Ontogeny of adenosine deaminase in the mouse decidua and placenta: immunolocalization and embryo transfer studies

This study has determined the cellular site of adenosine deaminase (ADA) expression in the mouse during development from Days 5 through 13 (day vaginal plug was found = Day 0) of gestation. Developmental expression of ADA progressed in two overlapping phases defined genetically (maternal vs. embryonal) and according to region (decidual vs. placental). In the first phase, ADA enzyme activity increased almost 200-fold in the antimesometrial region (decidua capsularis + giant trophoblast cells) from Days 6 through 9 of gestation but remained low in the mesometrial region. Immunohistochemical staining revealed a major localization of ADA to the secondary decidua. In the second phase, ADA activity increased several-fold in the placenta (labyrinth + basal zones) from Days 9 through 13 of gestation but remained low in the embryo proper. Immunohistochemical staining revealed a major localization of ADA to secondary giant cells, spongiotrophoblast, and labyrinthine trophoblast. Regression of decidua capsularis and growth of the spongiotrophoblast population accounted for an antimesometrial to placental shift in both ADA enzyme activity and a 40-kDa immunoreactive protein band. To verify a shift from maternal to fetal expression, studies were performed with two strains of mice (ICR, Eday) homozygous for a different ADA isozyme (ADA-A, ADA-B). Blastocysts homozygous for Adab were transferred to the uterus of pseudopregnant female recipients homozygous for Adaa. The isozymic pattern in chimeric embryo-decidual units analyzed at Days 7, 9, 11, and 13 revealed a predominance of maternal-encoded enzyme at Days 7 through 11 of gestation and a shift to fetal-encoded enzyme by Day 13. Thus, maternal expression of ADA in the antimesometrial decidua may play a role during establishment of the embryo in the uterine environment, whereas fetal expression of ADA in the trophoblast might be important to placentation.     

Developmental expression of adenosine deaminase in placental tissues of the early postimplantation mouse embryo and uterine stroma

In this study, we have investigated the distribution of adenosine deaminase (ADA) in embryonic, extra-embryonic, and decidual tissues of the developing mouse embryo. ADA catalyzes a key step in purine metabolism converting adenosine to inosine. ADA specific activity (nmol/min/micrograms protein) was present at low levels in the embryo-decidual unit during the first 2 days of postimplantation development but then increased starting late on Day 6 of gestation (Day 0 plug). By Day 9, ADA specific activity was 80-fold higher than on Day 6. A histochemical staining method for ADA activity was applied to cryostat sections of the implantation site. The developmental increase localized primarily to the trophoblast/antimesometrial decidua interface between Days 7 and 9 of gestation, and decidua basalis and the metrial gland by Day 11. Immunofluorescent staining with sheep anti-mouse ADA antiserum confirmed the presence of ADA antigenicity in tissues forming the maternal/fetal interface. ADA specific activity was 19-fold higher in homogenates of the Day 11 decidua/parietal yolk sac than in the thymus, a tissue generally thought of as ADA-rich. High levels of ADA activity and immunoreactivity were also detected in the embryonal plasma during organogenesis, but the embryo proper showed only low levels. These results indicate that ADA is tightly regulated within tissues forming the maternal/fetal interface during early postimplantation stages of development.     

Effects of (R)-deoxycoformycin (pentostatin) on intrauterine nucleoside catabolism and embryo viability in the pregnant mouse.

