The cell-surface expression of the cell adhesion molecule cellCAM 105 in rat fetal tissues and regenerating liver

In the present investigation we have used a sensitive immunohistochemical technique to study the appearance and cell-surface distribution of cellCAM 105 in rat fetal tissues and in regenerating liver. CellCAM 105 is an integral membrane glycoprotein that is involved in cell-cell adhesion of mature rat hepatocytes in vitro. In 12-day-old rat fetuses no cellCAM 105 was detected. CellCAM 105 then appeared on Day 13 in megakaryocytes of the fetal liver, on Day 16 in the liver parenchyme, and on Day 17 in the epithelial cells of the proximal kidney tubules and of the small intestinal mucosa. In the liver parenchyme cellCAM 105 first appeared in immature bile canaliculi. During Days 19-21 a significant staining also occurred on the contiguous sides of the hepatocytes, which at that time became closely associated when the blood-forming cells disappeared. This surface staining then gradually disappeared and 2-3 weeks after birth cellCAM 105 was expressed in the bile canalicular area which is typical of mature hepatocytes. In regenerating liver the amount of cellCAM 105 decreases to a minimum 2-3 days post-hepatectomy, then increases and reaches the normal concentration 10-15 days post-hepatectomy [Odin and Obrink (1986) Exp. Cell Res. 164, 103-114]. The cell-surface distribution of cellCAM 105 also changed, and on Days 3-5 post-hepatectomy it appeared on all faces of the hepatocytes which then were closely associated without obvious sinusoids in between. This staining pattern then slowly changed toward the normal pattern of mature liver, which appeared about 15 days post-hepatectomy. A theoretical analysis of the mode of hepatocyte cell division during liver regeneration suggested that the surface of the postmitotic hepatocytes should become unpolarized with respect to macromolecular composition. This is in agreement with the observed surface distribution of cellCAM 105. The results support the hypothesis that cell-surface interactions mediated by cellCAM 105 might contribute to the regular organization of hepatocytes in the normal, mature liver plates.     

Trophectoderm surface expression of the cell adhesion molecule cell-CAM 105 on rat blastocysts

A variety of cellular interactions is involved in the process of implantation of the mammalian embryo into the uterine tissue. Recent discoveries have demonstrated that intercellular recognition and adhesive events are governed by a class of cell surface molecules known as cell adhesion molecules (CAMs). In the present report, we have investigated the occurrence of the well-characterized cell adhesion molecule cell-CAM 105 on the surface of rat pre- and peri-implantation embryos of various stages. This was carried out by indirect immunofluorescence microscopy employing affinity-purified rabbit antibodies against cell-CAM 105. The embryonal stages investigated comprised morulae, normal day-4 blastocysts, and delayed and adhesive blastocysts obtained by using the method of experimentally delayed implantation. Cell-CAM 105 was absent in the early-morula stage, but in normal day-4 blastocysts and delayed blastocysts a specific staining for cell-CAM 105 was seen on the entire surface. However, adhesive-stage blastocysts exhibited a marked polarity with staining of the polar trophoblast cells. Scanning electron microscopy of adhesive-stage blastocysts revealed that the stronger staining of the polar region was not due to a greater number of microvilli on the polar trophoblast cells. Thus, it seems as if cell-CAM 105 is lost or masked from the surface of the mural trophoblast cells of adhesive-stage rat blastocysts. Since the mural trophoblast cells are the first to adhere to the uterine luminal epithelium during the onset of implantation and subsequently invade the uterine stroma, we suggest that the apparent downregulation of cell-CAM 105 in the mural trophoblast cells might be linked to the acquisition of trophoblast invasiveness.     

Quantitative determination of the organ distribution of the cell adhesion molecule cell-CAM 105 by radioimmunoassay

We have previously identified a 105,000-Da plasma membrane glycoprotein, denoted cell-CAM 105, that is involved in intercellular adhesion of reaggregating rat hepatocytes. In this communication we report on the development of a radioimmunoassay for cell-CAM 105, employing purified cell-CAM 105, specific antisera against the molecule, and formalin-fixed protein A-containing staphylococci for precipitation of the immune complexes. The assay was shown to be sensitive, specific, precise, rapid, and easy to perform. We used this radioimmunoassay in investigations of the occurrence of cell-CAM 105 in different rat organs. Cell-CAM 105 was present in a wide spectrum of organs in varying amounts. The highest concentrations were found in the gastrointestinal tract, liver, some secretory glands, vagina, kidney, and lung. In addition, cell-CAM 105 was detected in blood, where it was shown to reside mainly in the platelets. Other tissues, particularly the central nervous system and muscle tissues, were cell-CAM-negative. The results were confirmed by immunoblotting, which revealed one distinct protein component, corresponding to cell-CAM 105, in each positive organ.     

