Abstract
The effects of 17-β-estradiol in osteoblasts are primarily mediated by the nuclear transcription factors, estrogen receptor (ER)α and ERβ. ERs function through three general modes of action: DNA-binding dependent through estrogen response elements (EREs; designated nuclear ERE signaling); nuclear signaling via protein-protein interactions to other transcription factors (nuclear non-ERE signaling); and extra-nuclear signaling (membrane-bound functions of ERs). Identification of the specific transcriptional signatures regulated by each of these modes of action should contribute to an enhanced understanding of estrogen signaling in osteoblasts. To achieve this goal, we utilized specific mutations of ERα that eliminate the ability of the receptor to signal through a specific mode of action. The non-classical ERα knock-in (NERKI) mutation is incapable of signaling through direct DNA binding to EREs and the nuclear only ERα (NOER) mutation eliminates all membrane-localized signaling. Comparison of the gene expression patterns elicited by these mutations with the wild-type ERα (WT) pattern provides mode-specific data concerning transcriptional regulation by ERα. We expressed these constructs in the ER-negative osteoblastic cell line hFOB (−/+ estrogen) and performed global RNA-sequencing. Using a series of pair-wise comparisons, we generated three lists of genes that were regulated either by the nuclear ERE-dependent, nuclear ERE-independent, or extra-nuclear actions of ERα. Pathway and gene ontology analyses revealed that genes regulated through the nuclear ERE and nuclear non-ERE pathways were largely involved in transcriptional regulation, whereas genes regulated through extra-nuclear mechanisms are involved in cytoplasmic signaling transduction pathways. We also intersected our data with genes linked to bone density and fractures from a recent genome-wide association study and found 25 of 72 genes (35%) regulated by estrogen. These data provide a comprehensive list of genes and pathways targeted by these specific modes of ERα action and suggest that “mode-specific” ligands could be developed to modulate specific ERα functionality in bone.
Highlights
Estrogen (E) signaling is mediated by two receptors, estrogen receptor (ER)a and ERb
RNAseq analysis of human fetal osteoblastic cell line (hFOB) human osteoblastic cells expressing ERa modal variants The goal of this study was to identify and characterize estrogendependent gene expression patterns elicited by ERa through the nuclear estrogen response elements (EREs)-dependent, nuclear ERE-independent, or through extra-nuclear signaling in the ER-negative, human osteoblastic cell line hFOB [11] using global RNA sequencing (RNAseq)
As tools to facilitate this approach, we utilized an ERa mutation that eliminates DNA binding through EREs (NERKI) [2,20] and an ERa mutation which can only signal through the nucleus (NOER) [10]
Summary
Estrogen (E) signaling is mediated by two receptors, estrogen receptor (ER)a and ERb. Extensive research has been conducted to understand the role of ERs in bone through use of cellular and animal models, the understanding of gene regulation and cellular pathways regulated by E in osteoblasts is still incomplete. ERs modulate gene expression using a number of distinct modes of action. The classical pathway involves direct binding to estrogen response elements (EREs) in the control regions of genes, whereas an alternative nuclear pathway involves protein-protein interactions which are ERE-independent. To facilitate study of these pathways, an ERa mutation [non-classical ERa knock-in (NERKI)] has been made that eliminates ERE but retains non-ERE signaling (both nuclear and extra-nuclear) [2], allowing investigators to study the effects of non-ERE mediated
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