Evaluation of matrix effects in analysis of estrogen using liquid chromatography-tandem mass spectrometry.

Matrix effects of different biological samples, including phosphate-buffered saline-bovine serum albumin (PBS-BSA), gelded horse serum, mouse serum, and mouse brain, were investigated for the determination of 17α- and ß-estradiol using derivatization with dansyl chloride prior to LC-MS/MS. Matrix effects were evaluated based on the slopes of regression lines plotted from results obtained in biological matrices versus pure standard solutions. Such plots indicate the enhancement or suppression of signal based on the presence of a particular biological fluid for a particular method. The matrix effects from PBS-BSA were similar to those of mouse serum. In contrast, analyses performed from horse serum and mouse brain yielded significant ion suppression, especially for 17ß-estradiol. Precipitation during derivatization was observed when pre-concentrated samples were processed with ethyl acetate as an extraction solvent. This was overcome with the use of methyl tert-butyl ether; however, matrix effects from this preparation were still present, evidenced by signal suppression and poor linearity in the standard curve. This work affirms that caution should be taken in the transfer of methods for use with different biological matrices, especially in the case where surrogate matrices are necessary for calibration purposes.

Viral vector-mediated overexpression of estrogen receptor-alpha in striatum enhances the estradiol-induced motor activity in female rats and estradiol-modulated GABA release.

Classical estrogen receptor-signaling mechanisms involve estradiol binding to intracellular nuclear receptors [estrogen receptor-alpha (ERalpha) and estrogen receptor-beta (ERbeta)] to promote changes in protein expression. Estradiol can also exert effects within seconds to minutes, however, a timescale incongruent with genomic signaling. In the brain, estradiol rapidly potentiates stimulated dopamine release in the striatum of female rats and enhances spontaneous rotational behavior. Furthermore, estradiol rapidly attenuates the K(+)-evoked increase of GABA in dialysate. We hypothesize that these rapid effects of estradiol in the striatum are mediated by ERalpha located on the membrane of medium spiny GABAergic neurons. This experiment examined whether overexpression of ERalpha in the striatum would enhance the effect of estradiol on rotational behavior and the K(+)-evoked increase in GABA in dialysate. Ovariectomized female rats were tested for rotational behavior or underwent microdialysis experiments after unilateral intrastriatal injections of a recombinant adeno-associated virus (AAV) containing the human ERalpha cDNA (AAV.ERalpha) into the striatum; controls received either the same vector into areas outside the striatum or an AAV containing the human alkaline phosphatase gene into the striatum (AAV.ALP). Animals that received AAV.ERalpha in the striatum exhibited significantly greater estradiol-induced contralateral rotations compared with controls and exhibited behavioral sensitization of contralateral rotations induced by a low-dose of amphetamine. ERalpha overexpression also enhanced the inhibitory effect of estradiol on K(+)-evoked GABA release suggesting that disinhibition of dopamine release from terminals in the striatum resulted in the enhanced rotational behavior.

Protein kinase C activity is necessary for estrogen-induced Erk phosphorylation in neocortical explants.

Our laboratory showed previously that estrogen activates ERK in neocortical cultures. To further elucidate the precise signaling sequelae that lead to estrogen-induced ERK activity, we evaluated the involvement of protein kinase C (PKC). We found that neocortical explants expressed primarily PKC gamma and PKC epsilon. Consistent with the involvement of PKC in mediating estrogen-induced ERK phosphorylation, we found that estrogen treatment induced translocation of these PKC isoforms to the plasma membrane. Importantly, inhibition of these isoforms abolished the ability of estrogen to phosphorylate ERK. While direct activation of PKC mimicked the effect of estrogen on ERK, both in pattern of activation and resulting intraneuronal distribution of ERK, PKC-induced ERK phosphorylation required the activity of MEK but not B-Raf. Collectively, these data suggest a critical role for PKC in mediating estrogen induction of ERK activation in the developing brain via a MEK-dependent but B-Raf-independent pathway.

Estrogen and the brain: beyond ER-alpha, ER-beta, and 17beta-estradiol.

