Surface IgM mediated regulation of RAG gene expression in E mu-N-myc B cell lines.

Transgenic mice carrying either the c-myc or N-myc oncogene deregulated by the immunoglobulin heavy chain enhancer element (E mu) develop both pre-B and B cell lymphomas (E mu-c-myc and E mu-N-myc lymphomas). We report here that B cell lines derived from these tumors, as well as a line derived from v-myc retroviral transformation, simultaneously express surface immunoglobulin (a hallmark of mature B cells) as well as a common subset of genes normally restricted to the pre-B stage of development-including the recombinase activating genes RAG-1 and RAG-2. Continued RAG-1 and RAG-2 expression in these lines is associated with VDJ recombinase activity detected with a VDJ recombination substrate. Cross-linking of the surface immunoglobulin on these lines with an anti-mu antibody leads to rapid, specific and reversible down-regulation of RAG-1 and RAG-2 gene expression. We also find that a small but significant percentage of normal surface immunoglobulin bearing bone marrow B cells express the RAG-1 gene. These findings are discussed in the context of their possible implications for the control of specific gene expression during the pre-B to B cell transition.     

Structure and expression of canary myc family genes.

We found that the canary N-myc gene is highly related to mammalian N-myc genes in both the protein-coding region and the long 3' untranslated region. Examined coding regions of the canary c-myc gene were also highly related to their mammalian counterparts, but in contrast to N-myc, the canary and mammalian c-myc genes were quite divergent in their 3' untranslated regions. We readily detected N-myc and c-myc expression in the adult canary brain and found N-myc expression both at sites of proliferating neuronal precursors and in mature neurons.     

Amplification of the N-myc oncogene in an adenocarcinoma of the lung

c-myc oncogene is the most extensively studied member of the myc gene family, which now consists of three characterized members, namely the c-myc, N-myc, and L-myc genes. Deregulation owing to amplification and/or rearrangements of the c-myc gene have been described in a variety of human malignancies. Several neuroblastomas have amplifications of the N-myc genes. The c-myc, N-myc, or L-myc oncogenes are also found amplified in different cell lines from small cell carcinomas of the lung. In this study, we have examined the c-myc, N-myc, and c-erbB oncogenes in 34 clinical and autopsy tumor specimens representing various histopathological types of human lung cancer, including nine small cell lung cancers. A 30-fold amplification of the N-myc gene was found in a tumor histopathologically and histochemically verified as a typical adenocarcinoma. No amplifications of the c-myc or c-erbB oncogenes were seen in any of the tumors. In the DNA of one small cell carcinoma, an extra c-myc and N-myc cross-hybridizing restriction fragment was observed, possibly owing to an amplification of a yet uncharacterized myc-related gene.     

Neoplastic transformation by the human gene N-myc.

Amplification and abundant expression of a gene known as N-myc are found frequently in advanced stages of human neuroblastoma and may play a role in the genesis of several malignant human tumors. Previous studies have shown that N-myc can cooperate with a mutant allele of the proto-oncogene c-Ha-ras to transform embryonic rat cells in culture. Here we show that N-myc can also act alone to elicit neoplastic growth of an established line of rat fibroblasts (Rat-1). We used recombinant DNA vectors to express either N-myc or its kindred gene c-myc in transfected cells. Both genes caused morphological transformation, anchorage-independent growth, and tumorigenicity. We noticed two variables that appeared to influence the ability to isolate cells transformed by N-myc and c-myc: the abundance in which the genes were expressed and biological selection to eliminate untransformed cells from the cultures. Our findings sustain the belief that N-myc is an authentic proto-oncogene, lend further credibility to the role of N-myc in the genesis of human tumors, and establish a convenient assay that can be used to explore further the properties of both N-myc and c-myc.     

N-myc is frequently activated by proviral insertion in MuLV-induced T cell lymphomas.

We report a new common proviral insertion site in murine leukemia virus-induced T cell lymphomas to be N-myc. Proviral activation of N-myc was found in 35% of independently induced primary tumors. The vast majority of the proviral insertions occur within a small segment of the 3'-untranslated region of the N-myc gene, directly downstream of the protein-encoding domain. This results in an increased level of expression of a truncated N-myc mRNA. Together with the previously shown c-myc activation we now find involvement of myc genes in greater than 75% of the primary T cell lymphomas induced by Moloney murine leukemia virus in C57BL10 and BALB/c mice, and show for the first time that N-myc can be over-expressed by a mechanism other than gene amplification.     

Two N-myc polypeptides with distinct amino termini encoded by the second and third exons of the gene.

