Progesterone is a cell death suppressor that downregulates Fas expression in rat corpus luteum

In female rats, apoptotic cell death in the corpus luteum is induced by the prolactin (PRL) surge occurring in the proestrous afternoon during the estrous cycle. We have previously shown that this luteolytic action of PRL is mediated by the Fas/Fas ligand (FasL) system. During pregnancy or pseudopregnancy, apoptosis does not occur in the corpus luteum. Progesterone (P4), a steroid hormone secreted from luteal steroidogenic cells, attenuated PRL-induced apoptosis in cultured luteal cells in a dose-dependent manner. P4 significantly decreased the expression of mRNA of Fas, but not FasL, in cultured luteal cells prepared from both proestrous and mid-pseudopregnant rats. These data indicate that P4 suppresses PRL-induced luteal cell apoptosis via reduction of the expression level of Fas mRNA in the corpus luteum, suggesting that P4 acts as an important factor that can change the sensitivity of corpus luteum to PRL.     

Treatment of multidrug resistant (MDR1) murine leukemia with P-glycoprotein substrates accelerates the course of the disease

The prolactin (PRL) surge in cycling rats during the proestrous afternoon is an inducer of apoptotic cell death in luteal cells. This luteolytic action of PRL is peculiar, because PRL may be categorized as a survival factor, if other known physiological functions of PRL are taken into account. Here we analyzed the underlying molecular/cellular mechanisms of this PRL-induced apoptosis. Corpora lutea (CL) were prepared from the ovary on the proestrous day and cultured with or without PRL (2 microg/ml). An addition of PRL to the culture medium induced DNA breakdown in the nuclei of cells mostly identified as steroidogenic by 3beta-HSD activity staining, and the number of 3beta-HSD-positive cells were significantly decreased, indicating the induction of apoptotic cell death by PRL among luteal cells in culture. Next, the expression of membrane form-Fas ligand (mFasL) in the luteal cell lysate was quantified, because Fas receptor is known to have an exact physiological role in luteolysis. An addition of PRL increased the expression of mFasL. Immunostaining and TUNEL assay on regressing CL revealed that both CD3-positive cells and FasL-positive cells were co-localized in the regions where apoptosis convergently occurred. Moreover, an addition of concanavalin A (ConA), a T-cell specific activator, to the culture mimicked the PRL action by inducing apoptosis in luteal cells and enhancing the expression of mFasL. These data suggest that the CD3-positive T lymphocyte in the CL is at least one of the PRL-effector cell species during the process of luteolysis in rats, and that FasL expression of these cells is upregulated by PRL.     

Soluble Fas (FasB) regulates luteal cell apoptosis during luteolysis in murine ovaries

During luteolysis, luteal cell apoptosis is induced by the Fas ligand (FasL)/Fas system. In murine luteal bodies, we demonstrated the expression of mRNA of soluble form of Fas (FasB), which binds to FasL and prevents apoptosis induction. By in situ hybridization, strong expression of FasB mRNA was observed in normal luteal bodies, in which no apoptotic cells were detected, but negative/trace expression in regressing luteal bodies, in which many apoptotic cells were observed. Immunohistochemical staining revealed that Fas and TNF-alpha were localized in both normal and regressing luteal bodies, but IFN-gamma was localized only in regressing luteal bodies. Apoptosis was induced in primary cultured luteal cells, when they were pretreated with TNF-alpha and IFN-gamma and then incubated with TNF-alpha, IFN-gamma, and mouse recombinant FasL (rFasL). However, no apoptosis was detected in the cells, when they were treated with rFasL alone, TNF-alpha alone, IFN-gamma alone, TNF-alpha and rFasL, IFN-gamma and rFasL, or TNF-alpha and IFN-gamma. Fas mRNA expression in cultured luteal cells was up-regulated by the treatment of TNF-alpha, IFN-gamma, or TNF-alpha and IFN-gamma. The expression of FasB mRNA was down-regulated, when the cells were treated with TNF-alpha and IFN-gamma, but its expression was not changed by the treatment of TNF-alpha alone or IFN-gamma alone. We conclude that FasB inhibits the apoptosis induction in luteal cells of normal luteal bodies, and that decreased FasB production induced by TNF-alpha and IFN-gamma made possible the apoptosis induction in the luteal cells of regressing luteal bodies.     

