Ectopic expression of wild-type FGFR3 cooperates with MYC to accelerate development of B-cell lineage neoplasms.

The t(4;14) translocation in multiple myeloma (MM) simultaneously dysregulates two apparent oncogenes: fibroblast growth factor receptor 3 (FGFR3) controlled by the 3' immunoglobulin heavy chain enhancer on der(14) and MMSET controlled by the intronic Emu enhancer on der(4). Although all MM tumors and cell lines with a t(4;14) translocation have dysregulated MMSET, about 25% do not express FGFR3. Therefore, the function of dysregulated wild-type (WT) FGFR3 in the pathogenesis of MM remains unclear. We developed a murine transgenic (TG) model in which WT FGFR3 is overexpressed in B lymphoid cells. Although high levels of FGFR3 resulted in lymphoid hyperplasia in about one-third of older mice, no increase in tumorigenesis was observed. However, double TG FGFR3/Myc mice develop mature B lymphoma tumors that occur with a higher penetrance and shorter latency than in single TG Myc mice (P=0.006). We conclude that expression of high levels of WT FGFR3 can be oncogenic and cooperate with MYC to generate B lymphoid tumors. This suggests that dysregulated FGFR3 expression is likely to be essential at least for the early stages of pathogenesis of MM tumors that have a t(4;14) translocation.

Mad1 function is regulated through elements within the carboxy terminus.

Myc and Mad are basic helix-loop-helix leucine zipper (bHLH-LZ) proteins that heterodimerize with Max to bind DNA and thereby influence the transcription of Myc-responsive genes. Myc-Max dimers transactivate whereas Mad-Max-mSin3 complexes repress Myc-mediated transcriptional activation. We have previously shown that the N-terminal mSin3 binding domain and the centrally located bHLH-LZ are required for Mad1 to function during a molecular switch from proliferation to differentiation. Here we demonstrate that the carboxy terminus (CT) of Mad1 contains previously unidentified motifs necessary for the regulation of Mad1 function. We show that removal of the last 18 amino acids of Mad1 (region V) abolishes the growth-inhibitory function of the protein and the ability to reverse a Myc-imposed differentiation block. Moreover, deletion of region V results in a protein that binds DNA weakly and no longer represses Myc-dependent transcriptional activation. In contrast, deletion of the preceding 24 amino acids (region IV) together with region V restores DNA binding and transcriptional repression, suggesting a functional interplay between these two regions. Furthermore, phosphorylation within region IV appears to mediate this interplay. These findings indicate that novel regulatory elements are present in the Mad1 CT.

Inhibition of tumorigenicity in lung adenocarcinoma cells by c-erbB-2 antisense expression.

The lung carcinoma cell line Calu3, which overexpresses the c-erbB-2 oncogene, was stably transfected with antisense (AS) cDNA constructs encompassing different regions of the c-erbB-2 gene. Transfected cells were analyzed for their tumorigenic properties in vitro and in nude mice. Two independent clones, AS F1 (low erbB-2 expressor) and AS B12 (high erbB-2 expressor), as well as the polyclonal Calu3/AS 5', were selected for these analyses. In Calu3/AS 5' transfected cells and in the AS F1 clone, c-erbB-2 RNA and protein levels were lower than those detected in the parental cell line and the AS B12 clone. Anchorage-independent growth and tumor take were also significantly reduced. Furthermore, cells derived from primary tumors of Calu3/AS 5', AS F1 and AS B12 lost the AS c-erbB-2 DNA insert but retained the gene for G418 resistance. Our results suggest that a correlation between c-erbB-2 overexpression and tumorigenicity may exist in the Calu3 lung carcinoma cell line.

Function of the c-Myc antagonist Mad1 during a molecular switch from proliferation to differentiation.

Mad-Max heterodimers have been shown to antagonize Myc transforming activity by a mechanism requiring multiple protein-protein and protein-DNA interactions. However, the mechanism by which Mad functions in differentiation is unknown. Here, we present evidence that Mad functions by an active repression mechanism to antagonize the growth-promoting function(s) of Myc and bring about a transition from cellular proliferation to differentiation. We demonstrate that exogenously expressed c-Myc blocks inducer-mediated differentiation of murine erythroleukemia cells without disrupting the induction of endogenous Mad; rather, high levels of c-Myc prevent a heterocomplex switch from growth-promoting Myc-Max to growth-inhibitory Mad-Max. Cotransfection of a constitutive c-myc with a zinc-inducible mad1 results in clones expressing both genes, whereby a switch from proliferation to differentiation can be modulated. Whereas cells grown in N'N'-hexamethylene bisacetamide in the absence of zinc fail to differentiate, addition of zinc up-regulates Mad expression by severalfold and differentiation proceeds normally. Coimmunoprecipitation analysis reveals that Mad-Max complexes are in excess of Myc-Max in these cotransfectants. Moreover, we show that the Sin-binding, basic region, and leucine zipper motifs are required for Mad to function during a molecular switch from proliferation to differentiation.

c-Myc inactivation by mutant Max alters growth and morphology of NCI-H-630 colon cancer cells.

