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The Role of Apoptosis in the Regulation of Trophoblast Survival and Differentiation during Pregnancy

Department of Molecular, Cellular and Developmental Biology (S.L.S.-C.), Yale University, New Haven, Connecticut 06520; and Department of Obstetrics, Gynecology and Reproductive Sciences (V.M.A., G.M.), Yale University School of Medicine, New Haven, Connecticut 06520

Correspondence: Address all correspondence and requests for reprints to: Gil Mor, M.D., Ph.D., Department of Obstetrics, Gynecology and Reproductive Sciences, Reproductive Immunology Unit, Yale University School of Medicine, 333 Cedar Street FMB 301, New Haven, Connecticut 06520. E-mail: Gil.Mor{at}yale.edu

	Abstract

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
Apoptosis is important for normal placental development, but it may also be involved in the pathophysiology of pregnancy-related diseases. Normal placental development is dependent upon the differentiation and invasion of the trophoblast, the main cellular component of the placenta. Trophoblast apoptosis increases in normal placentas as gestation proceeds, and a greater incidence of trophoblast apoptosis has been observed in pregnancies complicated by preeclampsia or intrauterine growth retardation (IUGR). In response to different stimuli, apoptosis may be initiated extrinsically by the death receptor pathway or intrinsically by the mitochondrial pathway. The central executioners of apoptosis are the caspases, which cleave numerous vital cellular proteins to affect the apoptotic cascade. By inhibiting caspase activation, several endogenous inhibitors, including flice-like inhibitory proteins (FLIPs), inhibitors of apoptosis (IAPs), and antiapoptotic Bcl-2 family members, can prevent further propagation of the death signal. Macrophages present at the maternal-fetal interface may also contribute to trophoblast survival by removing apoptotic cells and producing cytokines and growth factors, which influence the progression of the apoptotic cascade. This review focuses on the role of apoptosis in trophoblast development and differentiation, the molecular mechanisms by which normal trophoblast apoptosis can occur, and how it is regulated to prevent excessive trophoblast apoptosis and possible pregnancy complications.

I. Introduction

A. An overview of apoptotic pathways

B. The role of apoptosis in normal pregnancy

II. Trophoblast Expression and Function of the TNF-R Family and Their Respective Ligands

A. Death domain-containing TNF-Rs

B. Non-death domain-containing TNF-Rs

C. Decoy receptors (DcRs)

III. The Role of Caspases in Trophoblast Differentiation

IV. Endogenous Regulators of Trophoblast Apoptosis

A. FLIPs

B. The Bcl-2 family

C. IAPs

D. Inhibition of IAPs

V. Exogenous Regulation of Trophoblast Apoptosis

A. T helper 1 (Th1)- and T helper 2 (Th2)-type cytokines

B. Growth factors

VI. The Role of Monocytes/Macrophages in the Regulation of Trophoblast Apoptosis

A. Monocytes/macrophages and the clearance of apoptotic trophoblast cells

B. Macrophages and the induction of apoptosis

VII. Trophoblast Apoptosis and Pregnancy Complications

A. The regulation of the apoptotic cascade in abnormal pregnancies

B. Apoptotic cell clearance in pregnancy-related diseases

C. Infection and trophoblast apoptosis

VIII. Summary and Conclusions

	I. Introduction

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
PREGNANCY COMPLICATIONS SUCH as preterm labor, preeclampsia, and intrauterine growth retardation (IUGR) affect a considerable number of pregnancies and account for significant perinatal morbidity and mortality. Although the pathophysiology has not been clearly defined, the common phenomenon observed between these diseases is abnormal development and function of the placenta (1, 2, 3).

Normal placental development is dependent upon the differentiation and invasion of the trophoblast, the main cellular component of the placenta that originates from the trophoectoderm of the blastocyst early in pregnancy. During this process of differentiation and invasion, trophoblast cells rapidly divide to form the interface between mother and embryo, while other trophoblast subpopulations invade the decidua (pregnant endometrium) to remodel the arterial blood vessels in the uterine wall, known as the spiral arteries, to accommodate the expansion of extraembryonic tissue and to increase blood flow to the placenta and developing fetus. As a developing organ, the placenta undergoes constant tissue remodeling, which is characterized by the functional loss of trophoblast cells by apoptosis. After proliferation and differentiation into specific cell subtypes, aging trophoblast cells are selectively removed and replaced by a younger population of trophoblasts without affecting neighboring cells (4).

Apoptosis, or programmed cell death, is an active process by which superfluous or dysfunctional cells are eliminated to maintain normal tissue function. Depending on the stimuli, apoptosis may be initiated by one of two known pathways: intrinsically by the mitochondrial pathway and extrinsically by either the death receptor-mediated pathway or in response to exogenous stimuli such as cytokines. The central executioners of apoptosis are the caspases, which are a family of cysteine proteases that cleave numerous vital cellular proteins to affect the apoptotic cascade (5). Several endogenous inhibitors, including flice-like inhibitory proteins (FLIPs), inhibitors of apoptosis (IAPs), and antiapoptotic Bcl-2 family members, inhibit caspase activation, thereby preventing further propagation of the death signal.

Whereas apoptosis is thought to be important for normal placental development, it may also be involved in the pathological conditions associated with this organ. Apoptotic cells have been identified in both the maternal and fetal compartments of the placenta during normal pregnancy, and the presence of these cells may be related to the stage of placental development, including the attachment and invasion of the trophoblast (6, 7), spiral artery transformation (8), trophoblast differentiation and turnover (9, 10, 11), and parturition (12, 13). Moreover, apoptosis has also been shown to play an important role in promoting maternal immune tolerance to paternal antigens expressed by trophoblast cells (6, 9, 14). In complicated pregnancies such as preeclampsia or IUGR, a greater incidence of trophoblast apoptosis has been observed (15, 16, 17, 18, 19, 20), suggesting that alterations in the regulation of trophoblast apoptosis may contribute to the pathophysiology of these diseases.

As cells undergo apoptosis, macrophages present at the maternal-fetal interface quickly remove apoptotic cells by phagocytosis to promote trophoblast survival and facilitate invasion and transformation of the spiral arteries (21). In placentas from complicated pregnancies, shallow trophoblast invasion and inefficient spiral artery transformation have been observed (22, 23), which may be partly due to the distribution and activation state of infiltrating macrophages.

In this review, we will discuss the role of apoptosis in the development and differentiation of the trophoblast, the molecular mechanisms by which trophoblast cell apoptosis can occur, how it is regulated during normal pregnancy, and the alterations that have been observed in pregnancy-related diseases associated with excessive trophoblast apoptosis. The role of macrophages in apoptotic cell clearance and trophoblast survival will also be discussed.

A. An overview of apoptotic pathways
1. The extrinsic pathway: characteristics of the TNF death receptor family.
Depending upon the stimuli, apoptosis can be initiated by one of two known pathways: the mitochondrial, or intrinsic, pathway and the death receptor-mediated, or extrinsic, pathway. If executed by the extrinsic pathway, apoptosis is initiated by members of the TNF death receptor family, which are part of the TNF-receptor (TNF-R) superfamily and have a C-terminal region of approximately 80 amino acids known as the death domain in common (24). To date, eight members of this family have been identified and include Fas (CD95/APO-1), TNF-R1 (CD120a), death receptor 3 (APO-3/WSL-1/TRAMP/LARD), TRAIL-R1 (death receptor 4), TRAIL-R2 (death receptor 5/TRICK2), death receptor 6, EDAR, and NGFR (25). Among the death receptors, Fas, TNF-R1, and TRAIL-R1/TRAIL-R2 are the most widely studied and best characterized. Several of these receptors and their corresponding ligand(s) have been shown to exist in at least two forms, a membranal form and a transmembrane-deficient soluble form, the latter of which may protect from death receptor-induced apoptosis under certain circumstances (26). A third, secreted form of Fas ligand (FasL), which is distinct from the soluble form, was recently described (27, 28). The interaction between a ligand and its membrane-bound death receptor results in the activation of preassociated death receptor trimers (29, 30). To transduce apoptotic signals, TNF death receptors have intracellular death domains, which mediate protein-protein interactions with other death domain-containing adaptor proteins such as the Fas-associated death domain (FADD; MORT1) and TNF-R-associated death domain (31). After FADD binds to the cytoplasmic tail of the death receptor either directly or, in the case of TNF-R1, indirectly through TNF-R-associated death domain (32), it recruits other cellular proteins, including procaspase-8 and procaspase-10 (33, 34) via death effector domains (DED) to form the death-inducing signaling complex (DISC), (35). This is the point at which the TNF death receptor pathways converge (Fig. 1). Once the DISC is assembled, "initiator" caspase-8 and caspase-10 can become activated (34, 36); however, the mechanism by which this occurs is not fully understood.

