Expression of lymphocyte perforin in the mouse uterus during pregnancy

HOXA10 signals on the highway through pregnancy

Implantation represents the remarkable synchronization between the development of the embryo and the differentiation of the endometrium. It depends on uterine-dependent and embryo-specific events, which are critically and sequentially coordinated. A plethora of molecules have been identified which play major roles before and after embryo implantation. In recent years HomeoboxA10 (HOXA10) has emerged as one of the most promising candidates which regulate the events occurring in the maternal compartment for successful establishment of pregnancy. HOXA10 is a transcription factor that is crucial for development and patterning of the uterus during embryogenesis. In the adult endometrium, HOXA10 is expressed in a menstrual cycle dependent manner and it is regulated by ovarian steroid hormones and embryonic signals, HOXA10 is required for uterine receptivity and implantation, and is a key regulator of decidualization. In the decidua, HOXA10 is involved in regulation of cell cycle and local immunomodulation. The present review summarizes the events that are regulated by HOXA10 in embryo implantation and decidualization.

Effect of the conceptus on uterine natural killer cell numbers and function in the mouse uterus during decidualization

Uterine natural killer (uNK) cells are the most abundant lymphocytes in the uterus during early pregnancy and play a role in spiral arteriole modifications. In the present study, we investigated whether uNK cell populations differed between mouse decidua and deciduoma. Histochemical staining using the Dolichos biflorus agglutinin (DBA) lectin was used to identify uNK cells and classify their stages of maturation. We found differences in the pattern of localization and density of uNK cells between the decidua and deciduoma at Days 2-4 after the onset of decidualization. The cells were more distributed and the densities were significantly greater in the mesometrial region of the decidua than in the deciduoma. Using double-labeling for DBA lectin binding and bromodeoxyuridine incorporation, we found that the higher number of uNK cells in the decidua was not due to an increase in uNK cell proliferation. Western blot analyses revealed that the increase in uNK cell number was accompanied by significant increases in the levels of interferon gamma (IFNG) and prointerleukin 18 when a conceptus was present. Vascular morphometry revealed that modifications of the spiral arterioles occurred in the mesometrial decidua but not in the deciduoma, which could be attributed to the differences observed in uNK cell number and IFNG production. The present study demonstrates that differences exist in uNK cell populations between the decidua and deciduoma, providing evidence that the conceptus generates signals that regulate uNK cell number and function in the uterus during implantation.

Hoxa-10 deficiency alters region-specific gene expression and perturbs differentiation of natural killer cells during decidualization

Uterine decidualization, a key event for successful implantation, is critically controlled by stromal cell proliferation and differentiation. One hallmark event of decidualization is the acquisition of stromal cell polyploidy through terminal differentiation at the anti-mesometrial pole of the implantation site. Hoxa-10, a developmentally regulated homeobox transcription factor, is highly expressed in decidualizing stromal cells, and targeted deletion of Hoxa-10 in mice shows severe decidualization defects, primarily due to reduced stromal cell responsiveness to progesterone. However, the underlying molecular mechanism by which Hoxa-10 regulates this process remains largely unknown. Here, we show that Hoxa-10 deficiency confers diminished core cell cycle activity during stromal cell proliferation without disturbing polyploidy, suggesting that these events depend on local regulators that impact cell cycle machinery. To further address this question, we compared global gene expression profiles in uteri of wild-type and Hoxa-10(-/-) mice after inducing decidualization. Our studies show two major aspects of decidualization downstream of Hoxa-10. First, Hoxa-10 deficiency results in the aberrant region-specific expression of cyclin-dependent kinase-4 (cdk4) and -6 (cdk6), growth differentiation factor 10 (Gdf10), hepatocyte growth factor (Hgf) and Snail2. Second, Hoxa-10 deficiency compromises natural killer (NK) cell differentiation without altering trafficking of NK precursor cells during decidualization. Collectively, the results provide evidence that Hoxa-10 influences a host of genes and cell functions necessary for propagating normal decidual development during the post-implantation period.

