Retroviral infection accelerates T lymphomagenesis in E mu-N-ras transgenic mice by activating c-myc or N-myc.

Transgenic mice bearing a mutant, activated N-ras oncogene directed to express within hematopoietic cells by an immunoglobulin enhancer (E mu) sporadically develop T-cell lymphomas and non-lymphoid tumors that may be of macrophage origin. To identify genes that can collaborate with N-ras in hematopoietic neoplasia, Moloney murine leukemia virus was used as an insertional mutagen. Infection of newborn E mu-N-ras mice with the virus greatly accelerated tumorigenesis, and nearly all the tumors proved to be T-cell lymphomas. Their variable surface phenotype (CD4+CD8-, CD4+CD8+ and CD4-CD8-) suggested that cells at several stages of T-cell development were susceptible to tumorigenesis. Southern blot analysis revealed that 68% of the tumors bore a proviral insert 5' to the c-myc gene, while 13% had an insert within the 3' untranslated region of the N-myc gene. Insertion was associated with elevated expression of these genes. Hence, activation of a myc gene appears to be the dominant pathway to tumorigenesis by insertional mutagenesis in lymphoid cells expressing a mutant ras gene. However, since many of the tumors were not transplantable, even the partnership of myc and ras may not suffice for full lymphoid malignancy.     

Transgenic overexpression of a dominant negative mutant of FADD that, although counterselected during tumor progression, cooperates in L-myc-induced tumorigenesis

Activation of the so-called death receptors, e.g., CD95/Fas/Apo-1, is a potent stimulus to trigger apoptosis. Overexpression of the C-terminal FADD deletion mutant FADD-DN blocks death receptor-induced apoptosis, but despite this antiapoptotic activity, lck FADD-DN transgenic mice do not develop lymphomas. To analyze whether functional inactivation of FADD cooperates with Myc overexpression in tumorigenesis, lck FADD-DN transgenic mice were crossed with Emicro L-myc transoncogenic animals. While no tumors were detected in single transgenic FADD-DN or L-myc mice within 15 months, 5 of 17 (29%) FADD-DN/L-myc double transgenic animals developed lymphomas with an average latency period of 47 weeks. Protein analysis of FADD-DN/L-myc tumors showed, however, undetectable levels of FADD-DN protein. FADD-DN protein expression was again lost in 16 of 17 FADD-DN/p53 k.o. T-cell lymphomas, though no significant acceleration of tumorigenesis in P53-deficient lck FADD-DN mice compared to p53 k.o. animals was observed. These data suggest a strong counterselection against the FADD-DN protein during tumor progression, which could be explained by the cell cycle inhibitory activity of FADD-DN. Such counterselection would have to be compensated for by other antiapoptotic mutations, and indeed, strong upregulation of the antiapoptotic Bcl-2 family member Bcl-xL was found in one of the tumors. This in vivo mouse model demonstrates that an antiapoptotic protein involved in the onset of tumorigenesis is selected against and consequently lost during tumor progression because of its additional antiproliferative activity.     

Hepatocellular carcinoma in WHV/N-myc2 transgenic mice: oncogenic mutations of beta-catenin and synergistic effect of p53 null alleles

The intronless N-myc2 gene was originally identified as the major target of hepatitis virus insertion in woodchuck liver tumors. Here we report that transgenic mice carrying the N-myc2 gene controlled by woodchuck hepatitis virus (WHV) regulatory sequences are highly predisposed to liver cancer. In a WHV/N-myc2 transgenic line, hepatocellular carcinomas or adenomas arose in over 70% of mice, despite barely detectable expression of the methylated transgene in liver cells. Furthermore, a transgenic founder carrying unmethylated transgene sequences succumbed to a large liver tumor by the age of two months, demonstrating the high oncogenicity of the woodchuck N-myc2 retroposon. Stabilizing mutations or deletions of beta-catenin were found in 25% of liver tumors and correlated with reduced tumor latency (P<0.05), confirming the important role of beta-catenin activation in Myc-induced tumorigenesis. The ability of the tumor suppressor gene p53 to cooperate with N-myc2 in liver cell transformation was tested by introducing a p53-null allele into WHV/N-myc2 transgenic mice. The loss of one p53 allele in transgenic animals markedly accelerated the onset of liver cancer (P=0.0001), and most tumors of WHV/N-myc2 p53+/Delta mice harbored either a deletion of the wt p53 allele or a beta-catenin mutation. These findings provide direct evidence that activation of N-myc2 and reduction of p53 levels act synergistically during multistage carcinogenesis in vivo and suggest that different genetic pathways may underlie liver carcinogenesis initiated by a myc transgene. Oncogene (2000).     

