Expression of the cell adhesion molecules N-CAM and L1 in B16 melanoma cells

The cell adhesion molecules N-CAM and L1 are important for cell-cell recognition and cell migration and so may be involved in the metastatic process. We have studied the biosynthesis of N-CAM and L1 in the B16 melanoma cell lines B16-F1 and B16-F10 which differ in metastatic capacity. N-CAM was synthesised as two glycosylated polypeptides with Mr of 150,000 and 210,000; L1 was synthesised as one polypeptide with Mr of 215,000. In fetal neurons N-CAM is synthesised as a 135,000 and a 200,000 Mr polypeptide and L1 as a 200,000 Mr polypeptide. Thus, the Mr of N-CAM and L1 in tumour cells appeared to be 10,000-15,000 higher than in the normal cells. L1 was phosphorylated in the tumour cells as in neurons. The tumour cells also phosphorylated the 210,000 Mr N-CAM polypeptide, whereas no phosphorylation of the 150,000 Mr polypeptide was observed. In neuronal cells both the corresponding polypeptides are phosphorylated and thus the biosynthesis of N-CAM in tumour cells seem to differ from that in neuronal cells with regard to phosphorylation. No differences in biosynthesis of N-CAM or L1 were apparent between the two tumour cell lines, B16-F1 and B16-F10.     

Characterization of the cell adhesion molecules L1, N-CAM and J1 in the mouse intestine.

To gain insight into the cellular and molecular mechanisms underlying epithelial cell surface interactions in the adult mouse intestine, we have characterized the cell adhesion molecules L1, N-CAM and J1 by immunocytological, biochemical and cell biological methods. Whereas N-CAM and J1 expression was found to be confined to the mesenchymal and neuroectodermally-derived parts of the intestine, L1 was localized in the proliferating epithelial progenitor cells of crypts, but not in the more differentiated epithelial cells of villi. L1 was detected in crypt cells by Western blot analysis in the molecular forms characteristic of peripheral neural cells, with apparent mol. wts of 230, 180 and 150 kd. Aggregation of single, enriched crypt, but not villus cells, was strongly inhibited in the presence of Fab fragments of polyclonal L1 antibodies. These observations show that L1 is not confined to the nervous system and that it may play a functional role in the histogenesis of the intestine in the adult animal.     

In situ chemical cross-linking on living cells reveals CD9P-1 cis-oligomer at cell surface

Tetraspanins are integral membrane proteins involved in a variety of physiological and pathological processes. They associate with each other in multimolecular complexes containing numerous membrane proteins. As a first step towards the study of the supramolecular organization of tetraspanin complexes, we have implemented a proteomic approach based on in situ protein cross-linking on living cells followed by affinity purification of tetraspanin complexes. This allowed observing the presence of high molecular weight protein complexes that were characterized as containing CD9P-1/CD315 using LC-MS/MS. Western blot analyses and the use of different tags demonstrated the presence of CD9P-1 oligomer in cis-association at cell surface. A significant amount of CD9P-1 oligomer was observed on various cell types. We have shown that CD9P-1 self-associates independently from its association with tetraspanins. However, the expression level of CD9 or CD81 that associate directly and specifically with CD9P-1, positively modulates the cross-linking efficiency of CD9P-1. Thus, tetraspanins can play a role on CD9P-1 oligomerization status.     

Expression of L1 and N-CAM cell adhesion molecules during development of the mouse olfactory system

The expression of the neural adhesion molecules L1 and N-CAM has been studied in the embryonic and early postnatal olfactory system of the mouse in order to gain insight into the function of these molecules during development of a neural structure which retains neuronal turnover capacities throughout adulthood. N-CAM was slightly expressed and L1 was not significantly expressed in the olfactory placode on Embryonic Day 9, the earliest stage tested. Rather, N-CAM was strongly expressed in the mesenchyme underlying the olfactory placode. In the developing nasal pit, L1 and N-CAM were detectable in the developing olfactory epithelium, but not in regions developing into the respiratory epithelium. At early developmental stages, expression of the so-called embryonic form of N-CAM (E-N-CAM) coincides with the expression of N-CAM, whereas at later developmental stages and in the adult it is restricted to a smaller number of sensory cell bodies and axons, suggesting that the less adhesive embryonic form is characteristic of morphogenetically dynamic neuronal structures. Moreover, E-N-CAM is highly expressed at contact sites between olfactory axons and their target cells in the glomeruli of the olfactory bulb. L1 and N-CAM 180, the component of N-CAM that accumulates at cell contacts by interaction with the cytoskeleton are detectable as early as the first axons extend toward the primordial olfactory bulb. L1 remains prominent throughout development on axonal processes, both at contacts with other axons and with ensheathing cells. Contrary to N-CAM 180 which remains detectable on differentiating sensory neuronal cell bodies, L1 is only transiently expressed on these and is no longer detectable on primary olfactory neuronal cell bodies in the adult. Furthermore, whereas throughout development L1 has a molecular form similar to that seen in other parts of the developing and adult central nervous systems, N-CAM and, in particular, N-CAM 180 retain their highly sialylated form at least partially throughout all ages studied. These observations suggest that E-N-CAM and N-CAM 180 are characteristic of developmentally active structures and L1 may not only be involved in neurite outgrowth, but also in stabilization of contacts among fasciculating axons and between axons and ensheathing cells, as it has previously been found in the developing peripheral nervous system.     

