Ligand-dependent interaction of estrogen receptor-alpha with members of the forkhead transcription factor family.

Estrogen acting through the estrogen receptor (ER) is able to regulate cell growth and differentiation of a variety of normal tissues and hormone-responsive tumors. Ligand-activated ER binds DNA and transactivates the promoters of estrogen target genes. In addition, ligand-activated ER can interact with other factors to alter the physiology and growth of cells. Using a yeast two-hybrid screen, we have identified an interaction between ER alpha and the proapoptotic forkhead transcription factor FKHR. The ER alpha-FKHR interaction depends on beta-estradiol and is reduced significantly in the absence of hormone or the presence of Tamoxifen. A glutathione S-transferase pull-down assay was used to confirm the interaction and localized two interaction sites, one in the forkhead domain and a second in the carboxyl terminus. The FKHR interaction was specific to ER alpha and was not detected with other ligand-activated steroid receptors. The related family members, FKHRL1 and AFX, also bound to ER alpha in the presence of beta-estradiol. FKHR augmented ER alpha transactivation through an estrogen response element. Conversely, ER alpha repressed FKHR-mediated transactivation through an insulin response sequence, and cell cycle arrest induced by FKHRL1 in MCF7 cells was abrogated by estradiol. These results suggest a novel mechanism of estrogen action that involves regulation of the proapoptotic forkhead transcription factors.

Genomic structure of the promoters of the human estrogen receptor-alpha gene demonstrate changes in chromatin structure induced by AP2gamma.

Expression of human estrogen receptor-alpha (ERalpha) involves the activity from several promoters that give rise to alternate untranslated 5' exons. However, the genomic locations of the alternate 5' exons have not been reported previously. We have developed a contig map of the human ERalpha gene that includes all of the known alternate 5' exons. By using S1 nuclease and 5'- rapid amplification of cDNA ends, the cap sites for the alternate ERalpha transcripts E and H were identified. DNase I-hypersensitive sites specific to ERalpha-positive cells were associated with each of the cap sites. A DNase I-hypersensitive site, HS1, was localized to binding sites for AP2 in the untranslated region of exon 1 and was invariably present in the chromatin structure of ERalpha-positive cells. Overexpression of AP2gamma in human mammary epithelial cells generated the HS1-hypersensitive site. The ERalpha promoter was induced by AP2gamma in mammary epithelial cells, and trans-activation was dependent upon the region of the promoter containing the HS1 site. These results demonstrate that AP2gamma trans-activates the ERalpha gene in hormone-responsive tumors by inducing changes in the chromatin structure of the ERalpha promoter. These data are further evidence for a critical role for AP2 in the oncogenesis of hormone-responsive breast cancers.

Monoallelic amplification of estrogen receptor-alpha expression in breast cancer.

Gene amplification and loss of heterozygosity are alterations to chromosomal structure whereby tumor cells alter patterns of gene expression. We have identified a novel mechanism of gene regulation in which cancer cells predominantly express one of the two alleles of a gene. Estrogen receptor (ER)-alpha is overexpressed in hormone-responsive breast cancer compared with normal breast epithelial cells. Using a polymorphism of codon 10, we examined allele-specific expression of the four different ER promoters in MCF-7 breast cancer cells and primary tumors. Monoallelic amplification of expression (MAX) for all four ER promoters was identified, resulting in an allelic preference of > 100-fold. MAX was the result of an amplification of allele copy number and a preference to transcribe the amplified allele. The effect of MAX was most significant for the promoters clustered near the 1' exon, whereas the expression from the distant H promoter mirrored template copy number. MAX of the ER gene was not found to occur in normal endometrial or breast tissue. As a novel mechanism in cancer genetics, MAX can result in functional homozygosity at a gene locus.

Prostate attenuated replication competent adenovirus (ARCA) CN706: a selective cytotoxic for prostate-specific antigen-positive prostate cancer cells.

Prostate-specific antigen (PSA) is a widely used marker for the diagnosis and management of prostate cancer. Minimal enhancer/promoter constructs derived from the 5' flank of the human PSA gene (prostate-specific enhancer) were inserted into adenovirus type 5 DNA so as to drive the E1A gene, thereby creating a prostate-specific enhancer-containing virus, CN706. E1A was expressed at high levels in CN706-infected human PSA-producing LNCaP cells but not in CN706-infected DU145 cells, which are human prostate cells that do not express PSA. The titer of CN706 was significantly higher in LNCaP cells compared to several human cell lines that do not produce PSA (HBL100, PANC-1, MCF-7, DU145, and OVCAR3). Furthermore, in LNCaP cells, the yield of CN706 was dependent on exogenous androgen (R1881). CN706 destroyed large LNCaP tumors (1 x 10(9) cells) and abolished PSA production in nu/nu mouse xenograft models with a single intratumoral injection.