Functional homology between N-myc and c-myc in murine plasmacytomagenesis: plasmacytoma development in N-myc transgenic mice.

Mouse plasmacytomas induced by pristane oil alone, or in combination with Abelson murine leukemia virus (A-MuLV), regularly carry one of three alternative chromosomal translocations that juxtapose c-myc to immunoglobulin heavy- or light-chain loci. E mu-c-myc transgenic mice develop translocation-free plasmacytomas after induction by pristane oil and/or A-MuLV [Sugiyama, H., Silva, S., Wang, Y., Weber, G., Babonits, M., Rosen, A., Wiener, F. & Klein, G. (1990). Int. J. Cancer, 46, 845-852]. In order to test whether another member of the myc family, N-myc, could play a similar role as c-myc, we treated E mu-N-myc transgenic mice with pristane and helper-free A-MuLV. Of 20 mice that received a single pristane injection followed by A-MuLV, 17 developed plasmacytomas with a mean latency period of 54 +/- 20 days. In a corresponding group that only received a single pristane injection, five out of six transgenic mice developed plasmacytomas with a mean latency period of 142 +/- 32 days. However, after three monthly injections of pristane, all 15 transgenic mice developed plasmacytomas with a mean latency period of 128 +/- 20 days. All plasmacytomas expressed the N-myc transgene, while none of them expressed either c-myc or endogenous N-myc. None of the tumors carried the usual plasmacytoma-associated translocations.     

Carcinogen-induced lymphomagenesis in pim-1 transgenic mice: dose dependence and involvement of myc and ras

Transgenic mice overexpressing the pim-1 oncogene in their lymphoid compartments are predisposed to T-cell lymphomagenesis but only to the extent that approximately 10% of the transgenic mice develop lymphomas within 34 weeks after birth. Recently, we have shown that lymphomagenesis in pim-1 transgenic mice can be accelerated by infecting pim-1 transgenic mice with murine leukemia viruses or by treating the mice with a relatively low dose of 60 mg of the carcinogen N-ethyl-N-nitrosourea (ENU) per kg of body weight. Here we describe the incidence of tumors as a function of the dose of ENU. Either 200, 15, 4, 1, or 0.1 mg/kg ENU was injected into transgenic and control mice and the tumor incidence was monitored. T-cell lymphomas developed in 100 and 70% of the pim-1 transgenic mice treated with 200 and 15 mg/kg ENU, respectively. Approximately 20% of the Emu-pim-1 transgenic mice developed lymphomas after treatment with either 4, 1, or 0.1 mg/kg ENU. The nontransgenic mice developed lymphomas only after injection with 200 mg/kg (45%). The data show that Emu-pim-1 transgenic mice are approximately 25-fold more susceptible to ENU-induced lymphomagenesis than control mice. In most tumors the expression of c-myc was strongly elevated, probably as a direct or indirect effect of ENU. Analysis of the lymphomas for ras mutations revealed that approximately 10% of the lymphomas bear a ras mutation. The data indicate that at least some of these mutations are not the direct result of alkylation by ENU but rather represent spontaneous mutations that occurred later in the tumorigenic process.     

Oncogene-linked in situ immunotherapy of pre-B lymphoma arising in E mu/ret transgenic mice.