Responsiveness of mouse corpora luteal cells to Fas antigen (CD95)-mediated apoptosis

Regression of the corpus luteum (CL) occurs by apoptosis. The Fas antigen (Fas) is a cell surface receptor that induces apoptosis in sensitive cells when bound to Fas ligand or agonistic anti-Fas monoclonal antibodies (Fas mAb). A potential role for Fas to induce apoptosis in dispersed CL cell preparations was tested in cells isolated from mice on Days 2-4 of pseudopregnancy. Total CL dispersates, containing steroidogenic luteal cells, fibroblasts, and endothelial cells, were cultured. The effect of pretreatment of cultures with cytokines interferon gamma (IFN) and tumor necrosis factor alpha (TNF) was examined because these cytokines demonstrated effects on Fas-mediated apoptosis in other cell types. Fas mAb had no effect on viability of CL cells cultured in 5% fetal bovine serum (FBS) and pretreated with or without IFN or TNF, but Fas mAb did kill 23% of the cells in cultures pretreated with IFN + TNF. Fas mRNA was detectable in cultured CL cells and was increased 2.1-, 2. 0-, and 11.8-fold by treatment with TNF, IFN, or IFN + TNF, respectively. CL cells treated with the protein synthesis inhibitor cycloheximide (CX) were killed by Fas mAb in the absence of cytokine pretreatment (34%); pretreatment with IFN or IFN + TNF further potentiated killing (62% and 96%, respectively), whereas pretreatment with TNF had no effect (42%). Cells cultured in medium supplemented with insulin, transferrin, and selenium instead of FBS were killed by Fas mAb in the presence of IFN (23%) or IFN + TNF (29%) but not in the presence of TNF. Cells derived from the mouse CL have a functional Fas pathway that is inhibited by FBS and activated by treatment with CX, IFN, and IFN + TNF.     

Size distribution of luteal cells from pregnant and non-pregnant marmoset monkeys and a comparison of the morphology of marmoset luteal cells with those from the human corpus luteum

The size distribution of marmoset luteal cells was determined on Days 6, 14 and 20 after ovulation in non-pregnant cycles and in early pregnancy. Image analysis was used to estimate the cell diameter of dispersed cells prepared from the marmoset corpus luteum (CL). Steroidogenic cells showed a size distribution consistent with one population of cells. There was a significant increase in mean cell diameter (P less than 0.05) from Day 6 to Day 14 in pregnant and non-pregnant animals with no further increase on Day 20. Micrographs of marmoset luteal tissue showed cells of greater than 10 micron containing the organelles typical of steroid-producing cells, and smaller non-steroidogenic cells surrounding the steroid-producing cells. On the basis of microscopy, there were no areas within the CL where cell composition was noticeably different. In contrast, micrographs of human luteal tissue showed two types of steroidogenic cell; most cells were similar to those in the marmoset CL but a smaller population of smaller cells could be distinguished around the periphery and along vascular septa. It is likely that these smaller and larger types of steroidogenic cells are of theca and granulosa cell origin respectively, the two cell populations differing in the degree of electron density and amount of rough endoplasmic reticulum. A distinguishing feature between marmoset and human luteal cells was the shape of the mitochondrian which were considerably rounder in marmoset luteal cells. The origin of steroidogenic cells in the marmoset CL is unclear, although in marmosets and man the luteal cell types display morphological characteristics distinct from the large and small luteal cells described for CL of the domestic ungulates.     

