TFAP2C governs the luminal epithelial phenotype in mammary development and carcinogenesis.

Molecular subtypes of breast cancer are characterized by distinct patterns of gene expression that are predictive of outcome and response to therapy. The luminal breast cancer subtypes are defined by the expression of estrogen receptor-alpha (ERα)-associated genes, many of which are directly responsive to the transcription factor activator protein 2C (TFAP2C). TFAP2C participates in a gene regulatory network controlling cell growth and differentiation during ectodermal development and regulating ESR1/ERα and other luminal cell-associated genes in breast cancer. TFAP2C has been established as a prognostic factor in human breast cancer, however, its role in the establishment and maintenance of the luminal cell phenotype during carcinogenesis and mammary gland development have remained elusive. Herein, we demonstrate a critical role for TFAP2C in maintaining the luminal phenotype in human breast cancer and in influencing the luminal cell phenotype during normal mammary development. Knockdown of TFAP2C in luminal breast carcinoma cells induced epithelial-mesenchymal transition with morphological and phenotypic changes characterized by a loss of luminal-associated gene expression and a concomitant gain of basal-associated gene expression. Conditional knockout of the mouse homolog of TFAP2C, Tcfap2c, in mouse mammary epithelium driven by MMTV-Cre promoted aberrant growth of the mammary tree leading to a reduction in the CD24(hi)/CD49f(mid) luminal cell population and concomitant gain of the CD24(mid)/CD49f(hi) basal cell population at maturity. Our results establish TFAP2C as a key transcriptional regulator for maintaining the luminal phenotype in human breast carcinoma. Furthermore, Tcfap2c influences development of the luminal cell type during mammary development. The data suggest that TFAP2C has an important role in regulated luminal-specific genes and may be a viable therapeutic target in breast cancer.

Transcriptional regulation of the GPX1 gene by TFAP2C and aberrant CpG methylation in human breast cancer.

The complexity of gene regulation has created obstacles to defining mechanisms that establish the patterns of gene expression characteristic of the different clinical phenotypes of breast cancer. TFAP2C is a transcription factor that has a critical role in the regulation of both estrogen receptor-alpha (ERα) and c-ErbB2/HER2 (Her2). Herein, we performed chromatin immunoprecipitation and direct sequencing (ChIP-seq) for TFAP2C in four breast cancer cell lines. Comparing the genomic binding sites for TFAP2C, we identified that glutathione peroxidase (GPX1) is regulated by TFAP2C through an AP-2 regulatory region in the promoter of the GPX1 gene. Knockdown of TFAP2C, but not the related factor TFAP2A, resulted in an abrogation of GPX1 expression. Selenium-dependent GPX activity correlated with endogenous GPX1 expression and overexpression of exogenous GPX1 induced GPX activity and significantly increased resistance to tert-butyl hydroperoxide. Methylation of the CpG island encompassing the AP-2 regulatory region was identified in cell lines where TFAP2C failed to bind the GPX1 promoter and GPX1 expression was unresponsive to TFAP2C. Furthermore, in cell lines where GPX1 promoter methylation was associated with gene silencing, treatment with 5'-aza-2-deoxycytidine (5'-aza-dC) (an inhibitor of DNA methylation) allowed TFAP2C to bind to the GPX1 promoter resulting in the activation of GPX1 RNA and protein expression. Methylation of the GPX1 promoter was identified in ∼20% of primary breast cancers and a highly significant correlation between the TFAP2C and GPX1 expression was confirmed when considering only those tumors with an unmethylated promoter, whereas the related factor, TFAP2A, failed to demonstrate a correlation. The results demonstrate that TFAP2C regulates the expression of GPX1, which influences the redox state and sensitivity to oxidative stress induced by peroxides. Given the established role of GPX1 in breast cancer, the results provide an important mechanism for TFAP2C to further influence oncogenesis and progression of breast carcinoma cells.

Characterization of glycoprotein E C-end of West Nile virus and evaluation of its interaction force with alphaVbeta3 integrin as putative cellular receptor.

