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.     

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.     

IL-22 is expressed by the invasive trophoblast of the equine (Equus caballus) chorionic girdle

The invasive trophoblast cells of the equine placenta migrate into the endometrium to form endometrial cups, dense accumulations of trophoblast cells that produce equine chorionic gonadotropin between days 40 and 120 of normal pregnancy. The mechanisms by which the trophoblast cells invade the endometrium while evading maternal immune destruction are poorly defined. A gene expression microarray analysis performed on placental tissues obtained at day 34 of gestation revealed a >900-fold upregulation of mRNA encoding the cytokine IL-22 in chorionic girdle relative to noninvasive chorion. Quantitative RT-PCR assays were used to verify high expression of IL-22 in chorionic girdle. Additional quantitative RT-PCR analysis showed a striking increase in IL-22 mRNA expression in chorionic girdle from days 32 to 35 and an absence of IL-22 expression in other conceptus tissues. Bioinformatic analysis and cDNA sequencing confirmed the predicted length of horse IL-22, which carries a 3' extension absent in IL-22 genes of humans and mice, but present in the cow and pig. Our discovery of IL-22 in the chorionic girdle is a novel finding, as this cytokine has been previously reported in immune cells only. IL-22 has immunoregulatory functions, with primary action on epithelial cells. mRNA of IL-22R1 was detected in pregnant endometrium at levels similar to other equine epithelia. Based upon these findings, we hypothesize that IL-22 cytokine produced by the chorionic girdle binds IL-22R1 on endometrium, serving as a mechanism of fetal-maternal communication by modulating endometrial responses to trophoblast invasion.     

Expression of MHC antigens on murine trophoblast and their modulation by interferon

Primary cultures of defined populations of mouse trophoblast, isolated from mature placentas, were analyzed for their MHC antigen expression and for the modulatory effect of interferon (IFN) by antibody- and complement-mediated cytotoxicity and flow cytofluorometry. The cells were obtained from placentas by enzymatic digestion, followed by Percoll gradient fractionation, and are large, fetally derived epithelial cells, which we previously characterized and identified as trophoblast cells. After 2 days in culture, a significant proportion of the trophoblast cells were susceptible to antibody- and complement-mediated lysis by anti-paternal strain alloantisera (40%) and, to a lesser degree, by an anti-class I monoclonal antibody (20%). Flow cytofluorometric analysis indicated that 20 to 50% of the cultured trophoblast cells expressed low levels of paternal strain class I antigens as compared to L cell fibroblasts. After culture for 48 hr with IFN-alpha/beta or IFN-gamma, the percent of class I-positive cells was increased to 68 to 76%, as was the mean fluorescence intensity, which correlated with the increased percent of antibody- and complement-mediated specific lysis (73%). No expression of class II MHC antigen by the cultured trophoblast cells was detected, even after culture in the presence of IFN-gamma. The cultured trophoblast cells, when tested for alkaline phosphatase (AP) activity, were composed of strongly positive and weakly positive subpopulations. An inverse correlation between strength of AP activity and the expression of H-2 was observed by double staining. These results indicate that trophoblast cells cultured in vitro are able to express paternal strain class I but not class II MHC antigens, as has been reported in vivo, and that this expression can be modulated by IFN. Further study of these cells should provide important clues for the understanding of materno-fetal coexistence in the face of MHC antigen differences.     

Autocrine induction of major histocompatibility complex class I antigen expression results from induction of beta interferon in oncogene-transformed BALB/c-3T3 cells.

By varying growth conditions, we identified a novel mechanism of autocrine regulation of major histocompatibility complex (MHC) class I gene expression by induction of beta interferon gene expression in transformed BALB/c-3T3 cells. Low-serum conditions enhanced MHC class I antigen expression in v-rasKi- and v-mos-transformed BALB/c-3T3 cells but not in untransformed BALB/c-3T3 cells. Transformed and untransformed cells grown under standard serum conditions (10% bovine calf serum) expressed similar cell surface levels of MHC class I antigens. However, low-serum conditions (0.5% bovine calf serum) induced four- to ninefold increases in cell surface levels of MHC class I antigens in both v-rasKi- and v-mos-transformed cells but not in untransformed cells. These increases in MHC class I gene expression were seen at both the mRNA and cell surface protein levels and involved not only the heavy-chain component of the class I antigens but also beta 2 microglobulin. Beta 1 interferon mRNA and beta interferon-inducible 2',5'-oligoadenylate synthetase mRNA were induced by growth under low-serum conditions in transformed BALB/c-3T3 cells, and antibodies to beta interferon blocked the induction of MHC class I antigen expression by serum deprivation in these cells. These results demonstrate that growth under low-serum conditions leads to induction of beta interferon expression in oncogene-transformed cells which then directly mediates autocrine enhancement of MHC class I gene expression.     