Progesterone is a suppressor of apoptosis in bovine luteal cells

Progesterone is suggested to be a suppressor of apoptosis in bovine luteal cells. Fas antigen (Fas) is a cell surface receptor that triggers apoptosis in sensitive cells. Furthermore, apoptosis is known to be controlled by the bcl-2 gene/protein family and caspases. This study was undertaken to determine whether intraluteal progesterone (P4) is involved in Fas L-mediated luteal cell death in the bovine corpus luteum (CL) in vitro. Moreover, we studied whether an antagonist of P4 influences gene expression of the bcl-2 family and caspase-3 and the activity of caspase-3 in the bovine CL. Luteal cells obtained from the cows in the midluteal phase of the estrous cycle (Days 8-12 of the cycle) were exposed to a specific P4 antagonist (onapristone [OP], 10(-4) M) with or without 100 ng/ml Fas L. Although Fas L alone did not show a cytotoxic effect, treatment of the cells with OP alone or in combination with Fas L resulted in killing of 30% and 45% of the cells, respectively (P <0.05). DNA fragmentation was observed in the cells treated with Fas L in the presence of OP. The inhibition of P4 action by OP increased the expression of Fas mRNA (P <0.01); however, it did not affect bax or bcl-2 mRNA expression (P >0.05). Moreover, OP stimulated expression of caspase-3 mRNA (P <0.01). The overall results indirectly show that intraluteal P4 suppresses apoptosis in bovine luteal cells through the inhibition of Fas and caspase-3 mRNA expression and inhibition of caspase-3 activation.     

Tumor-induced apoptosis of human IL-2-activated NK cells: role of natural cytotoxicity receptors

We provide evidence that tumor cells can induce apoptosis of NK cells by engaging the natural cytotoxicity receptors (NCR) NKp30, NKp44, and NKp46. Indeed, the binding between NCR on NK cells and their putative ligands on tumor target cells led to NK cell apoptosis, and this event was abolished by blocking NCR/NCR-ligand interaction by anti-NCR-specific mAbs. The engagement of NCR induced up-regulation of Fas ligand (FasL) mRNA, FasL protein synthesis, and release. In turn, FasL interacting with Fas at NK cell surface causes NK cell suicide, as apoptosis of NK cells was inhibited by blocking FasL/Fas interaction with specific mAbs. Interestingly, NK cell apoptosis, but not killing of tumor target cells, is inhibited by cyclosporin A, suggesting that apoptosis and cytolysis are regulated by different biochemical pathways. These findings indicate that NCR are not only triggering molecules essential for antitumor activity, but also surface receptors involved in NK cell suicide.     

Effects of luteinizing hormone on luteal cell populations in hypophysectomized ewes

To examine the effect of purified LH on development and function of luteal cells, 27 ewes were assigned to: (1) hypophysectomy plus 2 micrograms ovine LH given i.v. at 4-h intervals from Days 5 to 12 of the oestrous cycle (oestrus = Day 0; Group H + LH; N = 7); (2) hypophysectomy with no LH replacement (Group N-LH; N = 6); (3) control (no hypophysectomy) plus LH replacement as in Group H + LH (Group S + LH; N = 7); (4) control with no LH treatment (Group S-LH; N = 7). Blood samples were collected at 4-h intervals throughout the experiment to monitor circulating concentrations of LH, cortisol and progesterone. On Day 12 of the oestrous cycle corpora lutea were collected and luteal progesterone concentrations, unoccupied receptors for LH and number and sizes of steroidogenic and non-steroidogenic luteal cell types were determined. Corpora lutea from ewes in Group H-LH were significantly smaller (P less than 0.05), had lower concentrations of progesterone, fewer LH receptors, fewer small luteal cells and fewer non-steroidogenic cells than did corpora lutea from ewes in Group S-LH. The number of large luteal cells was unaffected by hypophysectomy, but the sizes of large luteal cells, small luteal cells and fibroblasts were reduced. LH replacement in hypophysectomized ewes maintained luteal weight and the numbers of small steroidogenic and non-steroidogenic luteal cells at levels intermediate between those observed in ewes in Groups L-LH and S-LH. In Group H + LH ewes, luteal and serum concentrations of progesterone, numbers of luteal receptors for LH, and the sizes of all types of luteal cells were maintained. Numbers of small steroidogenic and non-steroidogenic cells were also increased by LH in hypophysectomized ewes. In Exp. II, 14 ewes were assigned to: (1) sham hypophysectomy with no LH replacement therapy (Group S-LH; N = 5); (2) sham hypophysectomy with 40 micrograms ovine LH given i.v. at 4-h intervals from Day 5 to Day 12 of the oestrous cycle (Group S + LH; N = 5); and (3) hypophysectomy plus LH replacement therapy (Group H + LH; N = 4). Experimental procedures were similar to those described for Exp. I. Treatment of hypophysectomized ewes with a larger dose of LH maintained luteal weight, serum and luteal progesterone concentrations and the numbers of steroidogenic and non-steroidogenic luteal cells at control levels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Expression of apoptosis-related genes Fas/FasL, Bax/Bcl-2 and Caspase-3 in rat corpus luteum during luteal regression