View larger version (46K): [in this window] [in a new window]   FIG. 1. The extrinsic and intrinsic apoptotic pathways. Depending upon the stimuli, apoptosis can be initiated by one of two known pathways; the mitochondrial (intrinsic) pathway or the death receptor-mediated (extrinsic) pathway. Apoptosis is mediated by the caspases, a family of cysteine proteases, which can be subdivided into two groups, initiator caspases and downstream effector or executioner caspases. DD, Death domain.

For additional information on TNF death receptor-induced apoptosis and how cell proliferation, survival, and apoptosis are regulated by members of the TNF superfamily, please refer to Refs.41 and 42 .

2. The intrinsic pathway: characteristics of the mitochondrial pathway and its role in death receptor-induced apoptosis.
Unlike the extrinsic pathway, which depends on death receptor signaling, in the intrinsic pathway, the apoptotic signal is initiated by, or directed to, the mitochondria. In response to cellular stresses such as DNA damage or growth factor deprivation, the mitochondrial pathway can be activated by p53, a tumor suppressor protein that transactivates proapoptotic Bcl-2 family members (43). However, the extrinsic and intrinsic pathways are not necessarily autonomous, because p53 can up-regulate the expression of certain death receptors, and the mitochondrial pathway may act to amplify signals triggered by the death receptor pathway, suggesting that crosstalk can occur between the two pathways (44, 45).

In addition to activating effector caspases, caspase-8 can also cleave Bid, a proapoptotic Bcl-2 family member, resulting in the translocation of truncated Bid to the mitochondria and the activation of the intrinsic pathway (46) (Fig. 1). Consequently, other proapoptotic Bcl-2 family members such as Bax and Bak increase the permeability of the outer mitochondrial membrane by a highly controversial mechanism (47, 48, 49) to release cytochrome c, apoptosis-inducing factor (50), and other proapoptotic factors (51, 52, 53). As a result, cytochrome c binds the adaptor protein, apoptotic protease activating factor-1, which together with ATP or dATP, subsequently recruits and activates "initiator" caspase-9, forming a macromolecular complex called an "apoptosome" (54). Analogous to the DISC in the extrinsic pathway, the apoptosome serves as the activation complex for caspase-9 in the intrinsic pathway. After recruitment, caspase-9 dimerizes and is subsequently activated by an allosteric mechanism similar to that by which initiator caspase-8 and caspase-10 are activated at the DISC. In turn, active caspase-9 activates "effector" caspase-3, caspase-6, and caspase-7, the point at which the mitochondrial and death receptor pathways overlap (40) (Fig. 1).

As effector caspases, caspase-3, caspase-6, and caspase-7 cleave a variety of vital cellular proteins, including DNA repair enzymes, nuclear lamins, and cytoskeletal proteins (5), which might explain the characteristic features of apoptosis such as nuclear condensation, membrane blebbing, and cell shrinkage. In addition, inhibitor of caspase-activated deoxyribonuclease is also cleaved by effector caspases, releasing caspase-activated deoxyribonuclease to nonspecifically cut the genomic DNA into approximately 200-bp fragments (55), eventually ending in apoptosis.

B. The role of apoptosis in normal pregnancy
1. Apposition and adhesion of the trophoectoderm.
Embryonic implantation consists of three consecutive phases: apposition, adhesion, and invasion, all of which have been shown to involve apoptosis. In the apposition, or preattachment stage, the developing blastocyst interacts with the epithelial cells of the endometrium in preparation for implantation. Using an in vitro model that mimics the apposition and attachment phases of implantation, Galan et al. (7) demonstrated that the presence of a human blastocyst reduced the percentage of human (h) endometrial epithelial cell (EEC) apoptosis in comparison to hEECs cultured without a blastocyst. The authors speculated that the embryo produces antiapoptotic factors, which promote hEEC survival and facilitate the attachment of the trophoectoderm to the uterine epithelium in the adhesion phase. Once the blastocyst had adhered to the hEECs, however, a massive increase in hEEC apoptosis was observed at and around the site of embryo attachment, suggesting that the trophoectoderm induces a paracrine apoptotic reaction in hEECs (7). Interestingly, similar findings have been reported in rodents (56, 57).

A potential mechanism by which the blastocyst may induce hEEC apoptosis is through the Fas/FasL system. Indeed, the majority of hEECs express Fas on their apical surface, whereas FasL is expressed by the trophoectoderm. As the blastocyst invades, the FasL expressed on the surface of the trophoectoderm may bind to Fas on the hEECs and induce apoptosis. In the presence of a blocking anti-Fas antibody, embryonic adhesion and outgrowth are significantly reduced in hEECs cultured with mouse blastocysts compared with the nontreated control (7). This suggests that the interaction between Fas expressed on the endometrial epithelium and FasL expressed on the trophoectoderm may enable the embryo to breach the epithelial barrier and invade the decidua during implantation. A more recent study has demonstrated that trophoblast outgrowth is also inhibited by suppressing the intracellular p38 MAPK pathway, but not the ERK pathway, suggesting that EEC apoptosis may be mediated by p38 MAPK (58).

2. Extravillous trophoblast invasion and spiral artery transformation.
The trophoblast can be divided into two populations, villous and extravillous trophoblast, each of which can be further subdivided. Both villous and extravillous trophoblast cells are originally derived from the trophoectoderm of the implanting blastocyst early in pregnancy. Villous trophoblast comprises proliferating mononuclear cytotrophoblast cells, which continuously fuse to form the multinucleated syncytiotrophoblast, the second layer of trophoblast, which is in direct contact with the maternal circulation (4). Extravillous trophoblasts are a specialized population of cytotrophoblast cells, which have the capacity to invade the decidua and remodel the uterine blood vessels to establish an adequate blood supply for the fetus. Analogous to villous trophoblasts, extravillous trophoblasts can be subdivided into two populations: interstitial and endovascular trophoblast cells. Whereas interstitial trophoblasts invade the interstitium, or wall of the uterus, endovascular trophoblast cells infiltrate and transform the spiral arteries, thereby increasing nutrients and maternal blood flow to the placenta (59).

Although the initial changes to the arterial blood vessels appear to be trophoblast independent and part of the maternal response to pregnancy (60), it is clear that, in the absence of trophoblast invasion, vessel remodeling is significantly reduced (8), suggesting that the trophoblast is important for spiral artery transformation. It is thought that extravillous trophoblasts infiltrate the spiral arteries and migrate along the lumen of the vessels, replacing the endothelium and musculoelastic tissue in the vessel walls. Indeed, using first-trimester decidual and villous explants, Dunk et al. (61) reported a disruption in the endothelial cell lining of the vessel and a complete loss of organized smooth muscle surrounding the vessel concomitant with trophoblast invasion.

Recent evidence suggests that the transformation of the spiral arteries is mediated by the induction of apoptosis in the endothelial cells lining the lumen. Moreover, it appears that the proapoptotic signal inducing endothelial cell apoptosis may be delivered by the invading trophoblast. Using an in vitro coculture system consisting of fluorescently labeled first-trimester trophoblast cells and spiral arteries dissected from nonplacental bed biopsies obtained by cesarean section (62), Cartwright’s group demonstrated that only arteries with trophoblasts in the lumen of the vessels exhibited a loss in the endothelial layer, which stained positively for the caspase-mediated cleavage product of poly (ADP-ribose) polymerase (PARP), a marker of apoptosis. Similar results were obtained when endothelial cells were cocultured with a first-trimester extravillous trophoblast cell line. Furthermore, trophoblast-induced endothelial cell apoptosis was inhibited with the use of a pan caspase inhibitor (8).

Interestingly, the expression of Fas was detected on endothelial cells in spiral arteries and isolated primary endothelial cells, suggesting that the Fas/FasL system might represent the mechanism by which trophoblasts induce endothelial cell apoptosis. Indeed, trophoblast induction of endothelial cell apoptosis was abrogated in the presence of a blocking FasL antibody. This was confirmed using the spiral artery explant model, because apoptosis could not be detected in vessels when the blocking FasL antibody was added before trophoblast perfusion (8). Whether vascular smooth muscle cell loss is similarly regulated and endothelial cell apoptosis is required for changes in the smooth muscle layer remains to be determined. However, smooth muscle cells have also been shown to express Fas (8), and the Fas/FasL system was recently implicated as one mechanism by which trophoblasts may induce smooth muscle cell apoptosis (63, 64). Taken together, this suggests that the induction of apoptosis in endothelial cells, and possibly in smooth muscle cells, by the trophoblast is critical for spiral artery remodeling and to secure an adequate blood supply for the developing fetus. Defects in the signals delivered by the trophoblast, or in the response of the endothelium/vascular smooth muscle to the proapoptotic stimuli, may begin to explain the lack of vessel transformation observed in pregnancy complications such as preeclampsia.

