Estrogen receptor

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Estrogen receptors (ERs) are proteins found in cells that function as receptors for the hormone estrogen (17β-estradiol).<ref name="pmid17132854">Template:Cite journal</ref> There are two main classes of ERs. The first includes the intracellular estrogen receptors, namely ERα and ERβ, which belong to the nuclear receptor family. The second class consists of membrane estrogen receptors (mERs), such as GPER (GPR30), ER-X, and G_q-mER, which are primarily G protein-coupled receptors. This article focuses on the nuclear estrogen receptors (ERα and ERβ).

Upon activation by estrogen, intracellular ERs undergo translocation to the nucleus where they bind to specific DNA sequences. As DNA-binding transcription factors, they regulate the activity of various genes. However, ERs also exhibit functions that are independent of their DNA-binding capacity.<ref name="pmid15705661">Template:Cite journal</ref> These non-genomic actions contribute to the diverse effects of estrogen signaling in cells.

Estrogen receptors (ERs) belong to the family of steroid hormone receptors, which are hormone receptors for sex steroids. Along with androgen receptors (ARs) and progesterone receptors (PRs), ERs play crucial roles in regulating sexual maturation and gestation. These receptors mediate the effects of their respective hormones, contributing to the development and maintenance of reproductive functions and secondary sexual characteristics.

GenesEdit

In humans, the two forms of the estrogen receptor are encoded by different genes, Template:Gene and Template:Gene on the sixth and fourteenth chromosome (6q25.1 and 14q23.2), respectively.

StructureEdit

Template:Infobox protein family Template:Infobox protein family There are two different forms of the estrogen receptor, usually referred to as α and β, each encoded by a separate gene (Template:Gene and Template:Gene, respectively). Hormone-activated estrogen receptors form dimers, and, since the two forms are coexpressed in many cell types, the receptors may form ERα (αα) or ERβ (ββ) homodimers or ERαβ (αβ) heterodimers.<ref name="pmid15314175">Template:Cite journal</ref> Estrogen receptor alpha and beta show significant overall sequence homology, and both are composed of five domains designated A/B through F (listed from the N- to C-terminus; amino acid sequence numbers refer to human ER).Template:Citation needed

The N-terminal A/B domain is able to transactivate gene transcription in the absence of bound ligand (e.g., the estrogen hormone). While this region is able to activate gene transcription without ligand, this activation is weak and more selective compared to the activation provided by the E domain. The C domain, also known as the DNA-binding domain, binds to estrogen response elements in DNA. The D domain is a hinge region that connects the C and E domains. The E domain contains the ligand binding cavity as well as binding sites for coactivator and corepressor proteins. The E-domain in the presence of bound ligand is able to activate gene transcription. The C-terminal F domain function is not entirely clear and is variable in length.Template:Citation needed

Due to alternative RNA splicing, several ER isoforms are known to exist. At least three ERα and five ERβ isoforms have been identified. The ERβ isoforms receptor subtypes can transactivate transcription only when a heterodimer with the functional ERß1 receptor of 59 kDa is formed. The ERß3 receptor was detected at high levels in the testis. The two other ERα isoforms are 36 and 46kDa.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Only in fish, but not in humans, an ERγ receptor has been described.<ref>Template:Cite journal</ref>

Tissue distributionEdit

Both ERs are widely expressed in different tissue types, however there are some notable differences in their expression patterns:<ref name="pmid9348186">Template:Cite journal</ref>

• The ERα is found in endometrium, breast cancer cells, ovarian stromal cells, and the hypothalamus.<ref name="pmid15990721">Template:Cite journal</ref> In males, ERα protein is found in the epithelium of the efferent ducts.<ref name="pmid12904263">Template:Cite journal</ref>
• The expression of the ERβ protein has been documented in ovarian granulosa cells, kidney, brain, bone, heart,<ref name="pmid11861041">Template:Cite journal</ref> lungs, intestinal mucosa, prostate, and endothelial cells.

