The equine endometrial cup reaction: a fetomaternal signal of significance.

A remarkable feature of equine pregnancy is the development of the invasive trophoblast of the chorionic girdle and its formation of the gonadotrophin-secreting endometrial cup cells in early gestation. The details of this process have been revealed only slowly over the past century, since the first description of the endometrial cups in 1912. This centennial presents an opportunity to review the characteristics of the cells and molecules involved in this early, critical phase of placentation in the mare. The invasiveness of the chorionic girdle trophoblast appears to represent an atavistic attribute more commonly associated with the hemochorial placentae of primates and rodents but not with the more recently derived epitheliochorial placentae of the odd-toed ungulates. The nature of and raison d'être for the strong fetal signals transmitted to the mare by the endometrial cup reaction, and her responses to these messages, are the subject of the present review.

Molecular evidence for natural killer-like cells in equine endometrial cups.

OBJECTIVES: To identify equine orthologs of major NK cell marker genes and utilize them to determine whether NK cells are present among the dense infiltration of lymphocytes that surround the endometrial cup structures of the horse placenta during early pregnancy. STUDY DESIGN: PCR primers were developed to detect the equine orthologs of NKP46, CD16, CD56, and CD94; gene expression was detected in RNA isolated from lymphocytes using standard 2-step reverse transcriptase (RT) PCR and products were cloned and sequenced. Absolute real-time RT-PCR was used to quantitate gene expression in total, CD3+, and CD3- peripheral lymphocytes, and invasive trophoblast. Lymphocytes surrounding the endometrial cups (ECL) of five mares in early pregnancy were isolated and NK marker gene expression levels were assayed by quantitative RT-PCR. MAIN OUTCOME MEASURES: Absolute mRNA transcript numbers were determined by performing quantitative RT-PCR and comparing values to plasmid standards of known quantities. RESULTS: NKP46 gene expression in peripheral CD3- lymphocytes was higher than in CD3+ lymphocytes, CD16 levels were higher in the CD3+ population, and no significant differences were detected for CD56 and CD94 between the two groups. Expression of all four NK cell markers was significantly higher in lymphocytes isolated from the endometrial cups of pregnant mares compared to PBMC isolated from the same animal on the same day (NKP46, 14-fold higher; CD94, 8-fold higher; CD16, 20-fold higher; CD56, 44-fold higher). CONCLUSIONS: These data provide the first evidence for the expression of major NK cell markers by horse cells and an enrichment of NK-like cells in the equine endometrium during pregnancy.

Modeling trophoblast differentiation using equine chorionic girdle vesicles.

The chorionic girdle of the equine conceptus is comprised of specialized trophoblast cells which, at day 36-38 of equine pregnancy, gain an invasive phenotype and invade the endometrium to form endometrial cups. Studies of equine endometrial cups remain difficult to perform because of the invasive techniques required to obtain cup tissue and because sampling requires termination of the pregnancy. In this study we developed a system to model trophoblast differentiation and trophoblast-immune interactions in vitro and in vivo. We utilized a method of culturing chorionic girdle pieces in serum-free medium to promote spontaneous formation of vesicle structures enriched for terminally differentiated binucleate cells that secreted equine chorionic gonadotrophin (eCG). Immunohistochemical staining and scanning electron microscopy showed that the cells of the vesicles closely resembled the outer layers of chorionic girdle immediately prior to invasion. Chorionic girdle vesicles were harvested after 72h in culture and ectopically transplanted via injection into the vulvar mucosa of recipient mares. At 7, 14, 21 and 28days after transplantation, biopsies of the injection sites were obtained. Immunohistochemical labeling of cryostat sections of the biopsies with a panel of monoclonal antibodies to horse trophoblast molecules demonstrated survival, differentiation, and presence of trophoblast cells for at least 21days. Serial sections of the biopsies labeled with antibodies to the equine lymphocyte surface markers CD4 and CD8, together with lymphocyte microcytotoxicity assays, revealed that the recipients mounted both cellular and humoral antibody immune responses to the transplanted trophoblast cells. This new method for culturing equine chorionic girdle trophoblast cells, and for transplanting trophoblast vesicles to ectopic sites, should allow identification of key aspects of trophoblast differentiation and the interactions that occur between invasive trophoblast and the maternal immune system.