We attempted to induce anti-tumour immunity for rejecting pre-B lymphoma derived from E mu/ret transgenic mice (TGM). We established pre-B-lymphoma cell lines of C57BL/6 x Balb/c background (H-2b/d) into which H-2k alloantigen and C3H background were introduced (retL1-6 and retL6-6), and we inoculated BCF1 mice with these immunising tumour cells. After these tumours were rejected by alloantigen (H-2k/C3H background)-specific effector cells, the mice were challenged with the pre-B-lymphoma cell line derived from the original E mu/ret TGM (ret0-2). All non-immunised control mice died within 80 days, whereas half the immunised mice survived for over 300 days. The immunity was also effective against primary pre-B-lymphoma cells from E mu/ret TGM and the ret-driven melanoma cell line (MEL-ret), but not against the pre-B-lymphoma cell line from E mu/myc TGM. This immunity was at least in part mediated by cell-mediated cytotoxicity that was specific to the ret oncogene product or ret-regulated antigen. Next we immunised E mu/ret TGM by inoculating them with retL6-6 cells once every 2 weeks beginning at the age of 1 month. Interestingly, this immunisation enabled the TGM to survive longer than the non-immunised control group (P < 0.05). Moreover, 2 of 11 transgenic mice receiving such immunisation were free from both macroscopic and microscopic tumours at the time when all of the 12 non-immunised control TGM had died from their tumour. This provides a new model for oncogene-linked immunotherapy research.     

Activation of myc gene family in human lung carcinomas and during heterotransplantation into nude mice.

myc gene family activation (c-myc, L-myc, and N-myc) was examined in 26 human lung carcinomas and in their corresponding xenografts in nude mice. Of the 16 neuroendocrine (NE) carcinomas studied, amplification was observed in 4 with a c-myc probe and in 1 with both L- and N-myc probes. Overexpression was found in 1 of 7 cases studied for c-myc mRNA, in 1 of 7 cases for N-myc, and in 2 of 7 cases for L-myc. Of the 10 non-small cell lung carcinomas studied, only c-myc was amplified in 1 case and overexpressed in 5 of 7 cases. These results suggest that L- and N-myc gene activation are restricted to NE carcinomas. Over-expression of the myc gene without amplification was detected in 36% of cases. During heterotransplantation, there was a 27% change in myc gene abnormality and a 57% increase in myc expression levels, mostly in NE carcinomas (5 of 7; 71%). In a total of 42 xenografted lung carcinomas studied, 45% amplification and 77% overexpression of one of the myc genes were detected with a high prevalence of L-myc overexpression in NE carcinomas (50%) and of c-myc overexpression in non-small cell lung carcinomas (66%). Finally, 19 of 26 (73%) tumors are growing in nude mice with no myc gene amplification and 43% with no myc mRNA overexpression. Thus myc gene activation is not strictly required for heterotransplantation but seems to be a favorable factor in the maintenance and progression of lung carcinomas in vivo.     

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.     

Use of E mu-PIM-1 transgenic mice short-term in vivo carcinogenicity testing: lymphoma induction by benzo[a]pyrene, but not by TPA

E mu-pim-1 transgenic mice are predisposed to develop lymphomas. Due to their low spontaneous tumour incidence and their increased sensitivity towards the lymphomagen ethylnitrosourea these mice may present an interesting model for short-term carcinogenicity testing. Here, we report on the further exploration of this transgenic mouse model with two additional carcinogens known to have, among others, the lymphohaematopoietic system as target, i.e. benzo[a]pyrene (B[a]P) and 12-O-tetradecanoylphorbol-13-acetate (TPA). B[a]P, given three times a week (by gavage) for 13 weeks at 4.3, 13 or 39 mg/kg body weight, resulted in a dose-related increase in lymphomas up to a 90% incidence in E(mu)-pim-1 mice during the observation period of 40 weeks. B[a]P also induced tumours of the forestomach within this observation period, though at a lower incidence and apparently equally effective in wildtype and transgenic mice. TPA, on the other hand, was unable to induce lymphomas (or tumours in any other organ) in either transgenic or wildtype animals within the observation period of 44 weeks, when applied dermally at the maximum tolerated dose of 3 microg/mouse, twice a week for 35 weeks. Molecular analysis showed that B[a]P-induced lymphomas in transgenic mice were of T-cell origin, 80% of which had elevated levels of c-myc expression. None of the lymphomas had increased N-myc expression and mutation analysis of the ras-gene family revealed a K-ras mutation in only one out of eight tumours investigated. Also, none of the lymphomas showed aberrant expression of p53 as determined by immunohistochemistry. It is concluded that the E mu-pim-1 mouse model will not be very suitable for short-term carcinogenicity testing in general: only genotoxic chemicals that have the lymphohaematopoietic system as target for carcinogenesis in wild- type mice, appear to be efficiently identified.      

