The information encoded by the sex steroid hormones testosterone and estrogen: a hypothesis

It is suggested that the sex steroid hormones testosterone and estrogen (SSH) provide receptor cells with reliable information on protein synthesis and on the level of oxidative metabolism in the cells of the gonads. The SSH are derived from the oxidation of cholesterol. This oxidation is a side reaction of the oxidative processes in the mitochondria that generate most of the energy to the organism. The amount of SSH that is synthesized is correlated to the partial pressure of oxygen at the synthesizing cells. The amount of free SSH that a cell can hold is checked by the damage that free steroids may cause. This damage is prevented by proteins that bind with SSH. As a result, SSH levels are correlated also with the ability of the SSH synthesizing cell to produce proteins that bind with them. A cell can only synthesize SSH in relation to the oxidative processes within it and to its ability to produce the binding proteins necessary to prevent the damage caused by SSH. As a result, the information conveyed by SSH is reliable. We examine the specific damage caused by testosterone and estrogen, and suggest why each of them is best suited for its function. Although both SSH can provide similar information on the metabolism in the cells that synthesize them, there are secondary reasons why testosterone and estrogen were selected to serve particular functions. Testosterone improves the efficiency of the proton pump at the mitochondria in producing ATP, but increases oxidative damage. Estrogen on the other hand decreases oxygen damage but also decreases the efficiency of the proton pump. These differences between the two SSH may explain why females use estrogen to inform the body about the activity of the cells in their gonads while males do it by testosterone. The increased oxidative damage may also explain why in males the testosterone that reaches the brain is turned into estrogen. We also suggest why fish use 11-keto testosterone and why insects do not use these two steroids.     

The digitalis-like steroid hormones: new mechanisms of action and biological significance

Digitalis-like compounds (DLC) are a family of steroid hormones synthesized in and released from the adrenal gland. DLC, the structure of which resembles that of plant cardiac glycosides, bind to and inhibit the activity of the ubiquitous cell surface enzyme Na(+), K(+)-ATPase. However, there is a large body of evidence suggesting that the regulation of ion transport by Na(+), K(+)-ATPase is not the only physiological role of DLC. The binding of DLC to Na(+), K(+)-ATPase induces the activation of various signal transduction cascades that activate changes in intracellular Ca(++) homeostasis, and in specific gene expression. These, in turn, stimulate endocytosis and affect cell growth and proliferation. At the systemic level, DLC were shown to be involved in the regulation of major physiological parameters including water and salt homeostasis, cardiac contractility and rhythm, systemic blood pressure and behavior. Furthermore, the DLC system has been implicated in several pathological conditions, including cardiac arrhythmias, hypertension, cancer and depressive disorders. This review evaluates the evidence for the different aspects of DLC action and delineates open questions in the field.     

Membrane-initiated steroid signaling (MISS): genomic steroid action starts at the plasma membrane

Plasma membrane (PM) steroid recognition sites are thought to be responsible only for rapid, non-genomic responses without any link to the nuclear receptor-mediated genomic effects of steroids. We focused on a PM "glucocorticoid-importer" (GC-importer) that imports GC into rat liver cells. This site interacts also with particular gestagens (progesterone, P; medroxyprogesterone, MP; ethynodiol, Ethy) and estrogens (ethinylestradiol, EE(2); mestranol), which do not bind to the nuclear GC receptor (GR). To elucidate the role of the GC-importer, we transfected a rat wild-type hepatocyte (CC-1) and a hepatoma cell line, unable to import GC (MH 3924), with a GC<-->GR-responsive luciferase (luc)-reporter gene. Selected steroids were tested for their ability to induce or inhibit luc expression. Corticosterone (B) and dexamethasone (Dex), but also the GC-antagonists cortexolone (Cortex), P and MP, induced luc. Even the PM-impermeable BSA-derivatives of B, Dex and Cortex did so to almost the same extent as the free steroids. MH 3924 cells respond stronger than CC-1 to luc inducing steroids. Luc expression was inhibited by RU 38 486, but also by EE(2) and Ethy. The thiol reactive mesylate-derivatives of B, Dex and Cortex induced to a considerably lesser extent than the free or BSA-steroids. The thiol reagent mersalyl blocks cellular entry of GC and inhibits luc induction in CC-1 cells. Incubation with EE(2) and B of PM-vesicles, isolated from liver cells, resulted in a decrease of the density of two 75 and 52kDa G-proteins reflecting a diminished exchange of GDP by GTP. CONCLUSION: the PM-residing GC-importer, now renamed "Steroid Hormone Recognition and Effector Complex" (SHREC) is an interdependent part of the complete GC signal propagation in which G-proteins are involved. Free SH-groups of SHREC are a prerequisite for genomic GC activity. Specific interactions between SHREC and GC-agonist/-antagonist trigger steroid-dependent signaling. However, import of the ligand into the cell terminates it. Thus, the PM-related non-genomic steroid responses are clearly linked to the GR-related genomic effects.     

