Inhibition of estrogen-induced proliferation of cultured rabbit uterine epithelial cells by a cell density-dependent factor produced by the same cells

Regulation of Akt expression and phosphorylation by 17beta-estradiol in the rat uterus during estrous cycle

Molecular and intra-cellular mechanisms involved in the regulation of apoptosis processes in endometrial cells are poorly understood and documented. We have investigated the possibility that Akt survival pathway might be involved in the regulation of apoptosis in the uterus during the estrous cycle. Rats with regular estrous cycle (4 days) were killed at different days of estrous cycle (diestrus, proestrus, estrus and metestrus). Uteri were collected and fixed for immunohistochemical staining (IHC) and apoptotic cell death detection by [TdT]-mediated deoxyuridinetriphosphate nick end-labelling (TUNEL) or endometrial protein extracts collected for Western analysis. TUNEL analysis revealed that apoptosis was mainly found at estrus compared to other day of estrous cycle. TUNEL positive cells were apparent in luminal epithelial cells only. No apoptotic cells were observed at proestrus. In contrast, proliferation was maximal at proestrus as confirmed with the expression of CDC47/MCM7 (a cell proliferation marker). Intact form of caspase-3 was maximal at proestrus and was reduced only at estrus. Likewise, presence of a specific cleaved caspase-3 fragment was observed only at estrus and IHC revealed that cleaved caspase-3 signal was found in luminal epithelial cells. PTEN protein, a phosphatase involved in the regulation of Akt phosphorylation, was present at all days of estrous cycle and showed no significant regulation in relation to cycle. Expression of phospho-Akt (the activated form of Akt) was present at metestrus, diestrus, and proestrus but decreased significantly at estrus. Akt protein expression was maximal at estrus. IHC revealed that Akt expression was high in both stromal and epithelial cells at estrus. Further studies using ovariectomized rats demonstrated that 17beta-estradiol increased endometrial cell proliferation which was accompanied by an increase of both Akt expression and phosphorylation. These results suggest that increased Akt expression and activity in response to estradiol may be an important mechanism to protect endometrial cells from apoptotic triggering and to induce endometrial cell proliferation, whereas inhibition of Akt activity leads to caspase-3 activation and apoptosis in endometrial cells.

Regulation of the membrane estrogen receptor-alpha: role of cell density, serum, cell passage number, and estradiol

We used modified immunocytochemical conditions to quantify a membrane form of estrogen receptor-alpha (mERalpha) in a rat pituitary tumor cell line, GH3/B6/F10. We studied the regulation of mERalpha vs. levels of intracellular ERalpha (iERalpha) using our 96-well plate immunoassay. The anti-ERalpha antibody C542 was used to label the ERalpha (via conjugated alkaline phosphatase) in fixed permeabilized (for iERalpha) vs. nonpermeabilized cells (for mERalpha). Expression of mERalpha was highest at low cell densities (<1000 cells/well) and decreased significantly at densities where cellular processes touched, whereas the more abundant iERalpha increased with increasing cell density over the same range. Serum starvation for 48 h caused increases in mERalpha, whereas iERalpha levels showed no significant changes. A large decline in mERalpha and iERalpha levels with cell passage number was observed. Minutes after nM 17beta-estradiol (E2) treatment, a portion of the cells rounded up and detached from the culture plate, whereas nM cholesterol had no such effect. Although E2 treatment did not change mERalpha levels, the antigen was reorganized from a fine particulate to aggregation into asymmetric large granules of staining. That common culturing conditions favor down-regulation of mERalpha may explain the relatively few reports of this protein in other experimental systems.