In situ chemical cross-linking on living cells reveals CD9P-1 cis-oligomer at cell surface

Tetraspanins are integral membrane proteins involved in a variety of physiological and pathological processes. They associate with each other in multimolecular complexes containing numerous membrane proteins. As a first step towards the study of the supramolecular organization of tetraspanin complexes, we have implemented a proteomic approach based on in situ protein cross-linking on living cells followed by affinity purification of tetraspanin complexes. This allowed observing the presence of high molecular weight protein complexes that were characterized as containing CD9P-1/CD315 using LC-MS/MS. Western blot analyses and the use of different tags demonstrated the presence of CD9P-1 oligomer in cis-association at cell surface. A significant amount of CD9P-1 oligomer was observed on various cell types. We have shown that CD9P-1 self-associates independently from its association with tetraspanins. However, the expression level of CD9 or CD81 that associate directly and specifically with CD9P-1, positively modulates the cross-linking efficiency of CD9P-1. Thus, tetraspanins can play a role on CD9P-1 oligomerization status.     

Immunoelectron microscopic localization of the neural cell adhesion molecules L1 and N-CAM during postnatal development of the mouse cerebellum

The cellular and subcellular localization of the neural cell adhesion molecules L1 and N-CAM was studied by pre- and postembedding immunoelectron microscopic labeling procedures in the developing mouse cerebellar cortex. The salient features of the study are: L1 displays a previously unrecognized restricted expression by particular neuronal cell types (i.e., it is expressed by granule cells but not by stellate and basket cells) and by particular subcellular compartments (i.e., it is expressed on axons but not on dendrites or cell bodies of Purkinje cells). L1 is always expressed on fasciculating axons and on postmitotic, premigratory, and migrating granule cells at sites of neuron-neuron contact, but never at contact sites between neuron and glia, thus strengthening the view that L1 is not involved in granule cell migration as a neuron-glia adhesion molecule. While N-CAM antibodies reacting with the three major components of N-CAM (180, 140, and 120 kD) show a rather uniform labeling of all cell types, antibodies to the 180-kD component (N-CAM180) stain only the postmigratory granule cell bodies supporting the notion that N-CAM180, the N-CAM component with the longest cytoplasmic domain, is not expressed before stable cell contacts are formed. Furthermore, N-CAM180 is only transiently expressed on Purkinje cell dendrites. N-CAM is present in synapses on both pre- and post-synaptic membranes. L1 is expressed only preterminally and not in the subsynaptic membranes. These observations indicate an exquisite degree of fine tuning in adhesion molecule expression during neural development and suggest a rich combinatorial repertoire in the specification of cell surface contacts.     

Expression of the adhesion molecules L1, N-CAM and J1/tenascin during development of the murine small intestine

We have previously studied the immunohistological localization of the three adhesion molecules L1, N-CAM and J1/tenascin in adult mouse small intestine and shown that L1 expression in epithelial crypt cells underlies the adhesion of these cells to one another [63]. To obtain further insight into the functional roles of L1, N-CAM and J1/tenascin in this organ we studied their expression starting at embryonic day 14 during embryonic and early postnatal morphogenesis and during epithelial cell migration in the adult. Expression of L1 was restricted to neural cells until approximately postnatal day 5, when L1 started to be detectable on crypt but not on villus cells, predominantly on the basolateral membrane infoldings. As in brain, L1-specific mRNA was approximately 6 kb in size. L1 from intestine appears to differ from the brain-derived equivalent in possessing a higher level of glycosylation. N-CAM was detectable from embryonic day 14 onward in neural and also in mesenchymal cells. Expression by smooth muscle cells decreased during development. In the villus core, N-CAM was strongly detectable at contact sites between smooth muscle cells forming the cellular scaffold of the villus. From embryonic day 14 onward, N-CAM appeared in both 180- and 140-kDa forms. J1/tenascin was present in both neural and mesenchymal cells from embryonic day 14 onward. Starting at embryonic day 17, J1/tenascin appeared concentrated at the boundary between mesenchyme and epithelium in an increasing gradient from the crypt base to the villus top. From embryonic day 14 onward J1/tenascin consisted of the 190- and 220-kDa components. J1/tenascin from intestine differed from brain-derived J1 in its carbohydrate composition. These observations show that the three adhesion molecules are expressed by distinct cell populations and may serve as cell-type-specific markers in pathologically altered intestinal tissue.     

