Immunohistochemical localization of connective tissue growth factor (CTGF) in the mouse embryo between days 7.5 and 14.5 of gestation.

Connective tissue growth factor (CTGF) is a 38 kDa modular protein that is involved in processes such as cell proliferation, survival, migration, adhesion and extracellular matrix production. Target cells for CTGF include fibroblasts, smooth muscle cells and endothelial cells. Using a specific peptide antibody, CTGF was localized in tissue sections obtained from mouse embryos between days 7.5 and 14.5 of gestation. On day 7.5, CTGF was present at high levels in the embryonic ectoderm, mesoderm, and chorion, with weaker levels in the squamous endoderm. No CTGF was detected in Reichert's membrane, parietal endoderm, and visceral endoderm. Decidual cells of the maternal uterus stained strongly for CTGF. There was no specific staining for CTGF on day 11.5 but by day 13.5, the protein was detectable in a limited number of structures, most notably the liver, thymus, lung, and intestine. By day 14.5, staining for CTGF had become extensive and was present at high or moderate levels in the thymus, aorta, trachea, liver, lung, adrenal gland, kidney, iliac sinus, olfactory region, tongue, pharynx, esophagus, thyroglossal duct, choroid plexi, Rathke's pouch, stomach, pancreas, and midgut. Relatively weak staining was present in the heart and dorsal root ganglia. There was no staining in the vitelline duct or in the outer cortical or medullary regions of the brain. Among specific cell types, CTGF was localized at high levels in secretory and absorptive epithelial cells and liver parenchyma cells, at moderate levels in vascular endothelial cells and myoblasts and at low levels in mesenchymal and connective tissue cells. These data show that various tissues and organ systems produce CTGF in a specific temporo-spatial pattern during embryogenesis and support a role for CTGF in cellular differentiation and development during prenatal life.

MUC1/episialin: a critical barrier in the female reproductive tract.

The female reproductive tract must resist microbial infections as well as support embryonic development, implantation and placentation. Reproductive tract mucins, in general, and Muc1/episialin, in particular, play key roles in implantation related events and in protection from microbial infection. High levels of mucin expression in the lower reproductive tract presumably affords protection against infection while down-regulation of uterine mucins has been suggested to provide access to the uterine surface. The present studies demonstrate that mucins, particularly Muc1, are effective barriers to embryo attachment. Furthermore, a strain of female Muc1 null mice in normal housing displays chronic infection and inflammation of the lower reproductive tract and markedly reduced fertility rates. This phenotype is not observed when Muc1 nulls are housed in a pathogen-free environment indicating that this phenotype results from chronic microbial exposure. Only normal endogenous flora were isolated from the reproductive tracts of affected Muc1 null mice, suggesting that these bacterial species become opportunistic with loss of the mucin barrier. Staphylococcal adherence to lower reproductive tract epithelia was found to be mediated by cell surface mucin carbohydrates. Collectively, these studies demonstrate a critical barrier role for Muc1 in various aspects of female reproductive tract physiology.

Localization of connective tissue growth factor during the period of embryo implantation in the mouse.

A role for connective tissue growth factor (CTGF) in reproductive function has been suggested from recent studies in the pig. To extend these findings, we have analyzed the immunohistochemical localization of CTGF during the estrous cycle and early pregnancy in mice. During the diestrous and early proestrous stages, CTGF was localized at high levels to both luminal and glandular uterine epithelial cells and at much lower levels in the stroma or myometrium. Epithelial expression of CTGF was considerably reduced at estrus. On Days 1.5-3.5 of pregnancy, CTGF was localized mainly to the uterine epithelial cells, which showed a substantially reduced level of CTGF on Day 4.5. On Days 5.5 and 6.5, CTGF was present at high levels in uterine decidual cells. CTGF was detected in the trophectoderm and inner cell mass of the preimplantation embryo on Day 4.5 and became preferentially localized to embryonic endoderm and mesoderm on Days 5.5-6.5. Multiple mass forms of CTGF (Mr 14 000-38 000) were present in endometrial extracts and uterine luminal flushings. Collectively, these data support a role for CTGF in uterine cell growth, migration, adhesion, and extracellular matrix production during the estrous cycle and early pregnancy, as well as in early development of the embryo.

Characterization of 16- to 20-kilodalton (kDa) connective tissue growth factors (CTGFs) and demonstration of proteolytic activity for 38-kDa CTGF in pig uterine luminal flushings.

Connective tissue growth factor (CTGF) is a growth and chemotactic factor for fibroblasts encoded by an immediate early gene that is transcriptionally activated by transforming growth factor ss. Although the primary translational product of the pig CTGF gene is predicted to be of approximate Mr 38 000, pig uterine luminal flushings (ULF) contained 10- to 20-kDa CTGF proteins that were heparin-binding and mitogenic, whereas 38-kDa CTGF was not apparent. The N-termini of two microheterogeneous forms of 16-kDa CTGF, as well as 18-kDa and 20-kDa forms of CTGF, commenced at, respectively, Cys199, Ala197, Asp186, and Asp186 and did not correspond to intron-exon boundaries in the CTGF gene. Northern blotting revealed a single porcine (p) CTGF transcript of 2.4 kilobases in endometrium from Day 10 to 16 cycling or pregnant pigs. Ten- to twenty-kilodalton pCTGF proteins in ULF were stable for 48 h at 37 degreesC whereas native 38-kDa pCTGF was degraded within 10 min under the same conditions. CTGF-degrading activity in pig ULF was heat-sensitive and concentration- and time-dependent. Ten- to twenty-kilodalton CTGF levels in ULF peaked on Day 16 of the cycle and on Day 12 of pregnancy and were highly correlated with the levels of proteolytic activity for 38-kDa CTGF. Collectively these data suggest that bioactive 10- to 20-kDa CTGF proteins are generated in utero through limited proteolysis of the 38-kDa CTGF primary translational product.

