Caspase-12 compensates for lack of caspase-2 and caspase-3 in female germ cells.

Previously, we analyzed mice lacking either caspase-2 or caspase-3 and documented a role for caspase-2 in developmental and chemotherapy-induced apoptosis of oocytes. Those data also revealed dispensability of caspase-3, although we found this caspase critical for ovarian granulosa cell death. Because of the mutual interdependence of germ cells and granulosa cells, herein we generated caspase-2 and -3 double-mutant (DKO) mice to evaluate how these two caspases functionally relate to each other in orchestrating oocyte apoptosis. No difference was observed in the rate of spontaneous oocyte apoptosis between DKO and wildtype (WT) females. In contrast, the oocytes from DKO females were more susceptible to apoptosis induced by DNA damaging agents, compared with oocytes from WT females. This increased sensitivity to death of DKO oocytes appears to be a specific response to DNA damage, and it was associated with a compensatory upregulation of caspase-12. Interestingly, DKO oocytes were more resistant to apoptosis induced by methotrexate (MTX) than WT oocytes. These results revealed that in female germ cells, insults that directly interfere with their metabolic status (e.g. MTX) require caspase-2 and caspase-3 as obligatory executioners of the ensuing cell death cascade. However, when DNA damage is involved, and in the absence of caspase-2 and -3, caspase-12 becomes upregulated and mediates apoptosis in oocytes.

Genetic variance modifies apoptosis susceptibility in mature oocytes via alterations in DNA repair capacity and mitochondrial ultrastructure.

Although the identification of specific genes that regulate apoptosis has been a topic of intense study, little is known of the role that background genetic variance plays in modulating cell death. Using germ cells from inbred mouse strains, we found that apoptosis in mature (metaphase II) oocytes is affected by genetic background through at least two different mechanisms. The first, manifested in AKR/J mice, results in genomic instability. This is reflected by numerous DNA double-strand breaks in freshly isolated oocytes, causing a high apoptosis susceptibility and impaired embryonic development following fertilization. Microinjection of Rad51 reduces DNA damage, suppresses apoptosis and improves embryonic development. The second, manifested in FVB mice, results in dramatic dimorphisms in mitochondrial ultrastructure. This is correlated with cytochrome c release and a high apoptosis susceptibility, the latter of which is suppressed by pyruvate treatment, Smac/DIABLO deficiency, or microinjection of 'normal' mitochondria. Therefore, background genetic variance can profoundly affect apoptosis in female germ cells by disrupting both genomic DNA and mitochondrial integrity.

Role of apoptosis in functional luteolysis in the pregnant rabbit corpus luteum: evidence of a role for placental-derived factors in promoting luteal cell survival.

Corpora lutea (CL) were isolated from one rabbit ovary on days 4, 8, 16 (peak luteal function), 28 (functional regression) and 30 of pregnancy and processed for biochemical analysis of DNA integrity. Analysis of DNA integrity revealed the presence of oligonucleosomal fragments in day 28 and day 30 CL but not in day 16 CL. The extent of low molecular weight (<15 kb) DNA labeling was 6.6 +/- 0.84 fold higher in day 30 as compared to day 16 CL (mean +/- SEM; n = 4, P < 0.01). In a second series of experiments, healthy CL collected from day 16 pregnant rabbits were incubated for 2 h in the absence or presence of 250 microg/ml of placental extract (PE) obtained from day 16 and/or day 30 placentas. Analysis of DNA integrity revealed that extensive apoptosis occurred in CL incubated in medium alone and in medium containing day 30 PE. In contrast, day 16 PE significantly suppressed apoptosis vs control (70 +/- 4%). In a third series of experiments, expression of mRNA for bcl-x and bax was measured by Northern analysis of CL treated without and with day 16 PE using cRNA probes for bcl-x and bax developed in our laboratory by RT-PCR. Treatment with PE significantly reduced bax mRNA levels but did not change bcl-x mRNA levels. These studies provide evidence that functional luteolysis in the pregnant rabbit CL is correlated with the occurrence of apoptosis. The data suggest that a factor(s) derived from the placenta may be responsible for the prolongation of CL life span during pregnancy by its ability to alter the bax:bcl -x rheostat and suppress apoptosis.

Inhibition of nitric oxide synthesis potentiates apoptosis in the rabbit corpus luteum.

To determine if nitric oxide (NO) plays a role in corpus luteum (CL) physiology by affecting progesterone secretion or luteal apoptosis, an in-vitro pseudopregnant rabbit ovarian perfusion system was used to measure the effects of an inhibitor of NO synthesis, NG-nitro-L-arginine methyl ester (L-NAME), on progesterone secretion and corpus luteal apoptosis as measured by internucleosomal DNA breakdown. Pseudopregnant rabbit ovaries perfused in vitro with L-NAME did not demonstrate any significant differences compared with control ovaries in progesterone secretion. However, apoptosis, as measured by internucleosomal breakdown, was significantly increased in L-NAME-perfused CL compared with controls. While NO does not appear to directly affect progesterone secretion, there does appear to be a role for NO in CL maintenance, or a role for inhibition of NO production in CL regression.