Progestins prevent apoptosis in a rat endometrial cell line and increase the ratio of bcl-XL to bcl-XS

Endometrial cell proliferation and cell death are regulated by ovarian hormones. The fall of ovarian progesterone in late secretory phase, or the artificial withdrawal of ovarian hormones during early pregnancy, are followed by programmed cell death of uterine epithelial cells. Aspects of this cell-specific response have been reproduced in a newly established rat endometrial cell line which expresses functional progesterone receptor. At low concentrations of serum and in the absence of glucocorticoids, these cells were dependent on progestins for survival. Removal of progesterone or addition of the antiprogestins RU38486 or ZK98299 led to a substantial increase of apoptotic cells indicated by the accumulation of internucleosomally degraded DNA. The hormonal control of cell proliferation and cell death correlated with the overall quantity and distribution of the different bcl-X transcripts. Progesterone administration not only increased total bcl-X mRNA level but also shifted the quantitative ratio between the different mRNA isoforms in favor for the apoptosis inhibiting form, bcl-XL, compared with the apoptosis promoting form, bcl-XS. These effects were rapid and could not be prevented by inhibitors of protein synthesis. As the low level of bcl-2 and bax mRNA was not influenced by progesterone treatment, the observed changes in total amount of bcl-X transcripts and spliced isoforms could represent the mechanism by which progesterone controls cell death in epithelial cells of the endometrium.

Regulation and clinical implications of corneal epithelial stem cells

The corneal epithelium is known to have a rapid self-renewing capacity. The major advance in the field of corneal epithelial cell biology in the last decade is the establishment of the location of corneal epithelial stem cells at the limbus, i.e., the junctional zone between the cornea and the conjunctiva. This concept has helped explain several experimental and clinical paradoxes, produced a number of important clinical applications, and spawned many other research studies. This unique enrichment of epithelial stem cells at a site anatomically separated from their transient amplifying cells makes the ocular surface an ideal model to study the regulation of epithelial stem cells. The present review includes data from more recent studies and lays out other areas for future investigation, especially with respect to the role of apoptosis and cytokine dialogue between limbal epithelial stem cells and their stromal microenvironment.

Astrocytes and neurosteroids: metabolism of pregnenolone and dehydroepiandrosterone. Regulation by cell density

The rat central nervous system (CNS) has previously been shown to synthesize pregnenolone (PREG) and convert it to progesterone (PROG) and 7 alpha-hydroxy-PREG (7 alpha-OH PREG). Astrocytes, which participate to the regulation of the CNS function, might be involved in the metabolism of neurosteroids. Purified type 1 astrocytes were obtained from fetal rat forebrain with the use of selective culture conditions and were identified by immunostaining with specific antibodies (GFAP+, A2B5-). They were plated at low, intermediate, or high densities (2.5-5 x 10(5), 1-2 x 10(6), or 4-8 x 10(6) cells/dish, respectively) and maintained for 21 d. They were then incubated with 14C-PREG and 14C-DHEA for 24 h and the steroids extracted from cells and media were analyzed. Most radioactive derivatives were released into incubation media. Two metabolic pathways were mainly observed. PREG and DHEA were oxidized to PROG and androstenedione (ADIONE), respectively, [3 beta-hydroxysteroid-dehydrogenase, delta 5-->4 3-ketosteroid-isomerase (3 beta-HSD) activity], and converted to 7 alpha-OH PREG and 7 alpha-OH DHEA, respectively (7 alpha-hydroxylase activity). After low density plating, the formation of PROG and ADIONE was approximately 10% of incubated radioactivity, tenfold larger than that of 7 alpha-hydroxylated metabolites. In contrast, after high density plating, low levels of PROG and ADIONE were formed, whereas the conversion to either 7 alpha-OH PREG or 7 alpha-OH DHEA was > or = 50%. The results expressed per cell indicated that the 3 beta-HSD activity was almost completely inhibited at high cell density, in contrast to the 7 alpha-hydroxylation which was maintained or increased. The pattern of steroid metabolism was related to cell density at the time of measurement and not to an early commitment of cells: when primary cultures were plated at high density (8 x 10(6) cells/dish), then subcultured after several dilutions (3-, 9-, or 27-fold), the 3 beta-HSD activity was recovered only at low density. Furthermore, when 5 x 10(5) cells were centrifuged and the resulting clusters were plated, 3 beta-HSD activity was decreased, whereas steroid 7 alpha-hydroxylation was enhanced. This implies that cell density per se, but neither cell number nor a diffusible factor(s) is involved in the regulation of steroid metabolism. We conclude that astrocytes in culture metabolize PREG and DHEA, and that the metabolic conversions and, therefore, the related enzymatic activities depend on cell-to-cell contacts.(ABSTRACT TRUNCATED AT 400 WORDS)

