c-myc, it encodes a 416-amino-acid protein initiated at the myc translational initiation codon. We conclude that neither major structural changes, such as in-frame fusion with virion genes or internal deletions, nor specific, if any, missense mutations of the c-myc coding region are necessary for activation of the basic oncogenic function of transduced myc alleles.

Cellular myc (c-myc) in fish (rainbow trout): its relationship to other vertebrate myc genes and to the transforming genes of the MC29 family of viruses

We have isolated, cloned, and sequenced the rainbow trout (Salmo gairdneri) c-myc gene. The presumptive coding region of the trout c-myc gene shows extensive homology to the c-myc genes of chicken, mouse, and human. Comparison of nucleotide sequences reveals that human, mouse, chicken, and trout c-myc genes contain at least two coding exons, interrupted by introns of decreasing size of 1.38 kilobases (kb), 1.2 kb, 0.97 kb, and 0.33 kb, respectively. The exons are clearly delineated by donor-acceptor splice signals. The degree of nucleotide homology between trout, chicken, and human exon II is less than that observed for exon III. However, the greatest homology among these three genes is localized to two specific regions within exon II (myc boxes A and B). At the predicted amino acid level, fish c-myc shows considerable homology to vertebrate c-myc gene products. Trout c-myc is expressed in normal trout cells as a single 2.3-kb mRNA species, similar in size to other vertebrate transcripts.

Patterns of proviral insertion and deletion in avian leukosis virus-induced lymphomas

Sixty-eight lymphomas induced by eight different avian leukosis viruses have been analyzed on Southern blots for virus-induced mutations in the chicken c-myc gene. Sixty-six of the lymphomas exhibited a proviral insertion in c-myc, whereas one exhibited a new transduction of c-myc. Sixty-four of the proviral insertions were in the same transcriptional orientation as c-myc. Two were in the opposite transcriptional orientation. All of the insertions were upstream of the protein-coding sequences of c-myc, with most residing in the first exon or the first intron of c-myc. All of the lymphoma-inducing proviruses had deletions that included either sequences near the 5' long terminal repeat (LTR) or an LTR. The most frequent lymphoma-inducing provirus appeared to have retained both of its LTRs, but had lost sequences near its 5' LTR. The second and third most frequent lymphoma-inducing proviruses consisted of solo LTRs or of proviruses that had lost the 5' LTR as well as some internal sequences. Twenty-four insertions were mapped in c-myc. Each of these mapped to within 150 base pairs of one of the five DNase I-hypersensitive sites that occur in a 3-kilobase region immediately 5' to the protein-coding sequences of c-myc. One lymphoma contained a new c-myc transducing virus. This virus, MYC-3475, caused rapid-onset myelocytomatosis.

Enhanced transcription of c-myc in bursal lymphoma cells requires continuous protein synthesis

In several bursal lymphoma cell lines in which c-myc transcription is regulated by avian leukosis virus (ALV) long terminal repeat (LTR) sequences, protein synthesis inhibition decreases the transcriptional activity of c-myc as well as other LTR driven viral genes. This decrease in transcription is associated with a change in the chromatin structure of c-myc, as measured by deoxyribonuclease I (DNase I) hypersensitivity, and a shift of transcription from the LTR to the normal c-myc promoter. In contrast, cycloheximide had little or no effect on the transcription of LTR driven genes in infected chicken embryo fibroblasts treated with the drug. These results suggest that a labile, cell type-specific protein may interact with the retroviral LTR and regulate transcription of genes under LTR control. Further, the results demonstrate that the increase in intracellular concentration of c-myc RNA induced by cycloheximide treatment of normal cells is the result of stabilization of this message.