Trophoblast-uterine interactions during equine chorionic girdle cell maturation, migration, and transformation.

The structure of the equine chorionic girdle between days 28 and 42 of gestation was examined. Of particular interest were differentiation of trophoblastic cells within the girdle, adhesion between girdle and endometrium, invasion and displacement of the uterine epithelium, and the nature of the endometrium when girdle cells migrate into it to form endometrial cup cells. The chorionic girdle, identified initially as a band of tall columnar cells, becomes a stratified columnar epithelium indented by clefts and pits. Adhesion to and penetration through the endometrial luminal epithelium are rapid and occur initially in very limited areas. Stromal invasion occurs as strands of contiguous trophoblast cells invade through the basal lamina. Only girdle cells that are adjacent to the basal lamina or have entered the endometrial stroma undergo hypertrophy and differentiate into cup cells. At the initiation of trophoblastic invasion, the luminal epithelium contains numerous, large, intraepithelial, granular lymphocytes; small lymphocytes then accumulate in the stroma, but by day 42 lymphocytes are largely confined to the periphery of the cup. Although adhesion of trophoblast to the endometrial surface is initiated by small groups of girdle cells on restricted areas of the endometrial folds, the area is then increased by new areas of adhesion and by expansion of the initial invasion. Areas of girdle cells that do not attach undergo necrosis, as do superficial portions of areas of invasion. Consequently the girdle cells that form cups may be a minority of the original population. It is suggested that the differentiation of girdle cells is closely programmed and that cells that do not reach the stroma become necrotic at the same time that endometrial cup cells are differentiating.     

滋养层细胞表面主要组织相容性复合体

胎盘滋养层是直接与母体接触的与母体基因型不同的胎儿组织,滋养层细胞是否表达主要组织相容性复 合体(MHC)抗原以及表达何种MHC抗原对于妊娠成功与否至关重要.非经典MHCⅠ类抗原发现较晚,其中 HLA-G在滋养层细胞表达,可以保护带有父方同种异体抗原的胎儿免受母体免疫系统的杀伤.经典MHCⅠ类抗 原有多种亚型,不同亚型在滋养层细胞的表达有所不同.MHC Ⅱ类抗原在妊娠维持过程中表达极弱,新近的研 究资料表明,滋养层细胞CⅡTA在MHCⅡ类基因表达调控中起主要作用.     

Viral gene inhibition of class I major histocompatibility antigen expression: not a general mechanism governing the tumorigenicity of adenovirus type 2-, adenovirus type 12-, and simian virus 40-transformed Syrian hamster cells

The association between the level of class I major histocompatibility (MHC) antigen expression and the tumorigenic phenotype was determined for cells from a series of 15 lines of adenovirus type 2 (Ad2)-, Ad12-, and simian virus 40 (SV40)-transformed hamster cells and 16 lines of cells established from hamster tumors induced by SV40 mutants. These cells range from nontumorigenic to highly tumorigenic in both syngeneic and allogeneic adult hamsters. The Ad2-transformed cells--cells that were nontumorigenic in syngeneic adult hamsters--expressed either high levels or low levels of class I MHC antigens. The SV40-transformed cells--cells transformed in vitro that produced tumors with equal efficiency in both syngeneic and allogeneic adult hamsters--or cells derived from SV40-induced tumors expressed very high levels of class I MHC antigens. The Ad12-transformed cells uniformly expressed low levels of class I MHC antigens; these cells produced tumors 200- to 1,000-fold less efficiently in allogeneic adult hamsters than in syngeneic adult hamsters and produced tumors with about the same efficiency in immunoimmature newborns and immunocompetent syngeneic adult hamsters. We conclude that the expression of either high levels or low levels of class I MHC antigens is, at most, a minor factor in the differences observed among these adenovirus- and SV40-transformed cells in their tumor-inducing capacity in naive, immunocompetent hamsters.     

Expression of major histocompatibility complex antigens on the bovine placenta

Immunohistochemistry was utilized to determine expression of the major histocompatibility complex (MHC) antigens on Day 8-9 hatched blastocysts and fetal membranes of mid- to late gestation cows and to examine the pattern of leucocytic infiltration into the gravid uterus. Hatched blastocysts were weakly positive for MHC class I antigens. In the mature placenta, chorioallantoic membranes in the interplacentomal area showed positive immunostaining for class I antigens on the chorionic epithelium but had no staining for class II antigens. There was an accumulation of lymphoid cells expressing class II antigens directly beneath the luminal epithelium of the endometrium. In addition, cells staining for leucocyte common antigen were present both within and beneath the luminal epithelium. Some cells positive for class II and leucocyte common antigen (CD45) were also associated with uterine glands. In the placentomes, class I antigens were expressed only on maternal caruncular septa. Fetal cotyledonary villi had no detectable immunostaining for class I and II antigens. No distinct pattern of leucocyte infiltration in the maternal caruncular tissue was observed; the caruncular septa contained some cells that were labelled for CD45 and a few class II-positive cells around blood vessels. The results indicate that the fetal placenta of the cow expresses MHC class I antigens in a regionally defined manner and there is a differential accumulation of lymphoid cells in the uterus.     

