ABSTRACT
Wide spread use of Di-(2-ethylhexyl) phthalate (DEHP) has made it a ubiquitous contaminant in today’s environment, responsible for possible carcinogenic and endocrine disrupting effects. In the present investigation an integrative toxico-proteomic approach was made to study the estrogenic potential of DEHP. In vitro experiments carried out with DEHP (0.1-100 μM) induced proliferations (E-screen assay) in human estrogen receptors-α (ERα) positive MCF-7 and ERα negative MDA-MB-231 breast cancer cells irrespective of their ERα status. Further, DEHP suppressed tamoxifen (a potent anti-breast cancer drug) induced apoptosis in both cell types as shown by flowcytometric cell cycle analysis. Label-free quantitative proteomics analysis of the cell secretome of both the cell lines indicated a wide array of stress related, structural and receptor binding proteins that were affected due to DEHP exposure. The secretome of DEHP treated MCF-7 cells revealed the down regulation of lactotransferrin, an ERα responsive iron transport protein. The results indicated that toxicological effects of DEHP did not follow an ERα signaling pathway. However, the differential effects in MCF-7 and MDA-MB-231 cell lines indicate that ERα might have an indirect modulating effect on DEHP induced toxicity.
Subject(s)
Apoptosis/drug effects , Breast Neoplasms/pathology , Cell Cycle/drug effects , Cell Division/drug effects , Cell Line, Tumor/drug effects , Cell Line, Tumor/metabolism , Diethylhexyl Phthalate/toxicity , Environmental Pollutants/toxicity , Estrogen Receptor alpha/drug effects , Estrogen Receptor alpha/physiology , Estrogens , Female , Gene Expression Regulation, Neoplastic/drug effects , Humans , Lactoferrin/biosynthesis , Lactoferrin/genetics , Lactoferrin/metabolism , MCF-7 Cells/drug effects , MCF-7 Cells/metabolism , Mass Spectrometry/instrumentation , Microchemistry/instrumentation , Neoplasm Proteins/drug effects , Neoplasm Proteins/physiology , Neoplasm Proteins/metabolism , Neoplasms, Hormone-Dependent/pathology , Proteomics , Tamoxifen/antagonists & inhibitors , Tamoxifen/pharmacologyABSTRACT
El estrógeno y los receptores estrogénicos clásicos (REs), RE- alfa y RE-beta, han demostrado ser parcialmente responsable por las adaptaciones endoteliales uterinas durante el embarazo al corto y largo plazo. Las diferencias moleculares y estructurales, junto con los diferentes efectos causados por estos receptores en las células y los tejidos, sugieren que su función varía dependiendo de la manera en la cual el estrógeno se comunica con sus receptores. En ésta revisión bibliográfica se discuten la función del estrógeno y sus receptores clásicos en las adaptaciones cardiovasculares durante el embarazo y la expresión de los Res in vivo e in vitro en el endotelio de la arteria uterina durante el ciclo ovárico y el embarazo, a la vez comparado con la expresión en endotelio arterial de tejidos reproductivos y no reproductivos. Estos temas integran el conocimiento actual de este amplio campo científico con interpretaciones e hipótesis diversas relacionadas con los efectos estrogénicos mediados bien sea por uno o los dos REs. Esta revisión también incluye la relación con las adaptaciones vasodilatadoras y angiogénicas requeridas para modular el dramático incremento fisiológico en la perfusión útero-placentaria observada durante un embarazo normal.
Estrogen and classical estrogen receptors (ERs), ER- alpha and ER- beta, have been shown to be partially responsible for short and long term uterine endothelial adaptations during pregnancy. The molecular and structural differences, together with the various effects caused by these receptors in cells and tissues, suggest that their function varies depending upon estrogen and estrogen receptor signaling. In this review, we discuss the role of estrogen and its classic receptors in the cardiovascular adaptations during pregnancy and the expression of ERs in vivo and in vitro in the uterine artery endothelium during the ovarian cycle and pregnancy, while comparing their expression in arterial endothelium from reproductive and non-reproductive tissues. These themes integrate current knowledge of this broad scientific field with various interpretations and hypothesis that related estrogenic effects by either one or both ERs. This review also includes the relationship with vasodilator and angiogenic adaptations required to modulate the dramatic physiological increase to the uteroplacental perfusion observed during normal pregnancy.
Subject(s)
Humans , Female , Pregnancy , Endothelium, Vascular , Estrogens/physiology , Receptors, Estrogen/physiology , Uterus/blood supply , Blotting, Western , Immunohistochemistry , Neovascularization, Physiologic , Estrogen Receptor alpha/physiology , Estrogen Receptor beta/physiologyABSTRACT
The mammalian testis serves two main functions: production of spermatozoa and synthesis of steroids; among them estrogens are the end products obtained from the irreversible transformation of androgens by a microsomal enzymatic complex named aromatase. The aromatase is encoded by a single gene (cyp19) in humans which contains 18 exons, 9 of them being translated. In rats, the aromatase activity is mainly located in Sertoli cells of immature rats and then in Leydig cells of adult rats. We have demonstrated that germ cells represent an important source of estrogens: the amount of P450arom transcript is 3-fold higher in pachytene spermatocytes compared to gonocytes or round spermatids; conversely, aromatase activity is more intense in haploid cells. Male germ cells of mice, bank voles, bears, and monkeys express aromatase. In humans, we have shown the presence of a biologically active aromatase and of estrogen receptors (alpha and ß) in ejaculated spermatozoa and in immature germ cells in addition to Leydig cells. Moreover, we have demonstrated that the amount of P450arom transcripts is 30 percent lower in immotile than in motile spermatozoa. Alterations of spermatogenesis in terms of number and motility of spermatozoa have been described in men genetically deficient in aromatase. These last observations, together with our data showing a significant decrease of aromatase in immotile spermatozoa, suggest that aromatase could be involved in the acquisition of sperm motility. Thus, taking into account the widespread localization of aromatase and estrogen receptors in testicular cells, it is obvious that, besides gonadotrophins and androgens, estrogens produced locally should be considered to be physiologically relevant hormones involved in the regulation of spermatogenesis and spermiogenesis.