Corpus luteum (CL) is a transient endocrine organ formed from the ovulated follicle. CL produces progesterone and estrogen that are important in preparing the uterine environment for implantation and maintaining gestation. Pregnancy maintains the CL function; otherwise, CL re-gresses rapidly. Cycling formation and regression of CL is essential for initiation of new follicular growth and differentiation, and subsequently ovulation and luteinization[1]. Luteal regression could be divided int…     

Proliferation of Luteal Steroidogenic Cells in Cattle

The rapid growth of the corpus luteum (CL) after ovulation is believed to be mainly due to an increase in the size of luteal cells (hypertrophy) rather than an increase in their number. However, the relationship between luteal growth and the proliferation of luteal steroidogenic cells (LSCs) is not fully understood. One goal of the present study was to determine whether LSCs proliferate during CL growth. A second goal was to determine whether luteinizing hormone (LH), which is known have roles in the proliferation and differentiation of follicular cells, also affects the proliferation of LSCs. Ki-67 (a cell proliferation marker) was expressed during the early, developing and mid luteal stages and some Ki-67-positive cells co-expressed HSD3B (a steroidogenic marker). DNA content in LSCs isolated from the developing CL increased much more rapidly (indicating rapid growth) than did DNA content in LSCs isolated from the mid CL. The cell cycle-progressive genes CCND2 (cyclin D2) and CCNE1 (cyclin E1) mRNA were expressed more strongly in the small luteal cells than in the large luteal cells. LH decreased the rate of increase of DNA in LSCs isolated from the mid luteal stage but not in LSCs from the developing stage. LH suppressed CCND2 expression in LSCs from the mid luteal stage but not from the developing luteal stage. Furthermore, LH receptor (LHCGR) mRNA expression was higher at the mid luteal stage than at the developing luteal stage. The overall results suggest that the growth of the bovine CL is due to not only hypertrophy of LSCs but also an increase in their number, and that the proliferative ability of luteal steroidogenic cells decreases between the developing and mid luteal stages.     