Ultrastructural Study of Uterine Natural Killer Cells Found in Pregnant, Interleukin-2 Receptor .BETA.-chain Overexpressed Transgenic Mice

We previously reported that all fetuses died or were resorbed on day 12 of pregnancy (Day 1= the day of plug) in interleukin-2 (IL-2) receptor beta-chain overexpressed transgenic (Tg2Rbeta) mice. In this study, to clarify the role of uterine natural killer (uNK) cells in pregnancy, the ultrastructure of Tg2Rbeta mouse uNK cells was analyzed using a transmission electron microscope. uNK cells and their granules on day 10 of pregnancy were larger in Tg2Rbeta mice than control mice, indicating that differentiation of uNK cells in Tg2Rbeta mice progressed rapidly. Additionally, the granules of uNK cells in Tg2Rbeta mice on day 10 of pregnancy had an irregular morphology. The multivesicular regions were present in the cap structure of these granules, suggesting that the uNK cells of the Tg2Rbeta mice had cytotoxic activity.

cDNA subtraction cloning reveals novel genes whose temporal and spatial expression indicates association with trophoblast invasion

Trophoblast invasion is a critical process in development of most mammals that shares similarities with the invasive behavior of tumor cells. In the present investigation, a cDNA subtraction library was constructed between invasive trophoblast at day 8 of murine development and mature noninvasive placenta at day 18 of gestation. One of the differentially expressed clones, Epcs26, was mapped to the X chromosome and revealed no homology to any known gene. It was predominantly expressed in parietal endoderm, undifferentiated cells of the ectoplacental cone, and a few trophoblast giant cells. Another gene, designated Epcs50, was mapped to chromosome 19. It exhibited homologies to the mouse Mps1 gene and, like Mps1, may have a distant relationship to the lytic protein perforin. High expression was detected in parietal endoderm cells and in a subset of secondary trophoblast giant cells. Two sequences, Epcs24 and Epcs68, exhibited an extensive open reading frame that shared the common features of the cysteine proteinase cathepsin L. Expression was confined to an undefined subpopulation of trophoblast giant cells. Both genes were mapped to chromosome 13 in close proximity to cathepsins L and J. The known functions of MPS1 and cathepsin L proteins indicate that the related proteins EPCS50, EPCS24, and EPCS68 participate in conferring invasive properties to the mouse trophoblast.

Nitric oxide synthase-2 and expression of perforin in uterine NK cells

In human, mouse, and rat pregnancy, maternal NK cells accumulate and differentiate at implantation sites. These cells, termed uterine NK (uNK) cells, express NO synthase (NOS)-2 and develop cytolytic molecules such as perforin and granzymes during differentiation in situ. In this study, relationships between expression of the NOS-2 gene, uNK cell population density and tissue distribution, and synthesis of perforin were investigated. Uteri from wild-type (WT) and NOS-2-/- mice were collected at gestation days (g.d.) 8, 10, 12, 14, and 16 (n, >2/g.d.). Histochemical staining failed to reveal any differences between the population densities or tissue distributions of uNK cells in WT and NOS-2-/- uteri at any stage of gestation. By contrast, immunohistochemical staining with anti-perforin Abs demonstrated significantly fewer perforin-positive uNK cells in two uterine compartments of NOS-2-/- mice in comparison to the same compartments in WT mouse uteri. Perforin-positive uNK cells were reduced in NOS-2-/- metrial glands at g.d. 8, 10, and 12 and in decidua basalis at g.d. 12 (p < 0.05). Analysis of perforin protein by immunoblotting confirmed this observation. Northern blot hybridization studies showed that loss of perforin protein in NOS-2-/- mice was accompanied by decreased steady-state levels of perforin mRNA. These results demonstrate that migration of uNK cells into the uterus, selection of residency sites, and proliferation in situ are independent of NOS-2. By contrast, their differentiation, including transcription and translation of the cytotoxic molecule perforin, was shown to rely on normal expression of the NOS-2 gene.