myc family gene abnormality in lung cancers and its relation to xenotransplantability

In order to study the relationship between tumor transplantability to the nude mouse and abnormality of the myc family genes (c-myc, N-myc, L-myc) in human primary lung cancers, 32 various lung cancers were analyzed for abnormality of the myc family genes by Southern blot hybridization, and were transplanted s.c. into nude mice. Southern blot analysis showed that four non-small cell carcinomas and three small cell carcinomas had amplified c-myc and L-myc genes, respectively. Allelic deletion of the L-myc gene was observed in seven cancers, of which two also had an additional band of the c-myc gene or amplification of the L-myc gene. No abnormality of the N-myc gene was observed in this series. Of 13 cancers with abnormality of the myc family genes, 11, including all tumors with myc gene amplification, were transplantable to nude mice. Of 19 tumors without any abnormalities of the myc family genes, however, only five were transplantable to nude mice (P less than 0.005). These results indicate that abnormality of the myc family genes, especially gene amplification, might promote tumorigenic ability in xenotransplantation of lung cancers and this phenomenon might be closely related to the function of the myc gene.     

Loss of p27(Kip1) cooperates with cyclin E in T-cell lymphomagenesis

Cyclin E and p27(Kip1) are key regulators for cyclin-dependent kinases (Cdks) acting at the G1-/S-phase transition of the cell cycle. Whereas cyclin E is required for the activation of Cdk2, p27(Kip1) is a specific Cdk inhibitor and can block cell division. High levels of cyclin E and low levels of p27(Kip1) expression have been associated with malignant lymphomas in humans; the level of p27(Kip1) is even considered of prognostic significance. However, mice that lack p27(Kip1) do not develop any malignant lymphomas despite a pronounced lymphoid hyperplasia in thymus and spleen. We have previously described transgenic mice that carry a construct in which the cyclin E cDNA is under the control of the CD2 promoter/enhancer region and thus express high levels of cyclin E in the T-cell compartment (CD2-cyclin E). These animals are not predisposed for T-cell lymphomas in the absence of other cooperating events. Here we show that T-cells from CD2-cyclin E mice that at the same time are deficient for p27(Kip1) show a significantly higher Cdk2 activity than cells from wild-type or single mutant animals. Accordingly, a higher percentage of T cells in S/G2/M phase is found in CD2-cyclin E/p27(Kip1-/-) mice. After a long latency period of over 200 days, these animals develop spontaneous monoclonal T cell lymphoma whereas none of the single CD2-cyclin E transgenic or the p27(Kip1)-deficient mice showed any sign of lymphoid malignancies. Our findings demonstrate that a deregulation of control mechanisms at the G1/S transition by the combination of high cyclin E levels in the absence of p27(Kip1) is sufficient to predispose mice to develop lymphoid malignancies and further support a role of p27(Kip1) as a tumor suppressor and of cyclin E as a dominant oncogene.     

Oncogenic potential of cyclin E in T-cell lymphomagenesis in transgenic mice: evidence for cooperation between cyclin E and Ras but not Myc