Detection of Fas ligand in the bovine oviduct

Presence of a Fas-Fas ligand (FasL) system defines the immune-privileged status of certain tissues such as placenta. This study examined the fluids and tissue(s) of the bovine oviduct, where both spermatozoa and early embryos escape elimination by the female immune system, for the presence and the distribution of Fas and FasL, which might provide an explanation for the immune-privileged site of this organ. In the present study, the immunolocalisation of FasL and Fas, as well as the gene expression of FasL, were determined in the uterotubal junction (UTJ), isthmic (I) and ampullar (A) segments of the oviduct during oestrus and the luteal phase of the oestrous cycle. The degree of apoptosis of oviductal epithelium was examined by the TUNEL method. Oviductal fluid (ODF), collected chronically via indwelling catheters from the I or A segments during both non-luteal and luteal phases of the cycle, was analysed for the presence of FasL. The Fas immunostaining was scattered along the epithelium of all regions of the oviduct and cycle stages investigated, whereas FasL immunolabelling was more conspicuous in oestrous samples. This staining disappeared during the luteal phase, which was particularly evident in the sperm reservoir (UTJ and I). There were fewer TUNEL-positive cells than Fas- or FasL-positive cells in the oviductal epithelium, suggesting that tubal Fas and FasL are not directly involved in epithelial apoptosis. Western blot analyses detected FasL in ODF collected from both I and A, most conspicuously as a 24-27kDa band but also at a 40-45kDa band level. FasL mRNA was expressed in the epithelial cells from the sperm reservoir and A during both non-luteal and luteal phases. However, the level of expression differed significantly between segments during the luteal phase. The results provide novel evidence that the Fas-FasL system is present in the bovine oviduct and could be involved in mediating survival of spermatozoa and early embryos.     

Fas, FasL, Bcl-2, and Bax in the endometrium of rhesus monkey during the menstrual cycle

To study possible role and regulation of apoptosis occurred in primate endometrium, the expression of apoptosis-related molecules, Fas, FasL, B cell lymphoma/leukaemia-2 (Bcl-2), and Bax were analyzed in relation to occurrence of apoptosis and proliferation in the cycling endometrium of the rhesus monkey using immunohistochemistry and Western blot. The cell apoptosis and proliferation were evaluated by means of in situ 3'-end labeling and Ki67 immunostaining, respectively. The results showed that the expressions of Fas, Fas ligand (FasL), Bcl-2, and Bax were co-localized predominantly in the epithelial cells of the endometrium. Modest Fas staining with no obvious change was detected throughout the menstrual cycle, while the levels of FasL and Bax protein in the epithelial cells increased in the secretory phase when apoptosis was most prevalent. In contrast, epithelial immunostaining for Bcl-2 was maximal during the proliferative phase and decreased in the secretory phase. Bcl-2 immunoreactivity was also detected in some immunocytes. The coordinated expression of Fas, FasL, Bcl-2, and Bax in the cycling endometrium of the rhesus monkey suggests that the cyclic changes in endometrial growth and regression may be regulated by the balance of these factors under the action of ovary steroids.     

Fas-mediated apoptosis is suppressed by calf serum in cultured bovine luteal cells

Calf serum (CS) is a common supplement used in cell culture. It has been suggested that CS contains substances protecting cells against apoptosis. To examine whether a culture system including CS is appropriate for studying apoptosis in bovine luteal cells, we examined the influence of CS on the expression of Fas, bcl-2 and bax gene. Since progesterone (P(4)) is known to be an anti-apoptotic factor in bovine luteal cells, the present study was carried out to examine the P(4) effect on apoptosis. Bovine mid-luteal cells were exposed to Fas ligand (Fas L) in the presence or in the absence of P(4) antagonist (onapristone, OP) in a basal medium (BM) containing 5% CS (BM-CS) or BM containing 0.1% BSA (BM-BSA). Although Fas L alone, OP alone or Fas L plus OP did not show any cytotoxic effect on the cells cultured in BM-CS, administration of OP or OP in combination with Fas L resulted in the killing of 30% and 55% of the cells cultured in BM-BSA medium, respectively (p<0.05). Concomitantly, CS inhibited bax mRNA expression and stimulated bcl-2 expression in the cells (p<0.05). Moreover, in the cells cultured with BM-CS, Fas mRNA expression was smaller than that of cells incubated in BM-BSA medium (p<0.05). The overall results suggest that CS suppressed Fas-mediated cell death in cultured bovine luteal cells by promoting the ratio of bcl-2 to bax expression and by inhibiting Fas expression. Therefore, it may be suggested that CS contains such anti-apoptotic substances (growth factors) amplifying the cell survival pathways in the bovine corpus luteum (CL) in vitro.     