Progesterone directly and indirectly affects perforin expression in cytolytic cells

PROBLEM

Decidual lymphocytes (DL) expressing the cytolytic molecule perforin represent approximately 55% of DL in the first trimester of human pregnancy. Progesterone dominates this phase of pregnancy and controls the production of uterine cytokines and growth factors. The aim of this study was to investigate the role of progesterone and progesterone-induced blocking factor (PIBF) on perforin expression in DL and peripheral blood lymphocytes (PBL).

METHOD OF STUDY

Perforin expression was analyzed in PBL and DL incubated either in culture medium or with decidual adherent cells (DAC) and peripheral blood adherent cells (PBAC) and their supernatants with or without progesterone or PIBF. Perforin was detected by flow cytometry in PB and in decidual first trimester pregnancy lymphocytes.

RESULTS

Progesterone in high concentrations directly affects perforin expression in DL but not in PBL. Progesterone in a concentration dependent manner indirectly blocks perforin expression in DL and PBL cultured with adherent cells or their supernatants. PIBF blocked upregulation of perforin expression of DL cultured with DAC, but none of those cultured with PBAC. Similarly, PIBF was inefficient when PBL or DL were cultured with PBAC.

CONCLUSION

Progesterone present in a high concentration locally at the maternal-fetal interface modulates perforin expression in the first trimester pregnancy DL.

Granzymes D, E, F, and G Are Regulated Through Pregnancy and by IL-2 and IL-15 in Granulated Metrial Gland Cells

Granulated metrial gland (GMG) cells are NK cells that proliferate and differentiate within the murine uterus during pregnancy. They have been predicted to play important roles in nurturing the embryo, normal placentation, and uterine tissue remodeling. GMG cell differentiation is manifested by the accumulation of the cytolytic mediators, perforin, granzyme A, and granzyme B, within cytoplasmic granules. The signaling mechanisms required for GMG cell differentiation are largely unknown, although recent in vitro assays have implicated IL-15 in these events. In this report, we demonstrate that granzymes D, E, F, and G (granzymes D–G) are also expressed in GMG cells but at a later stage in pregnancy when compared with granzyme A expression. Whereas granzyme A is expressed in early to mid-gestation, the expression of granzymes D–G peak in mid- to late gestation. In addition, we show that the expression patterns of IL-2Rβ and the IL-2Rγ mRNAs overlap with that of granzyme D–G mRNAs in the pregnant uterus. Finally, we demonstrate that granzymes D–G are up-regulated by IL-2 and IL-15 in primary cultures containing GMG cells. Taken together, these results suggest that IL-2 and/or IL-15 may regulate GMG cell differentiation in vivo, and that granzymes D–G may have different functions than granzyme A during pregnancy.

Membrane phenotype and expression of perforin and serine esterases by CD3- peripheral blood and decidual granular lymphocyte-derived clones

PROBLEM

Human first-trimester pregnancy decidua were found to contain large numbers of perforin (P)-containing cells, which varied in their membrane antigen phenotype. In this study results obtained by analyzing CD3- clones derived from human early pregnancy decidua and peripheral blood are reported.

METHOD OF STUDY

Decidual tissue was obtained from vaginal termination of first trimester normal human pregnancies. CD3- clones were generated by limiting dilution cloning after the depletion of CD3+ lymphocytes. The cell membrane phenotype was determine by flow cytometry. Perforin was detected by fluorescence-activated cell sorter (FACS) analysis of permeabilised cells. Serine esterases (SE) were identified by histochemical staining for BLT-esterase.

RESULTS

Cloned decidual cell populations retained the overall antigenic phenotype of freshly isolated decidual natural killer (NK)-like cells. All CD3- clones, either derived from decidua or from peripheral blood contained perforin. Serine esterases were present in every decidual clone analyzed.