The viability of early mouse embryos is acutely sensitive to (R)-deoxycoformycin (pentostatin), a tight-binding inhibitor of adenosine deaminase (ADA). Previous studies have shown that a single 5-mg/kg dose on day 7 (plug = day 0) of gestation fully inhibits uteroplacental ADA activity within 0.5 h; causes massive cell death in the neural plate and primary mesenchyme by 6 h, major craniofacial anomalies by day 10, and resorption by day 12 (Knudsen et al., '89; Airhart et al., '91). The present study has examined further the developmental toxicity and early effects of this inhibitor on ADA metabolism. (R)-Deoxycoformycin was administered to pregnant CD-1 (ICR) mice as a single intraperitoneal dose of 0.5-10 mg/kg total body weight on days 6-11 of gestation. The major adverse effect, early resorption, was dose dependent and specific to day 7-8 exposure. Treatment with 5 mg/kg on day 7 resulted in 85% resorptions, 15% malformations, and a 24% reduction in mean fetal weight, whereas the same dose of (S)-deoxycoformycin had no effect. Levels of adenosine and 2'-deoxyadenosine, which are the endogenous substrates of ADA, were monitored in the embryo/decidual unit (E/D) by reversed-phase high-performance liquid chromatography (RP-HPLC). In response to the inhibitor, both nucleosides increased transiently in the antimesometrial compartment (antimesometrial decidua + embryo). Peak levels (Cmax) of adenosine and 2'-deoxyadenosine were dose dependent over the range tested (0.05-10 mg/kg). Exposure to 5 mg/kg on day 7 raised adenosine levels within 0.5 h to 42-fold over the basal level of 0.06 nmol/mg protein. There was an even stronger effect on 2'-deoxyadenosine levels, which were elevated 674-fold over the detection limit of 0.0005 nmol/mg protein. Direct exposure to the inhibitor in serum-free E/D culture produced similar results: 50 microM (R)-deoxycoformycin within 1 h raised adenosine levels 26-fold and 2'-deoxyadenosine levels 410-fold. In vivo studies also showed a general correlation between embryolethality and the length of adenine nucleoside pool expansion, apparent for exposure on day 7, 8, or 9 but not on day 6, suggesting that the embryo becomes sensitive to adenosine or 2'-deoxyadenosine once the neural plate has formed.     

Developmental expression of adenosine deaminase during decidualization in the rat uterus

Adenosine deaminase (ADA) is expressed in high concentrations at the fetal-maternal interface during postimplantation stages of gestation in the mouse. The experiments reported here were designed to identify the specific uterine cells that express ADA subsequent to implantation in the rat and to determine if embryonic cells contribute to ADA expression. The results of biochemical analysis demonstrate that ADA-specific activity increases to very high levels in implantation sites, beginning approximately 72 h after blastocyst attachment. Immunocytochemical analysis localized this ADA expression to the decidualized stromal cells in the antimesometrial region of the pregnant uterus. In experimentally induced deciduoma, these cells were capable of synthesizing high levels of both ADA and mRNA for ADA in the absence of embryos. The enzyme first appeared in decidual cell cytoplasm, approximately 72 h after induction of decidualization, and later was localized in the decidual cell nuclei. Since the expression of ADA and its mRNA in decidual cells follows the appearance of desmin, a protein marker for decidualization, by at least 48 h, ADA appears to be involved in the functioning of mature decidual cells rather than in stromal cell differentiation. The expression of ADA, but not desmin, was restricted to the antimesometrial decidual cells and decreased when these cells regressed. At mid-gestation ADA activity increased and was localized principally in the fetal placenta. The results presented here demonstrate that ADA is localized to the antimesometrial decidual cell and that its expression is consequent to differentiation of the uterine stromal cell and independent of any embryonic stimulus.     

Interferon-gamma contributes to the normalcy of murine pregnancy.

Uterine natural killer (uNK) cells are transient, large, heavily granulated, maternal lymphocytes present on the mesometrial side of the pregnant mouse uterus. These cells contribute to normal implantation site development. Cytokine production, particularly interferon (IFN)-gamma, is a major function of most NK cell subsets. In this study, uNK cells were assessed for IFN-gamma production. Local concentrations of IFN-gamma were measured in the mesometrial regions of murine implantation sites between Days 6 and 16 of gestation. IFN-gamma was detected by ELISA at all days studied in a random-bred (CD1) and an inbred (BALB/c) strain of immune-competent mouse and in two immune-deficient strains, SCID (NK(+), T(-), B(-)) and tgepsilon26 (NK(-), T(-), B(+)). Concentrations of IFN-gamma per implantation site peaked at Day 10 of gestation in NK(+) strains but were low and relatively constant in NK(-) mice. To evaluate the functions of IFN-gamma at murine implantation sites, pregnancy was studied in homozygously mated IFN-gamma(-/-) and IFN-gammaRalpha(-/-) mice and their congenic controls. Primiparous but not multiparous IFN-gamma(-/-) mice experienced significant fetal loss. Primiparous IFN-gammaRalpha(-/-) carried full litters to term. Implantation site pathology was demonstrated in both strains of gene-deleted mice by light microscopy and ultrastructurally. This included elevated numbers of uNK cells that contained fewer and smaller granules and, after Day 10 of gestation, progressive necrosis and loss of decidua. The presence of a fetus able to produce IFN-gamma did not modify the phenotype of pregnant IFN-gamma(-/-) mice. This study indicates that during murine pregnancy, uNK cells are the main source of IFN-gamma on the mesometrial side of the uterus and that IFN-gamma contributes to normal health of the midgestational decidua. Furthermore, evidence is presented that IFN-gamma-producing cells exist in mesometrial regions of implantation sites that are neither NK nor T cells.     