The ERs are regarded to be cytoplasmic receptors in their unliganded state, but visualization research has shown that only a small fraction of the ERs reside in the cytoplasm, with most ER constitutively in the nucleus.<ref>Template:Cite journal</ref> The "ERα" primary transcript gives rise to several alternatively spliced variants of unknown function.<ref>Template:Cite journal</ref>

Signal transductionEdit

Since estrogen is a steroidal hormone, it can readily diffuse through the phospholipid membranes of cells due to its lipophilic nature. As a result, estrogen receptors can be located intracellularly and do not necessarily need to be membrane-bound to interact with estrogen.<ref name="Yaşar_2017">Template:Cite journal</ref> However, both intracellular and membrane-bound estrogen receptors exist, each mediating different cellular responses to estrogen.<ref name="Fuentes_2019">Template:Cite journal</ref>

GenomicEdit

In the absence of hormone, estrogen receptors are predominantly located in the cytoplasm.<ref name = "Dahlman-Wright_2006">Template:Cite journal</ref> Hormone binding triggers a series of events, beginning with the migration of the receptor from the cytoplasm to the nucleus. This is followed by the dimerization of the receptor, where two receptor molecules join together. Finally, the receptor dimer binds to specific DNA sequences known as hormone response elements, initiating the process of gene regulation.

The DNA/receptor complex then recruits other proteins responsible for transcription of downstream DNA into mRNA and ultimately protein, resulting in changes in cell function.<ref name = "Dahlman-Wright_2006" /> Estrogen receptors are also present within the cell nucleus, and both estrogen receptor subtypes (ERα and ERβ) contain a DNA-binding domain, allowing them to function as transcription factors regulating protein production.<ref name = "Levin_2005">Template:Cite journal</ref>

The receptor also interacts with transcription factors such as activator protein 1 and Sp-1 to promote transcription, via several coactivators including PELP-1.<ref name = "Dahlman-Wright_2006" /> Tumor suppressor kinase LKB1 coactivates ERα in the cell nucleus through direct binding, recruiting it to the promoter of ERα-responsive genes. LKB1's catalytic activity enhances ERα transactivation compared to catalytically deficient LKB1 mutants.<ref>Template:Cite journal</ref> Direct acetylation of estrogen receptor alpha at lysine residues in the hinge region by p300 regulates transactivation and hormone sensitivity.<ref name="Wang_2001">Template:Cite journal</ref>

Non-genomicEdit

Nuclear estrogen receptors can also associate with the cell surface membrane and undergo rapid activation upon cellular exposure to estrogen.<ref name="pmid15642158">Template:Cite journal</ref><ref name="Björnström_2004">Template:Cite journal</ref>

Some ERs interact with cell membranes by binding to caveolin-1 and forming complexes with G proteins, striatin, receptor tyrosine kinases (e.g., EGFR and IGF-1), and non-receptor tyrosine kinases (e.g., Src).<ref name=pmid15705661/><ref name=pmid15642158/> Membrane-bound ERs associated with striatin can increase levels of Ca²⁺ and nitric oxide (NO).<ref name="pmid15569929">Template:Cite journal</ref> Interactions with receptor tyrosine kinases trigger signaling to the nucleus via the mitogen-activated protein kinase (MAPK/ERK) and phosphoinositide 3-kinase (Pl3K/AKT) pathways.<ref name="pmid7491495">Template:Cite journal</ref>

Glycogen synthase kinase-3 (GSK)-3β inhibits nuclear ER transcription by preventing phosphorylation of serine 118 on nuclear ERα. The PI3K/AKT and MAPK/ERK pathways can phosphorylate GSK-3β, thereby removing its inhibitory effect, with the latter pathway acting via rsk.