CONCLUSIONS

Limiting dilution cloning allows the clear-cut analysis of homogenous subsets of decidua-derived NK-like clones. The presence of large amounts of perforin in all of the CD3- clones underlines the extensive transcription of the perforin gene by NK-like lymphocytes.

Down-regulated expression of perforin-positive/CD16+ cells in the peripheral blood lymphocytes in the first trimester of pregnancy and up-regulation at the end of pregnancy

PROBLEM

Immunophenotypic profiles of perforin (P)-positive peripheral blood lymphocytes in the first trimester and at the term of human pregnancy were analyzed.

METHOD OF STUDY

Perforin expression in peripheral blood lymphocyte subsets was measured by simultaneous detection of P (intracellular antigen) and cell-surface antigens (CD3, CD4, CD8, CD16, and CD56) by flow cytometry in nonpregnant (NP) and pregnant women in the first trimester (FTP) and at the time of parturition (TP).

RESULTS

The percentage of total P+ cells in peripheral blood compared to nonpregnant women was slightly lower in the FTP but significantly higher at TP. Perforin-positive cells were significantly elevated in T lymphocyte subsets (CD3+P+, CD4+P+, CD8+P+) in both the FTP and TP groups, as was the percentage of CD56+P+ cells. Profound changes in the CD16+ subpopulation were found in the FTP group compared to both the NP and TP groups (a drastic decrease of CD16+P+ cells; CD16+ cells among P+ cells; P+ cells among CD16+ cells). A considerable part of CD3+ cells in both the FTP and TP groups are CD3+CD56+P+. The average fluorescence intensity (AFI) for P (a measure of P content per cell) was significantly decreased in FTP and increased in TP groups.

CONCLUSIONS

The CD16 molecule is Fc gamma RIIIA which is the only Fc receptor responsible for antibody dependent cell-cytotoxicity (ADCC) of NK and T-cells. In the first-trimester human pregnancy this mechanism is severely down-regulated compared to both the NP and TP groups.

Perforin-expressing lymphocytes in peripheral blood and decidua of human first-trimester pathological pregnancies

PROBLEM

We have shown previously that the decidua of first-trimester human pregnancy is heavily infiltrated with perforin-positive cells. The aim was to detect expression of perforin in both decidual lymphocytes (DL) and peripheral blood lymphocytes (PBL) in the first trimester of pathological pregnancies: Anembryonic pregnancy and missed abortion.

METHOD

Decidual tissue from a normal pregnancy group and from pathological pregnancies was obtained by vaginal curettage. Perforin (an intracellular antigen) and the cell surface antigens CD3, CD4, CD8, CD16, CD56, CD11c, and CD45RA were quantified simultaneously by flow cytometric analysis.

RESULTS

In the missed abortion group, we found: 1) a relative decrease in the frequency of both CD4+P+ cells and CD56+P+ cells as well as the mean fluorescence intensity for perforin; 2) a relative increase of CD16+P+ PBL cells; and 3) a relative increase of CD4+ cells in PBL compared with anembryonic pregnancy and normal pregnancy. There was also a significant relative decrease in the proportion of CD4+ and CD8+ cells among perforin-positive PBL in both anembryonic pregnancy and missed abortion.

CONCLUSION

Our results show that significant decreases in the prevalence of perforin-positive lymphoid cells, their subpopulations, and mean fluorescence intensity for perforin are associated with pregnancy failure.