The myc gene family has been implicated in multiple cell processes including proliferation, differentiation, tumorigenesis, and apoptosis. For its cellular growth promoting function, Myc must heterodimerize with Max. To study the effect of Myc inactivation on the growth and differentiation properties of epithelial tumor cells, we transfected the H-630 human colon cancer cell line with bm-max, a mutant Max protein in which DNA-binding activity has been abolished. Cells expressing high levels of bm-Max grow poorly, and the morphology of both colonies and single cells is altered. Moreover, increased bm-Max expression results in a prolonged G alpha/G1 phase accompanied by induced expression of p21 (WAF1/CIP1), elevated levels of alkaline phosphatase (ALP) activity, and accumulation of large fat granuli within the cells. These distinctive cell characteristics are associated with differentiation processes in numerous malignant cell lines. The results of this study support a model in which sequestering of endogenous Myc and Max proteins into "basic mutant" dimers lacking DNA-binding activity is sufficient both to inhibit proliferation and to induce changes in cell behavior consistent with differentiation.

Regulation of murine Max (Myn) parallels the regulation of c-Myc in differentiating murine erythroleukemia cells.

Max is a basic region-helix-loop-helix-leucine zipper protein that consists of two major isoforms, p22 (long form, Max-L) and p21 (short form, Max-S). These proteins are encoded by two [the 1.9- and the predominant 2.3-kilobase (kb) forms] of the five alternatively spliced max mRNA species. We now demonstrate that N,N'-hexamethylene bisacetamide-mediated differentiation of murine erythroleukemia cells leads to a pattern of biphasic down-regulation of the 1.9- and the 2.3-kb myn (murine max) mRNAs that closely parallels that which occurs for myc mRNA. In contrast, the p22/Myn-L and p21/Myn-S protein isoforms down-regulate in monophasic fashion. Unlike the short-lived myc mRNA, the myn message is quite stable. However, its half-life of 3-6 h is still consistent with the biphasic down-regulation that accompanies differentiation. Furthermore, unlike myc, the overexpression of which prevents differentiation, elevated max levels merely delay differentiation. Coincident with this is a delay in the second decline of c-myc mRNA. In N,N'-hexamethylene bisacetamide-induced cells blocked from differentiating by overexpression of c-, N- or L-myc, myn mRNA expression is constitutive. These findings suggest that myn may also be involved in differentiation.

Transfected wild-type and mutant max regulate cell growth and differentiation of murine erythroleukemia cells.

Max protein forms specific DNA-binding dimeric complexes with itself and with proteins of the c-myc gene family. A large volume of data has accumulated on the role of the c-myc proto-oncogene in cell proliferation, differentiation and tumorigenesis. To elucidate the role of max in regulating c-myc functions and the effect of both proteins on cell proliferation and differentiation, we transfected murine erythroleukemia (MEL) cells with a full-length wild-type (wt) human max gene and a mutant containing a double point mutation in the basic region (bm), which abolishes specific DNA binding. All clones expressing wt-max grow slowly, and the process of inducer-mediated differentiation is delayed. Furthermore, cells transfected with the mutated max exhibit growth retardation, accumulation in the G0/G1 phase of the cell cycle and spontaneous differentiation. Our findings are consistent with a model in which a large excess of wt-Max in the cells enhances the formation of Max-Max growth-suppressor complexes, while elevated bm-Max deprives the cell of growth-promoting Myc-Max heterodimers in a dominant-negative manner, presumably by inactivating endogenous Myc and Max.

Regions within the c-Myc protein that are necessary for transformation are also required for inhibition of differentiation of murine erythroleukemia cells.

The c-, L-, and N-Myc nuclear phosphoproteins share several highly conserved regions that partially overlap putative functional domains of the c-Myc protein. All three myc oncogenes can cooperate with an activated ras gene to transform primary rat embryo cells (REC), and deregulated expression of c- and L-myc can block differentiation of murine erythroleukemia (MEL) cells. In the present study, we demonstrate that N-myc also can block MEL cell differentiation, and we identify regions within the c-Myc protein that are necessary for inhibition of MEL differentiation. C19 MEL cells were transfected with six human c-myc genes which were partially deleted in different areas of the coding region. Four of the genes lack sequences that overlap either the putative transcriptional activation domain, the helix-loop-helix motif, or the leucine zipper motif and were previously shown to have lost REC cotransforming activity (J. Stone, T. DeLange, G. Ramsay, E. Jakobovitz, J.M. Bishop, H. Varmus, and W. Lee, Mol. Cell. Biol., 7: 1697-1709, 1987). In this study, we demonstrate that they also fail to inhibit N,N'-hexamethylene-bis-acetamide-induced differentiation of MEL cells. In contrast, two partially deleted c-myc genes, one lacking a short NH2-terminal region and the other lacking 118 amino acids at the center of the coding region, which were fully active in REC cotransformation, also exhibited full activity associated with the former and only partial activity with the latter in blocking MEL differentiation. We conclude that the mutated genes tested in this study behave similarly in inhibition of MEL cell differentiation and in REC cotransformation.