3. Maternal immune tolerance.
In the early 1950s, Medawar (65) described the "fetal-allograft analogy," in which the fetus was viewed as a semiallogenic conceptus that evaded immune rejection. More recently, this analogy was redefined as maternal-placental tolerance rather than maternal-fetal tolerance because it is the trophoblast and not the fetus that is in direct contact with the maternal immune system. Because trophoblast cells express paternal antigens, which are considered antigenically foreign to the mother, the trophoblast should, therefore, be rejected by the maternal immune system. However, under normal conditions, the trophoblast avoids maternal immune rejection and benefits from an immune privilege state during pregnancy.

Several theories exist to account for the immune privilege status of the trophoblast, including the expression of nonclassical human leukocyte antigen molecules (66) and complement regulatory proteins (67), tryptophan catabolism by the indoleamine 2,3-dioxygenase enzyme (68), immunosuppression by regulatory T cells (69), and the clonal deletion of specific T cell clone types (70, 71). Indeed, apoptotic leukocytes, particularly T lymphocytes, have been localized to the maternal-fetal interface of normal placentas (72, 73) and antigen-specific T cell deletion has been observed during pregnancy (70, 71). This suggests that the trophoblast can respond to the presence of maternal leukocytes and that the maternal immune system may not be indifferent to the fetus as was once previously thought (65). In support of this, two studies have demonstrated that maternal T cells, which recognize paternal antigens on the trophoblast, are selectively abrogated during pregnancy in mice (70, 71). Interestingly, Tafuri et al. (70) also reported that T cell numbers and reactivity were restored after delivery, suggesting that maternal T cells acquire a tolerant state that is both transient and reversible. Further studies, however, are necessary to confirm these findings.

Because Fas and FasL were originally implicated in the removal of activated peripheral T cells after an immune response (74), it was suggested that one of the possible mechanisms by which maternal T cells may be tolerized to paternal alloantigens is by the Fas/FasL system. Indeed, trophoblast cells isolated from mouse placentas were shown to induce apoptosis in a mouse T cell line that expresses Fas, but not in a Fas-deficient T cell line. In contrast, trophoblast cells purified from the placentas of homozygous gld (generalized lymphoproliferative disease) mice, which do not express functional FasL, did not induce apoptosis in the Fas-expressing T cell line (71). Similarly, Kauma et al. (75) demonstrated that a FasL-expressing first-trimester trophoblast cell line was able to induce Fas-mediated apoptosis in activated lymphocytes in vitro. However, several in vivo studies have reported that cells expressing membranal FasL were rejected when transplanted into allogenic animals (76, 77), which brings into question the role of the Fas/FasL system in immune privilege. This may be due to the overexpression of FasL in transplanted cells engineered to express membranal FasL. Indeed, the overexpression of membranal FasL has been shown to be associated with inflammation, neutrophil activation, and rejection (78).

Analogous to the trophoblast, certain tumor cells have been shown to express FasL. It has been postulated that FasL-expressing tumor cells may protect themselves from immune surveillance by inducing Fas-mediated apoptosis in immune cells that infiltrate the tumor (79) during a process called the "Fas counterattack" (80). More recently, our group has demonstrated that FasL is expressed in the cytoplasm of both epithelial ovarian cancer cells and isolated first-trimester trophoblast cells, rather than on the membrane, and that these cells can secrete the full-length functional form of FasL via the release of microvesicles (14, 27). After microvesicle disruption, the secreted FasL is able to induce apoptosis in Fas-bearing immune cells, suggesting that the constitutive secretion of FasL may be one mechanism by which the trophoblast promotes maternal tolerance to paternal antigens and prevents fetal rejection during pregnancy (14).

4. Villous trophoblast differentiation and turnover.
Another important function of apoptosis during pregnancy is related to the regulation of trophoblast growth and turnover in the villous part of the placenta. Morphological characteristics consistent with apoptosis have been observed in the villous trophoblast of normal placentas (10, 12, 13, 81), suggesting that villous trophoblast apoptosis is a physiological process that occurs during normal pregnancy. The villous trophoblast is an active tissue that is undergoing constant cell turnover and renewal by a well-orchestrated process of tissue remodeling involving apoptosis. Moreover, the percentage of apoptotic trophoblast cells has been shown to increase in villous placenta as gestation proceeds (12, 13), which suggests that villous trophoblast apoptosis is developmentally regulated. In pathological conditions such as preeclampsia and IUGR, a greater incidence of villous trophoblast apoptosis has been observed, suggesting that the appropriate regulation of trophoblast apoptosis is important for normal pregnancy (15, 16, 17, 18).

As mentioned previously, the villous trophoblast consists of two subpopulations: cytotrophoblast cells and the syncytiotrophoblast layer. The syncytiotrophoblast does not have the capacity to proliferate and is, therefore, dependent on the villous cytotrophoblast population for growth and renewal. Initially, proliferating cytotrophoblast cells begin to differentiate, leading to the fusion of these cells with the overlying syncytiotrophoblast. After syncytial fusion, a second differentiation process occurs in the outer syncytiotrophoblast layer, in which each aging nucleus is packed into a syncytial knot and extruded. Villous trophoblast turnover is completed once these syncytial knots are shed into the maternal circulation (4, 82).

Several components of the apoptotic cascade are differentially expressed in cytotrophoblast cells and the syncytiotrophoblast layer, and this is thought to be associated with the stage of apoptosis observed in the different compartments of placental villi. Activation of the apoptotic cascade is initiated in the villous cytotrophoblast and completed in the syncytiotrophoblast before the extrusion of apoptotic nuclei, suggesting that villous trophoblast apoptosis and differentiation are interdependent. However, the initial activation of the apoptotic cascade appears to be related to the differentiation of cytotrophoblast cells rather than trophoblast cell death. Therefore, apoptosis is not only involved in the removal of aging syncytiotrophoblasts, but it may also promote cytotrophoblast fusion and formation of the syncytial layer (9). Moreover, recent studies have demonstrated that caspases are important mediators of cytotrophoblast differentiation (83, 84, 85, 86). How caspases can promote cytotrophoblast differentiation without inducing apoptosis is an intriguing question, which will be discussed in a later section. For a recent review on the role of villous trophoblast apoptosis in placental morphology, please refer to Ref.82 .

To understand the differential effects of apoptosis in normal pregnancy and its potential role in pathological conditions, it is important to discuss the molecular mechanisms by which the above-described processes may be mediated. This is a rapidly expanding area of research as demonstrated by the increase in the number of publications in recent years. In the following section, we will discuss the current knowledge of the molecular mechanisms that regulate apoptosis in the trophoblast.

	II. Trophoblast Expression and Function of the TNF-R Family and Their Respective Ligands

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
A. Death domain-containing TNF-Rs
1. Fas and FasL.
Along with several others, we have shown that both villous cytotrophoblasts and syncytiotrophoblast (72, 87, 88, 89, 90, 91, 92, 93), as well as extravillous trophoblast cells (6, 72, 75, 94), express Fas and/or FasL. However, other groups have reported a lack of Fas expression in villous cytotrophoblast cells (9, 18), early extravillous cytotrophoblasts (73) or in villous syncytiotrophoblast at term (95), as well as punctuate or lack of staining for FasL in first-trimester and/or term syncytiotrophoblasts (9, 73, 94). These contradictory results may be due to differences between antibodies or in nonlabor- vs. labor-associated placentas (93). Therefore, particular consideration should be given to the antibodies selected for studying the expression of Fas and FasL in placental tissues (96).

Using different methods, our laboratory and others have demonstrated that isolated trophoblast cells predominantly express the full-length transmembrane form of Fas (88, 97) and that trophoblast Fas expression levels remain high throughout placental development (90). In contrast, the expression of FasL has been shown to decrease in villous trophoblasts at term (72, 89, 90, 93), but not in those collected before the onset of labor (6, 89), suggesting that a reduction in FasL expression may modulate the inflammatory processes associated with parturition (89). More recently, our group demonstrated that, contrary to previous notions, FasL is not expressed on the plasma membrane, but instead is associated with a specialized secretory lysosomal pathway in the cytoplasm of trophoblast cells and secreted via the release of microvesicles (14). This was recently confirmed in vivo by Mincheva-Nilsson’s group (98), who reported the presence of FasL-containing microvesicles in secretory lysosomes in first-trimester placentas by electromicroscopy. In addition, we also illustrated that this secreted form of FasL is able to induce apoptosis in activated immune cells and is distinct from the soluble form of FasL (14). The biological role of secreted FasL and how trophoblast secretion of FasL is regulated during pregnancy are areas that our group is currently investigating. Based on our in vitro studies, we postulate that FasL secretion is important for trophoblast immune privilege, which might explain why a decrease in FasL expression has been observed in villous trophoblast at term (89).