Immunology and immunity studied with viruses

Immunity to viruses is used to define important biological parameters of immunology. Specificity, tolerance and T and B cell memory were analysed with murine model infections. The key parameters of antigen kinetics, localization and patterns of T and B cell response induction in maintaining memory and in causing deletion of reactive lymphocytes were compared for self and for viral foreign antigens. Evidence is reviewed that suggests that B cells essentially recognize antigen patterns, whereas T cells react against antigens newly brought into lymphoid tissues; antigens outside lymphoid tissues are ignored, and antigens always present in, or spreading too fast throughout, lymphoid tissues exhaust and delete T cell responses. Finally, effector mechanisms of antiviral immunity are summarized, as they vary with different viruses. On this basis immunological T and B cell memory against viruses is reviewed. Memory studies suggest that increased precursor frequencies of B and T cells appear to remain in the host independent of antigen persistence. However, in order to protect against cytopathic viruses, memory B cells have to produce antibody to maintain protective elevated levels of antibody: B cell differentiation into plasma cells is driven by persisting antigen. Similarly, to protect against infection with a non-cytopathic virus, cytotoxic T cells have to recirculate through peripheral organs. Activation and capacity to emigrate into solid tissues as well as cytolytic effector function are also dependent upon, and driven by, persisting antigen. Because no convincing evidence is yet available of the existence of identifiable B or T cells with specialized memory characteristics, the phenotype of protective immunological memory correlates best with antigen-driven activation of low frequency effector T cells and plasma cells.

The involvement of interleukin (IL)-15 in regulating the differentiation of granulated metrial gland cells in mouse pregnant uterus

Previous studies have suggested that granulated metrial gland (GMG) cells are bone marrow-derived lymphoid cells, which differentiate in situ in the mouse pregnant uterus into natural killer (NK)-like cells. Similar to NK cells, GMG cells express an abundant level of cytolytic mediators such as perforin. The factor(s) regulating the differentiation of GMG cells remain(s) to be identified, although cytokines previously implicated in the stimulation/activation of NK cells (e.g., IL-2, IL-6, IL-7, and IL-12) can be considered as potential candidates. Recently, IL-15, a novel cytokine, which displays biological activities similar to IL-2, has also been shown to be capable of activating NK cells. Using reverse transcription-polymerase chain reaction (RT-PCR) analysis, we have demonstrated in the present study that IL-15 and its cognate receptor, but not the other cytokines, are expressed in the mouse pregnant uterus, with a time course concomitant with those of cytolytic mediators in differentiated GMG cells. Moreover, IL-15, though not IL-2, is capable of inducing the expression of perforin and granzymes in pregnant uterine tissues explanted in vitro. Data obtained from in situ hybridization study have suggested that the macrophages present in the pregnant uterus may be responsible for the production of IL-15. These results suggest that IL-15 is involved in regulating the differentiation of GMG cells during mouse pregnancy.

The role of perforin-expression by granular metrial gland cells in pregnancy

The pregnant uterus of humans and rodents contains a population of granulated lymphoid cells, which, in the mouse, are called granular metrial gland (GMG) cells and have been described to express high levels of perforin. Since there is evidence for cytolytic activity of these cells and since perforin is a crucial effector molecule for the lytic action of cytotoxic T cells and natural killer cells, we evaluated the function of perforin in the pregnant uterus by using perforin-deficient mice. Perforin-deficient female mice were found to reproduce as efficiently as normal control females when bred either with syngeneic or allogeneic males. However, perforin-deficient mice differed from normal mice in that the frequency of GMG cells was significantly higher within maternal blood spaces and within several compartments of the feto-maternal interface. Proliferating GMG cells, identified by [3H] thymidine incorporation, were observed during more advanced stages of pregnancy when compared to normal controls. In contrast to normal mice, perforin-deficient mice did not display GMG cells attached to degenerating trophoblasts; instead perforin-deficient GMG cells were often observed in association with small maternal lymphocytes. In addition, the lack of transmission of lymphocytic choriomeningitis virus from infected pregnant perforin-deficient mice to the fetuses argued against a role of perforin expression by GMG cells in prevention of virus transmission from the mother to the fetus. Our data indicate that functional perforin is not necessary for successful pregnancies. The morphological changes in the pregnant uterus of perforin-deficient mice might, however, point to a certain, as-yet undefined function of perforin in the uterus of pregnant normal mice, which is functionally compensated in perforin-deficient mice.

