Daniel D. Carson

Heparin/heparan sulfate is involved in attachment and spreading of mouse embryos in vitro

The involvement of embryonic cell surface proteoglycans in the attachment and outgrowth of cultured mouse embryos has been investigated. Several lines of evidence indicate that periimplantation stage blastocysts express heparin/heparan sulfate proteoglycans on their cell surfaces that can mediate embryo attachment and trophoblast outgrowth on a variety of matrices. First, in the presence of soluble heparin, the rate at which embryos attach and outgrow on laminin, fibronectin, or monolayers of uterine epithelial cells is reduced considerably. In the case of fibronectin, the rate of outgrowth in the presence of the heparin is slower than in the presence of the Arg-Gly-Asp-Ser-containing peptide that is recognized by a fibronectin receptor. Embryos also attach and exhibit a limited ability to outgrow on platelet factor IV, a heparin binding protein that does not possess the additional binding domains of laminin or fibronectin. Attachment on platelet factor IV is inhibited by heparin. Second, cell surface digestion of attachment-component embryos with heparinase, but not chondroitinase ABC, slows the rate of outgrowth on tissue culture plates in the presence of serum. Third, selective staining for sulfated molecules on the trophectoderm surface of periimplantation stage embryos indicates that such molecules are abundant and uniformly distributed on these cell surfaces. Last, heparin/heparan sulfate proteoglycans are detected as major cell surface components of embryos using vectorial labeling with lactoperoxidase and Na125I. Collectively, these data indicate that heparin/heparan sulfate-bearing molecules have a direct role in attachment and outgrowth of implantation stage blastocysts.

Histological studies of gene-ablated mice support important functional roles for natural killer cells in the uterus during pregnancy

Maternal lymphocytes having a large and granulated morphology accumulate at healthy implantation sites in normal mice. Insight into the functions of these cells has come from a previous study of two independent lines of mice deficient in natural killer (NK) cells. In pregnant Tg epsilon 26 mice, vascular pathology was found that led to the major complications of either fetal death or intrauterine growth retardation. In pregnant p56lck null x IL-2R beta null mice, extensive distension of the decidua was observed that separated the placenta from the myometrium and appeared to be interstitial edema. To strengthen assignment of uterine large granulated lymphocytes to the NK cell lineage and to understand which aspects of NK cell biology may be important for a uterine-based, pregnancy-associated subset, mid-gestation implantation sites from a new series of mice having gene deletions which alter NK cells (IL-2R gamma null, Stat4 null, IL-12 p40 null, beta 7 integrin null and Muc-1 null) have been examined histologically. The findings support the assignment of pregnancy-associated large granulated cells of mice to the NK cell lineage and suggest that the primary functions of these tissue-based NK cells are to support normal development of the decidua and/or its vasculature using pathways that involve IL-12 mediated signal transduction.

Cell Surface Expression of HIP, a Novel Heparin/Heparan Sulfate-binding Protein, of Human Uterine Epithelial Cells and Cell Lines

Previous studies established that uterine epithelial cells and cell lines express cell surface heparin/heparan sulfate (HP/HS)-binding proteins (Wilson, O., Jacobs, A. L., Stewart, S., and Carson, D. D.(1990) J. Cell. Physiol. 143, 60-67; Raboudi, N., Julian, J., Rohde, L. H., and Carson, D. D.(1992) J. Biol. Chem. 267, 11930-11939). The accompanying paper (Liu, S., Smith, S. E., Julian, J., Rohde, L. H., Karin, N. J., and Carson, D. D.(1996) J. Biol. Chem. 271, 11817-11823) describes the cloning of a full-length cDNA corresponding to a candidate cell surface HP/HS interacting protein, HIP, expressed by a variety of human epithelia. A synthetic peptide was synthesized corresponding to an amino acid sequence predicted from the cDNA sequence and used to prepare a rabbit polyclonal antibody. This antibody reacted with a protein with an apparent M of 24,000 by SDS-polyacrylamide gel electrophoresis that was highly enriched in the 100,000 × g particulate fraction of RL95 cells. This molecular weight is similar to that of the protein expressed by 3T3 cells transfected with HIP cDNA. HIP was solubilized from this particulate fraction with NaCl concentrations ≥0.8 M demonstrating a peripheral association consistent with the lack of a membrane spanning domain in the predicted cDNA sequence. HIP was not released by heparinase digestion suggesting that the association is not via membrane-bound HS proteoglycans. NaCl-solubilized HIP bound to heparin-agarose in physiological saline and eluted with NaCl concentrations of 0.75 M and above. Furthermore, incubation of I-HP with transblots of the NaCl-solubilized HIP preparations separated by two-dimensional gel electrophoresis demonstrated direct binding of HP to HIP. Indirect immunofluorescence studies demonstrated that HIP is expressed on the surfaces of intact RL95 cells. Binding of HIP antibodies to RL95 cell surfaces at 4°C was saturable and blocked by preincubation with the peptide antigen. Single cell suspensions of RL95 cells formed large aggregates when incubated with antibodies directed against HIP but not irrelevant antibodies. Finally, indirect immunofluorescence studies demonstrate that HIP is expressed in both lumenal and glandular epithelium of normal human endometrium throughout the menstrual cycle. In addition, HIP expression increases in the predecidual cells of post-ovulatory day 13-15 stroma. Collectively, these data indicate that HIP is a membrane-associated HP-binding protein expressed on the surface of normal human uterine epithelia and uterine epithelial cell lines.