Although first-trimester trophoblast cells express both Fas and FasL, they are resistant to Fas-mediated apoptosis under normal conditions (88, 90, 99). Therefore, the expression of Fas and FasL by trophoblast cells does not necessarily correlate with susceptibility to Fas-induced apoptosis. Recent evidence from our laboratory suggests that trophoblast resistance to Fas-mediated apoptosis is due to the inhibition of the pathway downstream of Fas stimulation (99), which will be discussed in a later section. Interestingly, first-trimester trophoblast cells have been shown to actually proliferate rather than undergo apoptosis after Fas stimulation (99). This may be explained by studies illustrating that signals transmitted by Fas, as well as the other prototypical death receptors, TNF-R1 and TRAIL-R2, may also promote growth in certain cells through the activation of nuclear factor-B (NF-B) and mitogen-activated kinases such as c-jun N-terminal kinase (100, 101, 102). Therefore, if the intracellular apoptotic cascade is blocked, the same receptors that induce apoptosis in trophoblast cells may also promote trophoblast cell proliferation under certain circumstances.

Interestingly, the soluble forms of Fas and FasL have been detected in the peripheral blood of normal pregnant women as well as in complications of pregnancy such as preeclampsia. Although the number of patients evaluated in these studies was relatively small, the levels of soluble Fas and FasL were shown to be higher in preeclamptic women than in the normotensive pregnant controls (103, 104, 105). The significance of these biological findings, however, is not fully understood.

2. TNF-R1 and TNF-.
The expression of TNF-R1 and TNF-, the ligand for TNF-R1, has also been localized to villous (49, 106, 107, 108, 109, 110, 111, 112), as well as extravillous trophoblast cells (108, 113). Moreover, there is some evidence indicating that TNF-R1 and TNF- expression increases in placental tissues with gestational age (106, 110), suggesting that along with the Fas/FasL system, TNF-R1 and TNF- may also be involved in the process of parturition. However, in contrast to Fas, TNF- is a potent inducer of trophoblast apoptosis (88, 97, 108, 114). Because TNF-R1 and Fas have several components of the intracellular apoptotic cascade in common, we hypothesize that TNF- might activate an alternative pathway in trophoblast cells rather than the classical TNF death receptor pathway (99, 115).

Interestingly, TNF- can be proteolytically cleaved from the membrane to generate a soluble form of TNF-; however, only a small amount of TNF- could be detected in the culture supernatants from first-trimester villous explants (116) and isolated cytotrophoblast cells (117). This suggests that the trophoblast is not a primary source of soluble TNF- in placental tissues and that TNF- may instead be released from macrophages, natural killer cells, or other cells at the maternal-fetal interface (49, 106, 118). Nevertheless, because membranal TNF- and TNF-R1 colocalize to trophoblast subpopulations, other mechanisms must exist to prevent TNF--induced trophoblast apoptosis. Indeed, soluble TNF-Rs have been detected in the amniotic fluid and urine samples from pregnant women, suggesting that the secretion of soluble TNF-Rs may protect against the cytotoxic effects of TNF- expression (119). Moreover, Knofler et al. (108, 120) demonstrated that isolated villous trophoblast cells shed large quantities of soluble TNF-Rs, which suggests that the trophoblast may represent the source of the secreted soluble TNF-Rs.

3. TRAIL-R1/R2 and TRAIL.
In contrast to the TNF-R1/TNF- and the Fas/FasL system, TNF-related apoptosis-inducing ligand (TRAIL) and its receptors, TRAIL-R1 and TRAIL-R2, appear to be differentially expressed in villous placenta. Villous cytotrophoblast cells have been shown to express high levels of TRAIL-R1/TRAIL-R2, whereas strong TRAIL expression was detected in syncytiotrophoblasts from both trimesters of pregnancy (49, 121). This disparate localization of TRAIL-R1 and TRAIL-R2 to cytotrophoblasts and TRAIL to syncytiotrophoblasts may not only provide protection from maternal immune cells but may also prevent autocrine or paracrine killing by the same or neighboring trophoblast cell. Moreover, Chen et al. (121) revealed that the expression of TRAIL-R1 and TRAIL-R2 increased in villous trophoblasts with gestational age, suggesting that these receptors may cooperate with other TNF death receptors to increase trophoblast apoptosis toward the end of pregnancy.

With regard to the response of TRAIL-R1/TRAIL-R2 to TRAIL in trophoblast cells, the only study that has tested TRAIL sensitivity, of which we are aware, used trophoblast-derived choriocarcinoma cell lines, which were shown to be resistant to recombinant TRAIL (122). Whether normal trophoblast cells exhibit similar resistance to TRAIL-induced apoptosis is unknown.

4. Death receptors 3 and 6.
The TNF death receptors, death receptors 3 and 6, have also been shown to be expressed by isolated term trophoblast cells (49). However, trophoblast expression of the death receptor 3 ligand, TNF-like 1A (123), has not been reported, and a ligand for death receptor 6 has yet to be identified. Therefore, whether or not death receptors 3 and 6 have a functional role in trophoblast cells remains to be determined.

B. Non-death domain-containing TNF-Rs
In addition to the classical TNF death receptors, trophoblast cells have also been shown to express several non-death domain-containing TNF-Rs such as TNF-R2, lymphotoxin-ß receptor (LT-ßR), and herpes virus entry mediator (HVEM) and their respective ligands, TNF-, LT-/LT-ß, and LIGHT (49, 124). The expression of 4–1BB (CD137), another non-death domain-containing TNF-R, has not been detected, but the expression of its ligand, 4–1BBL, was observed in isolated term cytotrophoblast cells (49).

The precise role of non-death domain-containing TNF-Rs in trophoblast cell apoptosis and survival is not completely understood. Although capable of inducing apoptosis in other cell types (125), it was previously shown that TNF-R2 does not participate in TNF--induced trophoblast cell apoptosis and that apoptosis induced by TNF- is mediated almost entirely by TNF-R1 (109). This was supported by another study, which demonstrated that recombinant mouse TNF- decreased the viability of trophoblast cells isolated from TNF-R2 knockout mice, whereas similar treatment had no effect on TNF-R1-deficient mouse trophoblast cells (126). Recent evidence suggests that receptor interacting protein (RIP), a death domain-containing serine/threonine kinase, which is recruited to TNF-R1 upon receptor activation, may also affect TNF-R2 signaling. In the presence of RIP, TNF-R2 was able to trigger apoptosis, but when RIP was absent, TNF-R2 activated the NF-B pathway, suggesting that RIP may be important for TNF-R2-mediated apoptosis in certain cell types (101). Whether RIP is expressed by trophoblast cells and has a functional role in trophoblast TNF-R signaling remains to be elucidated.

Unlike TNF-R2, recent data from Gill and Hunt (127) suggest that HVEM and/or LT-ßR are capable of inducing LIGHT-mediated trophoblast apoptosis. Therefore, whether non-death domain-containing TNF-Rs promote trophoblast cell survival or induce apoptosis may depend on which receptors are expressed, the type or strength of stimulus, and the activation status of the intracellular apoptotic cascade and/or survival pathways in trophoblast cells.

C. Decoy receptors (DcRs)
A new area of research that has generated much interest in the field of apoptosis is the expression and function of DcRs. Interestingly, trophoblast cells have been shown to express several decoy receptors, which lack death domains and are unable to transduce an apoptotic signal. As the name implies, decoy receptors compete with the classical TNF death receptors, Fas and TRAIL-R1/R2, as well as the non-death domain-containing TNF-Rs, HVEM and LT-ßR, for ligand binding, thereby suppressing receptor-induced apoptosis (42).

Isolated term cytotrophoblasts have been shown to express DcR3 (TR6) (127), the decoy receptor for FasL and LIGHT, as well as DcR1 and DcR2 (49), both of which are capable of binding TRAIL. DcR1 and DcR2 are expressed in cytotrophoblast cells and the syncytiotrophoblast of placental tissues throughout gestation, however, the levels of DcR1 and DcR2 expression decrease in villous trophoblast with gestational age (121), suggesting that a reduction in decoy receptor expression may promote death receptor/ligand binding and allow trophoblast cell apoptosis to occur. Using a recombinant DcR3-Fc (rhDcR3-Fc) fragment to inhibit LIGHT binding to HVEM or LT-ßR, Gill and Hunt (127) also demonstrated that the rhDcR3-Fc fragment was able to restore cell viability in isolated cytotrophoblast cells treated with interferon- (IFN-) and LIGHT, which suggests that DcR3 protects trophoblast cells from LIGHT-mediated apoptosis.