Analysis of lectin-specific cell surface glycoprotein on neuroblastoma cells

The binding sites for the lectins wheat germ agglutinin, Ricinus communis agglutinin and concanavalin A on mouse neuroblastoma cell membranes were identified using SDS-gel electrophoresis in combination with fluorescent lectins. Ricinus communis agglutinin and wheat germ agglutinin were found to bind almost exclusively to a single polypeptide with an apparent molecular weight of 30 000. Concanavalin A labeled over 20 different polypeptides, most with molecular weights greater than 50 000. However, when the neuroblastoma cells were treated with concanavalin A so as to internalize all the concanavalin A binding sites visible at the level of the fluorescent microscope and the purified plasma membranes analyzed for their concanavalin A binding polypeptides, only four of the 20 glycopolypeptides were missing or significantly reduced in amount. Thus, these four high molecular weight concanavalin A-binding polypeptides appear to be the major cell surface receptors for concanavalin A. Binding studies with iodinated concanavalin A indicated that these polypeptides represented the high affinity concanavalin A binding sites $\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 2 · 10}{}^{\mathrm{?7}}\text{M}$). Low affinity concanavalin A binding sites were present on the cell surface after internalization of high affinity concanavalin A binding sites.     

Expression of the cell adhesion molecules, L-CAM and N-CAM during avian scale development

To examine the involvement of cell adhesion molecules in the inductive epithelial-mesenchymal interactions during avian scale development, a study of the spatiotemporal distribution of L-CAM and N-CAM was undertaken. During scutate scale development, L-CAM and N-CAM are expressed together in cells of the transient embryonic layers destined to be lost at hatching. The ongoing linkage of the cells of these layers by both CAMs sets them apart, early in development, as unique cell populations. L-CAM and N-CAM were also expressed simultaneously at the basal surface of the early germinative cells where signal transduction is presumed to occur. In spite of the differences in cell shape, adhesion, density and proliferative state between populations of epidermal placode and interplacode cells, the expression of L-CAM and N-CAM appeared to be uniform and nondiscriminating for these discrete cell lineages. The same pattern of L-CAM and N-CAM expression was observed during morphogenesis of reticulate scales that develop without placode formation. While L-CAM and N-CAM are present during the early stages of scale development and most likely function in cell adhesion, the data do not support a role for these adhesion molecules in the formation of the morphogenetically critical placode and interplacode cell populations. In both scale types, L-CAM became predominantly epithelial, and N-CAM became predominantly dermal as histogenesis occurred. Initially, N-CAM was concentrated near the basal lamina where it may be involved in the reciprocal epidermal-dermal interactions required for morphogenesis. However, as development of the scales progressed, N-CAM disappeared from the tissues. L-CAM expression continued in the epidermis and was intense on all suprabasal cells undergoing differentiation into either an alpha-stratum or beta-stratum. However, L-CAM was more prevalent on the basal cells of alpha-keratinizing regions than on the basal cells of beta-keratinizing regions.     

Immunoelectron microscopic localization of neural cell adhesion molecules (L1, N-CAM, and myelin-associated glycoprotein) in regenerating adult mouse sciatic nerve

The localization of the neural cell adhesion molecules L1, N-CAM, and the myelin-associated glycoprotein was studied by pre- and postembedding staining procedures at the light and electron microscopic levels in transected and crushed adult mouse sciatic nerve. During the first 2-6 d after transection, myelinated and nonmyelinated axons degenerated in the distal part of the proximal stump close to the transection site and over the entire length of the distal part of the transected nerve. During this time, regrowing axons were seen only in the proximal, but not in the distal nerve stump. In most cases L1 and N-CAM remained detectable at cell contacts between nonmyelinating Schwann cells and degenerating axons as long as these were still morphologically intact. Similarly, myelin-associated glycoprotein remained detectable in the periaxonal area of the degenerating myelinated axons. During and after degeneration of axons, nonmyelinating Schwann cells formed slender processes which were L1 and N-CAM positive. They resembled small-diameter axons but could be unequivocally identified as Schwann cells by chronical denervation. Unlike the nonmyelinating Schwann cells, only few myelinating ones expressed L1 and N-CAM. At the cut ends of the nerve stumps a cap developed (more at the proximal than at the distal stump) that contained S-100-negative and fibronectin-positive fibroblast-like cells. Most of these cells were N-CAM positive but always L1 negative. Growth cones and regrowing axons expressed N-CAM and L1 at contact sites with these cells. Regrowing axons of small diameter were L1 and N-CAM positive where they made contact with each other or with Schwann cells, while large-diameter axons were only poorly antigen positive or completely negative. 14 d after transection, when regrowing axons were seen in the distal part of the transected nerve, regrowing axons made L1- and N-CAM-positive contacts with Schwann cells. When contacting basement membrane, axons were rarely found to express L1 and N-CAM. Most, if not all, Schwann cells associated with degenerating myelin expressed L1 and N-CAM. In crushed nerves, the immunostaining pattern was essentially the same as in the cut nerve. During formation of myelin, the sequence of adhesion molecule expression was the same as during development: L1 disappeared and N-CAM was reduced on myelinating Schwann cells and axons after the Schwann cell process had turned approximately 1.5 loops around the axon. Myelin-associated glycoprotein then appeared both periaxonally and on the turning loops of Schwann cells in the uncompacted myelin.(ABSTRACT TRUNCATED AT 400 WORDS)     