Synthesis and Intracellular Trafficking of Muc-1 and Mucins by Polarized Mouse Uterine Epithelial Cells

Mucins function as a protective layer rendering the apical surface of epithelial cells nonadhesive to a variety of microorganisms and macromolecules. Muc-1 is a transmembrane mucin expressed at the apical cell surface of mouse uterine epithelial cells (UEC) that disappears as UEC become receptive for embryo implantation (Surveyor, G. A., Gendler, S. J., Pemberton, L., Das, S. K., Chakraborty, I., Julian, J., Pimental, R. A., Wegner, C. W., Dey, S. K., and Carson, D. D. (1995) Endocrinology 136, 3639-3647). In the present study, the kinetics of Muc-1 assembly, cell surface expression, release, and degradation were examined in polarized mouse UEC in vitro. Mucins were identified as the predominant glycoconjugates synthesized, apically expressed, and vectorially released in both wild-type and Muc-1 null mice. When mucins were released, greater than 95% were directed to the apical compartment. Approximately half of the cell-associated mucins lost during a 24-h period were found in the apical compartment. Vectorial biotinylation detected apically disposed, cell-surface mucin and indicated that at least 34% of these mucins are released apically within 24 h. This suggests that release of mucin ectodomains is part of the mechanism of mucin removal from the apical cell surface of UEC. The half-lives of total cell-associated mucins and Muc-1 were 19.5 ± 1 and 16.5 ± 0.8 h, respectively. Muc-1 represented approximately 10% of the [3H]glucosamine-labeled, cell-associated mucins. Studies of the kinetics of intracellular transport of Muc-1 indicated transit times of 21 ± 15 min from the rough endoplasmic reticulum to Golgi apparatus and 111 ± 28 min from the Golgi apparatus to the cell surface. Collectively, these studies provide the first comprehensive description of Muc-1 and mucin maturation, metabolism, and release by polarized cells, as well as defining a major metabolic fate for mucins expressed by UEC. Normal metabolic processing appears to be sufficient to account for the removal of Muc-1 protein during the transition of UEC to a receptive state.

cDNA Cloning and Expression of HIP, a Novel Cell Surface Heparan Sulfate/Heparin-binding Protein of Human Uterine Epithelial Cells and Cell Lines