17β-Estradiol has been shown to activate the G protein-coupled receptor GPR30.<ref name="pmid17222505">Template:Cite journal</ref> However, the subcellular localization and precise role of this receptor remain controversial.<ref name="pmid18566127">Template:Cite journal</ref>

Clinical significanceEdit

CancerEdit

Estrogen receptors are over-expressed in around 70% of breast cancer cases, referred to as "ER-positive", and can be demonstrated in such tissues using immunohistochemistry. Two hypotheses have been proposed to explain why this causes tumorigenesis, and the available evidence suggests that both mechanisms contribute:

• First, binding of estrogen to the ER stimulates proliferation of mammary cells, with the resulting increase in cell division and DNA replication, leading to mutations.
• Second, estrogen metabolism produces genotoxic waste.

The result of both processes is disruption of cell cycle, apoptosis and DNA repair, which increases the chance of tumour formation. ERα is certainly associated with more differentiated tumours, while evidence that ERβ is involved is controversial. Different versions of the ESR1 gene have been identified (with single-nucleotide polymorphisms) and are associated with different risks of developing breast cancer.<ref name="pmid16511588"/>

Estrogen and the ERs have also been implicated in breast cancer, ovarian cancer, colon cancer, prostate cancer, and endometrial cancer. Advanced colon cancer is associated with a loss of ERβ, the predominant ER in colon tissue, and colon cancer is treated with ERβ-specific agonists.<ref name="pmid14500559">Template:Cite journal</ref>

Endocrine therapy for breast cancer involves selective estrogen receptor modulators (SERMS), such as tamoxifen, which behave as ER antagonists in breast tissue, or aromatase inhibitors, such as anastrozole. ER status is used to determine sensitivity of breast cancer lesions to tamoxifen and aromatase inhibitors.<ref name="pmid12363457">Template:Cite journal</ref> Another SERM, raloxifene, has been used as a preventive chemotherapy for women judged to have a high risk of developing breast cancer.<ref name="pmid15755972">Template:Cite journal</ref> Another chemotherapeutic anti-estrogen, ICI 182,780 (Faslodex), which acts as a complete antagonist, also promotes degradation of the estrogen receptor.

However, de novo resistance to endocrine therapy undermines the efficacy of using competitive inhibitors like tamoxifen. Hormone deprivation through the use of aromatase inhibitors is also rendered futile.<ref>Template:Cite journal</ref> Massively parallel genome sequencing has revealed the common presence of point mutations on ESR1 that are drivers for resistance, and promote the agonist conformation of ERα without the bound ligand. Such constitutive, estrogen-independent activity is driven by specific mutations, such as the D538G or Y537S/C/N mutations, in the ligand binding domain of ESR1 and promote cell proliferation and tumor progression without hormone stimulation.<ref>Template:Cite journal</ref>

MenopauseEdit

The metabolic effects of estrogen in postmenopausal women has been linked to the genetic polymorphism of estrogen receptor beta (ER-β).<ref name="pmid21117950">Template:Cite journal</ref>

AgingEdit

Studies in female mice have shown that estrogen receptor-alpha declines in the pre-optic hypothalamus as they grow old. Female mice that were given a calorically restricted diet during the majority of their lives maintained higher levels of ERα in the pre-optic hypothalamus than their non-calorically restricted counterparts.<ref name="pmid15990721"/>

ObesityEdit

A dramatic demonstration of the importance of estrogens in the regulation of fat deposition comes from transgenic mice that were genetically engineered to lack a functional aromatase gene. These mice have very low levels of estrogen and are obese.<ref name="pmid12933663">Template:Cite journal</ref> Obesity was also observed in estrogen deficient female mice lacking the follicle-stimulating hormone receptor.<ref name="pmid11089565">Template:Cite journal</ref> The effect of low estrogen on increased obesity has been linked to estrogen receptor alpha.<ref name="pmid11095962">Template:Cite journal</ref>

SERMs for other treatment purposesEdit

SERMs are also being studied for the treatment of uterine fibroids<ref name=":0">Template:Cite journal</ref> and endometriosis.<ref name=":1">Template:Cite journal</ref> The evidence supporting the use of SERMs for treating uterine fibroids (reduction in size of fibroids and improving other clinical outcomes) is inconclusive and more research is needed.<ref name=":0" /> It is also not clear if SERMs is effective for treating endometriosis.<ref name=":1" />