Changes in the amount and synthesis of DNA in the nuclei of large decidual cells in rats during their differentiation

Using cytophotometry of the Feulgen-stained nuclei, the quantity of DNA was measured in the nuclei of rat's large decidua cells (LDC) on tissue sections of the antimesometrial region within days 7-13 of gestation. The quantity of nuclear DNA was expressed in units of ploidy, the haploid DNA standard being the quantity of DNA in rat's spermatid nucleus. On different days of gestation, the nuclear DNA was seen to vary in cells located in different zones of decidua. The maximum DNA content was found in the LDC located on days 9-12 of gestation somewhat in the middle of the decidua thickness. On day 11, the quantity of nuclear DNA in these cells reached in average, 22c. The quantity of DNA in the nuclei of the least differentiated LDC located on the periphery of decidua never exceeded 4.9c, whereas that in the nuclei of the most differentiated LDC, located close to the embryo, varied from 2.9c to 9.3c. On days 10 and 11 of rat's false gestation, the maximum DNA contents in the nuclei were registered in the LDC located in the middle of the decidua thickness. 3H-thymidine incorporation into the nuclei of the most differentiated LDC located nearest to the embryo stopped starting from day 10 of gestation. Phenomena of lesser quantities of nuclear DNA in most differentiated LDC, compared to that in LDC in the previous steps of differentiation, are discussed.     

Light and electron microscopic examination of the mature decidual cells of the rat with emphasis on the antimesometrial decidua and its degeneration

Rat gestation sites were obtained on days 10 through 16 of normal pregnancy. Light and electron microscopic examination of day-10 sites revealed a consistent complex pattern of stromal cell morphologies. Six distinct regions were identified: an antimesometrial region of epithelioid decidual cells that form the gestation chamber containing the embryo and extraembryonic membranes; an abembryonic antimesometrial decidual region, the decidual crypt, where the cells are separated by large extracellular spaces; a mesometrial region with granule-containing cells and mesometrial decidual cells; a region of spiny cells that are lateral to the antimesometrial decidual cells and continuous with the mesometrial decidual cells; and a region of undifferentiated stromal cells adjacent to the myometrium. Between days 12 and 16, the antimesometrial decidua becomes thinner and is eventually sloughed into the newly formed uterine lumen. The role of the antimesometrial decidual cells is discussed with reference to trophoblast invasiveness, protein synthesis, and especially remodeling of the gestation chamber. Differences between decidua and deciduoma are considered.     

Involvement of cyclin D3, CDKN1A (p21), and BIRC5 (Survivin) in interleukin 11 stimulation of decidualization in mice

Interleukin 11 receptor alpha (Il11ra) null mice are infertile due to defective decidualization and abnormal trophoblast invasion. We have previously shown in these mice that downregulation of decidual proteinase inhibitors plays a role in uncontrolled trophoblast invasion. However, the decidua is abnormally smaller in pseudopregnant Il11ra null mice, where trophoblast invasion is not a factor. Here, we examined whether defective decidualization is due to dysregulation of key molecules involved in decidual cell growth and differentiation. We found a dramatic downregulation of cyclin D3 in Il11ra null mice. We also found that IL11 robustly stimulates the expression of cyclin D3 in cell culture. CDK4 and CDK6, known partners of cyclin D3, are not affected. Immunolocalization studies show absence of cyclin D3 in the mesometrial site and absence of differentiated polyploid cells in the antimesometrial site of Il11ra null mice. We also examined the expression of cell differentiation factors CDKN1A (p21) and CDKN1B (p27), and found that in both in vivo and cell culture the expression of CDKN1A (p21) but not CDKN1B (p27) is under the control of IL11. Another clear target of IL11 in the decidua is BIRC5 (Survivin), whose expression is repressed in the decidua of Il11ra null mice and stimulated by IL11 in cell culture. Taken together, these results provide, at least in part, an explanation for the defective small decidua of mice lacking the Il11ra gene, and reveal for the first time that cyclin D3, CDKN1A (p21), and BIRC5 (Survivin) are targets of IL11 in the decidua.     

Teratogenic potential of inhaled carbon monoxide in mice and rabbits.