Prostate-specific antigen expression is regulated by an upstream enhancer.

Prostate cancer can be detected using assays for blood-borne prostate-specific antigen (PSA), which is the clinically most useful diagnostic marker of malignant disease. This paper characterizes the 5 -flanking prostate-specific enhancer which controls expression of the human PSA gene This enhancer, located between -5824 and -3738, is androgen-responsive and requires a promoter for activity. Inductions of 12-100-fold activity occur at 1 nM concentrations of the testosterone analog R1881. The enhancer demonstrated tissue specificity as judged by transfections of several human cell lines. Electrophoretic mobility shift assays comparing nuclear extracts from breast cancer cells MCF-7, and prostate cancer cells LNCaP, showed three regions of prostate-specific binding. These three regions are -4168 to -4797 (region I), -4710 to 4479 (region II), and -4168 to -3801 (region III). Region III contained a putative androgen response element at -4136 that markedly affected activity if mutated. These data suggest that prostate-specific gene expression may involve interaction of prostate-specific proteins or protein complexes with the enhancer in addition to binding of the androgen receptor to androgen response elements.

Nuclear factor I interferes with transformation induced by nuclear oncogenes.

The four nuclear factor I genes (NFI-A, NFI-B, NFI-C, and NFI-X) give rise to multiple isoforms by alternative splicing in many tissues. These NFI proteins cooperate with AP-1, Myc, and other transcription factors in regulating transcription of numerous cellular and viral genes. We have investigated the growth-regulatory potential of NFI by overexpressing cDNAs from chicken NFI genes -A, -B, -C, and -X in chicken embryo fibroblasts (CEF). None of the NFI cDNAs induced oncogenic transformation of CEF. However, overexpression of each of the NFI proteins caused similar morphological alteration of the cells, inducing them to become flattened and polygonal and to show increased adherence. The growth properties of these cells were similar to normal CEF. When these morphologically altered CEF were challenged by superinfection with oncogenic retroviruses, they were resistant to transformation by the nuclear oncogenes jun, fos, junD, myc, and qin but were readily transformed by cytoplasmic oncogenes src, mil/raf, ras, and fps. The NFI-A1 protein was able to alter transactivation by the cellular and viral Jun proteins in a promoter-dependent manner. The changes in cell morphology and reduced susceptibility to nuclear oncogenes were not seen with a carboxy-terminal truncation in the transactivation domain of NFI, suggesting that this region of the protein is essential for the observed effects. The dichotomy between the activities of nuclear and of cytoplasmic oncogenes in this system is discussed.

Distribution of alternatively spliced chicken c-myb exon 9A among hematopoietic tissues.

The role of the c-myb proto-oncogene in cellular differentiation may be regulated in part by alternative splicing of its mRNAs. Previously, two forms of alternative splicing of the chicken c-myb gene between exons 9 and 10 were described: one form utilizes the entire 360 base pair (bp) exon 9A while a second form utilizes exon 9A' which consists of the 3' 150 bp of exon 9A. In this study the distribution among chicken hematopoietic tissues of these two forms of alternative splicing was determined by Northern blot analysis using a probe specific for exon 9A. RNA species of 4.2 kilobases (kb) and 4.4 kb which contain exon 9A' or exon 9A, respectively, were detected in each tissue tested. Quantitative analysis of the major 4.0 kb c-myb species and the c-myb species containing exon 9A and exon 9A' revealed that cells from yolk sac contained both the highest absolute and the highest relative levels of alternatively spliced c-myb mRNA, presumably because of the preponderance of immature erythroid cells in these preparations.

Chimeras of herpes simplex viral VP16 and jun are oncogenic.

The Jun protein binds DNA and regulates transcription as a component of the AP-1 transcription factor complex. In its oncogenic form, Jun can transform cells in culture and cause tumors in animals. Both trans-activation and transformation require several functional domains of Jun, including an amino-terminal trans-activation domain. In this study, properties of Jun required for trans-activation and transformation were explored by replacing the trans-activation domains of c-Jun and its oncogenic counterpart, v-Jun, with the constitutively active trans-activation domain from the herpes simplex virus VP16 protein. The VP16-v-Jun chimera retained similar oncogenic properties to its parent, v-Jun. The VP16-c-Jun chimera, however, was considerably more oncogenic than c-Jun. Substitutions of a phenylalanine in the VP16 domain of the VP16-c-Jun chimera diminished or abolished transformation. Each of the chimeras bound to the AP-1 consensus recognition sequence from the collagenase promoter or from the human T-cell leukemia virus type I long terminal repeat in vitro. None of the VP16-Jun chimeras efficiently stimulated transcription from the collagenase promoter or an artificial promoter containing the human T-cell leukemia virus type I element in vivo. These results demonstrate that the Jun trans-activation domain can be replaced by a heterologous trans-activation domain with retention of oncogenic activity. However, this oncogenic activity is not reflected in the trans-activating properties of the chimeras.