Differential expression of the major histocompatibility antigen complex (MHC) on a series of Burkitt's lymphoma lines

We compared the expressions of class I and class II major histocompatibility antigen complex (MHC) on the surface of Jijoye and P3HR-1 cells of Burkitt's lymphoma sublines. Jijoye cells had a large amount of class I and class II MHC antigens, whereas these antigens were less expressed on P3HR-1 cells. On a subline of P3HR-1 K cells the expression of class I antigen markedly diminished and class II antigen was undetectable. On the other hand, Jijoye, P3HR-1, and P3HR-1 K cell lines were confirmed to be Epstein-Barr virus (EBV) nonproducer, low producer, and high producer, respectively. The chemical activation of EBV genome by treating P3HR-1 cells with 12-O-tetradecanoyl phorbol-13 acetate (TPA) and n-butyrate resulted in inhibition of the expression of class I and II antigens, while the addition of retinoic acid, an inhibitor of virus replication, blocked the decrease in the MHC antigen expression. These findings suggested that there might be an inverse correlation between the virus production and the expression of class I and II MHC antigens.     

Interaction of monoclonal antibodies with MHC class I antigens on mouse spleen cells. II. Levels of expression of H-2K, H-2D, and H-2L in different mouse strains

The numbers of MHC class I molecules expressed by spleen cells from various mouse strains were determined by using MHC-specific monoclonal antibodies and a radioactive binding assay. Although small differences were found to exist in some cases, our general conclusion is that different mice of the same strain, congenic mice of different haplotypes, and syngeneic mice of varying background all express similar numbers of class I antigens. B10.A mice (8 to 10 wk old), for example, express 5.3 X 10(4) Kk molecules/cell, 5.4 X 10(4) Dd molecules/cell, and 2.2 X 10(4) Ld molecules/cell. Some of the differences observed in class I antigen expression included: 1) the level of Kk expression increased to a small but significant extent with age in B10.A mice; 2) female B10.A mice expressed slightly higher amounts of Kk than male mice; and 3) B10.A(2R) and B10.A(4R) recombinant strains expressed elevated levels of K-end antigens and slightly decreased levels of D-end antigens when compared with the unrecombinant B10.A strain. In several strains, F1 mice express approximately 50% as many copies of each parental antigen as do the homozygous parents. B10 mice, which are negative for the L antigen, nevertheless express the same total number of D-end molecules as do B10.A mice. The data suggest that the levels of expression of MHC class I molecules are controlled by at least two factors: gene dosage and another factor(s) that gives rise to the small variations in class I antigen expression seen with age, sex, and strain, and to the low expression of Ld relative to Dd and Kk.     

Enhanced MHC I antigen expression on tumour target cells is inversely correlated to lysis by allogenic but not by xenogenic NK cells

Relationship between the levels of MHC class 1 antigen expressed on tumour cells and their susceptibility to allogenic and xenogenic NK cells was investigated. Mouse and human natural killer-resistance inducing factor (NK-RIF) preparations were used for augmenting/inducing MHC 1 antigen expression on murine YAC and human K562 tumour cells, respectively YAC cells with augmented MHC I antigen expression became relatively resistant to lysis by murine NK cells but not to rat NK cells. Similarly, induction of MHC I antigens on K562 cells reduced their susceptibility to human NK cells but not to monkey NK cells. These results indicate that the inverse correlation of MHC I antigen expression and NK susceptibility does not hold true for xenogenic pairs of NK effector and target cells.     

Accessory cell function of human endothelial cells. I. A subpopulation of Ia positive cells is required for antigen presentation

The expression of class I and class II HLA antigens on preparations of human endothelial cells, isolated from umbilical cord veins, was investigated by immunofluorescence. While virtually all endothelial cells expressed class I antigens, less than 1% were positive for class II antigens, as detected with a panel of 10 different monoclonal antibodies. Antigen specific T cell lines proliferated in response to mumps antigen in the presence of endothelial cells or blood monocytes from HLA-DR matched donors. However, these T cell lines failed to respond in the absence of accessory cells or when accessory cells from HLA-D-region mismatched cord donors were used. The ability of both monocytes and endothelial cells to present antigen was abolished by treatment of the cells with monoclonal antibodies specific for either class I or class II HLA antigens plus complement. Similar treatment with monoclonal antibodies specific for monocytes greatly reduced antigen presentation by endothelial cells. These results indicate that preparations of endothelial cells contain a subpopulation of Ia positive cells, distinct from monocytes, which are required for antigen presentation.