The effect of skin allografting on the equine endometrial cup reaction.

This research tested the hypothesis that immunological sensitization of mares by skin allografting, followed by the establishment of pregnancy using semen from the skin-graft donor, would give rise to secondary immune responses to the developing horse conceptus, resulting in an earlier demise of the fetally derived endometrial cups. Maiden mares received skin allografts from a stallion homozygous for Major Histocompatibility Complex (MHC) antigens and/or equivalent autografts and were subsequently mated to the skin-graft donor stallion during the next two breeding seasons. Mares that had been immunologically primed to the foreign MHC class I antigens of the skin-graft donor stallion developed strong secondary antibody responses early in their first pregnancies, whereas autografted mares made weak primary antibody responses in their first pregnancies and strong secondary responses in their second pregnancies. In contrast, histological examination of the endometrial cups after surgical pregnancy termination at Day 60 of gestation revealed no discernible differences between allografted and autografted mares, and there were no significant differences in the concentrations and/or duration of secretion of the endometrial cup-specific hormone, equine chorionic gonadotrophin (eCG), between allografted and autografted mares, nor in either group between first and second pregnancies. The vigorous antibody response observed in the pregnant allografted mares supported the first part of our hypothesis, providing evidence of systemic immunological priming. However, there was a lack of an equivalent heightened cellular response to the endometrial cups. These findings provided strong evidence for an asymmetric immune response to the conceptus, characterized by strong humoral immunity and a dampened cellular response.

Inhibition of lymphocyte proliferation and activation: a mechanism used by equine invasive trophoblast to escape the maternal immune response.

At days 36-38 of gestation, the equine invasive trophoblast cells migrate into the endometrium of the pregnant mare to form the endometrial cups. During their migration, they become surrounded by maternal CD4+ and CD8+ T lymphocytes, and stimulate a cytotoxic antibody response to the paternal major histocompatibility complex class I antigens that they express. Nevertheless, endometrial cup cells remain viable at the site of uterine invasion up to days 80-100 of gestation, suggesting the participation of immunomodulatory mechanisms to the maternal cellular immune response. To determine the effects of the invasive trophoblast cells on lymphocyte proliferation, an in vitro co-culture system was developed using isolated equine invasive trophoblast cells and peripheral blood lymphocytes. Fetal fibroblast cells from the same conceptuses were used as controls. The presence of invasive trophoblast cells or their pre-conditioned medium inhibited 50% or more of lymphocyte proliferation, while fetal fibroblasts had no effect. The invasive trophoblast cell inhibitory factor needed to be present constantly to affect lymphocyte proliferation, and it was ineffective if lymphocytes had been previously stimulated to proliferate. The lymphoproliferative inhibitory mechanism affected lymphocyte subpopulations similarly. In addition, lymphocyte expression of cytokine mRNA including IFNgamma, IL-2, IL-4, and IL-10 was affected compared to controls. The implication of these observations in vivo may explain, in part, the apparent equine maternal immune acceptance of the presence and development of endometrial cup cells.

Immortalization of equine trophoblast cell lines of chorionic girdle cell lineage by simian virus-40 large T antigen.