Proliferation of guinea-pig uterine epithelial cells in serum-free culture conditions: effect of 17 beta-estradiol, epidermal growth factor and insulin

The effects of 17 beta-estradiol (E2), epidermal growth factor (EGF) and insulin, alone or in association on guinea-pig uterine epithelial cell proliferation were examined in serum-free culture conditions. Primary cultures of epithelial cells were made quiescent by serum depletion, then incubated in a chemically defined medium. In this medium, insulin increased DNA synthesis but not in a dose-dependent manner for concentrations ranging from 0.2 to 10 micrograms/ml. A significant effect of EGF was found only for the highest concentration tested (100 ng/ml). E2 alone or in the presence of insulin (1 microgram/ml) had no effect whatsoever on the concentration tested (10(-10)-10(-5)M). Insulin (10 micrograms/ml) plus EGF (100 ng/ml) exerted on DNA synthesis and cell proliferation a significant additive effect which was identical to the growth stimulation induced by 10% fetal calf serum. The effects of insulin plus EGF were not modified by the addition of E2. These findings suggest that E2 is not directly mitogenic for uterine epithelial cells in defined culture conditions and that the mitogenic response to optimal concentration of insulin plus EGF is independent of E2.

Progesterone in vitro stimulates secretion of a specific protein by ovine epithelial endometrial cells

Cultured ovine epithelial endometrial cells from oestrogen-treated ovariectomized ewes were treated in vitro with combinations of oestradiol-17 beta (E), progesterone (P) and the P-receptor antagonist RU486 (each 10(-6) to 10(-9) M), in the presence of [35S]methionine. Neither DNA content of dishes nor total protein were increased in treatment compared with control dishes. Incorporation of [35S] into secreted protein was lower from cells treated in vitro with P or E + P (10(-9) M) than from those treated with E (10(-9) M, P less than 0.01). Incorporation of [35S] into cellular protein was decreased by P (10(-9) M, P less than 0.025). SDS-PAGE analysis of secreted proteins enabled measurement of levels of a 46K protein which is secreted maximally following E + P administration in vivo. In vitro, P either alone or with E (each 10(-7) M) increased the abundance of the 46K protein in cell secretions by a factor of 1.5 +/- 0.1 (N = 9) or 1.8 +/- 0.3 (N = 10) respectively (P less than 0.01) compared with controls. The administration of E (10(-7) M) or either or both steroids at 10(-9) M, was without effect. RU486 alone (10(-6) to 10(-8) M) was also without effect but in the presence of E + P or P, blocked the increase in the 46K protein, suggesting this effect is mediated via binding of P to its receptor.

Evidence for soluble factors regulating cell death and cell proliferation in primary cultures of rabbit endometrial cells grown on collagen

Primary cultures of rabbit endometrial cells grown on collagen substrates exhibit cyclic changes in DNA content throughout extended periods of culture. These cycles are characterized by periods of significant increases and decreases in the DNA content of the cultures or number of cells present, yet through the entire duration of culture there is no net change in the total DNA. The rates of cell proliferation and cell death change through time in culture with the same periodicity as the changes in DNA. Neither changes in the rate of cell proliferation nor the rate of cell death alone are sufficient to account for the changes in DNA. Rather, there appears to be a feedback mechanism operating between cell proliferation and cell death such that when one increases, the other increases concomitantly in order to maintain a homeostasis in total culture mass. This homeostasis appears to be mediated by a soluble cell proliferation factor (CPF) and a cell death factor (CDF) produced by the cells. CPF and CDF may be obtained from either conditioned media or cultured cell extracts. These biological activities are heat and trypsin sensitive. The major mode of cell death in these cultures appears to be apoptosis or programmed cell death, characteristic of renewing epithelia. The data suggest that this tissue culture model system represents a renewing cell population containing stem cells and their progeny, whose total growth is strictly regulated by CPF and CDF. As such, it provides a model system in which to study homeostasis and how it may be altered in hyperplasia and neoplasia, as well as its regulation by hormones.