Chemical characterization of cell-CAM 105, a cell-adhesion molecule isolated from rat liver membranes.

Cell-CAM 105, a glycoprotein that is involved in recognition and adhesion between isolated rat hepatocytes in vitro, was purified to homogeneity by a combination of immunoaffinity chromatography, gel-exclusion chromatography and ion-exchange chromatography. Electrophoretic, compositional and enzymic analyses were performed and the glycoprotein was shown to consist of two peptide chains, of apparent Mr 110,000 and 105,000 respectively, that are glycosylated to similar extents. Carbohydrate analyses demonstrated the presence of sialic acid, galactose, mannose, fucose and glucosamine, but no galactosamine, indicating that only N-linked oligosaccharides occurred. The total content of carbohydrate amounted to 33%. Peptide mapping indicated that the two peptide chains were structurally very similar. After incubation of cultured hepatocytes with [32P]Pi, phosphorylated cell-CAM 105 could be isolated. Both peptide chains were labelled and phospho-amino-acid analysis demonstrated that serine residues had become phosphorylated. A significant feature of cell-CAM 105 was a susceptibility to autolytic degradation that was difficult to inhibit. The major degradation products had apparent Mr 90,000 and 70,000, respectively. The effect of purified cell-CAM 105 on cell-cell adhesion of re-aggregating hepatocytes was studied. A significant inhibition was observed, indicating that the protein is directly involved in intercellular adhesion of these cells.     

Proliferation and cell death of hepatocytes in regenerating rat fetal liver

Proliferation and death of hepatocytes in regenerating liver of 17-day white rat fetuses were investigated. During 2 days after liver resection (20%), animals were sacrificed every 3 h. In experimental groups, the index of Ki67-positive hepatocytes increased sharply in 15 h after liver resection. In all experimental and control groups, the ratio of the metaphase, the longest phase of mitosis, and index to mitotic index remained unchanged, indicating identical duration of hepatocytes mitoses in regenerating liver. In the regenerating and intact liver hepatocytes labeled with antibodies to caspase 3 were not detected. Thus, resection of 20% rat fetal liver did not contribute to increased apoptosis of hepatocytes.     

Proliferation and cell death of hepatocytes in regenerating fetal rat liver

Proliferation and death of hepatocytes in regenerating liver were studied in 17-day-old fetal white rats. Two days after liver resection (20%), animals were sacrificed every 3 h. In experimental groups, the index of Ki67-positive hepatocytes increased sharply 15 h after liver resection. In all experimental and control groups, the ratio of the index of the metaphase, the longest phase of mitosis, to the mitotic index remained unchanged, indicating the same duration of hepatocyte mitoses in regenerating liver. In regenerating and intact liver, hepatocytes labeled with antibodies to caspase 3 were not detected. Thus, resection of 20% fetal rat liver did not promote enhancement of apoptosis of hepatocytes.     

C-CAM (cell-CAM 105)--a member of the growing immunoglobulin superfamily of cell adhesion proteins

Cell recognition and adhesion, being of prime importance for the formation and integrity of tissues, are mediated by cell adhesion molecules, which can be divided into several distinct protein superfamilies. The cell adhesion molecule C-CAM (cell-CAM 105) belongs to the immunoglobulin superfamily, and more specifically is a member of the carcinoembryonic antigen (CEA) gene family. C-CAM can mediate adhesion between hepatocytes in vitro in a homophilic, calcium-independent binding reaction. The molecule, which occurs in various isoforms, is expressed in liver, several epithelia, vessel endothelia, platelets and granulocytes and its expression is dynamically regulated under various physiological and pathological conditions. It is proposed that C-CAM in different cells and tissues plays different functional roles, where the common denominator is membrane-membrane binding.     

N-myc down regulates neural cell adhesion molecule expression in rat neuroblastoma.

In human neuroblastoma, amplification of the N-myc oncogene is correlated with increased metastatic ability. We recently showed that transfection of the rat neuroblastoma cell line B104 with an N-myc expression vector resulted in an increase in metastatic ability and a significant reduction in the expression of major histocompatibility complex class I antigens. We examined whether N-myc causes additional phenotypic changes in these cells. We showed that expression of N-myc leads to a dramatic reduction in the levels of neural cell adhesion molecule (NCAM) polypeptides and mRNAs. Spontaneous revertants of the high N-myc phenotype were found to have regained significant levels of NCAM expression, indicating that the continued expression of N-myc is required to maintain the low NCAM phenotype. NCAM was not reduced in B104 cells transfected with the neomycin resistance vector alone, and other neuronal markers were not specifically reduced in N-myc-transfected B104 cells. As NCAM functions in cell-cell adhesion, decreased NCAM expression could contribute significantly to the increased metastatic potential of N-myc-amplified neuroblastomas.     