The role of steroid hormones in ART

Steroid hormones hold a major role in female fertility and their proper utilisation and monitoring in modern assisted reproduction protocols is important. Oocyte maturation and endometrial receptivity are the two major factors that appear to be related to a successful outcome in Assisted Reproductive Technology (ART). Many reports suggest that oocyte immaturity accounts for a considerable loss of efficiency in ART, mainly due to the poor quality of the obtained embryos and their inability to develop normally. Oestrogen appears to exert its effects on the cytoplasmic maturation of the oocyte, while progesterone has been shown to accelerate meiotic resumption. Moreover, ovarian stimulation appears to affect the normal luteal function and shifts in the window of implantation as a response to hormonal supplementation have also been observed. The ethical limitations in conducting in vivo studies of human implantation, have led to an indirect hormonal- and morphologic-oriented assessment of endometrial receptivity. The two main protocols of luteal support involve either progesterone supplementation or hCG administration, whereas the combined supplementation with oestradiol remains controversial. This brief review aims to summarize the current knowledge on steroidal actions during the above processes and to address their potential use in the improvement of current ART protocols.     

Responsiveness and mechanisms of action of steroid hormones in human endometrial adenocarcinoma cells

The responsiveness and action mechanisms of steroid hormones and epidermal growth factor on human endometrial carcinoma cells are analyzed by using in vitro culture system. 1) The Ishikawa cells, derived from a well differentiated endometrial adenocarcinoma and possess ER and PR, are shown to respond to estrogens by increasing a variety of parameters, viz cell proliferation, PR levels, ALP and DNA polymerase activities. 2) ER and PR of those cells are localized in the nuclei by immunocytochemical staining using the monoclonal antibodies against to ER and PR, confirming the correctness of Gorski and Greene's one step theory involving the action mechanisms of steroid hormones. 3) Progestins reduced the ER level and stimulate E2DH activities and glycogen content, which are completely abolished by anti-progestin (RU486), suggesting that PR of those cells should be functional. 4) These responses to steroid hormones of Ishikawa cells are synergistically enhanced or appeared earlier by addition of EGF. 5) The main metabolite of E2 incubated with Ishikawa cells is E2-3-sulfate instead of E1, indicate that the higher estrogenic status may be persisted in endometrial cancer tissues.     

Effect of steroid hormones on vaginal epithelial cells: Anin vitro model for steroid hormone action

Conditions have been standardized to maintain rat vaginal epithelial cellsin vitro with more than 95% viability. Cultured epithelial cells were used to study the effects of normal fetal calf scrum, estradiol and progesterone on the incorporation of [³H]-uridine in RNA and incorporation of [¹⁴C]-aminoacids in proteins. While fetal calf serum and estradiol stimulate the incorporation of both uridine and afno acids, progesterone did not show any effect. Estradiol treated vaginal cells show typical fcroridges (indicative of keratinization of cells) in contrast to estradiol deprived cells, which show microvilli on cell surface when examined in scanning electron microscope.