Alternative splicing of the chicken c-myb exon 9A.

The c-myb gene products are thought to be regulators of cellular replication and of differentiation and heterogeneity may underlie their multiple functions. To investigate the possible existence of heterogeneity we have examined the chicken c-myb mRNAs by Northern blot analysis and polymerase chain reaction amplification of cDNAs (RT-PCR). Northern blot analysis with the c-myb cDNA clone pSG3, which contains the entire open reading frame (ORF) plus 500 base pairs of 3' untranslated sequences (Gerondakis & Bishop, 1986), and genomic probes revealed c-myb RNA species of 4.3 kb in addition to the major 4.0 kb species. The 4.3 kb c-myb RNA contained the alternatively spliced exon 9A which is highly conserved and has also been detected in a minor 4.3 kb alternatively spliced c-myb mRNA in murine and human cells. Sequencing of the avian exon 9A revealed 360 bp exon homologous to that found in murine and human mRNAs, which contains three highly conserved sequence regions shared by all three species. RT-PCR demonstrated usage of exon 9A in five hematopoietic tissues and revealed an additional splicing variant which used the 3' portion of exon 9A. Northern blot analysis using splice site-specific oligonucleotide probes spanning the two splice junctions between exon 9 and 9A revealed four additional c-myb RNAs of 4.4 kb, 2.2 kb, 2.0 kb and 1.4 kb.

Expression of MYB proteins in avian hematopoietic tissues.

MYB gene products are thought to be regulators of cellular replication and of differentiation. The major product of the avian MYB gene is a 75 kDa nuclear phosphoprotein which can activate transcription. A minor 89 kDa MYB protein of unknown function has also been described in murine and human cells. Additional heterogeneity at the level of MYB RNA which could affect the structure of MYB proteins has been described in several species. Such heterogeneity could explain the diverse effects of the MYB gene. To investigate the possible existence of heterogeneous and/or cell lineage-specific MYB proteins, five different avian hematopoietic tissues (bone marrow, bursa of Fabricius, embryonic spleen, thymus and yolk sac) were examined by immunoprecipitation with several MYB-specific antisera and SDS-PAGE analysis. In all five tissues there was a 75 kDa protein of uniform size which varied in abundance in a tissue-specific manner paralleling that observed for the 4.0 kb MYB RNA. A less abundant 89 kDa protein was also detected by several antisera in bone marrow, spleen, thymus and yolk sac but not in bursa. This 89 kDa MYB protein appears to be analogous to the 89 kDa MYB protein encoded by a minor but larger (360 nucleotides) MYB mRNA in murine and human cells. Immunoprecipitation of MYB proteins with an antiserum specific for exons 8 and 9 revealed a 74 kDa protein which co-precipitated and appeared to be complexed with p75 in normal hematopoietic cells and with the 48 kDa product of v-myb in leukemic cells.

Proto-oncogene expression in avian hematopoietic tissues.

Previous findings from this laboratory (Kim & Baluda, 1988) have shown that the proto-oncogenes ETS, FPS, MHT (RAF), MYC and REL are expressed in avian myeloblastosis virus (AMV)-transformed cells, whereas the MYB gene is repressed. In this study five different chicken hematopoietic tissues which contained varying concentrations of target cells for AMV transformation were analyzed to determine whether the expression of these proto-oncogenes resulted from, or was altered by, v-myb-induced leukemogenesis. Poly-A+ RNA from hematopoietic cells of 11-13 day yolk sac, 16 day embryonic spleen, 1 day post-hatch bursa of Fabricius, bone marrow and thymus, as well as from chicken embryonic fibroblasts (CEF) was examined by Northern blot analysis. All five proto-oncogenes were found to be expressed in the normal hematopoietic tissues. The ETS, MHT (RAF), MYC, and REL genes, but not FPS, were expressed in CEF. The expression of these five proto-oncogenes was not quantitatively or qualitatively altered in AMV-transformed myeloid cells as compared with their normal counterparts. While their expression is part of the hematopoietic phenotype of the target cells and as such is necessary for susceptibility to AMV transformation, it is not sufficient because thymocytes with a high level of expression are not transformed. This is in contrast to MYB expression, which is totally repressed in leukemic cells but probably not as a result of v-myb expression.