Dynamic expression of the cell adhesion molecule fasciclin I during embryonic development in Drosophila.

A number of different cell surface glycoproteins expressed in the central nervous system (CNS) have been identified in insects and shown to mediate cell adhesion in tissue culture systems. The fasciclin I protein is expressed on a subset of CNS axon pathways in both grasshopper and Drosophila. It consists of four homologous 150-amino acid domains which are unrelated to other sequences in the current databases, and is tethered to the cell surface by a glycosyl-phosphatidylinositol linkage. In this paper we examine in detail the expression of fasciclin I mRNA and protein during Drosophila embryonic development. We find that fasciclin I is expressed in several distinct patterns at different stages of development. In blastoderm embryos it is briefly localized in a graded pattern. During the germ band extended period its expression evolves through two distinct phases. Fasciclin I mRNA and protein are initially localized in a 14-stripe pattern which corresponds to segmentally repeated patches of neuroepithelial cells and neuroblasts. Expression then becomes confined to CNS and peripheral sensory (PNS) neurons. Fasciclin I is expressed on all PNS neurons, and this expression is stably maintained for several hours. In the CNS, fasciclin I is initially expressed on all commissural axons, but then becomes restricted to specific axon bundles. The early commissural expression pattern is not observed in grasshopper embryos, but the later bundle-specific pattern is very similar to that seen in grasshopper. The existence of an initial phase of expression on all commissural bundles helps to explain the loss-of-commissures phenotype of embryos lacking expression of both fasciclin I and of the D-abl tyrosine kinase. Fasciclin I is also expressed in several nonneural tissues in the embryo.     

Biosynthesis of the D2 cell adhesion molecule: pulse-chase studies in cultured fetal rat neuronal cells

D2 is a membrane glycoprotein that is believed to function as a cell adhesion molecule (CAM) in neural cells. We have examined its biosynthesis in cultured fetal rat brain neurones. We found D2-CAM to be synthesized initially as two polypeptides: Mr 186,000 (A) and Mr 136,000 (B). With increasing chase times the Mr of both molecules increased to 187,000-201,000 (A) and 137,000-158,000 (B). These were similar to the sizes of D2-CAM labeled with [14C]glucosamine, [3H]fucose and [14C]mannosamine, indicating that the higher Mr species are glycoproteins. In the presence of tunicamycin, which specifically blocks the synthesis of high mannose cores, Mr were reduced to 175,000 (A) and 124,000 (B). Newly synthesized A and B are susceptible to degradation by endo-beta-N-acetyl-glucosaminidase H, which specifically degrades high mannose cores, but they are resistant to such degradation after 150 min of posttranslational processing. Hence, we deduce that A and B are initially synthesized with four to five high mannose cores which are later converted into N-linked complex oligosaccharides attached to asparagine residues. However, no shift of [35S]methionine radioactivity between A and B was detected with different pulse or chase times, showing that these molecules are not interconverted. Thus, our data indicate that the neuronal D2-CAM glycoproteins are derived from two mRNAs.     

Neural cell adhesion molecule expression in Xenopus embryos

The spatiotemporal pattern of expression of the neural cell adhesion molecule NCAM was mapped immunohistochemically in embryos of the frog Xenopus, from blastula to early swimming stages, using a polyclonal antibody that recognizes Xenopus NCAM. The neural plate stage was the earliest at which NCAM could be detected. The initial sites of NCAM immunoreactivity were neural ectoderm, somitic mesoderm, and chordamesoderm. During formation of the neural tube, NCAM immunoreactivity became restricted to the neuroectoderm and its derivatives. During closure of the neural tube and for 2-4 hr thereafter, NCAM was expressed in a distinctive radial pattern in coronal sections of the neural tube. NCAM was observed in neural crest cells before migration and after formation of cranial and spinal ganglia. During the period of initial neurite outgrowth, NCAM became concentrated in the developing central nerve fiber pathways. NCAM was seen on peripheral nerves from the time of their initial outgrowth and it was strongly expressed at neuromuscular junctions during the period of their formation. These results show that NCAM is expressed after neural induction and functions during morphogenesis of the neural plate and tube, some neural crest derivatives, development of nerve fiber tracts, and formation of neuromuscular connections.     