Altogether, these studies demonstrate that trophoblast cells possess multiple death receptors, including those that lack death domains, as well as several decoy receptors, but how these receptors function simultaneously to regulate trophoblast cell apoptosis and/or survival throughout pregnancy is only beginning to be understood.

	III. The Role of Caspases in Trophoblast Differentiation

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
Morphological changes consistent with apoptosis, such as nuclear condensation, membrane blebbing, and DNA fragmentation, have been observed in villous trophoblast of placentas from uncomplicated pregnancies (10, 12, 13, 81), suggesting that apoptosis is associated with the normal remodeling of this tissue. As discussed in a previous section, several of these apoptotic characteristics are the result of caspase activation, which indicates that caspases may be involved in villous trophoblast cell turnover and renewal. Indeed, first- and third-trimester cytotrophoblast cells have been shown to express the proforms of caspase-3, caspase-6, and caspase-7, whereas the active forms of caspase-3 and caspase-6 have been observed in syncytiotrophoblasts after syncytial fusion (83). In contrast, Yusuf et al. (85) demonstrated that not only do third-trimester cytotrophoblast cells have effector caspase activity, but that the activity of caspase-3 and caspase-6, as well as initiator caspase-9, is greater in cytotrophoblasts than in syncytiotrophoblasts. This may explain why cytotrophoblast cells from third-trimester placentas have been shown to exhibit a higher level of apoptosis than syncytiotrophoblasts in culture (128), although the opposite has been observed in vivo (12, 13). Nevertheless, two effector caspase substrates, PARP and nuclear lamin B, have been reported to be expressed only in the nuclei of villous cytotrophoblasts, whereas the caspase-mediated degradation product of PARP was detected in syncytiotrophoblasts (9, 83). Moreover, using the M30 antibody, which recognizes a neoepitope that is exposed only after effector caspase-mediated cleavage of the cytoskeleton-associated protein, cytokertain-18, it was shown that the majority of M30-postive cells in villous tissue are the syncytiotrophoblasts (129, 130).

Interestingly, it appears that the activity of initiator caspase-8 is more prevalent in first- (83) and third-trimester cytotrophoblasts (85) than in syncytiotrophoblasts. In addition, villous cytotrophoblast cells have been shown to exhibit annexin-V binding (9), which measures the externalization of the aminophospholipid, phosphatidylserine, from the inner to the outer leaflet of the plasma membrane in cells undergoing the initial stages of apoptosis. However, early apoptotic events, such as caspase-8 activation and phosphatidylserine externalization, may not be associated with trophoblast cell death, but instead may be required for the fusion of cytotrophoblast cells with the syncytiotrophoblast layer (83). Using an in vitro model consisting of trophoblast-derived choriocarcinoma cells, Rote and co-workers (131) demonstrated that treatment with forskolin induced cell fusion, whereas application of antibodies directed against phosphatidylserine prevented fusion in JAR cells, suggesting that phosphatidylserine externalization may be important for the induction of syncytial fusion in normal villous trophoblast.

Caspase activation and, in particular, the activation of caspase-8 (132, 133), are thought to be involved in the externalization of phosphatidylserine and, therefore, cytotrophoblast differentiation. Indeed, Huppertz et al. (83) reported the loss of fodrin, a cytoskeletal protein that is initially cleaved by active caspase-8, in villous cytotrophoblast before its differentiation into syncytiotrophoblast. Using antisense oligonucleotides and peptide inhibitors to inhibit caspase-8 expression and activity, respectively, the same group also demonstrated that the inhibition of caspase-8 reduces syncytial fusion, thereby preventing progression of the apoptotic cascade in syncytiotrophoblast and resulting in the accumulation of mononucleated cytotrophoblast cells (84). This suggests that the activation of caspase-8 is initiated in villous cytotrophoblast cells, which, in turn, promotes their fusion with the syncytiotrophoblast and formation of the syncytial layer.

Along with the results of these studies arose additional questions of how the trophoblast survives despite caspase activation. More specifically, 1) what prevents apoptotic signaling events downstream of caspase-8 activation in cytotrophoblast cells, 2) which other components of the apoptotic cascade are involved in this process, and 3) how trophoblast apoptosis is regulated in parallel with syncytial fusion during pregnancy, which will be addressed in the following section.

	IV. Endogenous Regulators of Trophoblast Apoptosis

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
A. FLIPs
Each step of the apoptotic cascade is tightly controlled by endogenous inhibitors, which prevent further propagation of the death signal at the "initiator" and/or "effector" level (Fig. 2). Several of these intracellular inhibitors are expressed in the placenta, including FLIPs, which share significant structural homology with caspase-8 in that they each contain two DEDs. This feature enables FLIPs to interfere with the recruitment and activation of caspase-8 at the DISC, thereby preventing death receptor-mediated apoptosis (134). Indeed, an increase in FLIP expression has been shown to protect first-trimester trophoblast cells from Fas-induced apoptosis (97). Moreover, FLIPs may reinforce the inhibition of the intracellular apoptotic cascade by activating survival pathways such as NF-B and promoting cell proliferation (135).

View larger version (34K): [in this window] [in a new window]   FIG. 2. Intracellular regulation of the apoptotic cascade. Several endogenous inhibitors, including FLIPs, IAPs, and antiapoptotic Bcl-2 family members, such as Bcl-2 and Bcl-xL, can prevent caspase activation and further propagation of the death signal at the "initiator" and/or "effector" level. DD, Death domain.

View larger version (25K): [in this window] [in a new window]   FIG. 3. First-trimester trophoblast cells express FLIPS. Western blot analysis of FLIPS expression (28 kDa) in isolated 7- to 12-wk first-trimester trophoblast cells and the first-trimester trophoblast cell lines, 3A and HTR-8 (H8). H8 cells transfected with FLIPS were used as a positive control (+C).

B. The Bcl-2 family
Bcl-2 family members can modulate death signals either directed toward or initiated by the intrinsic pathway by differentially regulating the release of proapoptotic factors from the mitochondria. The Bcl-2 family is comprised of three functional groups, which are characterized by varying numbers of Bcl-2 homology (BH) domains. Members of the first group, such as Bcl-2 and Bcl-x_L, contain four BH domains (BH1–BH4) and inhibit apoptosis, whereas Bax and Bak, which are part of the second group, are proapoptotic and lack a N-terminal BH4 domain. Whereas Bax and Bak increase the permeability of the mitochondrial membrane to cytochrome c release, Bcl-2 and Bcl-x_L inhibit the release of cytochrome c and other proapoptotic factors from mitochondria, thereby preventing further propagation of the apoptotic signal (47, 139) (Fig. 2). The BH3-only proteins, Bid and Bik, are members of the third group and promote apoptosis by either activating proapoptotic members, such as Bax and Bak, or binding antiapoptotic Bcl-2 family members to inhibit their function. Thus, the outcome may depend on the relative abundance of pro- vs. antiapoptotic family members in the cell (140).

Syncytiotrophoblasts have been shown to express Bcl-2 at higher levels than villous cytotrophoblasts throughout pregnancy (9, 141, 142, 143, 144, 145, 146). Similarly, the expression of myeloid cell leukemia-1 (Mcl-1), another antiapoptotic Bcl-2-related family member, is more prominent in syncytiotrophoblasts compared with cytotrophoblast cells (9, 144). The expression of Bcl-2 and Mcl-1 in syncytiotrophoblasts was originally thought to be associated with the prevention of syncytiotrophoblast apoptosis after syncytial fusion. However, Bcl-2 and Mcl-1 prevent the activation of caspase-9 and do not have a direct effect on caspase-8 activation, which occurs during cytotrophoblast differentiation. In addition, caspase-8 can directly activate effector caspases without mitochondrial support (40), which might explain why apoptosis is still observed in Bcl-2- and Mcl-1-expressing syncytiotrophoblasts (12, 13, 147). Moreover, syncytiotrophoblasts have also been shown to express Bax (148) and Bak (145), suggesting that the expression of proapoptotic Bcl-2 family members may also promote syncytiotrophoblast apoptosis (142, 148). These findings also suggest that other intracellular inhibitors outside of the mitochondria may exist to prevent apoptosis from occurring in the syncytial layer.

C. IAPs
IAPs are unique in that they are capable of inhibiting both the mitochondrial and death receptor-mediated pathways (Fig. 2). To date, eight human IAPs have been identified and include X-linked IAP (XIAP; MIHA/ILP-1), ILP-2 (Ts-IAP), c-IAP1 (HIAP2/MIHB), c-IAP2 (HIAP1/MIHC), neuronal apoptosis inhibitory protein, Survivin (TIAP), Livin (KIAP/ML-IAP), and Apollon (Bruce). IAP family members are characterized by varying numbers of baculoviral IAP repeat (BIR) domains and, with the exception of neuronal apoptosis inhibitory protein, survivin, and Apollon, also contain a C-terminal really interesting new gene (RING)-zinc finger domain (149). The RING domain has E3 ubiquitin ligase activity, which enables IAPs to ubiquitinate and degrade themselves or other interacting proteins after certain apoptotic stimuli (150). In addition, c-IAP1 and c-IAP2 also contain a caspase-recruitment domain (151), the function of which in these proteins is still unknown (152). For a recent review on IAPs, please refer to Ref.153 .