Characteristics of perforin expressing lymphocytes within the first trimester decidua of human pregnancy

PROBLEM

The number of perforin (P)-positive cells in decidua of pregnancy is larger than that observed in any other pathological condition. The aim was to investigate the distribution and the phenotype of P+ cells.

METHOD

Decidual tissue was obtained from the first trimester vaginal termination of pregnancy. Tissue distribution of P+ cells was analyzed by immunohistochemistry. The method for simultaneous measurement of P and cell surface is presented.

RESULTS

There is no difference in number and distribution of P+ cells between decidua basalis (DB) and decidua parietalis (DP). The percentage of P+ decidual lymphocytes (DL) is two times higher than in peripheral blood lymphocytes (PBL) (55% vs. 27%), and the prevalent phenotype is CD3- CD4- CD8- CD2+ (95%) CD11c+ (68%) and CD56+ (82%). CD56bright+ DL are also Pbright+ and this is the largest DL subpopulation (42.4% DL). Two different subpopulations of CD8+ DL exist: 1) CD8bright+, which are CD3+ CD56- P- and 2) CD8dim+, which are CD3- CD56+ P+.

CONCLUSION

P expressing DL are prevalently nonclassical NK cells (CD16-) with low cytolytic activity but fully equipped with potent cytolytic machinery (Pbright+). There are no classical cytotoxic lymphocytes (CTL) (CD3+ CD8+ P+) in the decidua, and all CD8+ P+ cells are CD3- CD56+. The number of P+ cells is even higher in DP in the vicinity of noninvasive trophoblast, than in DB.

Synthesis and granular localization of tumor necrosis factor-alpha in activated NK cells in the pregnant mouse uterus

The synthesis and cellular localization of tumor necrosis factor-alpha (TNF-alpha) were studied in mouse GMG cells, which are activated NK cells in uterine decidual tissue during pregnancy. Synthesis of the protein was demonstrated in GMG cells on days 10 and 14 of pregnancy by in situ hybridization of TNF-alpha message. Immunostaining demonstrated that TNF-alpha protein was localized in the cytoplasmic granules of GMG cells at these times. The results suggest that the cytolytic activity of uterine NK cells may be due in part to TNF-alpha, and that this cytokine may be delivered to target cells intracellularly via transmembrane pores formed by perforin, which is also localized in uterine NK cell granules.

Cell-mediated cytotoxic mechanisms

There are two competing, but probably really complementary, models for the mechanism of cell-mediated cytotoxicity. One depends upon contact-mediated transmembrane signaling, and the other on the exocytosis of toxic materials by the killer cell. There is exciting news on both fronts. Transmembrane signaling has been shown to involve the surface molecule Fas/APO-1 on targets and its ligand on cytotoxic T cells. The Fas ligand has been cloned, and is a member of the tumor necrosis factor family. The major cytolytic molecule in the exocytosis pathway is perforin; perforin knock-out mice have been produced, and they display many intriguing abnormalities. It has been a bumper year for cytotoxicologists.

Granulated metrial gland cells--not part of the natural killer cell lineage?

The relationship of rodent granulated metrial gland (GMG) cells to the natural killer (NK) cell lineage is reviewed. The antigenic profile of GMG cells provides insufficient evidence to indicate that these cells form part of the NK cell lineage. No good evidence is found that GMG cells are cytotoxic to the NK cytotoxicity target, Yac-1. In Beige mice, which have a defect in the lytic pathway of NK cells, GMG cells were found to kill labyrinthine cytotrophoblast. It is concluded that GMG cells are not a type of NK cell but a novel member of the leucocyte population.