Regulation of cultured rat vaginal epithelial cells by 17 beta-estradiol and progesterone

We have previously described a technique to obtain short-term cultures of epithelial cells from Wistar rat vaginae. In order to improve the efficiency and life span of these cultures, in the present study we have cultured the vaginal cells with lethally irradiated 3T3 cell feeder layers. Under this condition, cells can grow for several weeks while retaining epithelial characteristics and can eventually be subcultured. The proliferative effect of the ovarian hormones in these cultures was studied using two different approaches, [Methyl-3H]Thymidine (3HTdr) incorporation and increase in cell number. Both assays indicated a proliferative effect of 17 beta-estradiol and progesterone at physiological concentrations. This proliferative effect was also shown in feeder layer-free cultures, ruling out an indirect effect through the mesodermal cells. The capacity of the hormones to modify terminal differentiation in the culture was also studied, using colony stratification as an indicator of differentiation. Progesterone and fetal calf serum had an inhibitory effect on terminal differentiation, whereas 17 beta-estradiol induced a stimulatory action. This culture model allowed us to show a direct effect of the ovarian hormones on vaginal cells in vitro and seems to be a useful model to study hormone-cell interactions in vitro.

Estrogen response of MCF-7 cells grown on diverse substrates and in suspension culture: promotion of morphological heterogeneity, modulation of progestin receptor induction; cell-substrate interactions on collagen gels

In this study we observed the incidence of hormone sensitivity in the response of MCF-7 cells to estrogen stimulation when the cells were cultured in different contact environments (hydrophilic plastic, bovine corneal extracellular matrix, type I collagen and in suspension culture). The major purpose was to describe the influence of cell to cell and cell to substrate contacts on the morphological response to estrogen treatment. However, other parameters including growth and induction of progestin receptor were also explored, keeping in mind that the MCF-7 cell line, although representative of normal mammary epithelium in that it contains a similar hormone receptivity, was selected in vitro from a metastatic population in a pleural effusion. Although substrate conditions did not modify growth enhancement by estrogens, progestin receptor levels were significantly higher in three-dimensional spheroid cultures in which cell to cell contacts were optimal due to elimination of basal contact. A careful morphological survey of large surfaces lead to an objective opinion of the overall effect of the hormone treatment on the non-cloned cell line in which a marked heterogeneity in the response of individual cells was observed. In terms of morphofunctional differentiation, the edification of acini with dense microvillus coating was best in suspension culture. When sections were made perpendicular to the plane of cultures on collagen gel rafts two other phenomena were noted: decrease in intercellular junctions, resulting in reduced cell to cell cohesion, and accumulation biodegradation products in the collagen lattice. This suggested a hormone-mediated interaction between the metastatic cells and the fibrillar substrate, collagen I, one of the major constituents of tissue stroma. This estrogen response might be related to the metastatic phenotype and must be distinct from their hormone sensitivity in terms of growth and differentiation since hormone receptivity is generally considered to be a favorable prognosis for breast cancer.

Induction of DNA synthesis in cultured rabbit uterine cells by estradiol and inhibition of the estrogen response

Addition of 17 beta-estradiol to primary cultures of rabbit uterine cells resulted in the induction of DNA synthesis. This phenomenon is present only in cells cultured at low density. Culture medium taken from high density cultures inhibited it, suggesting that those cells produce a soluble estrogen-inhibiting factor.

A developmental view of endometrial hyperplasia and carcinoma based on experimental research

On the basis of experimental research, using rabbit uterine epithelium as a model, it is postulated that human endometrial hyperplasia or carcinoma may be due to derangement of intrinsic growth mechanisms such as cell proliferation, migration, loss and differentiation. Ovarian hormones, estrogen inhibitor or amplifying factors, prostaglandins, stroma-epithelial interactions, proteolytic activity and hormone receptors, all regulate the described intrinsic growth mechanisms, and their excess or lack could result in altered growth patterns. It is also proposed that different types of endometrial carcinoma could result from neoplastic transformation of cells at different stages of differentiation. Since cells at those stages could respond to various hormones in different ways, it would seem of therapeutic value to know the cell of origin in each type of endometrial carcinoma.