XIAP, c-IAP1, c-IAP2, NAIP, Survivin, and Livin all have been shown to be expressed in villous trophoblasts and, except for c-IAP1, in extravillous trophoblast cells (90, 154, 155, 156). Among the IAPs, XIAP is the most potent and versatile member of the family because it is able to inhibit both the mitochondrial and death receptor-mediated pathways (157). XIAP contains three tandem BIR domains and a C-terminal RING domain, which have been shown to differentially inhibit initiator and effector caspases (158). Whereas the caspase-9-inhibitory activity of XIAP was localized to the BIR3-RING domain (159), the BIR2 domain, together with the linker region between the BIR1 and BIR2 domains of XIAP, has been shown to inhibit the activation of caspase-3 and caspase-7 (160). In response to certain apoptotic stimuli, XIAP can be cleaved into two distinct fragments, an N-terminal fragment containing BIR1–2 and a second fragment containing BIR3-RING. The BIR1–2 fragment has diminished ability to inhibit caspase-3 and may be susceptible to further caspase-mediated degradation, whereas the BIR3-RING fragment is more stable and retains the ability to inhibit caspase-9, but is unable to suppress Fas-induced apoptosis (150).

XIAP is highly expressed in villous cytotrophoblasts and syncytiotrophoblasts of first-trimester placentas, and its expression significantly decreases in third-trimester placentas (90), which correlates with the concomitant increase in placental apoptosis (12, 13). Similarly, a decrease in XIAP expression in primary trophoblast cells isolated from first-trimester placentas either by treatment with Phenoxodiol, which down-regulates XIAP, (99, 161) or by XIAP RNA interference (S. L. Straszewski-Chavez and G. Mor, unpublished observations) allows the release of caspase-9 and caspase-3 and the induction of trophoblast cell apoptosis. Furthermore, the down-regulation of XIAP renders first-trimester trophoblast cells sensitive to Fas-mediated apoptosis, as evidenced by the decrease in trophoblast cell viability and an increase in the activation of caspase-8, caspase-9, and caspase-3 (99) (Fig. 4). Therefore, we hypothesize that XIAP protects trophoblast cells from the proapoptotic effect of caspase-8 activity during cytotrophoblast differentiation by inhibiting caspase-9 and caspase-3 activation and promoting the formation of the syncytium. If the expression of XIAP decreases, as in villous cytotrophoblasts and syncytiotrophoblasts of third-trimester placentas (90), the protective effect of XIAP is removed and an increase in villous trophoblast apoptosis is observed (12, 13). Similar changes in XIAP expression and function may contribute to pathological conditions (S. L. Straszewski-Chavez and G. Mor, unpublished observations) and may be associated with the increase in trophoblast apoptosis observed in complicated pregnancies (15, 16, 17, 18, 19, 20).

View larger version (75K): [in this window] [in a new window]   FIG. 4. XIAP protects first-trimester trophoblast cells from Fas-mediated apoptosis. Western blot analysis of 3A trophoblast cells pretreated with or without Phenoxodiol (1 µg/ml) for 2 h followed by treatment with Phenoxodiol (1 µg/ml) alone or the combination of Phenoxodiol (1 µg/ml) and an agonistic anti-Fas monoclonal antibody (mAb) (500 ng/ml) for 24 h. Untreated cells (NT) served as a negative control. The XIAP cleavage product (30 kDa) was only observed in trophoblast cells treated with Phenoxodiol (Ph.) or Phenoxodiol and the anti-Fas mAb (Ph.+ -Fas). The appearance of the p30 XIAP fragment correlated with an increase in the activation of caspase-8 (41/43 kDa), caspase-9 (36 kDa), and caspase-3 (17/19 kDa) after treatment with the anti-Fas mAb.

View larger version (37K): [in this window] [in a new window]   FIG. 5. XAF1 is differentially expressed in first- vs. third-trimester placentas. Western blot analysis of XAF1 expression in first-trimester and term placentas obtained from normal pregnancies. XAF1 (34 kDa) is expressed in term placentas, but not in first-trimester placentas. The expression of XAF1 correlates with the expression levels of the active, full-length form (45 kDa) and the cleavage product (30 kDa) of XIAP. Note that the expression of the full-length form of XIAP is reduced, whereas the expression of the p30 XIAP fragment is higher in term placentas than in first-trimester placentas.

In relation to the other members of the IAP family, Gill and Hunt (127) demonstrated that c-IAP2 expression levels decrease in cytotrophoblast cells after treatment with both IFN- and LIGHT, suggesting that c-IAP2 may protect trophoblast cells from LIGHT-mediated apoptosis, but this result was not definitive. Future studies are needed to determine whether the other members of the IAP family can inhibit trophoblast apoptosis and how each of the IAPs is regulated in trophoblast cells.

D. Inhibition of IAPs
In order for apoptosis to occur, the inhibitory effect of IAPs must be removed, which is mediated by a group of proteins that antagonize the anticaspase activity of the IAP family. Members of this group include second mitochondria-derived activator of caspase/direct IAP-binding protein with low-PI (Smac/DIABLO), high-temperature requirement protein A2 (OMI/HtrA2) and XIAP-associated factor 1 (XAF1) (Fig. 6). Whereas XAF1 is a proapoptotic nuclear protein (167), Smac/DIABLO and OMI/HtrA2 are mitochondrial-associated proteins that are released from mitochondria upon certain apoptotic stimuli to inhibit IAP function (51, 52, 53), albeit by different mechanisms. Both Smac/DIABLO and OMI/HtrA2 bind to the BIR domains within IAPs, thereby displacing caspases and allowing caspase activation, however, OMI/HtrA2 is also a serine protease that can cleave IAPs, rendering them inactive (168, 169).

View larger version (43K): [in this window] [in a new window]   FIG. 6. Intracellular regulation of the IAP family. The IAP family is regulated by a group of intracellular proteins that include Smac/DIABLO, OMI/HtrA2, and XAF1, which antagonize the anticaspase activity of IAPs and allow apoptosis to occur.

View larger version (43K): [in this window] [in a new window]   FIG. 7. XAF1 localizes to the mitochondria. Western blot analysis of XAF1 expression in the cytoplasmic and mitochondrial fractions of 3A trophoblast cells after cell fractionation. 3A cells were transfected with XAF1 (+XAF1), and the cytoplasmic and mitochondrial fractions were separated by centrifugation. The expression of XAF1 (34 kDa) localizes to both the cytoplasm and the mitochondria, with a higher level of XAF1 expression observed in the mitochondrial fraction. The mitochondrial-specific protein, COX4 (17 kDa), which is retained in the inner mitochondrial membrane even in cells undergoing apoptosis, was used as a control to ensure the integrity of the preparations. NT, No treatment; +C, positive control.

	V. Exogenous Regulation of Trophoblast Apoptosis

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

A. T helper 1 (Th1)- and T helper 2 (Th2)-type cytokines
Several years ago Wegmann et al. (172) hypothesized that protection from maternal immune rejection may be due to the production of Th2-type cytokines at the maternal-fetal interface during pregnancy. Since this observation, numerous studies have been published in support of the notion that the predominance of Th2 over Th1 cytokines is essential for a successful pregnancy (173, 174, 175). This shift in cytokine profile not only promotes immune protection (176), but it may also directly regulate trophoblast survival (177). One of the possible mechanisms by which cytokines may affect trophoblast survival is by regulating the expression and/or function of components of the apoptotic cascade. Th1, proinflammatory cytokines such as TNF- and IFN-, may induce trophoblast apoptosis by up-regulating the expression of XAF1 (115) or Fas (97) in cytotrophoblast cells, thereby increasing caspase-3 activity (97, 108). In contrast, treatment with IL-10, a Th2, antiinflammatory cytokine, may inhibit the proapoptotic effect of TNF- and IFN- treatment by increasing FLIP expression in trophoblast cells (97). Interestingly, IL-10 has also been shown to up-regulate the expression of FasL in first-trimester trophoblast cells (97), which we postulate may increase FasL secretion and, therefore, promote trophoblast immune protection (Fig. 8A). Because first-trimester trophoblast cells are normally resistant to Fas-mediated apoptosis, IL-10-induced FLIP expression may protect against the autocrine or paracrine effects of FasL secretion. Moreover, an increase in FasL expression may further promote trophoblast survival by inducing Fas-mediated NF-B activation (100, 101, 102).