Commuting the death sentence: how oocytes strive to survive.

Programmed cell death claims up to 99.9% of the cells in the mammalian female germ line, which eventually drives irreversible infertility and ovarian failure - the menopause in humans. New insights into the mechanisms that underlie germ-cell apoptosis have been provided by the study of oocyte death in lower organisms and in genetically manipulated mice that lack apoptosis-regulatory proteins. With new therapeutic tools to control fertility, oocyte quality and ovarian lifespan on the horizon, understanding how and why the female body creates, only to delete, so many germ cells is imperative.

A sperm ion channel required for sperm motility and male fertility.

Calcium and cyclic nucleotides have crucial roles in mammalian fertilization, but the molecules comprising the Ca2+-permeation pathway in sperm motility are poorly understood. Here we describe a putative sperm cation channel, CatSper, whose amino-acid sequence most closely resembles a single, six-transmembrane-spanning repeat of the voltage-dependent Ca2+-channel four-repeat structure. CatSper is located specifically in the principal piece of the sperm tail. Targeted disruption of the gene results in male sterility in otherwise normal mice. Sperm motility is decreased markedly in CatSper-/- mice, and CatSper-/- sperm are unable to fertilize intact eggs. In addition, the cyclic-AMP-induced Ca2+ influx is abolished in the sperm of mutant mice. CatSper is thus vital to cAMP-mediated Ca2+ influx in sperm, sperm motility and fertilization. CatSper represents an excellent target for non-hormonal contraceptives for both men and women.

Caspase-2 deficiency prevents programmed germ cell death resulting from cytokine insufficiency but not meiotic defects caused by loss of ataxia telangiectasia-mutated (Atm) gene function.

It is well established that programmed cell death claims up to two-thirds of the oocytes produced during gametogenesis in the developing fetal ovaries. However, the mechanisms underlying prenatal germ cell loss in females remain poorly understood. Herein we report that caspase-11 null female mice are born with a reduced number of oocyte-containing primordial follicles. This phenotype is likely due to failed cytokine processing known to occur in caspase-11 mutants since neonatal female mice lacking both interleukin (IL)-1alpha and IL-1beta also exhibit a reduced endowment of primordial follicles. In addition, germ cell death in wild-type fetal ovaries cultured ex vivo is suppressed by either cytokine, likely via ligand activation of type 1 IL-1 receptors expressed in fetal germ cells. Normal oocyte endowment can be restored in caspase-11 null female mice by simultaneous inactivation of the gene encoding the cell death executioner enzyme, caspase-2. However, caspase-2 deficiency cannot overcome gametogenic failure resulting from meiotic recombination defects in ataxia telangiectasia-mutated (Atm) null female mice. Thus, genetically distinct mechanisms exist for developmental deletion of oocytes via programmed cell death, one of which probably functions as a meiotic quality-control checkpoint that cannot be overridden.

Aromatic hydrocarbon receptor-driven Bax gene expression is required for premature ovarian failure caused by biohazardous environmental chemicals.

Polycyclic aromatic hydrocarbons (PAHs) are toxic chemicals released into the environment by fossil fuel combustion. Moreover, a primary route of human exposure to PAHs is tobacco smoke. Oocyte destruction and ovarian failure occur in PAH-treated mice, and cigarette smoking causes early menopause in women. In many cells, PAHs activate the aromatic hydrocarbon receptor (Ahr), a member of the Per-Arnt-Sim family of transcription factors. The Ahr is also activated by dioxin, one of the most intensively studied environmental contaminants. Here we show that an exposure of mice to PAHs induces the expression of Bax in oocytes, followed by apoptosis. Ovarian damage caused by PAHs is prevented by Ahr or Bax inactivation. Oocytes microinjected with a Bax promoter-reporter construct show Ahr-dependent transcriptional activation after PAH, but not dioxin, treatment, consistent with findings that dioxin is not cytotoxic to oocytes. This difference in the action of PAHs versus dioxin is conveyed by a single base pair flanking each Ahr response element in the Bax promoter. Oocytes in human ovarian biopsies grafted into immunodeficient mice also accumulate Bax and undergo apoptosis after PAH exposure in vivo. Thus, Ahr-driven Bax transcription is a novel and evolutionarily conserved cell-death signaling pathway responsible for environmental toxicant-induced ovarian failure.

Caspase-3 gene knockout defines cell lineage specificity for programmed cell death signaling in the ovary.