Pregnant CF-1 mice and New Zealand rabbits were exposed to carbon monoxide at a concentration of 250 ppm for 7 or 24 hours daily during the period of major organogenesis, days 6 through 15 of gestation in mice and 6 through 18 of gestation in rabbits. Carboxyhemoglobin levels in the range of 10--15% were observed in both species (control animals had 0.7% or less). Carbon monoxide was not found to be teratogenic in either species. In mice, a significant increase in the incidence of some minor skeletal variants was observed. One litter in each of the carbon monoxide-exposed groups of mice was completely resorbed; none of the litters of control mice or of control or exposed rabbits were completely resorbed. The fetuses of mice exposed to carbon monoxide for seven hours daily were heavier than control fetuses, and those exposed for 24 hours daily were lighter than control fetuses. The reason for this result is not known.     

Thymidylate synthetase in the antimesometrial and mesometrial portions of decidual tissue under normal conditions and following application of the antifolate preparation chloridine]

Specific activity of thymidylate synthetase (TMS) under normal conditions and after the action of pyrimethamine was investigated in antimesometrial (A) and mesometrial (M) parts of rat decidua. On the 9th-11th days of pregnancy specific activity of TMS in the A part proved to be higher than in the M part of decidua, and the former one reached its maximum by the 10th day. Specific activity of TMS in the M part decreased gradually from the 9th to 11th days of gestation. Pyrimethamine, applied on the 9th day of pregnancy caused a wave-like increase in the specific activity of TMS in the A part; this elevation was not so pronounced in the M part; A study of the physico-chemical properties of TMS from the decidua and the embryos of rats showed that the enzyme had a molecular weight of 58000, an optimal pH of 6.9, and could be quickly inactivated by heating.     

Coordinate developmental regulation of purine catabolic enzyme expression in gastrointestinal and postimplantation reproductive tracts

Using histochemical detection, we have visualized in situ the complete metabolic pathway for the degradation of purine nucleotides. From the tongue to the ileum, diverse epithelial cell types lining the lumen of the mouse gastrointestinal (GI) tract strongly coexpress each of the five key purine catabolic enzymes. Dramatic increases in the expression of each enzyme occurred during postnatal maturation of the GI tract. Using in situ hybridization, an intense accumulation of adenosine deaminase (ADA) mRNA was detected only within GI epithelial cells undergoing postmitotic differentiation. In a similar manner, at the developing maternal-fetal interface, high level expression of the purine catabolic pathway also occurred in a unique subset of maternal decidual cells previously known to express high levels of alkaline phosphatase and ADA. This induction occurred almost immediately after implantation in the periembryonic maternal decidual cells, shortly thereafter in antimesometrial decidual cells, and later in cells of the placental decidua basalis: all of which contain cell types thought to be undergoing programmed cell death. The expression of the pathway at the site of embryo implantation appears to be critical because its pharmacologic inhibition during pregnancy has been found to be embryolethal or teratogenic. Purine destruction at these nutritional interfaces (placenta and gastrointestinal tract) seem to override any potential economy of purine salvage, and may represent biochemical adaptation to nucleic acid breakdown occurring in the context of dietary digestion or extensive programmed cell death.     

Granulated metrial gland cells in the pregnant uterus of mice expressing the collagen mutation tight-skin (Tsk/+)

Summary Influences of the extracellular matrix (ECM) on the differentiation and distribution of granulated metrial gland (GMG) cells, a uterine natural killer (NK)-like cell subset, were studied by histological examination of implantation sites in the mouse mutant Tsk/+. Tsk/+ mice overproduce collagens I and III. GMG cell differentiation appeared to progress normally in Tsk/+ mice between days 6.5 and 12.5 of gestation. The distribution of GMG cells, however, was abnormal. Significant numbers of GMG cells were found in the antimesometrial and lateral decidual regions at day 8.5 of gestation and in the regions between implantation sites until day 10.5 of gestation. Loss of GMG cells from these regions normally occurs by day 6.5 of gestation. These data suggest that alterations to the ECM change the migration properties or life span of GMG cells.     