Interferon alpha augments activation-induced T cell death by upregulation of Fas (CD95/APO-1) and Fas ligand expression.

Interferon alpha (IFN-alpha) plays a prominent role in the therapy of a variety of diseases. The Fas/FasL system is crucial for the cytotoxic function and the peripheral elimination of activated T lymphocytes (ATC) by a mechanism referred to as activation-induced cell death (AICD). Recent studies suggest a link between IFN-alpha, the 2', 5'- oligoadenylate system and apoptosis. We therefore asked whether IFN-alpha is able to regulate the Fas/FasL pathway and thereby affects AICD. Peripheral blood mononuclear cells (PBMC), purified T cells and ATC of healthy volunteers were stimulated with various agents and the influence of IFN-alpha on Fas/FasL was assessed by mRNA and protein studies. The proportion of ATC undergoing AICD or anti-Fas-induced apoptosis was determined by FITC-annexin V staining and propidium iodide uptake. IFN-alpha upregulated mRNA expression of Fas and FasL in activated PBMC. Furthermore the concentration of the soluble form of FasL (sFasL) was increased in PBMC and T cells co-stimulated with IFN-alpha and various agents, whereas Fas surface expression was enhanced by IFN-alpha alone. IFN-alpha enhanced apoptosis induced by anti-Fas antibody and augmented AICD via the Fas/FasL pathway. IFN-alpha-regulated AICD may contribute to lymphopenia observed during IFN-alpha therapy. Our data further support that IFN-alpha is a multifunctional cytokine with profound effects on the immune cascades.     

Expression of apoptosis-related genes Fas/FasL,Bax/Bcl-2 and Caspase-3 in rat corpus luteum during luteal regression

Using immunohistochemistry, in situ hybridization, Western blot and TUNEL methods, we have studied the expression of Fas/FasL, Bcl-2/Bax and caspase-3 in the corpora lutea (CL) at various stages of pseudopregnant rat induced by injection of PMSF/hCG. The results showed that no apoptotic signal could be observed until Day 14 after hCG injection. Fas weakly expressed in the CL at all the stages increased when luteolysis took place. FasL signal increased dramatically on Day 14 and reached the maximum level on Day 21. The expression of Bcl-2 and Bax was detected in a time-dependent manner. At the early stage of CL development, Bcl-2 expression was stronger, while Bax was low. The expression of Bcl-2 and Bax in the CL was completely reversed. Caspase-3 antigen could be detected throughout all the phases of CL development in a time-dependent fashion, low on Day 2 and reaching the maximum on Day 21. These results suggest that luteal regression at the late phases may be related to cell apoptosis.     

Lysophosphatidylcholine-induced apoptosis in H19-7 hippocampal progenitor cells is enhanced by the upregulation of Fas Ligand

Lysophospholipids regulate a wide array of biological processes including apoptosis and neutrophil migration. Fas/Apo-1 and its ligand (FasL) participate in neuronal cell apoptosis causing various neurological diseases. Here, we use hippocampal neuroprogenitor cells to investigate how lysophosphatidylcholine (LPC) induces apoptosis in H19-7 hippocampal progenitor cells via Fas/Fas ligand-mediated apoptotic signaling pathway. Exposed cells with LPC presented on apoptotic morphology, positive TUNEL staining, and DNA fragmentation. We found that the expression of FasL was increased after LPC treatment. Furthermore, LPC-induced H19-7 cell apoptosis was decreased by agonistic anti-FasL antibody. In addition to promotion of caspase cascade activity by LPC, the administration of the caspase inhibitor, DEVD-fmk, prevented H19-7 cell apoptosis. LPC also increased the activation of nuclear factor-κB (NF-κB), which in turn, significantly increased FasL mRNA level. The increase in FasL mRNA level by NF-κB transfection was significantly decreased in the presence of IκB-SR, a super-repressor of IκB. Taken together, these results demonstrate that LPC has the ability to induce apoptosis in H19-7 cells through the upregulation of FasL expression via NF-κB activation.