The brain of both sexes is a major target of estradiol and a site of estrogen synthesis during development and in the adult. In addition to the classical intranuclear estrogen receptors (ERs) ER-alpha and ER-beta, we have recently identified a novel, plasma membrane-associated ER that is neither ER-alpha nor ER-beta in the brain and uterus, which we have designated "ER-X". ER-X is a developmentally regulated estrogen-binding protein that is present in wild-type, ER-alpha gene-disrupted (alphaERKO) and ER-alpha-null mice. ER-X is re-expressed after ischemic brain injury and in adult transgenic mice with Alzheimer's disease. Although ER-X shares some homology with the C-terminal region of ER-alpha, it is not an alternative splicing variant of ER-alpha and may be a new gene. ER-X mediates 17alpha-estradiol and 17beta-estradiol activation of MAPK/ERK. In contrast, ER-alpha does not elicit ERK activation but, surprisingly, is inhibitory. The potential importance of 17alpha-estradiol, the preferred ligand of ER-X, for the brain is underscored by our findings by liquid chromatography/tandem mass spectrometry that the endogenous levels of 17alpha-estradiol are significantly elevated in the postnatal day-7 and adult mouse neocortex and hippocampus, as compared with 17beta-estradiol. That there is so much more 17alpha-estradiol than 17beta-estradiol in the brain suggests that this enantiomer would be readily available to the brain. In considering estrogens for postmenopausal treatment, one should consider all the ERs present in the brain, not just ER-alpha and ER-beta, but ER-X as well, and focus on ligands such as 17alpha-estradiol that may be more selective for this ER.

17alpha-estradiol: a brain-active estrogen?

The estrogen 17beta-estradiol has profound effects on the brain throughout life, whereas 17alpha-estradiol, the natural optical isomer, is generally considered less active because it binds less avidly to estrogen receptors. On the contrary, recent studies in the brain document that 17alpha-estradiol elicits rapid and sustained activation of the MAPK/ERK and phosphatidylinositol 3-kinase-Akt signaling pathways; is neuroprotective, after an ischemic stroke and oxidative stress, and in transgenic mice with Alzheimer's disease; and influences spatial memory and hippocampal-dependent synaptic plasticity. The present study measured the endogenous content of 17alpha-estradiol in the brain and further clarified its actions and kinetics. Here we report that: 1) endogenous levels of 17alpha-estradiol and its precursor estrone are significantly elevated in the postnatal and adult mouse brain and adrenal gland of both sexes, as determined by liquid chromatography/tandem mass spectrometry; 2) 17alpha-estradiol and 17beta-estradiol bind estrogen receptors with similar binding affinities; 3) 17alpha-estradiol transactivates an estrogen-responsive reporter gene; and 4) unlike 17beta-estradiol, 17alpha-estradiol does not bind alpha-fetoprotein or SHBG, the estrogen-binding plasma proteins of the developing rodent and primate, respectively. 17alpha-Estradiol was also found in the brains of gonadectomized or gonadectomized/adrenalectomized mice, supporting the hypothesis that 17alpha-estradiol is locally synthesized in the brain. These findings challenge the view that 17alpha-estradiol is without biological significance and suggest that 17alpha-estradiol and its selective receptor, ER-X, are not part of a classical hormone/receptor endocrine system but of a system with important autocrine/paracrine functions in the developing and adult brain. 17alpha-Estradiol may have enormous implications for hormone replacement strategies at the menopause and in the treatment of such neurodegenerative disorders as Alzheimer's disease and ischemic stroke.

Estrogen activates mitogen-activated protein kinase in native, nontransfected CHO-K1, COS-7, and RAT2 fibroblast cell lines.

CHO-K1, COS-7, and Rat2 fibroblast cell lines are generally believed to be devoid of estrogen receptors (ERs) and have been widely used to study the functions of ER-alpha and ER-beta after transfection of their cDNAs. Numerous studies have demonstrated that transfected ER-alpha or ER-beta mediates estradiol-induced activation of multiple signaling pathways, including the MAPK/ERK pathways. We report here for the first time that both 17alpha-estradiol and 17beta-estradiol elicit activation of MAPK/ERK in native, nontransfected CHO-K1, COS-7, and Rat2 fibroblast cell lines. We further report that, contrary to the generally held belief, these cell lines are not unresponsive to estradiol in their native, nontransfected state, and that this estrogen responsiveness is associated with estrogen binding. Using multiple ER antibodies, we failed to find ER-alpha or ER-beta isoforms or even ER-X. In view of these findings, researchers, using such cells as models to investigate mechanisms of estrogen action, must always take into account the existence of endogenous estrogen binding proteins other than ER-alpha, ER-beta, or ER-X.

Minireview: A plethora of estrogen receptors in the brain: where will it end?