To study the oncogenic activity of cyclin E in an in vivo system we generated transgenic mice expressing high levels of cyclin E in T-lymphocytes by using a construct containing the CD2 locus control region. These animals were neither predisposed to develop any tumors spontaneously nor showed an increased incidence when crossbred with Emu L-myc transgenic mice but developed hyperplasia in peripheral lymphoid organs at later age with an incidence of 27%. When treated with the DNA methylating carcinogen N-methylnitrosourea (MNU) that provokes the development of T-cell lymphomas, CD2-cyclin E transgenic animals came down with T-cell neoplasia showing a significant higher incidence (54%) than normal non transgenic controls (31%). In one of eight tumors that arose in normal MNU treated mice we could find an expected activating point mutation in the Ki-ras gene (12.5%). In contrast, the same mutation occurred in five of 16 tumors from CD2-cyclin E transgenic mice (31.2%). Whereas cyclin E overexpression alone did not lead to an increased CDK2 activity we observed in all tumors that emerged from either MNU treated normal mice or treated CD2-cyclin E transgenics a downregulation of p27KIP1 and a higher histone H1 kinase activity in CDK2 immunoprecipitates compared to normal tissue. These findings demonstrate that high level expression of cyclin E can predispose T-cells for hyperplasia and malignant transformation. However, the results also suggest that this activity of cyclin E is manifest only when other cooperating oncogenes in particular ras genes are present and activated. This would be consistent with our previous finding that cyclin E and Ha-Ras cooperate in focus formation assays in rat embryo fibroblasts.     

Coamplification of the L-myc and N-myc oncogenes in a neuroblastoma cell line

The L-myc, N-myc and c-myc genes are members of the myc oncogene family. In particular, L-myc is novel, and amplification of L-myc is still unknown except in small cell lung carcinoma. We examined L-myc amplification in 30 human neuroblastomas using Southern blot hybridization, and found that the L-myc gene was amplified approximately 5-fold in GOTO, a human neuroblastoma cell line. The N-myc gene was also amplified approximately 60-fold and furthermore, over-expression of L-myc and N-myc genes was observed in this cell line. In this report, we describe the coamplification of the myc gene family in the GOTO neuroblastoma cell line.     

Analysis of the activation of the myc family oncogene and of its stability over time in xenografted human lung carcinomas

In order to validate the use of the nude mouse as a model for studying lung cancers, 21 different lung cancers were xenografted onto nude mice and the tumoral DNA and RNA were analyzed for abnormality in the myc family genes (c-myc, L-myc, and N-myc). Six of 14 small cell lung cancers (SCLC) showed a 4-35-fold amplification for L-myc, 5 of 7 non-SCLC a 3-5-fold amplification for c-myc, and 1 of 14 SCLC an 80-fold amplification for N-myc. Of the 7 SCLC with amplified L- or N-myc oncogenes, 4 were of the small and large histological type, while only 5 of the 21 cases studied were of the small and large type. All xenografted tumors with amplification of one of the myc genes showed overexpression of the related mRNA. Overexpression without amplification of the myc genes was observed for 3 SCLC and 2 non-SCLC. These results indicate that the L-myc gene seems to be associated with the small and large phenotype in SCLC, whereas c-myc seems to be implicated in non-SCLC. Of the 21 lung cancers studied 14 were analyzed for myc family gene activation for serial passages into nude mice. No variation of DNA amplification was observed during long-term growth in nude mice for any of the myc oncogenes. Changes in the level of mRNA expression were observed only for c-myc; a beginning of expression in one SCLC and an increase in expression in one non-SCLC were noted in late passages when compared with early ones. The nude mouse is therefore a valuable model for the study of lung cancers "over a 4-year period at least."     

Overexpression of Ras, Raf and L-myc but not Bcl-2 family proteins is linked with resistance to TCR-mediated apoptosis and tumorigenesis in thymic lymphomas from TCR transgenic mice

Mice with transgenic TCR anti H-Y/Db develop spontaneous thymic tumors with a high frequency (up to 50%). Oncogenicity of TCR transgenes could depend on the deregulated expression of oncoproteins engaged in transduction pathways leading to proliferation or apoptosis. In agreement with this possibility we have found that cells of thymic lymphomas from TCR transgenic mice were largely resistant to TCR-dependent Ca++-mediated apoptosis but not to TCR-independent, p53-mediated (etoposide) apoptosis. Here we show raised expression of Bcl-2 protein in some but not in all thymic lymphoma cell lines. It suggests that the antiapoptotic function of Bcl-2 is not necessary for the process of tumorigenesis and the resistance of these lymphomas to Ca++-mediated apoptosis. On the other hand we show that all thymic lymphomas overexpressed Ras/Raf and L-myc proteins. Stimulation of the Ras/Raf pathway was reported to be required to maintain cell viability by preventing programmed cell death in thymic tumors derived from lck transgenic mice. Similarly, in TCR transgenic lymphomas overexpression of Ras, Raf and L-myc but not Bcl-2 family proteins may be responsible for the resistance of these lymphomas to TCR-mediated apoptosis but not affect p53-mediated apoptosis.     

