Creation of an active estrogen-responsive element by a single base change in the flanking sequence of a cellular oncogene: a possible mechanism for hormonal carcinogenesis?

Loss of Angelman Syndrome Protein E6AP Disrupts a Novel Antagonistic Estrogen-Retinoic Acid Transcriptional Crosstalk in Neurons

Angelman syndrome (AS) is a complex genetic disorder that affects the nervous system. AS affects an estimated 1 in 12,000 to 20,000 individuals. Characteristic features of AS includes developmental delay or intellectual disability, severe speech impairment, seizures, small head size (microcephaly), and problems with movement and balance (ataxia). AS individuals usually have microdeletion of the maternal copy of 15q11.2-15q13 region of chromosome 15. The E6-associated protein (E6AP, an E3 ubiquitin protein ligase enzyme) is encoded by the gene UBE3A, which is located in this region, and it has been shown that deregulation of E6AP gives rise to AS and neuropathology of autism spectrum disorders (ASDs) (e.g., autism and Rett syndromes). We have shown that E6AP also acts as a coactivator of the estrogen receptor (ER). ER is a ligand-induced transcription factor that exerts potent and wide-ranging effects on the developing brain. Furthermore, the expression pattern of ER in the brain overlaps with that of E6AP. Up till now, all the published studies have examined the role of the ubiquitin-protein ligase activity of E6AP in the development of AS, and it is not known what role the newly discovered coactivation functions of E6AP and ER plays in the pathology of AS. Here, we demonstrate that E6AP and ER co-immunoprecipitate and are in the same protein complex in neuronal cells (Neuro2a). In addition, both colocalize in nuclear and cytoplasmic compartments of the mouse hippocampal neurons and Neuro2a cells. Moreover, we identified a novel E6AP and ER direct transcriptional regulation of a gene Cyp26b1 known to be involved in learning and memory processes. This transcriptional regulation involves recruitment of E6AP and ER to a newly discovered functional estrogen response element (ERE) located at the Cyp26b1 gene promoter and is associated with transcription permissive epigenetic events leading to increase of active transcription of the gene in neurons upon estrogen treatment. This novel transcriptional regulation was also validated in the AS mouse model where E6AP expression is abrogated in the mouse brain. In fact, Cyp26b1 expression is decreased by 31% in AS mice versus age-matched control (Ctrl) mice hippocampi. Also, retinoic acid transcriptional signaling was shown to be amplified as evidenced by specific increased Rarβ and decreased Erbb4 mRNA expression in AS mice versus Ctrl mice hippocampi. These transcript level changes were also supported by the same trend of changes at the protein level. Collectively, our data present a proof of principle that the transcriptional coactivation function of E6AP may have a crucial role in the pathobiology of AS. This function, yet to be thoroughly investigated, reveals the possibility of harnessing the antagonistic estrogen-retinoic acid transcriptional signaling crosstalk and potentially other unknown effectors for the investigation of important possible targets as putative novel treatment modalities and venues for reversing neurological manifestations in AS and related syndromes like ASDs.

Sequence requirements for estrogen receptor binding to estrogen response elements

The estrogen receptor (ER) is a transcription factor that binds to a specific DNA sequence found in the regulatory regions of estrogen-responsive genes, called the estrogen response element (ERE). Many genes that contain EREs have been identified, and most of these EREs contain one or more changes from the core consensus sequence, a 13-nucleotide segment with 10 nucleotides forming an inverted repeat. A number of genes have multiple copies of these imperfect EREs. In order to understand why natural EREs have developed in this manner, we have attempted to define the basic sequence requirements for ER binding. To this end, we measured the binding of homodimeric ER to a variety of nonconsensus EREs. We discovered that an ERE containing even a single change from the consensus may be unable to bind ER. However, an ERE with two changes from the consensus may be capable of binding avidly to ER in the context of certain flanking sequences. We found that changes in the sequences flanking a nonconsensus ERE can greatly alter ER-ERE affinity, either positively or negatively. Careful study of sequences flanking a series of EREs made it possible to develop rules that predict whether ER binds to a given natural ERE and also to predict the relative amounts of binding when comparing two EREs.