Estrogen insensitivity syndromeEdit

Estrogen insensitivity syndrome is a rare intersex condition with 5 reported cases, in which estrogen receptors do not function. The phenotype results in extensive masculinization. Unlike androgen insensitivity syndrome, EIS does not result in phenotype sex reversal. It is incredibly rare and is anologious to the AIS, and forms of adrenal hyperplasia. The reason why AIS is common and EIS is exceptionally rare is that XX AIS does not result in infertility, and therefore can be maternally inheirented, while EIS always results in infertility regardless of karyotype. A negative feedback loop between the endocrine system also occurs in EIS, in which the gonads produce markedly higher levels of estrogen for individuals with EIS (119–272 pg/mL XY and 750–3,500 pg/mL XX, see average levels) however no feminizing effects occur.<ref>Template:Cite book</ref><ref>Template:Cite journal</ref>

LigandsEdit

AgonistsEdit

• Endogenous estrogens (e.g., estradiol, estrone, estriol, estetrol)
• Natural estrogens (e.g., conjugated estrogens)
• Synthetic estrogens (e.g., ethinylestradiol, diethylstilbestrol)

Mixed (agonist and antagonist mode of action)Edit

• Phytoestrogens (e.g., coumestrol, daidzein, genistein, miroestrol)
• Selective estrogen receptor modulators (e.g., tamoxifen, clomifene, raloxifene)

AntagonistsEdit

• Antiestrogens (e.g., fulvestrant, ICI-164384, ethamoxytriphetol)

AffinitiesEdit

Template:Affinities of estrogen receptor ligands for the ERα and ERβ

Binding and functional selectivityEdit

The ER's helix 12 domain plays a crucial role in determining interactions with coactivators and corepressors and, therefore, the respective agonist or antagonist effect of the ligand.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref>

Different ligands may differ in their affinity for alpha and beta isoforms of the estrogen receptor:

• estradiol binds equally well to both receptors<ref name=pmid16728493>Template:Cite journal</ref>
• estrone, and raloxifene bind preferentially to the alpha receptor<ref name=pmid16728493/>
• estriol, and genistein to the beta receptor<ref name=pmid16728493/>

Subtype selective estrogen receptor modulators preferentially bind to either the α- or the β-subtype of the receptor. In addition, the different estrogen receptor combinations may respond differently to various ligands, which may translate into tissue selective agonistic and antagonistic effects.<ref name="pmid15950373">Template:Cite journal</ref> The ratio of α- to β- subtype concentration has been proposed to play a role in certain diseases.<ref name="pmid18166184">Template:Cite journal</ref>

The concept of selective estrogen receptor modulators is based on the ability to promote ER interactions with different proteins such as transcriptional coactivator or corepressors. Furthermore, the ratio of coactivator to corepressor protein varies in different tissues.<ref name="Shang_2002">Template:Cite journal</ref> As a consequence, the same ligand may be an agonist in some tissue (where coactivators predominate) while antagonistic in other tissues (where corepressors dominate). Tamoxifen, for example, is an antagonist in breast and is, therefore, used as a breast cancer treatment<ref name="pmid16511588">Template:Cite journal</ref> but an ER agonist in bone (thereby preventing osteoporosis) and a partial agonist in the endometrium (increasing the risk of uterine cancer).

DiscoveryEdit

Estrogen receptors were first identified by Elwood V. Jensen at the University of Chicago in 1958,<ref name="pmid12796359">Template:Cite journal</ref><ref name="pmid21888507">Template:Cite journal</ref> for which Jensen was awarded the Lasker Award.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The gene for a second estrogen receptor (ERβ) was identified in 1996 by Kuiper et al. in rat prostate and ovary using degenerate ERalpha primers.<ref name="pmid8650195">Template:Cite journal</ref>

See alsoEdit

• Membrane estrogen receptor
• Estrogen insensitivity syndrome
• Aromatase deficiency
• Aromatase excess syndrome

ReferencesEdit

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External linksEdit

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