Heparan sulfate proteoglycans and their corresponding binding sites have been suggested to play an important role during the initial attachment of murine blastocysts to uterine epithelium and human trophoblastic cell lines to uterine epithelial cell lines. Previous studies on RL95 cells, a human uterine epithelial cell line, had characterized a single class of cell surface heparin/heparan sulfate (HP/HS)-binding sites. Three major HP/HS-binding peptide fragments were isolated from cell surfaces by tryptic digestion, and partial amino-terminal amino acid sequence for each peptide fragment was obtained (Raboudi, N., Julian, J., Rohde, L. H., and Carson, D. D.(1992) J. Biol. Chem. 267, 11930-11939). In the current study, using approaches of reverse transcription-polymerase chain reaction and cDNA library screening, we have cloned and expressed a novel, cell surface HP/HS-binding protein, named HP/HS interacting protein (HIP), from RL95 cells. The full-length cDNA of HIP encodes a protein of 159 amino acids with a calculated molecular mass of 17,754 Da and pI of 11.75. Transfection of HIP full-length cDNA into NIH-3T3 cells demonstrated cell surface expression and a size similar to that of HIP expressed by human cells. Predicted amino acid sequence indicates that HIP lacks a membrane spanning region and has no consensus sites for glycosylation. Northern blot analysis detected a single transcript of 1.3 kilobases in both total RNA and poly(A) RNA. Examination of human cell lines and normal tissues using both Northern blot and Western blot analyses revealed that HIP is expressed at different levels in a variety of human cell lines and normal tissues but absent in some cell lines and some cell types of normal tissues examined. HIP has relatively high homology (80% both at the levels of nucleotide and protein sequence) to a rodent ribosomal protein L29. Thus, members of the L29 family may be displayed on cell surfaces where they may participate in HP/HS binding events.

Heparanase and a synthetic peptide of heparan sulfate-interacting protein recognize common sites on cell surface and extracellular matrix heparan sulfate

Heparanase is an endo-β-d-glucuronidase that degrades the glycosaminoglycan chains of heparan sulfate (HS) proteoglycans at specific sites. Elevated levels of heparanase are associated with the metastatic potential of melanoma and other types of tumor cells. We previously reported heparanase degradation of cell surface HS subpopulations of the human adenocarcinoma cell line RL95. In the present study, heparanase activity was examined on RL95 cell surface HS subpopulations in the presence of a synthetic peptide (CRPKAKAKAKAKDQTK) of heparin/heparan sulfate-interacting protein (HIP; Liu, S., Smith, S. E., Julian, J., Rohde, L. H., Karin, N. J., and Carson, D. D. (1996) J. Biol. Chem. 271, 11817–11823). Heparanase digestion generated HS fragments from cell surface- or extracellular matrix-derived HS of approximately 25 and 9 kDa, respectively. In contrast, HS of various size classes isolated from proteoglycans secreted or released by RL95 and endothelial cells in culture were not susceptible to heparanase digestion. Incubation of heparanase-containing melanoma cellular extracts or partially purified heparanase preparations with cell surface- or ECM-derived HS and HIP peptide, but not a scrambled sequence of this peptide or other HS-binding proteins present in ECM, completely inhibited heparanase action. Conversely, predigestion of cell surface HS with either heparanase-containing cellular extracts or with secreted or partially purified heparanase destroyed binding to HIP peptide. Preincubation of HS with HIP peptide prevented subsequent heparanase digestion. Collectively, these data demonstrate that HIP peptide and heparanase recognize specific, common motifs within HS chains at cell surfaces and in ECM and may mutually modulate HS-dependent activities.

Glycoconjugate Expression and Interactions at the Cell Surface of Mouse Uterine Epithelial Cells and Periimplantation-Stage Embryo

The periimplantation stage mammalian embryo is extraordinary with regard to its adhesive and invasive potential. At the blastocyst stage, embryos first develop the ability to attach to and displace a variety of cell types in vitro (Sherman, 1978; Sherman and Wudl, 1976; Glass et al., 1979; Van Blerkom and Chavez, 1981). Furthermore, transplanted blastocysts have the capacity to invade a number of organs and tissues in host animals (c.f. Cowell, 1969). This property contributes to the occurrence of various teratocarcinomas and ectopic pregnancies (Rubin et al., 1983). The adhesive/invasive properties of periimplantation stage embryos reside in the trophectodermal cells surrounding the embryoblast. Given the wide range of biomolecules that can serve as substrates for attachment, it may be expected that mammalian embryos express a variety of cell adhesion systems. Nonetheless, the observations that preimplantation-stage blastocysts do not display adhesive/invasive properties (Sherman and Wudl, 1976) indicate that these systems are developmentally regulated and first are expressed during development of the blastocyst.

