CCAAT/enhancer binding protein beta (C/EBPbeta)-2 transforms normal mammary epithelial cells and induces epithelial to mesenchymal transition in culture.

The transcription factor CCAAT/enhancer binding protein (C/EBP)beta is critical for normal growth and differentiation of the mammary gland. The intronless C/EBPbeta gene encodes a single mRNA that produces three protein isoforms, C/EBPbeta-1, -2, and -3, which share a common basic-leucine zipper domain at their C-terminus, but are distinguished at their N-termini by the in-frame methionine codon used to initiate translation. Although C/EBPbeta-1 and -2 are both transactivators, they likely perform distinct functions in mammary epithelial cells. C/EBPbeta-1 is the only isoform detected in normal human mammary tissue. In breast cancer cell lines, C/EBPbeta-1 is absent, and the C/EBPbeta-2 transactivator is expressed. Moreover, our data suggest that C/EBPbeta-2 is upregulated in human primary breast tumors. To assess C/EBPbeta-2's ability to participate in the transformation process, we generated recombinant retrovirus selectively encoding epitope-tagged C/EBPbeta-2. Strikingly, 10 days after infecting a normal human mammary epithelial cell line (MCF10A) with C/EBPbeta-2 virus, transformed subcultures were readily generated. Specifically, C/EBPbeta-2-overexpressing MCF10A cells form foci, gain anchorage independence, express markers associated with having undergone an epithelial-to-mesenchymal transition, and acquire an invasive phenotype. These studies, and our previous observations, provide supportive evidence that deregulated expression of C/EBPbeta-2 contributes to malignant conversion of the human breast.

C/EBP beta and Elk-1 synergistically transactivate the c-fos serum response element.

BACKGROUND: The serum response element (SRE) in the c-fos promoter is a convergence point for several signaling pathways that regulate induction of the c-fos gene. Many transcription factors regulate the SRE, including serum response factor (SRF), ternary complex factor (TCF), and CCAAT/enhancer binding protein-beta (C/EBPbeta). Independently, the TCFs and C/EBPbeta have been shown to interact with SRF and to respond to Ras-dependent signaling pathways that result in transactivation of the SRE. Due to these common observations, we addressed the possibility that C/EBPbeta and Elk-1 could both be necessary for Ras-stimulated transactivation of the SRE. RESULTS: In this report, we demonstrate that Elk-1 and C/EBPbeta functionally synergize in transactivation of both a Gal4 reporter plasmid in concert with Gal4-SRF and in transactivation of the SRE. Interestingly, this synergy is only observed upon activation of Ras-dependent signaling pathways. Furthermore, we show that Elk-1 and C/EBPbeta could interact both in an in vitro GST-pulldown assay and in an in vivo co-immunoprecipitation assay. The in vivo interaction between the two proteins is dependent on the presence of activated Ras. We have also shown that the C-terminal domain of C/EBPbeta and the N-terminal domain of Elk-1 are necessary for the proteins to interact. CONCLUSIONS: These data show that C/EBPbeta and Elk-1 synergize in SRF dependent transcription of both a Gal-4 reporter and the SRE. This suggests that SRF, TCF, and C/EBPbeta are all necessary for maximal induction of the c-fos SRE in response to mitogenic signaling by Ras.

Tandemization of a subregion of the enhancer sequences from SRS 19-6 murine leukemia virus associated with T-lymphoid but not other leukemias.

Most simple retroviruses induce tumors of a single cell type when infected into susceptible hosts. The SRS 19-6 murine leukemia virus (MuLV), which originated in mainland China, induces leukemias of multiple cellular origins. Indeed, infected mice often harbor more than one tumor type. Since the enhancers of many MuLVs are major determinants of tumor specificity, we tested the role of the SRS 19-6 MuLV enhancers in its broad disease specificity. The enhancer elements of the Moloney MuLV (M-MuLV) were replaced by the 170-bp enhancers of SRS 19-6 MuLV, yielding the recombinants DeltaMo+SRS(+) and DeltaMo+SRS(-) M-MuLV. M-MuLV normally induces T-lymphoid tumors in all infected mice. Surprisingly, when neonatal mice were inoculated with DeltaMo+SRS(+) or DeltaMo+SRS(-) M-MuLV, all tumors were of T-lymphoid origin, typical of M-MuLV rather than SRS 19-6 MuLV. Thus, the SRS 19-6 MuLV enhancers did not confer the broad disease specificity of SRS 19-6 MuLV to M-MuLV. However, all tumors contained DeltaMo+SRS M-MuLV proviruses with common enhancer alterations. These alterations consisted of tandem multimerization of a subregion of the SRS 19-6 enhancers, encompassing the conserved LVb and core sites and adjacent sequences. Moreover, when tumors induced by the parental SRS 19-6 MuLV were analyzed, most of the T-lymphoid tumors had similar enhancer alterations in the same region whereas tumors of other lineages retained the parental SRS 19-6 MuLV enhancers. These results emphasize the importance of a subregion of the SRS 19-6 MuLV enhancer in induction of T-cell lymphoma. The relevant sequences were consistent with crucial sequences for T-cell lymphomagenesis identified for other MuLVs such as M-MuLV and SL3-3 MuLV. These results also suggest that other regions of the SRS 19-6 MuLV genome contribute to its broad leukemogenic spectrum.