Until 1996, when estrogen receptor (ER)-beta was discovered, life seemed simple. The gonadal steroid hormone 17 beta-estradiol had one receptor, the ER, a ligand-inducible nuclear transcription factor. ER variants, the result of base pair insertions, transitions, and deletions, as well as alternative splicing, were considered abnormal and a prominent feature of breast cancer. Since then, like many other scientific beliefs, this concept has increased dramatically in complexity, and we are now faced with an ever-increasing array of estrogen-binding proteins, putative ERs, in the brain as well as in the extraneural targets of estrogen. The end is unlikely to be in sight. Some of these putative receptors have been localized to plasma or nuclear membranes, and others to the cytoplasm and/or nucleus. The molecular characteristics of membrane ERs are still in question, and, in most instances, the proteins have not been sequenced or cloned. However, based on transfection and immunohistochemistry, the generally held view, if not dogma, maintains that both nuclear and plasma membrane-associated ERs probably originate from the same gene and transcript that produce the classical intranuclear receptors ER-alpha and ER-beta. However, the physiological relatedness of this observation remains open to question. This review addresses evidence that, in addition to ER-alpha and ER-beta, there exist a variety of non-ER-alpha/non-ER-beta nuclear, cytoplasmic, and plasma membrane ERs in the brain, including G protein-coupled receptors; a novel, developmentally regulated, membrane-associated ER, ER-X; a functional, truncated ER-alpha variant, ER-46; and a putative ER that is immunochemically, structurally, and functionally completely distinct from ER-alpha and ER-beta.

ER-X: a novel, plasma membrane-associated, putative estrogen receptor that is regulated during development and after ischemic brain injury.

We showed previously in neocortical explants, derived from developing wild-type and estrogen receptor (ER)-alpha gene-disrupted (ERKO) mice, that both 17alpha- and 17beta-estradiol elicit the rapid and sustained phosphorylation and activation of the mitogen-activated protein kinase (MAPK) isoforms, the extracellular signal-regulated kinases ERK1 and ERK2. We proposed that the ER mediating activation of the MAPK cascade, a signaling pathway important for cell division, neuronal differentiation, and neuronal survival in the developing brain, is neither ER-alpha nor ER-beta but a novel, plasma membrane-associated, putative ER with unique properties. The data presented here provide further evidence that points strongly to the existence of a high-affinity, saturable, 3H-estradiol binding site (K(d), approximately 1.6 nm) in the plasma membrane. Unlike neocortical ER-alpha, which is intranuclear and developmentally regulated, and neocortical ER-beta, which is intranuclear and expressed throughout life, this functional, plasma membrane-associated ER, which we have designated "ER-X," is enriched in caveolar-like microdomains (CLMs) of postnatal, but not adult, wild-type and ERKO neocortical and uterine plasma membranes. We show further that ER-X is functionally distinct from ER-alpha and ER-beta, and that, like ER-alpha, it is re-expressed in the adult brain, after ischemic stroke injury. We also confirmed in a cell-free system that ER-alpha is an inhibitory regulator of ERK activation, as we showed previously in neocortical cultures. Association with CLM complexes positions ER-X uniquely to interact rapidly with kinases of the MAPK cascade and other signaling pathways, providing a novel mechanism for mediation of the influences of estrogen on neuronal differentiation, survival, and plasticity.

Estradiol-induced phosphorylation of ERK1/2 in explants of the mouse cerebral cortex: the roles of heat shock protein 90 (Hsp90) and MEK2.

Confocal laser scanning microscopy was used to identify the cells within organotypic slice cultures of the developing mouse cerebral cortex that respond to estradiol treatment by phosphorylation of ERK1 and ERK2. Estrogen-responsive cells resembled neurons morphologically and expressed the neuronal marker microtubule-associated protein 2B. The intracellular distribution of the phospho-ERK signal was both cytoplasmic and nuclear, but inhibition of protein synthesis abolished the appearance of the nuclear signal. ERK1and ERK2 also coimmunoprecipitated with heat shock protein 90 (Hsp90) in the cerebral cortical explants. Geldanamycin effectively disrupted this association and prevented ERK phosphorylation. Surprisingly, MEK2 but not MEK1 was the principal mediator of estradiol-induced activation of ERK. Our data demonstrate the requirement for Hsp90 in estrogen-induced activation of ERK1 and ERK2 by MEK2 in the developing mouse cerebral cortex and also provide insight into alternative mechanisms by which estradiol may influence cytoplasmic and nuclear events in responsive neurons via the MAP kinase cascade.