Immortalized cell lines have many potential experimental applications including the analysis of molecular mechanisms underlying cell-specific gene expression. We have utilized a recombinant retrovirus encoding the simian virus-40 (SV-40) large T antigen to construct several immortalized cell lines of equine chorionic girdle cell lineage - the progenitor cells that differentiate into the equine chorionic gonadotropin (eCG) producing endometrial cups. Morphologically, the immortalized cell lines appear similar to normal chorionic girdle cells. Derivation of the immortalized cell lines from a chorionic girdle cell lineage was verified by immunological detection of cell-surface antigens specific to equine invasive trophoblasts. The cell lines differed, however, from mature chorionic girdle cells or endometrial cup cells in that they did not produce eCG and did express MHC class I molecules. Thus, these cell lines appear to have been arrested at a stage of development prior to final differentiation into endometrial cup cells. It was also determined that some of these cell lines as well as endometrial cups express the estrogen receptor-related receptor beta gene, but not the glial cell missing gene (GCMa) both of which are expressed in the murine and human placenta. Among these cell lines, three (eCG 50.5, 100.6 and 500.1) express eCG alpha mRNA. Since regulation of eCG alpha subunit gene is largely unknown, we investigated the signal transduction pathways regulating the eCG alpha subunit gene. Both activators of protein kinase A (PKA) and protein kinase C (PKC) induced the expression of eCG alpha subunit expression 3.2 (P<0.05)- and 1.9 (P<0.05)-fold respectively, in the eCG 500.1 cell line. However, activation of these pathways failed to induce eCG beta subunit expression. In conclusion, lines of equine trophoblast cells have been immortalized that display markers characteristic of those with the equine chorionic girdle and endometrial cup cell lineage. A subset of these cells expresses the eCG alpha subunit gene which is responsive to activators of the PKA and PKC signal transduction pathways.

Ectopic transplantation of equine invasive trophoblast.

A system for transplanting invasive equine trophoblast (i.e., chorionic girdle) to ectopic sites has been developed as a means to study the differentiation of this tissue and to assess maternal immune responses to the conceptus tissue in a site outside the uterus. Chorionic girdle was isolated from Day 33 to 34 conceptuses and surgically placed into the vulvar mucosa or subdermal skin of recipient mares. Biopsy specimens of the graft sites for immunohistochemical staining were taken at weekly or biweekly intervals after grafting. Serum samples were collected from each recipient and tested for antibody to donor major histocompatibility complex (MHC) class I antigens using the lymphocyte microcytotoxicity assay. Transplanted trophoblast cells expressed differentiation markers associated with invading chorionic girdle and endometrial cup cells. The transplanted trophoblast cells were also labeled by an antibody to eCG. Strong cellular and humoral immune responses to the transplanted tissue were mounted by the recipients, similar to those occurring during normal equine pregnancy. Despite these responses, the invasive trophoblast transplants survived for at least 28 days after grafting and downregulated MHC class I antigens, as do the mature endometrial cup cells in equine pregnancy. These findings suggest that invasive equine trophoblast has the capacity to differentiate fully in equine nonuterine tissues, and that it can evade maternal immune responses independent of the physiological state of pregnancy and in sites other than the uterus.

Characterization of equine natural killer and IL-2 stimulated lymphokine activated killer cell populations.

Natural killer (NK) cells are an important component of the innate immune system. Though intensively studied in humans and rodents. NK cells remain less well characterized in other species. Studies are often limited by the lack of specific cell markers; however, the mAb NK-5C6 has been suggested to recognize an evolutionarily conserved molecule on NK cells and reacts with cells from several species. This mAb was used in the current investigation to identify and characterize equine NK cells, and was found to label approximately 10% of peripheral blood lymphocytes (PBL). Two-color flow cytometry analysis identified the NK-5C6+ cell population as being CD3-CD4- and CD8-, but positive for MHC class I and LFA-1 expression. Depletion of CD3+ T cells increased the percent NK-5C6+ cells in PBL; this enriched population demonstrated a specific cytotoxic response against a major histocompatibility complex (MHC) deficient NK target cell line (K-562), but not MHC+ target cells (EqT8888). These results provide evidence for an equine NK cell population, which exhibits endogenous lytic activity and a phenotype similar to that of human and mouse NK cells. Stimulation of peripheral blood mononuclear cells (PBMC) with IL-2 promoted the development of LAK cells. These cells were predominantly CD3+ T cells, demonstrated intracellular perforin expression, and effectively lysed both K-562 and EqT8888 target cells. Hence, equine NK cells can be identified by the NK-5C6 mAb and distinguished from IL-2 stimulated LAK cells by their cytotoxic response to specific target cell lines.

The equine homologue of LFA-1 (CD11a/CD18): cellular distribution and differential determinants.