The ligand insertion hypothesis in the genomic action of steroid hormones

Gene regulation by steroids is tightly coupled to hormone concentration and stereochemistry. A key step is binding of hormones to receptors which interact with consensus DNA sequences known as hormone response elements (HREs). The specificity and strength of hormone binding do not correlate well with hormonal activity suggesting an additional step involving recognition of ligand by the gene. Stereospecific fit of hormones between base pairs and correlation of fit with hormonal activity led to the proposal that such recognition involves insertion of hormone into DNA. Here, the feasibility of insertion was investigated using computer models of the glucocorticoid receptor DNA binding domain bound to its HRE. The site reported to accommodate glucocorticoids was found in the HRE and was exposed to permit unwinding at this locus. The resulting cavity in the unwound DNA/receptor interface fit cortisol remarkably well; cortisol formed hydrogen bonds to both the receptor and DNA. Current experimental evidence is generally consistent with ligand binding domains of receptors undergoing a conformational change which facilitates transfer of the ligand into the unwound DNA/receptor interface. We propose this step is rate limiting and alterations in receptor, DNA or hormone which attenuate insertion impair hormonal regulation of gene function.

Laboratory diagnostic tests for retroviral infections in dairy and beef cattle

Detection of bovine retroviruses stretches our diagnostic creativity to its limits. The nucleic acid-based, PCR-amplified assays are finding increased clinical use as the veterinary and livestock industry seek earlier detection of infection for eventual corrective management decisions. We are evolving from a point of disease diagnosis by tumor identification through conventional histopathology, to molecular diagnostics for early identification of retroviral nucleic acid (provirus). The clinical use of antibody-based assays lies in the simplicity of testing large numbers of animals, the relative sensitivity of the assays, and the low cost of testing. Although the pathogenicity of bovine leukemia virus (BLV) for cattle has been well documented, the disease potential for bovine immunodeficiency-like virus (BIV) for cattle is still being determined. Nevertheless, pressure to test for retroviral infections of livestock and, when feasible, removal of these infected animals from the herd will be increased.

Expression of estrogen receptor variants in normal and neoplastic human uterus

Estrogen receptor variants lacking internal exons and representing dominant positive and negative activity may be involved in the initiation and/or progression of endocrine dependent tumors. To assess the role of estrogen receptor in uterine disease, we have analyzed both normal and neoplastic uterine samples for the presence of variant estrogen receptors using the sensitive technique of RT-PCR and direct automated DNA sequencing of the amplified products. Our analysis was conducted to determine the presence of spliced variants lacking exons 3 through exon 8. We demonstrate that both the normal and neoplastic human uterus contains a number of spliced variants of the estrogen receptor that co-exist with the wild type receptor. Variants lacking exons 4, 5 and 7 but not exons 3 and 6 were detected. Also, a novel partial deletion in exon 8 was detected in both the normal and neoplastic tissues, although a total deletion of this exon was not observed. In addition another region of exon 8 deletion was found to be present in one tumor tissue which also contained an insertion within this region, however, other tumors did not contain this variant. In addition, double exon deletion variants were observed lacking exons 3 and 4, exons 4 and 5, and exon 7 with part of exon 8. Although our data represents a limited number of samples it suggests that splicing of the estrogen receptor message occurs in the normal physiological setting. There does not appear to be any association between the presence or absence of spliced variants of estrogen receptor and uterine tumor formation at the mRNA level.

The protooncogene c-jun contains an unusual estrogen-inducible enhancer within the coding sequence

Estrogens have previously been shown to induce c-jun mRNA levels in target cells during hormone induced proliferation, and this appears to be a primary hormonal response involving transcriptional activation. In this report we have now identified an estrogen dependent enhancer within the coding sequence of c-jun. This element has the sequence GCAGAnnnTGACC which is identical to the consensus estrogen response element GGTCAnnnTGACC in the second half site, but varies considerably in the first half site. Synthetic oligodeoxynucleotides containing this jun sequence bind the estrogen receptor in cell-free studies using a competitive band shift assay with the consensus element. The jun element also confers hormone inducibility to reporter plasmids in yeast and mammalian based transcriptional systems. Structure-function studies illustrate that the TGACC half-site and its immediate flanking dinucleotides, but not the GCAGA half-site, are required for estrogen receptor binding. In contrast, both the GCAGA and TGACC half-sites are obligatory for hormone-inducible transcriptional activation. These results suggest a model in which the estrogen receptor functions as a heterodimer to regulate transcription of the c-jun protooncogene. Coupled with reports of estrogen response elements in c-fos and estrogenic induction of c-fos and c-jun in vivo, these findings also support a role for AP-1 components as early response genes in estrogen-induced proliferation.