View larger version (59K): [in this window] [in a new window]   FIG. 8. The effect of apoptotic cell clearance on trophoblast survival. A, During normal pregnancy, the uptake of apoptotic cells promotes the production of antiinflammatory and immunosuppressive cytokines (IL-10) and growth factors (TGF-ß) by macrophages. The secretion of such cytokines and growth factors may influence trophoblast survival by inducing the expression of antiapoptotic factors in the apoptotic cascade and maintaining immune tolerance. B, In complicated pregnancies, a significant increase in the number of apoptotic cells may overwhelm the macrophages and promote macrophage production of proinflammatory cytokines, which further enhances trophoblast cell death. This cytokine milieu may result in changes in trophoblast sensitivity to Fas-mediated apoptosis and the immune privilege status of the trophoblast.

Altogether, this network of different cytokines and growth factors may promote or inhibit trophoblast apoptosis by influencing the expression of either pro- or antiapoptotic factors in the apoptotic cascade or by activating survival pathways. Understanding how these growth factor and cytokine networks are regulated during pregnancy may help elucidate the pathophysiology of pregnancy complications and provide new therapeutic approaches for the treatment of pregnancy-related diseases.

	VI. The Role of Monocytes/Macrophages in the Regulation of Trophoblast Apoptosis

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
Apoptosis, contrary to previous notions, is by no means the end of the story. The quick and effective removal of apoptotic cells by phagocytosis before the release of their intracellular contents is critical for the prevention of an inflammatory response and tissue damage. This process is neither neutral nor passive, but rather an active and coordinated one. In addition to preventing an immune response, phagocytic cells such as macrophages may also affect the growth and survival of the surrounding tissue during apoptotic cell clearance (183).

A. Monocytes/macrophages and the clearance of apoptotic trophoblast cells
As previously mentioned, the predominance of antiinflammatory over proinflammatory cytokines at the maternal-fetal interface is thought to be crucial for determining the success or failure of a pregnancy (172, 174). Immune cells, particularly macrophages, are a primary source of cytokines and growth factors and may, therefore, contribute to maintaining the appropriate microenvironment at the maternal-fetal interface during pregnancy (184). Macrophages constitute approximately 20–30% of the immune cells at the implantation site, and their numbers remain high throughout pregnancy (185, 186). During the first weeks of human implantation, macrophages are detected both in the decidua and in close proximity to the placenta, whereas in rodents, macrophages have been shown to accumulate at or near the site of implantation (187). By the end of the first trimester of human pregnancy, macrophages are observed in the stroma surrounding the extravillous trophoblasts as they invade and transform the spiral arteries. Originally, this dense macrophage infiltration was thought to represent an immune response against the invading trophoblast, but now it appears that, in addition to performing their typical immunological tasks, macrophages may also be involved in specific pregnancy-related functions. Once in close proximity to trophoblast cells, macrophages may assist in the tissue remodeling necessary to accommodate expansion of extraembryonic tissue (183).

During pregnancy, the amount of apoptotic material that is shed from the syncytiotrophoblast into the maternal circulation is considerable, particularly toward the end of gestation (82). As mentioned previously, trophoblast cells are carriers of paternal antigens, which are antigenically foreign to the maternal immune system and if released, as a result of cell death, may initiate or accelerate an immune response with lethal consequences for the fetus. Therefore, the appropriate removal of dead or dying trophoblast cells before the release of their intracellular contents is critical for the prevention of tissue damage and fetal rejection. In addition, self-antigens may also be released from apoptotic endothelial and vascular smooth muscle cells during the process of spiral artery transformation and, although genetically this does not pose a problem, it can induce an inappropriate immune response. The clearance of apoptotic cells is effectively mediated by tissue macrophages or by circulating monocytes in the peripheral blood. Macrophages present at the maternal-fetal interface are, therefore, vital not only for apoptotic cell clearance, but also for maintaining tissue homeostasis. However, macrophages are not merely scavengers of dying cells, but may also actively orchestrate the death or survival of neighboring cells in the process of tissue remodeling (183). The binding to, and ingestion of, apoptotic trophoblasts or other cells by macrophages may result in an antiinflammatory or immunosuppressive response (Fig. 8A). Indeed, Voll et al. (188) demonstrated that after the coculture of monocytes with apoptotic lymphocytes, TNF- secretion was inhibited, whereas the production of IL-10 and TGF-ß by monocytes was increased). This was supported by an in vivo study showing that the TGF-ß released by macrophages had antiinflammatory effects on inflamed tissue (189). As discussed in the previous section, the secretion of such cytokines and growth factors may directly promote trophoblast survival and maintain an antiinflammatory environment at the maternal-fetal interface.

Interestingly, the capacity for monocytes/macrophages to influence cell death or survival may be regulated by the extent of apoptotic cell uptake. The induction of glomerular cell apoptosis by macrophages stimulated with either IFN- and lipopolysaccharide or TNF- was shown to be suppressed by the uptake of apoptotic cells (190). Similarly, the cytolysis of tumor cells by activated macrophages could also be inhibited by the ingestion of apoptotic, but not necrotic, cells (191). Using an in vitro system consisting of monocyte-derived macrophages and apoptotic first-trimester trophoblast cells, we recently demonstrated that the level of apoptotic cell uptake by macrophages could influence trophoblast cell survival. Trophoblast cells incubated with the conditioned media collected from macrophages that had been cocultured with low numbers of apoptotic trophoblasts expressed only the active form of XIAP and exhibited no caspase-3 activation. However, in trophoblast cells that were treated with conditioned media from macrophages cocultured with high levels of apoptotic trophoblasts, the XIAP p30 fragment and the activation of caspase-3 were observed (21). This suggests that an excess of apoptotic trophoblasts stimulates macrophages to produce proapoptotic factors, which may promote further trophoblast cell death (Fig. 8B). It also supports the hypothesis that macrophages present at the maternal-fetal interface during pregnancy are necessary for the removal of apoptotic cells that arise from normal tissue remodeling. The appropriate apoptotic cell clearance by macrophages may prevent the release of potentially harmful factors that may otherwise cause tissue damage and fetal rejection (183).

B. Macrophages and the induction of apoptosis
In addition to phagocytosing apoptotic cells and secreting cytokines, macrophages may also directly induce apoptosis in target cells. By selectively depleting macrophages in transgenic mice, it was demonstrated that the developmental remodeling of the eye was incomplete. If bone marrow-derived macrophages were added to the macrophage-depleted mouse, however, normal apoptosis and eye remodeling were observed (192, 193). This suggests that macrophages are actively inducing apoptosis during eye development and, once the apoptotic program is complete, are then able to quickly engulf their victims (194). A similar situation can be envisioned during pregnancy, in which macrophages facilitate the invasion of trophoblast cells and the transformation of the spiral arteries by inducing apoptosis in endothelial and vascular smooth muscle cells.

One possible mechanism by which macrophages may induce apoptosis is through the release of FasL. Macrophages, like trophoblast cells, contain an intracellular supply of FasL that can be released upon activation (14, 195). It was previously demonstrated that FasL is released from macrophages after engulfing apoptotic neutrophils (196), suggesting that macrophages may release FasL to kill other neutrophils in the area. This finding suggests a powerful mechanism whereby macrophages may protect the invading trophoblast against neutrophils or other potentially harmful leukocytes during pregnancy. In this capacity, the macrophage may, therefore, contribute to the immune privilege status of the trophoblast. Furthermore, macrophages, together with trophoblast cells, may also induce Fas-mediated apoptosis in endothelial and vascular smooth muscle cells to promote spiral artery transformation (8, 63, 64).

	VII. Trophoblast Apoptosis and Pregnancy Complications

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
A greater incidence of villous (15, 16, 17, 18) as well as extravillous (19, 20) trophoblast apoptosis has been detected in placentas from pregnancies complicated by preeclampsia or IUGR, suggesting that the appropriate regulation of trophoblast apoptosis is important for normal pregnancy. In this section, we will discuss the alterations that have been observed in pregnancy-related diseases such as preeclampsia, IUGR, and preterm labor.

A. The regulation of the apoptotic cascade in abnormal pregnancies
Although earlier studies observed no differences in the expression of Bcl-2, Bcl-x_L, Bax, or Bak in placental villi from complicated and normal pregnancies (15, 197), a subsequent study reported that Bcl-2 expression was less abundant in syncytiotrophoblasts from severe preeclamptic and IUGR placentas than in the normal controls (18). However, Levy et al. (197) did find that the expression of p53, the tumor suppressor protein that activates proapoptotic Bcl-2 family members such as Bax in response to DNA damage or growth factor deprivation, was up-regulated in villous tissue from IUGR placentas. In addition, Fisher and associates (19, 20) also demonstrated that the apoptotic extravillous cytotrophoblasts detected in preeclamptic samples were negative for Bcl-2 expression, suggesting that a decrease in Bcl-2 expression may induce apoptosis in extravillous trophoblast cells. Interestingly, we have observed high levels of the p30 XIAP fragment in preeclamptic and IUGR placentas (S. L. Straszewski-Chavez and G. Mor, unpublished observations), which suggests that an increase in XIAP cleavage may be involved in these disease processes.