The equine homologue of the leucocyte integrin LFA-1 (CD11a/CD18) has been characterized using a panel of four monoclonal antibodies (mAbs). The antibodies labelled almost all leukocytes, thymocytes and lymph node cells from normal horses, and immunoprecipitated two noncovalently associated polypeptides with molecular weights of 180 kDa and 100 kDa, respectively. The antigen recognized by one mAb could be precipitated by another in this cluster in a sequential immunoprecipitation assay. The mAbs, however, did not block the activities on lymphocyte function of one another. A mAb to the beta subunit of human LFA-1 cross-reacted with equine LFA-1, but an antibody to its alpha subunit did not, suggesting that the beta subunit of the leukocyte integrin may be more highly-conserved. Functionally, H20A and a human CD18 antibody (MHM23) inhibited phorbol ester-mediated homotypic lymphocyte aggregation, whereas mAb CZ3.2 induced rather than inhibited the homotypic cell aggregation. The formation of lymphocyte aggregates induced by CZ3.2 was not blocked by the inhibitory antibodies H20A or MHM23. CZ3.1 seemed to have little inducible or inhibitory effects on homotypic cell aggregation. The mAb CZ3.1 defined a unique LFA-1 determinant present on granulocytes, but absent on lymphocytes in members of an extended horse family, in contrast to the other antibodies which labelled both granulocytes and lymphocytes from these animals. In all other horses tested, no differences in reactivity of CZ3.1 and the other LFA-1 antibodies were observed when the antibodies were tested on lymphocytes or granulocytes. Our results indicate that common epitopes are shared' between human and equine LFA-1, and that the described panel of monoclonal antibodies identifies distinct determinants present on the equine LFA-1 molecule. The following monoclonal antibodies used in this study were given official workshop designations at the Second International Workshop on Equine Leukocyte Antigens (Lunn et al., 1998) CZ3.1 (Cor) = W45; CZ3.2 (Cor) = W77.

Equine sarcoids.

Sarcoids, the most common tumor of the horse, are fibroblastic, wart-like skin lesions that show variable manifestations. They are often invasive and recurrent, although they do not fulfill all criteria of malignancy. Due to their anatomic location, these tumors can sometimes cause loss of use of the horse. There is very strong evidence that sarcoids are caused by viruses closely related or identical to bovine papilloma viruses, and genetic studies have shown associations between genes in or near the equine major histocompatibility complex (MHC) and susceptibility to sarcoid. Several types of treatments have been successful in treating sarcoids, although the response to therapy is not consistent. Current treatment of sarcoids primarily involves antitumor therapy, but the development of preventative measures in the future may be directed against the causative papilloma virus. Sarcoid continues to be an important clinical entity for the equine practitioner.

Analysis of MHC class I expression in equine trophoblast cells using in situ hybridization.

Down-regulation of major histocompatibility complex (MHC) genes by trophoblast cells is considered to be a primary mechanism preventing maternal immune rejection of the fetal-placental unit in mammalian pregnancy by rendering these cells, which form the primary barrier between mother and fetus, relatively non-antigenic. In situ hybridization with probes encoding human and horse MHC class I genes was used to characterize the pattern of MHC class I mRNA expression in the various forms of horse trophoblast. Strong hybridization signals were observed in the invasive trophoblast cells of chorionic girdle tissue. In contrast, no hybridization signal specific for MHC class I mRNA transcripts was observed in the descendent endometrial cup trophoblast cells. In the non-invasive trophoblast cells of the allantochorion, no hybridization signals specific for horse MHC class I mRNA transcripts were consistently detected. In parallel to the in vivo results, strong hybridization signals were observed in the small, mononuclear cells present in chorionic girdle cell explant cultures, but not in the population of large binucleate cells corresponding to endometrial cup cells. The results obtained using in situ hybridization are consistent with the hypothesis that expression of MHC class I genes may be controlled at the transcriptional level in horse invasive and non-invasive trophoblast cells, and suggest that down-regulation of MHC class I antigen expression in endometrial cup cells may be accomplished by the same mechanisms in vivo and in vitro.