Expression and localization of SerpinB11 in mouse uteri during peri-implantation and the estrous cycle

Serine protease inhibitor (Serpin) B11 has been identified as a novel serine protease inhibitor but the biological functions of SerpinB11 in female reproduction are unknown. Therefore, we investigate the spatiotemporal expression and regulation of SerpinB11 during the peri-implantation period. SerpinB11 mRNA and protein were detected in the uteri of pregnant mice on days 1–8 (day 1?=?presence of a vaginal plug). SerpinB11 protein was localized in the embryonic implantation site on day 5 when embryo implantation occurred and was also strongly expressed in the primary decidual zone on day 6 and secondary decidual zone on days 7 and 8. The expression of SerpinB11 was induced by the activated blastocyst (based on patterns of expression during pseudopregnancy and delayed implantation) and by artificially induced decidualization. Moreover, expression of SerpinB11 was regulated by estradiol and progesterone in ovariectomized mice. The results were further supported by data from the estrous cycle. Thus, SerpinB11 is probably involved in embryo implantation and decidualization.     

Immunocytochemical studies of relaxin in ovaries of pregnant and cycling mice

Immunocytochemical staining for relaxin in ovarian sections of pregnant mice from day 11 through day 18 of gestation revealed that only corpora lutea (CL) of pregnancy are stained. Evaluation of serial sections of ovaries from a day 16 pregnant mouse revealed that the only luteal structures present are CL of pregnancy. The number of CL present in each ovary equaled the number of implantation sites in each related horn (7 on the right side and 8 on the left side). These large CL varied in shape, being round in some profiles to very elongate in others. All CL were immunochemically stained for relaxin using the peroxidase-antiperoxidase method of L. Sternberger (Immunocytochemistry, 2nd ed. Wiley, New York, 1979). The intensity of the strain varied from cell to cell within each CL. Small luteal structures that were observed to be immunochemically stained for relaxin were demonstrated to represent the periphery of CL of pregnancy. No luteinized follicles were observed and interstitial cells and follicles were not immunochemically stained in any of the day 16 serial ovarian sections or in any of the ovarian sections from pregnant mice on the other days of gestation studied. CL of previous cycles were not observed to be present in the ovaries at days 15, 16, or 18 of gestation. However on day 14 and before, CL of previous cycles were observed and they did not exhibit any relaxin immunostaining. Immunocytochemical studies using the biotin-avidin system revealed that no relaxin immunostaining could be demonstrated in the ovaries of cycling mice at any stage of the estrous cycle. In conclusion, this study revealed that the only ovarian structures demonstrating relaxin immunocytochemical staining in the mouse were CL of pregnancy.     

Ultrastructural aspects of the antimesometral implantation in the rabbit

A scanning and transmission electron microscope study of blastocysts immediately prior to ovo implantation and of antimesometrial implantation sites was conducted. External membranes of the eggs showed at 6 days post coitum the imprint of the endometrial surface, pointing to the early establishment of contact between egg and uterus. At 7 days the antimesometrial region showed flattening with continued evidence of gland openings that appear to be the elective sites of attraction of the trophoblastic knobs. Attachment of the trophoblastic knobs followed on days 8 and 9.     

Regulated temporal and spatial expression of the calcium-binding proteins calcyclin and OPN (osteopontin) in mouse tissues during pregnancy.

In situ hybridization and northern/slot blot analyses were used to quantify the expression of calcyclin (2A9, 5B10), osteopontin (opn, secreted phosphoprotein, 2ar) and calmodulin mRNAs in mouse tissues that support pregnancy. High-to-moderate levels of the mRNAs of all three genes were detected at discrete locations in the uterus, decidua and placenta as a function of gestation time. Calmodulin expression was constant in these tissues; calcyclin mRNA was high during early pregnancy and declined after day 8-9 of gestation; and opn mRNA was undetectable before day 7, with maximal levels on days 9-12 in each of these tissues. Calcyclin, but not opn, expression was also observed in the chorioamnion after day 12. Calcyclin was expressed throughout the decidua on day 8 but became restricted to the primary (antimesometrial) decidual zone and decidua lateralis on day 9, and the decidua capsularis after day 9. By contrast, opn mRNA was localized on day 9 to the mesometrial triangle, which contains a large population of granulated metrial gland cells, and to the decidua basalis. These two genes may serve as markers for the two types of decidual tissue. We suggest that one function of OPN, which may be an indicator of cells in the decidua that have a bone marrow genealogy, is to mediate the flux of calcium from the maternal circulation to the developing embryo.     