The elevated trophoblast apoptosis observed in pregnancies complicated by preeclampsia and IUGR may be due, in part, to placental oxidative stress, which can be triggered by hypoxia (128, 198, 199). Hypoxia has been shown to induce apoptosis in other cell types (200, 201), and the mechanism by which hypoxia mediates its proapoptotic effect is thought to involve the mitochondrial pathway (202). Indeed, it was demonstrated that hypoxia enhances apoptosis in term trophoblasts by decreasing the expression of Bcl-2 while increasing the expression of p53 and Bax (198) and activating caspase-9 and caspase-3 (203). Moreover, Perkins et al. (203) also reported that EGF protects trophoblast cells from hypoxia and that EGF exerts its antiapoptotic effect independently of the phosphatidylinositol 3-kinase/protein kinase B (Akt) survival pathway.

B. Apoptotic cell clearance in pregnancy-related diseases
An increase in trophoblast cell death might explain the insufficient trophoblast invasion and lack of spiral artery transformation often observed in abnormal pregnancies (22, 23). If increased trophoblast apoptosis occurs early in pregnancy, it may limit interstitial and endovascular invasion by extravillous trophoblasts (19, 20, 204). However, a recent study by Kadyrov et al. (205) suggests that the reduced trophoblast invasion observed in preeclampsia is not associated with higher rates of apoptosis because a decrease in interstitial trophoblast apoptosis was detected in preeclamptic placentas compared with the normal controls. These findings might be the result of when the samples were analyzed, because the placentas evaluated in this study were obtained from patients with active disease, and the presence of apoptotic trophoblast cells may have preceded the time of analysis. Moreover, the lack of apoptotic cells may also be due to an increase in the phagocytic activity of macrophages, which might quickly remove apoptotic trophoblast cells before they could be microscopically detected (194).

The antiinflammatory response after the clearance of apoptotic cells may be perturbed in pregnancy-related diseases (11). During normal pregnancy, the uptake of apoptotic cells suppresses macrophages from secreting proinflammatory cytokines such as TNF- and IFN- and promotes the release of antiinflammatory and immunosuppressive cytokines (Fig. 8A). In pregnancies complicated with preeclampsia or IUGR, a significant increase in the number of apoptotic cells may overwhelm the macrophages and promote macrophage production of proinflammatory cytokines, which may further enhance trophoblast cell death (Fig. 8B). Indeed, Pijnenborg et al. (113) reported a higher incidence of cell clusters secreting TNF- in the placental bed of patients with severe preeclampsia. Using macrophage-specific antibodies, we demonstrated that cell clusters in placental bed biopsies of preeclamptic patients were composed primarily of CD68+ macrophages (183).

The distribution pattern of macrophages in placentas of complicated pregnancies may also be different from that of normal pregnancies. Whereas macrophages are normally located in the stroma surrounding the extravillous trophoblast and spiral arteries, in preeclamptic and IUGR placentas, macrophages have been observed in the stroma between the spiral arteries and the trophoblast cells (1, 183, 204). Moreover, excess macrophages residing in the placental bed of preeclamptic women have been shown to limit extravillous trophoblast invasion by secreting TNF- (204), which induces trophoblast apoptosis. This suggests a differential role for macrophages in trophoblast invasion and differentiation according to the activation status of macrophages. Whereas in normal pregnancies, macrophages function as support cells by facilitating trophoblast invasion and transformation of the spiral arteries, in pathological conditions, macrophages act as a barrier to trophoblast invasion and differentiation by inducing trophoblast apoptosis, thereby preventing spiral artery transformation (Fig. 9) (21).

View larger version (41K): [in this window] [in a new window]   FIG. 9. Differential distribution of macrophages in normal and abnormal pregnancies. A, In normal pregnancies, macrophages function as support cells by facilitating trophoblast invasion and transformation of the spiral arteries. B, In pathological conditions, such as preeclampsia and IUGR, macrophages act as a barrier to trophoblast invasion and differentiation by inducing trophoblast apoptosis, thereby preventing spiral artery transformation.

C. Infection and trophoblast apoptosis
Another factor that may cause an increase in trophoblast apoptosis during pregnancy is infection. Intrauterine infections have been linked to pregnancy complications such as preeclampsia, IUGR, and preterm delivery (207, 208, 209, 210). Although the precise mechanism by which infection influences the progression of these diseases is not clearly understood, recent studies suggest that bacterial products can have a direct effect on the trophoblast. The trophoblast may respond to infection through the expression of a family of innate immune receptors, known as toll-like receptors (TLRs), which recognize conserved sequences on the surface of microorganisms (211). The expression of TLR-2 and TLR-4 has been demonstrated in first-trimester and term placental tissues (212, 213, 214), and isolated first-trimester trophoblast cells have been shown to express TLR-1 through TLR-4 (214, 215). Classically, TLR ligation results in the activation of the NF-B pathway and the production of cytokines (211). Indeed, the ligation of TLR-4 with lipopolysaccharide causes first-trimester trophoblast cells to produce cytokines, including TNF- and IFN-, which may induce trophoblast cell apoptosis (214). In contrast, after ligation of TLR-2 with peptidoglycan, first-trimester trophoblast cells undergo apoptosis, and the p30 cleavage product of XIAP and the activation of the caspase cascade are observed. Moreover, TLR-2-induced apoptosis in first-trimester trophoblast cells is dependent upon FADD, suggesting that TLR-2 may act as a death receptor (214). Taken together, this suggests that trophoblast cell apoptosis may be either directly induced, after TLR-2 ligation, or indirectly induced through a TLR-4-mediated pathway and the production of proinflammatory cytokines. The expression/function of TLR in trophoblast cells may represent a link between intrauterine infections, the regulation of trophoblast apoptosis, and pregnancy complications such as preeclampsia, IUGR, and preterm labor.

	VIII. Summary and Conclusions

Top Abstract I. Introduction II. Trophoblast Expression and... III. The Role of... IV. Endogenous Regulators of... V. Exogenous Regulation of... VI. The Role of... VII. Trophoblast Apoptosis and... VIII. Summary and Conclusions References

 
The placenta is a remarkable organ that depends on the growth and development of the trophoblast to deliver blood and nutrients to the fetus during pregnancy. Apoptosis, and the factors involved in its regulation, is associated with almost all stages of trophoblast development and differentiation. Although the number of studies evaluating the role of apoptosis in trophoblast development and function has significantly increased in recent years, relatively little is still known about what controls apoptosis in the placenta. These studies emphasize not only the complexity of the apoptotic events that occur in the placenta, but also how important the appropriate regulation of trophoblast apoptosis is for a successful pregnancy. More mechanistic studies should enhance our understanding of how trophoblast apoptosis is regulated during normal pregnancy and may provide new therapeutic approaches for the treatment of pregnancy-related diseases associated with excessive trophoblast apoptosis.

	Acknowledgments

 
We thank Dr. Harold R. Behrman for critically reviewing the manuscript.

	Footnotes

 
This work was supported by National Institutes of Health Grants RO1HD37137–01A2 and RO1CA92435–01 (to G.M.).

First Published Online May 18, 2005

Abbreviations: BH, Bcl-2 homology; BIR, baculoviral IAP repeat; DcR, decoy-like receptor; DED, death effector domain; DISC, death-inducing signaling complex; EEC, endometrial epithelial cell; EGF, epidermal growth factor; FADD, Fas-associated death domain; FasL, Fas ligand; FLIP, flice-like inhibitory protein; FLIP_L, long FLIP isoform; FLIP_S, short FLIP isoform; h, human; HVEM, herpes virus entry mediator; IAP, inhibitor of apoptosis; IFN, interferon; IUGR, intrauterine growth retardation; LT-ßR, lymphotoxin-ß receptor; Mcl-1, myeloid cell leukemia-1; NF-B, nuclear factor-B; PARP, poly (ADP-ribose) polymerase; RING, really interesting new gene; RIP, receptor-interacting protein; Smac/DIABLO, second mitochondria-derived activator of caspase/direct IAP-binding protein with low-PI; Th1, T helper 1; TLR, toll-like receptor; TNF-R, TNF receptor; TRAIL, TNF-related apoptosis-inducing ligand; XAF1, XIAP-associated factor 1; XIAP, X-linked IAP.

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