The maternal leucocyte response to the endometrial cups in horses is correlated with the developmental stages of the invasive trophoblast cells.

Invading trophoblasts form endometrial cups in the endometrium of the pregnant mare. In the present study we characterized the maternal leucocyte response to endometrial cups from their formation to their regression. The maternal leucocyte response was correlated with the stages of trophoblast development. (1) Aggregates of CD4+ and CD8+ cells were present between the migrating and differentiating endometrial cup trophoblasts and surrounding the forming endometrial cups. (2) Numbers of CD4+ cells within the mature endometrial cups were much reduced. At the periphery of the endometrial cups CD4+ and CD8+ cells were found in patchy accumulations around endometrial glands; small clusters of CD79+ B lymphocytes were present as well. (3) Scattered CD4+ and CD8+ cells were found within dying endometrial cups; areas of cell death were infiltrated with neutrophils. Large aggregates of CD4+ cells and CD8+ cells, and small but numerous clusters of CD79+ cells and eosinophils, were found outside of the dying endometrial cups. The CD4+ or CD8+ cells were mostly CD3+ T cells; some were probably macrophages which can express both of these markers in horses. The correlation between the developmental stages of the endometrial cup trophoblast and the maternal leucocyte response suggests a complicated cytokine-mediated regulatory network.

Horse trophoblasts produce tumor necrosis factor alpha but not interleukin 2, interleukin 4, or interferon gamma.

The distribution of four cytokines was analyzed in the endometrium and trophoblast of the horse between Days 30 and 55 of gestation. Endometrial tissues, invasive trophoblast (chorionic girdle), and noninvasive trophoblast (chorion and allantochorion) were examined separately. Cytokine expression was determined by amplification of specific mRNA via the reverse transcriptase polymerase chain reaction (RT-PCR). Messenger RNA for interleukin 2 (IL-2), interleukin 4 (IL-4), and interferon gamma (IFN gamma) was detected in endometrial tissues, unstimulated peripheral blood lymphocytes, and control kidney tissue, but not in trophoblasts. leukocytes resident in the endometrium or traversing the uterus via blood vessels might be the source of these cytokines. Endometrial tissues and invasive and noninvasive trophoblasts expressed mRNA for tumor necrosis factor alpha TNF alpha). Immuonoreactive TNF alpha protein was detected in different cell types of the endometrium and in the invasive and noninvasive trophoblast. The ubiquitous expression of TNF alpha by the endometrium and trophoblasts suggests that this cytokine might have an important role in regulating placental growth and differentiation or maternal leukocyte responses to trophoblasts. IL-2, IL-4, and IFN gamma might have important immunoregulatory roles within the endometrium.

Intravascular leukostasis and systemic aspergillosis in a horse with subleukemic acute myelomonocytic leukemia.

Leukemia is a neoplastic disease of one or more of the cell types of the hemopoietic system and is rarely diagnosed in the horse. This report describes a case of subleukemic acute myelomonocytic leukemia in an 11-year-old gelding. Preliminary cytological diagnosis was supported by two types of laboratory investigations. Cytochemical characterization of blood and bone marrow neoplastic cells was consistent with a myelomonocytic origin. Neoplastic blast cells in peripheral blood were labeled by monoclonal antibodies specific for cell surface molecules of horse granulocytes, but they were not labeled by antibodies to T- or B-lymphocytes or macrophages. Treatment was attempted but was unsuccessful. At necropsy, intravascular leukostasis was present in all tissues examined. Fungal hyphae were also found in lung interstitium and colonic submucosa, suggesting the presence of a systemic mycosis. Nucleated cells were isolated from peripheral blood and cultured in vitro; they survived for up to 2 weeks and had evidence of cell division that was not sustained. Frozen-thawed cells stored in liquid nitrogen were also successfully cultured in vitro, but no permanent cell lines could be established.

An equine B cell surface antigen defined by a monoclonal antibody.