Lymphomagenesis in E mu-myc transgenic mice can involve ras mutations

Transgenic mice bearing c-myc driven by the immunoglobulin heavy chain enhancer (E mu) initially exhibit a preneoplastic lymphoproliferative syndrome from which clonal pre-B or B lymphomas develop at random. To investigate whether this transition involves the activation of oncogenes capable of transforming fibroblasts, we transfected DNA from 14 E mu-myc lymphomas into NIH3T3 cells and tested the tumorigenicity of the transfectants in nude mice. By this assay and subsequent direct analysis of the lymphoma mRNA by cDNA cloning or the polymerase chain reaction, two independent E mu-myc lymphomas were shown to contain an N-ras or a K-ras oncogene mutated at codon 61. When incorporated into a recombinant retrovirus, the mutant N-ras allele could collaborate with myc to transform preneoplastic E mu-myc bone marrow pre-B cells. These results indicate that spontaneous mutation of ras genes is one pathway to lymphomagenesis in E mu-myc mice but that many of the lymphomas arise in response to changes that do not register in fibroblasts.     

Heterogenous amplification of myc family oncogenes in small cell lung carcinoma

One hundred forty-two foci of small cell lung carcinoma (SCLC) from 47 patients were examined for amplification of myc family oncogenes (c-myc, N-myc, and L-myc), by dot blot hybridization using formalin-fixed and paraffin-embedded materials which were resected surgically or obtained at autopsy. Some selected patients were also examined by in situ hybridization. Amplification of myc family genes was detected in 11 patients (23.4%) (c-myc in one, N-myc in five, and L-myc in five). Two of the 11 patients (one with N-myc and one with L-myc) had heterogenously amplified clones. In the patient with N-myc amplification, amplification was detected in metastatic tumors in the pancreas, lung, and pleura, but not in the liver and lymph node metastases. In the primary tumor, areas with and without N-myc amplification were seen. In the patient with L-myc amplification, although amplification was not detected in the surgically resected primary lesion, mediastinal lymph node metastatic lesions obtained at autopsy showed L-myc gene amplification. These two cases, together with previously reported evidence, suggest that myc gene amplification plays an important role in malignant progression, rather than development, of SCLC. In Stage III and IV groups, patients with over ten-fold myc gene amplification were suggested to survive for a shorter time than patients without such amplification (P = 0.06).     

Differential expression of myc, max and RB1 genes in human gliomas and glioma cell lines.

Deregulated expression of myc proto-oncogenes is implicated in several human neoplasias. We analysed the expression of c-myc, N-myc, L-myc, max and RB1 mRNAs in a panel of human gliomas and glioma cell lines and compared the findings with normal neural cells. The max and RB1 genes were included in the study because their protein products can interact with the Myc proteins, being thus putative modulators of Myc activity. Several gliomas contained c/L-myc mRNAs at levels higher than those in fetal brain, L-myc predominantly in grade II/III and c-myc in grade III gliomas. High-level N-myc expression was detected. In one small-cell glioblastoma and lower levels in five other gliomas. In contrast, glioma cell lines totally lacked N/L-myc expression. The in situ hybridisations revealed mutually exclusive topographic distribution of myc and glial fibrillary acidic protein (GFAP) mRNAs, and a lack of correlation between myc expression and proliferative activity, max and RB1 mRNAs were detected in most tumours and cell lines. The glioma cells displayed interesting alternative splicing patterns of max mRNAs encoding Max proteins which either suppress (Max) or augment (delta Max) the transforming activity of Myc. We conclude that (1) glioma cells in vivo may coexpress several myc genes, thus resembling fetal neural cells; but (2) cultured glioma cells expression only c-myc; (3) myc, max and RB1 are regulated independently in glioma cells; and (4) alternative processing of max mRNA in some glioma cells results in delta Max encoding mRNAs not seen in normal fetal brain.