Recombinant polypeptide containing the 260-466 amino acid sequence of West Nile virus (WNV) strain LEIV-Vlg99-27889-human glycoprotein E (gpE, E(260-466)) was constructed. Immunochemical similarity between the E(260-466) and gpE of WNV was proven by enzyme immunoassay (EIA), immunoblot, competitive EIA, hemagglutination inhibition, and neutralization tests using polyclonal and monoclonal antibodies against the viral gpE and recombinant E(260-466). Polypeptide E(260-466) induced formation of virus neutralizing and cross-reactive antibodies that were interactive with various epitopes of this recombinant protein. It is shown by evaluation of the interaction of E(260-466) with one of the proposed cell receptors of WNV that average E(260-466)-alphaVbeta3 integrin-specific interaction force measured using atomic force spectroscopy was 80 and 140 pN for single and double interactions, correspondingly. Taken together with previously described interaction between laminin-binding protein (LBP) and WNV gpE domain II, it is proposed that WNV gpE can interact specifically with two cellular proteins (LBP and alphaVbeta3 integrin) during virus entry.

[Immunochemical properties of West Nile virus protein prM and protein M C-end].

Complementary DNA fragments (nucleotides 466-966 and 878-1088) encoding prM protein and polypeptide M31-75-E1-30 of West Nile virus (WNV), strain LEIV-Vlg99-27889-human, were obtained and cloned. Recombinant polypeptides prM and M3175-E1-30 having amino acid sequences corresponding to the cloned cDNA fragments were purified by affinity chromatography. According to ELISA and Western blotting prM protein interacted with polyclonal antibodies against WNV. This is indicative the immunochemical similarity of WNV recombinant and native protein prM. 6 types of species-specific monoclonal antibodies (MAbs) raised against recombinant polypeptide prM recognized at least four epitopes within recombinant polypeptides prM and M31-75-E1-30. MAbs 7D11 were active in the virus - neutralization assay. Analysis of interaction of the MAbs with recombinant polypeptides prM, M31-75-EI-30, E1-180, E260-466 revealed cross-reactive epitopes within 260-466 amino acid residues (aa) of WNV protein E, 31-75 aa of polypeptide M31-75-E1-30 and protein prM. Proposed spatial model of proteins E and M C-end fragments shown similarity of their three-dimensional structures confirming results of immunochemical assay. Neutralization of viral infectivity by MAbs 7D11 raised against epitope within 31-75 aa t of protein M is evidence of important function of C-end region in the process of flaviviral penetration into host cell.

[Immunochemical properties of short recombinant polypeptides of proteine of, the West Nile virus bearing epitopes of domains I and II].

Fragments cDNA (nt 935-1475, 1091-1310, 935-1193) encoding N-terminal part of protein E of West Nile virus (WNV), strain LEIV-Vlg99-27889-human were obtained and cloned. Recombinant polypeptides of glycoprotein E (E1-86, E53-126, E1-180) of the WNV with corresponding amino acid sequence to the cloned fragments of cDNA and modeling the epitopes of domains I and II of surface glycoprotein E were purified by affinity chromatography. Twelve types of monoclonal antibodies (MAbs) created in our laboratory against recombinant polypeptide E1-180 interact with glycoprotein E of the WNV as results of Western blot and ELISA that is demonstrating an similarity of chemical structure of short recombinant polypeptides and corresponding amino acid sequence regions of WNV protein E. Analysis of interactions of MAbs with short recombinant polypeptides and protein E of tick-borne encephalitis virus let us reveal no less than six epitopes within domains I and II of glycoprotein E of the WNV. No less than seven types of MAbs to 86-126 aa region of the domain II were found where located peptide providing fusion of virus--cell membranes (98-110 aa). The epitope for anti-receptor MAbs 10H10 within 53-86 aa region of domain II of protein E of the WNV was mapped and it shows that the fusion peptide and co-receptor of protein E for cellular laminin-binding protein (LBP) are spatial nearness. X-ray model of protein E let us suppose that bc-loop (73-89 aa) of domain II interacts with LBP and together with cd-loop (fusion peptide) determines an initial stages of penetration virions into cell.