HEPARIN/HEPARAN SULFATE (HP/HS) INTERACTING PROTEIN (HIP) SUPPORTS CELL ATTACHMENT AND SELECTIVE, HIGH AFFINITY BINDING OF HP/HS

Heparin/heparan sulfate (HP/HS), HS proteoglycans, and their binding proteins play important roles in a variety of biological processes. Previously, we identified a novel cell surface HP/HS interacting protein (HIP) from human uterine epithelia and a variety of other human epithelial and endothelial cells and cell lines (Liu, S., Smith, S. E., Julian, J., Rohde, L. H., Karin, N. J., and Carson, D. D. (1996) J. Biol. Chem. 271, 11817–11823; Rohde, L. H., Julian, J., Babaknia, A., and Carson, D. D. (1996) J. Biol. Chem. 271, 11824–11830). In the current studies, we have purified and characterized HIP from HEC cells, a human uterine epithelial cell line, as well as recombinant HIP from a bacterial expression system. HIP supports attachment of the human trophoblastic cell line, JAR, in a HS-dependent fashion. Predigestion of JAR cells with a mixture of heparitinases, but not chondroitinase AC, abolished cell attachment to HIP. In addition, JAR cell attachment to HIP is highly sensitive to HP inhibition and much more selective for HP/HS than other glycosaminoglycans. Dermatan sulfate displays partial inhibitory activity as well, consistent with the observation that chondroitinase ABC digestion partially reduces JAR cell attachment to HIP. Solid-phase binding assays indicate HIP binds [3H]HP with high affinity (apparentK D = 8 nm). Furthermore, HIP bound cell surface/extracellular matrix-associated HS, expressed by RL95 cells, a human uterine epithelial cell line. Anti-HIP antibody generated against a synthetic peptide derived from a putative HP/HS-binding motif resident within HIP inhibited about half of [3H]HP binding to HIP, indicating that this domain is a functional HP-binding domain of HIP. Similarly, this same synthetic peptide motif of HIP could block about 50% of [3H]HP binding to HIP; however, this peptide almost completely inhibited cell attachment to HIP, suggesting a critical role, in this regard. Collectively, these results suggest that HIP can function as a HP/HS-binding cell-cell/cell-matrix adhesion molecule.

Cell surface glycoconjugates as modulators of embryo attachment to uterine epithelial cells.

Attachment of mammalian embryos to the uterine wall involves the coordinated development of both the embryo and the uterine epithelium to an attachment-competent state. This coordination is achieved directly or indirectly through the actions of ovarian steroids. Acquisition of attachment competence is proposed to reflect two processes. The first is the loss of non-adhesive glycoproteins at the cell surface of embryos, e.g. zona pellucida subunits, as well as uterine epithelial cells, e.g. mucin glycoproteins. The second process is the functional expression of complementary adhesion-promoting molecules at these cell surfaces. A series of studies indicates that heparan sulfate proteoglycans and their corresponding binding sites can play an important role in the initial stage of embryo attachment to the uterine surface.

Uterine stromal cell chondroitin sulfate proteoglycans bind to collagen type I and inhibit embryo outgrowth in vitro

Chondroitin sulfate proteoglycans (CSPGs) are the major class of proteoglycans synthesized by mouse uterine stroma in vitro (Jacobs, A. L., and Carson, D. D. (1991). J. Biol. Chem. 266, 15,464-15,473). In the present study, stromal CSPGs were isolated and examined with regard to their ability to bind to specific extracellular matrix (ECM) components. Of a variety of ECM components tested, only collagen type I formed stable complexes with stromal CSPGs in both solid phase and solution binding assays. Proteolytic digestion of the CSPGs did not affect binding and suggested that the protein cores did not participate directly in binding. Furthermore, free chondroitin sulfate polysaccharides do not compete effectively in the binding assays. Therefore, interactions with multiple CS chains and/or the higher charge density afforded by intact CSPGs appear to be required for retention by collagen type I. Intact CSPGs were examined for their ability to modulate embryo attachment and outgrowth in vitro on fibronectin- or collagen type I-coated surfaces. In both cases, intact CSPGs, but not their constituent protein cores or polysaccharides, inhibited both the rate and the extent of outgrowth formation. In addition, embryo outgrowth on stromal ECM was enhanced by predigestion with chondroitinase. Addition of exogenous CSPG markedly retarded embryo outgrowth on stromal matrix. Collectively, these data indicate that stromal cell-derived CSPGs are retained by collagen type I in the stromal interstitial ECM where these molecules may attenuate trophoblast invasive behavior.