Cell surface localization and tissue distribution of a hepatocyte cell-cell adhesion glycoprotein (cell-CAM 105)

We recently identified a 105,000-dalton plasma membrane glycoprotein, denoted cell-CAM 105 (CAM, cell adhesion molecule), that is involved in intercellular adhesion of reaggregating rat hepatocytes (Ocklind, C., and B. Obrink, 1982, J. Biol. Chem., 257:6788-6795). In this communication we used a monospecific rabbit antiserum against cell-CAM 105 to localize the antigen by indirect immunofluorescence on isolated rat cells and on frozen rat tissue sections. This antiserum stained the surface of freshly isolated hepatocytes. In liver sections, however, the fluorescence seemed to be located exclusively along the bile canaliculi. In addition, cell-CAM 105 showed a very specific tissue distribution. Thus a specific fluorescence was seen only in the epithelia of the stomach, the small intestine, the large intestine, the glandular epithelium of the parotid gland, and the tubules of the kidney. No specific fluorescence was found in variety of other tissues, including cartilage, interstitial connective tissue, smooth muscle, skeletal muscle, heart muscle, eye, brain, skin, the epithelia of oesophagus, bladder, uterin mucosa, thyroid follicles, prostate gland, or collecting ducts of the kidney. In the simple epithelia of the intestine and the kidney tubules the fluorescence was confined to the apical, luminal portion. Thus, both in these epithelia and in liver, cell-CAM 105 was confined to the apical, luminal portion. Thus, both in these epithelia and in liver, cell-CAM 105 was located where the typical junctional complexes between cells are found. These findings taken together with the fact that cell-CAM 105 is involved in intercellular adhesion between hepatocytes suggest with the fac that cell-CAM 105 is involved in intercellular adhesion between hepatocytes suggest that cell-CAM 105 is a member of the junctional complexes of hepatocytes and some simple epithelia.     

Comparison of two cell-adhesion molecules, uvomorulin and cell-CAM 105

Two cell adhesion molecules, cell-CAM 105 and uvomorulin (UM), were compared by analysing their antigenic structures, their activity in cell aggregation assays and their expression in various tissues. Cell-CAM 105 is a membrane glycoprotein which mediates the intercellular adhesion of reaggregating rat hepatocytes, and UM was first described to be involved in the compaction of preimplantation mouse embryos and embryonal carcinoma cells. UM is not only expressed during embryonic development but also in various adult tissues including liver, epithelia of lung, gut, kidney and uterus. A similar distribution for UM was found in rat tissues on cell types where cell-CAM 105 is known to be present. Our studies show that (i) cell-CAM 105 and UM are distinct and different proteins; (ii) uvomorulin is involved in the compaction of rat preimplantation embryos but Fab anti-UM has no effect on reaggregating rat hepatocytes, where Fab anti-cell CAM is effective; (iii) distribution studies show that UM is expressed on a broader range of epithelial cells while cell-CAM 105 is more restricted to hepatocytes and simple epithelia. In cases where both cell adhesion molecules are expressed on the same cell types they can be localized to different parts of the cell surface.     

The cell adhesion molecule Cell-CAM 105 is an ecto-ATPase and a member of the immunoglobulin superfamily

Cell-CAM 105 (C-CAM), a cell adhesion molecule in rat hepatocytes, was digested with trypsin, and peptides were isolated and sequenced by Edman degradation. The sequences of 4 peptides agreed with different regions of rat liver ecto-ATPase. Detailed biochemical analyses confirmed the identity between C-CAM and the ecto-ATPase. C-CAM/ecto-ATPase is a transmembrane protein having 4 immunoglobulin-like domains in the extracellular portion, demonstrating membership of the immunoglobulin superfamily. The ATPase activity suggests that ATP might influence cell adhesion, which would explain the inhibitory effect of exogenously added ATP on adhesion of several cell types.     

Effect of human fetal liver cells on the rate of DNA and nRNA synthesis in regenerating rat liver

The model of partial hepatectomy was utilized to investigate the influence of human fetal liver cells (FLCs) and of human embryo tissue (PCF) postnuclear cytoplasm fraction injection on the rate of DNA and nRNA synthesis in regenerating rat liver cells. Single infusion of FLCs and PCF into the spleen pulp of rats has been shown to increase the DNA synthesis 24 hours after the operation in 2.5 +/- 0.4 and 3.2 +/- 0.5 times respectively. A group of rats has been identified with no influence of the infusion on the DNA synthesis 24 hours after partial hepatectomy, this process having been even retarding in 48 hours after the operation. Meanwhile the FLCs and PCF infusion enhanced the intensity of nRNA synthesis in 72 hours after the operation in all the animal groups. The effect demonstrated is probably caused by the biologically active substances contained in the fetal tissues.     

Potential neural progenitor cells in fetal liver and regenerating liver

From unfractionated embryonic mice liver cells, appreciable amount of spherical bodies containing nestin-positive cells were generated in the presence of neuronal growth factors. Following cultivation on poly-d-lysine/laminin-coated slips, approximately 70% of the cells expressed neuronal markers, and 16% had long processes. Functional analysis of these long-process-bearing cells with the whole-cell patch clamp method showed an inward current in response to glutamate, GABA, and serotonin as the neuronal characteristics. Furthermore, regenerating liver in adult mice also contained nestin-positive cells to the same extent as fetal liver. Regenerating liver could have potential as a source of neural cells for autologous transplantation.