The N-myc and c-myc genes encode closely related nuclear phosphoproteins. We found that the N-myc protein from human tumor cell lines appears as four closely migrating polypeptide bands (p58 to p64) in sodium dodecyl sulfate-polyacrylamide gels. This and the recent finding that the c-myc protein is synthesized from two translational initiation sites located in the first and second exons of the gene (S. R. Hann, M. W. King, D. L. Bentley, C. W. Anderson, and R. N. Eisenman, Cell 52:185-195, 1988) prompted us to study the molecular basis of the N-myc protein heterogeneity. Dephosphorylation by alkaline phosphatase reduced the four polypeptide bands to a doublet with an electrophoretic mobility corresponding to the two faster-migrating N-myc polypeptides (p58 and p60). When expressed transiently in COS cells, an N-myc deletion construct lacking the first exon produced polypeptides similar to the wild-type N-myc protein, indicating that the first exon of the N-myc gene is noncoding. Furthermore, mutants deleted of up to two thirds of C-terminal coding domains still retained the capacity to produce a doublet of polypeptides, suggesting distinct amino termini for the two N-myc polypeptides. The amino-terminal primary structure of the N-myc protein was studied by site-specific point mutagenesis of the 5' end of the long open reading frame and by N-terminal radiosequencing of the two polypeptides. Our results show that the N-myc polypeptides are initiated from two alternative in-phase AUG codons located 24 base pairs apart at the 5' end of the second exon. Both of these polypeptides are phosphorylated and localized to the nucleus even when expressed separately. Interestingly, DNA rearrangements activating the c-myc gene are often found in the 1.7-kilobase-pair region between the two c-myc translational initiation sites and correlate with the loss of the longer c-myc polypeptide. Thus the close spacing of the two N-myc initiation codons could explain the relative resistance of the N-myc gene to similar modes of oncogenic activation.     

Promotion of growth and apoptosis in c-myc nullizygous fibroblasts by other members of the myc oncoprotein family

c-myc nullizygous fibroblasts (KO cells) were used to compare the abilities of c-myc, N-myc and L-myc oncoproteins to accelerate growth, promote apoptosis, revert morphology, and regulate the expression of previously described c-myc target genes. All three myc oncoproteins were expressed following retroviral transduction of KO cells. The proteins all enhanced the growth rate of KO cells and significantly shortened the cell cycle transition time. They also accelerated apoptosis following serum deprivation, reverted the abnormal KO cell morphology, and modulated the expression of previously described c-myc target genes. In most cases, L-myc was equivalent to c-myc and N-myc in restoring all of the c-myc-dependent activities. These findings contrast with the previously reported weak transforming and transactivating properties of L-myc. Myc oncoproteins may thus impart both highly similar as well as dissimilar signals to the cells in which they are expressed.     

Specific phosphorylation of the acidic central region of the N-myc protein by casein kinase II.

The central region of the N-myc protein has a characteristic amino acid sequence EDTLSDSDDEDD, which is very similar to those of particular domains of adenovirus E1A, human papilloma virus E7, Simian virus 40 large T, c-myc and L-myc proteins. Domains of these three viral oncoproteins have recently been shown to be specific binding sites for the tumor-suppressor gene retinoblastoma protein. We have noted that the sequence of serine followed by a cluster of acidic amino acids is exactly the same as that of a typical substrate of casein kinase II (CKII). Therefore, we investigated whether these nuclear oncoproteins are phosphorylated by CKII. For this purpose, we fused the beta-galactosidase and N-myc genes including this domain and expressed it in Escherichia coli cells. Several mutant N-myc genes, containing single amino acid substitutions in this domain, were also used to produce fused proteins. Strong phosphorylation by CKII was detected with the fused protein of wild-type N-myc. However, no phosphorylation of beta-galactosidase itself was observed and the phosphorylations of fused mutant proteins were low. Another fused N-myc protein containing most of the C-terminal region downstream of this acidic region was not phosphorylated by CKII. Analysis of phosphorylation sites in synthetic peptides of this acidic region identified the major sites phosphorylated by CKII as Ser261 and Ser263. On two-dimensional tryptic mapping of phosphorylated N-myc proteins, major spots of in vitro-labeled and in-vivo-labeled N-myc proteins were detected in the same positions. These results suggest that two serine residues of the acidic central region of the N-myc protein are phosphorylated by CKII in vivo as well as in vitro. The functional significance of this acidic domain is discussed.     

Nucleotide sequence of the coding region of the mouse N-myc gene.

A genomic clone for the mouse N-myc gene was isolated and the total nucleotide sequence (4807 bp) of the two coding exons and an intron located between them was determined. The amino acid sequence of the N-myc protein was deduced from the DNA sequence. This protein is composed of 462 amino acids, slightly larger than human and mouse c-myc proteins, and is rich in proline like the c-myc protein. Comparison of the amino acid sequences of the mouse N-myc and c-myc proteins showed that conserved sequences are located in eight regions: four regions are in the N-terminal half of the N-myc protein and are separated from each other by regions poorly homologous to those of the c-myc protein, and the four others are located in the C-terminal half, throughout which certain homology exists. A remarkable sequence containing 13 successive acidic amino acids is present in one of the conserved regions located in the middle of the N-myc protein.     

Transrepression of the N-myc expression by c-myc protein

In the human neuroblastoma cell line IMR32 the N-myc gene happens to be amplified and actively expressed, whereas no stable c-myc RNA can be detected in the same cells. In this report, we show that in IMR32 cells the expression of the N-myc gene is repressed by introduction of a c-myc expression vector (c-myc cDNA conjugated with an SR promoter). Moreover, dose response experiments showed that the amount of endogenous c-myc protein present in HeLa cells (which express c-myc but not N-myc) is enough to repress the expression of N-myc in IMR32 cells.