Molecular and phylogenetic analysis of SRS 19-6 murine leukemia virus.

The complete nucleotide sequence of the genome of Solid-type Reticulum cell Sarcoma 19-6 murine leukemia virus (SRS 19-6 MuLV) was determined. This virus was isolated in mainland China from laboratory mice that had been separated from western mice since the 1930s. The genome is 8,256 nucleotides in length and exhibits a genetic organization characteristic of replication competent MuLVs. Phylogenies constructed from reverse transcriptase (RT) domains showed that SRS 19-6 MuLV is closely related to other MuLV-related retroviruses; however, it has clearly diverged from previously isolated MuLVs. Comparative sequence analysis of the env sequences indicated that SRS 19-6 MuLV encodes a surface (SU) glycoprotein that is related to other ecotropic MuLVs in the VR-A and VR-B variable regions. However, SRS 19-6 MuLV env glycoprotein was distinct from all other MuLVs (ecotropic and non-ecotropic) in the proline-rich hypervariable region. No evidence for recombination with endogenous MuLV env sequences in generation of SRS 19-6 MuLV was observed. Comparisons of long terminal repeat (LTR) sequences revealed that the GV 1.4 molecular clone of Graffi MuLV contained 96% sequence identity to SRS 19-6 MuLV's LTR with 99% identity when comparisons were restricted to the U3 regions of the two viruses. The consensus enhancer binding motifs contained in the U3 regions of the two viruses were nearly identical. Nevertheless the two viruses have previously been shown to induce distinct patterns of disease. Comparisons between 196 and Graffi GV1.4 MuLVs may provide insights into the mechanisms of disease specificity induced by MuLVs.

Biological characterization and molecular cloning of murine C-type retroviruses derived from the TSZ complex from mainland China.

Characterization of the SRS murine retrovirus complex, derived from the TSZ system of murine leukemia developed in China, was carried out. The initial stock contained XC+, NB-tropic virus (and possibly other viruses), and induced several neoplastic diseases in neonatally inoculated NIH Swiss mice: erythroid leukemia, myeloid leukemia (acute myeloblastic leukemia), and lymphoblastic lymphoma (both B- and T-lymphoid). In addition, approximately 30% of inoculated animals developed central nervous system disease--hindlimb paralysis or semilateral paralysis. Rescue of virus from the spleen of an animal with combined erythroid/myeloid leukemia, followed by endpoint dilution gave two stocks: 19-6 (XC+, NB-tropic) and 19-7 (XC-, NB-tropic). Both stocks induced erythroid and myeloid leukemia, and 19-6 induced CNS symptoms as well. Southern blot analysis indicated that the predominant viruses from the 19-6 and the 19-7 cultures were related, but different in the env region. An infectious virus molecular clone of provirus from 19-6 cells was obtained. The resulting cloned virus [SRS 19-6 murine leukemia virus (MuLV)] induced four kinds of leukemia: erythroid, myeloid, B-lymphoma, and T-lymphoma; in many cases, more than one tumor type was identified in the same animal. Such a broad spectrum of leukemias induced by a cloned MuLV is unusual. Flaccid hindlimb paralysis induced by SRS 19-6 MuLV could be attributed to meningeal B-lymphoma. Immunofluorescent staining with a panel of env-specific monoclonal antibodies confirmed that the 19-6 and 19-7 viral stocks contained different viruses, which differed from previously characterized MuLVs. The viruses of the SRS complex may provide interesting reagents for investigations of MuLV-induced disease.