Ovarian steroid receptors and activated MAPK in the regional decidualization in rats

Though the decidua serves a critical function in implantation, the hormonal regulated pathway in decidualization is still elusive. Here we describe in detail the regional distribution and the effects of progesterone receptors (PGR), estrogen receptors (ESR), and MAPK activation on decidualization. We showed an increase in PGR A, PGR B, ESR1, and phosphorylated MAPK3-1 proteins (p-MAPK3-1), but not in ESR2, in the decidual tissue up to Day 8 of pregnancy. PGR was predominantly found in the nuclei of mesometrial decidual cells and of undifferentiated stromal cells where it colocalizes with ESR2 and ESR1. In the antimesometrial decidua, all the receptors showed cytoplasmic localization. MAPK was activated exclusively in undifferentiated stromal cells of the junctional zone between the antimesometrial and mesometrial decidua and at the border of the antimesometrial decidua. Treatment with the progesterone antagonist onapristone and/or the estrogen antagonist faslodex reduced the extent of decidual tissue and downregulated the levels of PGR and ESR1. The expression level of ESR2 was affected only by the progesterone receptor antagonist, while neither the antiprogestin nor the antiestrogen significantly modified the p-MAPK3-1 level. The inhibition of MAPK3-1 phosphorylation by PD98059 impaired the extent of decidualization and the closure reaction of the implantation chamber, and significantly downregulated ESR1. These results confirm a role of both steroid receptors in the growth and differentiation of the different decidual regions and suggest a new function for p-MAPK3-1 in regulating expression levels of ESR1, thereby maintaining the proliferation capacity of stromal cells and limiting the differentiation process in specified regions of decidual tissues.     

Influence of pregnancy on the course of malaria in mice infected with Plasmodium berghei

The course of malarial infection was compared in pregnant mice inoculated with Plasmodium berghei at different stages of gestation. When 12-14 wk old, pregnant BALB/c mice were inoculated with 1 x 10(6) of P. berghei NK65-infected red cells at gestation day 0, 2, 4, 6, 8, 10, 12, 14 or 16, the mice inoculated on gestation days 6-12 expired 6.5 days after inoculation compared to 9.5 days in non-pregnant mice. Parasitemia in these pregnant mice increased rapidly on day 4 after inoculation and anemia also developed earlier on day 5. However, the degree of parasitemia and anemia in the terminal stage of infection in these pregnant mice was milder than that of non-pregnant controls. Blood urea nitrogen increased at the terminal stage although the degree of increase in mice inoculated on gestation days 6-10 was comparatively small. Pregnant malarial mice died earlier with less physiological changes than non-pregnant controls. It was concluded that pregnancy makes the host susceptible to physiological changes caused by malaria.     

Chorioallantoic placenta formation in the rat: I. Luminal epithelial cell death and extracellular matrix modifications in the mesometrial region of implantation chambers.

On days 7 and 8 of pregnancy, mesometrial regions of rat gestation sites were examined by light microscopy and transmission electron microscopy to determine what changes occur before the chorioallantoic placenta forms in that region. By day 7, gestation sites contained a uterine lumen mesometrially and an antimesometrial extension of the uterine lumen, the implantation chamber. The implantation chamber consisted of a mesometrial chamber between the uterine lumen and the conceptus, an antimesometrial chamber that contained the conceptus, and a decidual crypt antimesometrial to the conceptus. Stromal cells that formed the walls of the implantation chamber were closely packed decidual cells, while those that surrounded the uterine lumen were loosely arranged. Late on day 7, a portion of the epithelium lining the mesometrial chamber was degenerating, but this area of initial degeneration was never adjacent to the antimesometrial chamber. By early day 8, most of the epithelial cells lining the mesometrial chamber were degenerating and were being sloughed into the chamber lumen. Although degeneration of these epithelial cells morphologically resembled necrosis, it was precisely controlled, since adjacent epithelial cells lining the uterine lumen remained healthy. The space that separated the denuded luminal surface of the mesometrial chamber from underlying decidual cells became wider and was occupied by an extracellular matrix rich in cross-banded collagen fibrils. Decidual cell processes, that earlier had penetrated the basal lamina beneath healthy epithelial cells, protruded into this matrix and penetrated the basal lamina at the luminal surface. By late day 8, large areas of denuded chamber wall were covered with decidual cell processes, little remained of the basal lamina, and cross-banded collagen fibrils were scarce in the area occupied by decidual cell processes. During the times studied, uterine tissues that formed the walls of the mesometrial chamber were not in direct contact with the conceptus. This study indicates that trophoblast does not play a direct role in epithelial degeneration, basal lamina penetration, or extracellular matrix modifications in the mesometrial region of implantation chambers where part of the chorioallantoic placenta forms, although trophoblast may be required to trigger or modulate some of the changes.