Distribution of perforin-containing cells in normal and pregnant mice

Cytotoxic T lymphocytes (CTL) and natural killer (NK) cells elaborate a cytolytic protein named perforin or cytolysin. It was widely held that, in vivo, high quantities of perforin are not present in resting lymphocytes and are usually produced only by activated lymphocytes found under pathological conditions. Until now, only one tissue was known to synthesize abundant quantities of perforin under nonpathological conditions, the uterus during pregnancy. To investigate the possibility that perforin might also be synthesized by other tissues, several tissues besides the uterus from pregnant and normal mice were tested by immunofluorescence and immunoperoxidase for the presence of perforin. The tissues studied were the ears, brain, nasal epithelium, tongue, salivary gland, larynx, thymus, stomach, liver, spleen, small intestine, and lymph nodes; two cell populations with different sizes and levels of perforin expression were found. Large cells, displaying the NK cell phenotype and expressing high levels of perforin, were detected not only in the uterus but also in the salivary gland and lungs of pregnant mice. Small cells, expressing low levels of perforin, were detected mainly in the stomach and small intestine, and they were expressed in both pregnant and normal mice. Taken together, these results imply that perforin-containing cells exist in vivo under nonpathological conditions, and that the immune system is endowed with heretofore unknown mechanisms for stimulating the activation of NK cells in a limited number of tissues during pregnancy.

Elevated endometrial natural killer cell activity during early porcine pregnancy is conceptus-mediated

This study investigated an extended time course of endometrial NK cell activity during gestation and the mechanisms underlying changes in uterine NK cell activity in pigs. Endometrial tissues were collected from cyclic, pseudopregnant and pregnant nulliparous pigs on various days post-estrus, and from pigs 10 days after insemination with seminal plasma or killed spermatozoa. NK effector cells were isolated from each endometrial sample, size fractionated and tested for cytolytic activity against NK target cells (K562) using chromium release assays and immunocytochemically for the frequency of perforin-positive cells. Various cell fractions showed different levels of NK activity and had different proportions of cells expressing perforin. Morphologically, cells in the fraction with maximal NK activity almost all showed typical lymphocyte size and shape. Substantially elevated NK cell activity was recorded in pregnant pigs on days 10 and 20 of gestation. By day 30, the cytolytic activity declined dramatically to an almost undetectable level. Very little activity was found in uterine cells isolated from cyclic, pseudopregnant, and seminal plasma or killed spermatozoa inseminated animals, and no differences were detected either between follicular and luteal phases of the estrous cycle or between different days of pseudopregnancy. These results indicate that elevated NK cell activity during early porcine pregnancy cannot be attributed to contributions from either the maternal systemic endocrine status or from components of boar semen. The changes in NK cell activity observed in porcine endometrial tissues during early pregnancy must therefore be associated with the actual presence of conceptuses.

Granulated metrial gland cells: a natural killer cell subset of the pregnant murine uterus

The metrial gland develops in the uterus of many rodent species during normal pregnancy. It is a maternally-derived tissue that contains stromal and vascular elements plus a population of large cells, striking in their light microscopic appearance due to the presence of numerous cytoplasmic granules. These cells, which have become known in mice and rats as granulated metrial gland (GMG) cells, are derived from bone marrow precursors and recent work suggests they are a subset of lymphocytes belonging to the natural killer (NK) cell lineage. The functions of GMG cells during normal gestation have not been clearly defined. In vitro, GMG cells have been shown to produce cytokines and their cytokine profile is altered upon addition of medium containing the T cell growth factor interleukin-2 (IL-2). GMG cell granules contain the cytolytic protein perforin but GMG cells have a very limited capacity to kill in vitro unless they have been stimulated by IL-2 or interferon-gamma. Histological study of GMG cells has suggested they preferentially associate with fetal trophoblast. Since trophoblast appears resistant to immune lysis, except by IL-2-activated effector lymphocytes, and because resorbing murine embryos become infiltrated by lytic cells of the NK cell lineage, it is important to establish whether GMG cells are activated by pregnancy-associated events to play a major lytic role in vivo.