Previous studies have proposed the involvement of caspase-3, a downstream executioner enzyme common to many paradigms of programmed cell death (PCD), in mediating the apoptosis of both germ and somatic cells in the ovary. Herein we used caspase-3 gene knockout mice to directly test for the functional requirement of this protease in oocyte and/or granulosa cell demise. Using both in vivo and in vitro approaches, we determined that oocyte death initiated as a result of either developmental cues or pathological insults was unaffected by the absence of caspase-3. However, granulosa cells of degenerating antral follicles in both mouse and human ovaries showed a strong immunoreaction using an antibody raised against the cleaved (activated) form of caspase-3. Furthermore, caspase-3 mutant female mice possessed aberrant atretic follicles containing granulosa cells that failed to be eliminated by apoptosis, as confirmed by TUNEL (terminal deoxynucleotidyl transferase-mediated deoxy-UTP nick end labeling) analysis of DNA cleavage and 4',6-diamidino-2-phenylindole staining of nuclear morphology (pyknosis). These in vivo results were supported by findings from in vitro cultures of wild-type and caspase-3-deficient antral follicles or isolated granulosa cells. Contrasting the serum starvation-induced occurrence of apoptosis in wild-type granulosa cells, caspase-3-null granulosa cells deprived of hormonal support were TUNEL-negative, showed attenuated chromatin condensation by 4',6-diamidino-2-phenylindole staining and exhibited delayed internucleosomal DNA cleavage. Such ex vivo findings underscore the existence of a cell autonomous (granulosa cell intrinsic) defect in apoptosis execution resulting from caspase-3 deficiency. We conclude that caspase-3 is functionally required for granulosa cell apoptosis during follicular atresia, but that the enzyme is dispensable for germ cell apoptosis in the female.

Programmed cell death in the ovary: insights and future prospects using genetic technologies.

Programmed cell death (PCD) plays a prominent role in development of the fetal ovaries and in the postnatal ovarian cycle. As is the case with other major organ systems, an evolutionarily conserved framework of genes and signaling pathways has been implicated in determining whether or not ovarian germ cells and somatic cells will die in response to either developmental cues or pathological insults. However, the identification of increasing numbers of potential ovarian cell death regulatory factors over the past several years has underscored the need for studies to now separate correlation (e.g. endogenous gene expression) from function (e.g. requirement of the gene product for the execution of PCD). In this regard, genetic technologies have recently been used to examine the functional significance of specific proteins and signaling molecules to the regulation of PCD in the female gonad in vivo. In addition to the more classic approaches, such as the use of genetic null and transgenic mice, methods that achieve cell lineage-selective and/or developmentally timed gene targeting are on the horizon for use by reproductive biologists to more accurately dissect the mechanisms by which PCD is controlled in the ovary. This minireview will highlight some of the advances that have already been made using gene knockout and transgenic mice, as well as provide an overview of the current and future status of cell lineage-selective gene disruption, in the context of PCD and ovarian function.

Emerging technologies to control oocyte apoptosis are finally treading on fertile ground.

As the medical community strives to improve on the efficacy of anticancer treatments, a critical issue not to be overlooked since the overall quantity of life has been substantially increased in many cancer survivors is the quality of that life post-therapy. Indeed, one of the most worrisome side effects of conventional cancer treatments is damage to the gonads. This problem is compounded in females since the ovaries, unlike the testes, are incapable of germ cell renewal in postnatal life. As a consequence, the inappropriate destruction of female germ cells (oocytes) following exposure to chemotherapeutic drugs and radiation is irreparable, often leading to premature menopause and infertility . Considering recent estimates that 1 in 52 human females between birth and age 39 (i.e., the pre-reproductive and reproductive years) will be diagnosed with, and presumably treated for, cancer , new strategies to minimize or prevent gonadal damage during such treatments would have a profound positive impact on millions of lives.

Identification of potassium-dependent and -independent components of the apoptotic machinery in mouse ovarian germ cells and granulosa cells.

Recent studies with thymocytes have suggested a critical role for intracellular potassium in the regulation of apoptosis. In this study, we examined the pathways of K(+) regulation during ovarian cell death. In initial studies, fluorographic analysis demonstrated a significant loss of K(+) during apoptosis stimulated by doxorubicin in oocytes and trophic hormone deprivation in granulosa cells. In oocytes, suppression of potassium efflux by potassium-enriched medium prevented condensation, budding, and fragmentation, although it did not block DNA degradation, suggesting the existence of potassium-independent nucleases in oocytes. Culture of granulosa cells in potassium-enriched medium inhibited internucleosomal DNA cleavage, although high-molecular weight DNA cleavage was apparent, suggesting that the nuclease or nucleases responsible for generating 50-kilobase (kb) fragments in these cells is potassium independent. To address this directly, isolated granulosa cell nuclei were stimulated to autodigest their DNA, and internucleosomal, but not large-fragment, cleavage was completely blocked by 150 mM potassium. We next examined whether the proapoptotic caspases are targets for potassium regulation. In cell-free assays, processing of pro-interleukin-1beta and proteolysis of cellular actin by recombinant caspase-1 and caspase-3, respectively, were suppressed by the presence of 150 mM potassium. Other monovalent ions (NaCl, LiCl) exerted a similar effect in these cell-free assays. Thus, in oocytes and granulosa cells, potassium efflux appears to occur early in the cell death program and may regulate a number of apoptotic events including caspase activity and internucleosomal DNA cleavage. However, there also exist novel potassium-independent pathways in both ovarian germ cells and somatic cells that signal certain apoptotic events, such as large-fragment DNA cleavage.