Characterization of pig connective tissue growth factor (CTGF) cDNA, mRNA and protein from uterine tissue.

Connective tissue growth factor (CTGF) is a 38kDa mitogen and chemotactic factor for fibroblasts that is transcriptionally activated by serum or transforming growth factor-beta and may play a role in wound healing and various skin diseases. In these studies, pig endometrium was shown to contain a single CTGF transcript of 2.4kb and to produce a 38kDa CTGF-immunoreactive protein. Cloning and sequencing of a 1.5kb pig uterine CTGF cDNA revealed that the predicted pCTGF primary translation product displayed 92% identity to human CTGF and 93% identity to mouse CTGF. The pCTGF cDNA encoded a 26 amino acid signal peptide followed by a 323-residue sequence containing 38 highly conserved cysteine residues. In common with mouse and human CTGF proteins, pCTGF is predicted to resemble a multi-functional mosaic protein that contains four distinct modules.

Production and characterization of WEG-1, an epidermal growth factor/transforming growth factor-alpha-responsive mouse uterine epithelial cell line.

Uterine epithelial cells (UEC) isolated from 6-week-old CF-1 mice were immortalized using retroviral-mediated transfection of SV40 large T-antigen. One line, WEG-1, retained epithelial morphology and reacted with antibodies to cytokeratins 18, 19, laminin, fibronectin, and beta-catenin. In addition, WEG-1 cells displayed strong nuclear immunoreactivity to SV40 large T-antigen, confirming integration of the retrovirus vector and expression of this gene. WEG-1 cells were negative for nonepithelial markers such as desmin and factor 8. WEG-1 cells did not proliferate in serum-free medium; however, addition of 0.5% FBS supported proliferation to the same extent as 10% FBS. Addition of 50 ng/ml epidermal growth factor to medium containing 0.5% charcoal-stripped FBS restored proliferation comparable with 0.5% whole FBS. Epidermal growth factor or transforming growth factor-alpha (50 ng/ml), but not transforming growth factor-beta, leukemia-inhibiting factor, or fibroblast growth factor, induced the secretion of three proteins (M(r) approximately to 158K, 148K, and 36K). Comparison of protein secretions of WEG-1 cells and UEC showed shared as well as distinct bands. Like UEC, WEG-1 cells secreted PGF2a and PGE2 and expressed PG GH synthase-2. Unlike UEC, WEG-1 cells showed no apical/basal preference for either uptake of methionine or secretion of proteins. The absence of immunoreactive E-cadherin or zona occludens-1 was consistent with the absence of cell polarity in WEG-1 cells. Primary UEC, which polarize in vitro, do not support blastocyst attachment. WEG-1 cells, although not polarized in vitro, also exhibited delayed blastocyst attachment compared with nonuterine cell lines, suggesting that WEG-1 cells partially retained some aspects of UEC function relevant to embryo attachment. WEG-1 cells expressed messenger RNA for Muc-1, an UEC mucin suggested to have antiadhesive properties. Furthermore, WEG-1 cells did not display high affinity heparin binding sites, an activity associated with embryo attachment. WEG-1 cells may provide a model for studying various aspects of UEC function and murine embryo attachment.

Expression and steroid hormonal control of Muc-1 in the mouse uterus.

Previous studies from our laboratory established that large M(r) mucin glycoproteins are major apically disposed components of mouse uterine epithelial cells in vitro. The present studies demonstrate that Muc-1 represents one of the apically disposed mucin glycoproteins of mouse uterine epithelia, and that Muc-1 protein and messenger RNA (mRNA) expression are regulated in the periimplantation mouse uterus by ovarian steroids. Muc-1 expression is exclusive to the epithelial cells of the uterus under all conditions examined. Muc-1 expression is high in the proestrous and estrous stages and decreases during diestrous. Both Muc-1 protein and mRNA decline to barely detectable levels by day 4 of pregnancy, i.e. before the time of blastocyst attachment. In contrast, Muc-1 expression in the cervix and vagina is maintained during this same period. Delayed implantation was established in pregnant mice by ovariectomy and maintained by the administration of exogenous progesterone (P). Initiation of implantation was triggered by coinjection of P-maintained mice with a nidatory dose of 17 beta-estradiol (E2). Muc-1 levels in the uterine epithelia of P-maintained mice declined to low levels similar to those observed on day 4 of normal pregnancy. Coinjection of E2 did not alter Muc-1 expression, suggesting that down-regulation of Muc-1 is a P-dominated event. This was confirmed in ovariectomized nonpregnant mice, which displayed stimulation of Muc-1 expression after 6 h of E2 injection. E2-Stimulated Muc-1 expression was inhibited by the pure antiestrogen, ICI 164,384. Although P alone had no effect on Muc-1 expression, it antagonized the action of E2. Injection of pregnant mice with the antiprogestin, RU486, a known implantation inhibitor, on day 3 of pregnancy restored high level expression of Muc-1 mRNA on day 4, indicating that down-regulation of Muc-1 is P receptor mediated. Collectively, these data indicate that Muc-1 expression in mouse uterine epithelium is strongly influenced by ovarian steroids. It is suggested that the loss of Muc-1 contributes to generation of a receptive uterine state.