A surface antigen of equine B lymphocytes was identified using the Equine Leucocyte Antigen Workshop antibody WS 65. This marker was expressed on almost all equine B cells, but not on T cells, granulocytes or thymocytes. WS 65 strongly stained cells in the follicular areas of lymph nodes and cells in the splenic nodules when tested on frozen tissue sections by immunohistochemistry. Equine leukemic T cells were not labeled by WS 65, and neither were the cells from a horse with B cell leukemia, although these latter cells carried surface immunoglobulin. Immunoprecipitation of lymphocyte membrane molecules with the antibody produced a band at 85-90 kDa under reducing conditions. The equine B cell antigen defined by WS 65 appears to be different from surface immunoglobulin by its molecular characteristics and its lack of expression on malignant B cells.

Effects of fetal genotype and uterine environment on placental development in equids.

Measurement of the concentrations of equine chorionic gonadotrophin (eCG) in the serum of pregnant mares and Jenny donkeys carrying normal intraspecies and hybrid interspecies pregnancies suggested that the production of this hormone may be influenced by parental gene imprinting. Specifically, a differential expression of maternal and paternal genes may control the size and secretory activity of the structures that secrete eCG, the fetal endometrial cups. However, bisection of an interspecies mule embryo followed by transfer of the resulting demi-embryos and other intact mule embryos to horse and donkey recipients resulted in striking differences in the size, secretory activity and lifespan of the endometrial cups in two types of surrogate mother. This finding has therefore demonstrated the ability of uterine factors to alter profoundly the development and characteristic phenotype of the specialized invasive chorionic girdle portion of the equine trophoblast that gives rise to the endometrial cups.

DNA of bovine papillomavirus type 1 and 2 in equine sarcoids: PCR detection and direct sequencing.

Nucleotide sequences of bovine papillomavirus (BPV) DNA amplified by the polymerase chain reaction (PCR) from samples of equine sarcoid skin tumours were determined. All naturally occurring sarcoids (n = 58 tumours from 32 horses and 2 donkeys) contained BPV-DNA. All but 3 of the genome fragments belonged to the BPV type 1 strain (BPV-1); the remaining were BPV type 2. Similar results were obtained with cutaneous bovine papillomas used as controls (n = 20). One of the horses, carrying 2 sarcoids, was particularly interesting; one tumour contained BPV-1 DNA whilst the other sarcoid yielded BPV-2 DNA, suggesting that horses are not immune to super-infection. BPV-DNA was even amplified from the sarcoid samples which had yielded negative results in previous investigations when DNA isolated from the lesions was used in Southern blot hybridization with BPV probes. In addition, there was no detectable BPV-DNA in any equine or bovine tissue examined other than sarcoids or cutaneous bovine papillomas. Biopsies of normal skin surrounding lesions yielded exclusively negative results. The described nucleotide differences represent a natural genomic variation of this BPV type between geographically distant locations. The identical variations recovered from cattle and horses in Switzerland, a finding of great epidemiological interest, strongly suggest that a uniform variant of BPV-1 is one of the etiologic agents of equine sarcoid and bovine papilloma in a given region.

Developmental regulation of class I major histocompatibility complex antigen expression by equine trophoblastic cells.

Between days 36-38 of pregnancy equine trophoblastic cells of the chorionic girdle migrate and form endometrial cups. Just prior to invasion, the chorionic girdle cells express high levels of polymorphic, paternally inherited, major histocompatibility complex (MHC) class I antigens. Their descendents, the mature, invasive trophoblast cells of the endometrial cups, however, express low or undetectable levels of MHC class I antigens by day 44 of pregnancy. Experiments with MHC compatible pregnancies, the study of residual chorionic girdle cells that had failed to invade the endometrium and remained on the surface of a conceptus, and the study of chorionic girdle cells recovered on days 34-36 of pregnancy and then maintained in vitro for up to 24 days strongly suggest that the reduction of MHC class I antigen expression by mature invasive trophoblast cells of the endometrial cups is developmentally regulated. This phenomenon does not appear to be induced by a maternal antibody response or by other uterine factors acting after the chorionic girdle trophoblast cells invade the endometrium.