Oocyte apoptosis is suppressed by disruption of the acid sphingomyelinase gene or by sphingosine-1-phosphate therapy.

The time at which ovarian failure (menopause) occurs in females is determined by the size of the oocyte reserve provided at birth, as well as by the rate at which this endowment is depleted throughout post-natal life. Here we show that disruption of the gene for acid sphingomyelinase in female mice suppressed the normal apoptotic deletion of fetal oocytes, leading to neonatal ovarian hyperplasia. Ex vivo, oocytes lacking the gene for acid sphingomyelinase or wild-type oocytes treated with sphingosine-1-phosphate resisted developmental apoptosis and apoptosis induced by anti-cancer therapy, confirming cell autonomy of the death defect. Moreover, radiation-induced oocyte loss in adult wild-type female mice, the event that drives premature ovarian failure and infertility in female cancer patients, was completely prevented by in vivo therapy with sphingosine-1-phosphate. Thus, the sphingomyelin pathway regulates developmental death of oocytes, and sphingosine-1-phosphate provides a new approach to preserve ovarian function in vivo.

Expression of BCL-2, BAX and BAK in the trophoblast layer of the term human placenta: a unique model of apoptosis within a syncytium.

The regulation of apoptosis in the syncytiotrophoblast is of particular interest because this is the only true syncytial epithelium in human cell biology. Nuclei characteristic of apoptotic cells have been localized to this syncytium especially in association with fibrin-containing fibrinoid deposits. The factors responsible for regulating cell death-like features in the trophoblast syncytium are unknown. We tested the hypothesis that fibrin was required for trophoblast apoptosis. TUNEL (terminal deoxynucleotidyltransferase-mediated dUTP end-labelling) staining to detect DNA fragmentation typical of apoptosis was performed in term human placentae revealing labelled nuclei associated with fibrin-type fibrinoid, as well as labelled nuclei in discrete areas of syncytiotrophoblast without fibrin. We also hypothesized that members of the BCL-2 family of apoptosis-associated proteins contribute to the regulation of syncytiotrophoblast apoptosis. To identify members of this protein family that might regulate trophoblast apoptosis, we assessed expression of three important members of the bcl-2 gene family. We used immunohistochemistry with monoclonal antisera against human BCL-2 and polyclonal antisera against human BAX and BAK to study paraffin-embedded sections of human term placentae (n=5) from uncomplicated pregnancies. The anti-apoptotic BCL-2 protein was expressed throughout the syncytium of normal villi with much less staining in cytotrophoblast. Staining was also seen adjacent to fibrin deposits and in syncytium overlying fibrin deposits. Expression of the pro-apoptotic BAX protein was undetectable in the syncytiotrophoblast, was expressed in rare cytotrophoblast and was prominent in connective tissue and perivascular cells within the villous core. Localization of a second pro-apoptotic protein, BAK, revealed immunoreactivity in isolated areas of intact syncytium of normal villi. Additionally, fibrin deposits were associated with intense BAK staining in both syncytiotrophoblast and cytotrophoblast. From these data, we speculate that modulation of BAK expression is one factor regulating apoptosis in human trophoblast.

Sphingolipid regulation of female gonadal cell apoptosis.

Ceramide and sphingosine-1-phosphate (S1P) are sphingosine-based lipid signaling molecules that have been implicated as key mediators of cellular growth, differentiation, and apoptosis. The cellular response depends on cell type, on the absence or presence of other signals initiated by the same or another stimulus, and on the subcellular location of sphingomyelin hydrolysis leading to ceramide generation. Consistent with mounting evidence implicating components of the sphingomyelin pathway as mediators of cellular life and death in nonreproductive tissues, recent data have indicated that sphingolipid-based signaling events are also prominent features of cellular development and apoptosis in the fetal and postnatal female gonads. This area of investigation represents a new research avenue of considerable significance for both basic biology and clinical medicine because of the massive levels of developmental death that occur normally in the female germ line, especially during gametogenesis, as well as of the central role of oocyte apoptosis in female gonadal failure resulting from pathologic insults.