The transferrin receptor and the tetraspanin web molecules CD9, CD81, and CD9P-1 are differentially sorted into exosomes after TPA treatment of K562 cells

Here we show that treatment of K562 cells with the phorbol ester TPA induces the down-modulation of various surface antigens. Among them, the transferrin receptor (TfR), the tetraspanin CD81, and a CD81-associated protein, CD9P-1, were unique in that their expression levels were lower after 24 h incubation than after 3 h. We demonstrated that like the TfR, CD81 was internalized at early times, and was less synthesized at latter times. Despite the association of a fraction of the TfR with CD81, these two molecules were subjected to different fates. TPA increased targeting of CD81 and CD9P-1 into exosomes but strongly reduced the localization of the TfR in these vesicles. Using this model we have shown that a fraction of CD81 and CD9P-1 in exosomes comes from a surface pool and that these molecules remain associated in exosomes. However, CD9P-1 could be targeted to exosomes in the absence of CD81 and of another tetraspanin, CD9. The targeting of CD9 into exosomes did not require palmitoylation of the protein. J. Cell. Biochem. 102: 650-664, 2007. (c) 2007 Wiley-Liss, Inc.     

Expression of the neural cell adhesion molecules L1 and N-CAM and their common carbohydrate epitope L2/HNK-1 during development and after transection of the mouse sciatic nerve

The expression of the neural cell adhesion molecules L1 and N-CAM and of their shared carbohydrate epitope L2/HNK-1 was studied during the development and after the transection of mouse sciatic nerves. During development, L1 and N-CAM were detectable on most, if not all, Schwann cells at embryonic day 17, the earliest stage tested. With increasing age, the immunoreactivity was reduced being confined to non-myelinating Schwann cells by post-natal day 10, at which stage the staining pattern resembled that seen in adult sciatic nerves. Double-immunolabelling experiments revealed a complete overlap between L1 and N-CAM antibodies. The L2/HNK-1 epitope was not detectable in developing sciatic nerves until the end of the 2nd post-natal week, when it appeared to be associated with the outer profiles of thick myelin sheets, as also seen in adult sciatic nerves. Three days after the transection of adult sciatic nerves, L1 antigen and N-CAM was detectable in more Schwann cells in the distal nerve end than in untreated control nerves. The peak level of the reappearance of L1 antigen and N-CAM in Schwann cells occurred between 2 and 4 weeks after transection. The reduction of L1-antigen expression to its normal adult level took more than a year, thus recapitulating normal development, but on a more protracted time scale. Similarly, the L2/HNK-1 epitope remained undetectable until the transected nerve had returned to its normal state of myelination, i.e. approximately 1 year after transection.     

Inhibition of CD62L+ T-cell response in vitro via a novel sulfo-glycolipid, beta-SQAG9 liposome that binds to CD62L molecule on the cell surface

We previously reported that synthetic sulfo-glycolipid, 3-O-(6-deoxy-6-sulfono-beta-D-glucopyranosyl)-1,2-di-O-acylglycerol (beta-SQDG(18:0)) which was deduced from sulfonoquinovosyl-diacylglycerols of sea urchin possessed immunosuppressive effects, such as human mixed lymphocyte reaction (MLR) and skin allograft in rat, and that these effects were caused by contact inhibition between T-cells and antigen presenting cells (APCs). Here, we investigated the mechanism of these immunosuppressive effects on human MLR by beta-SQAG9 which had been newly synthesized from beta-SQDG(18:0) to improve structural stability in water solution. CD62L+ T-cells in peripheral blood predominantly respond to APCs, and beta-SQAG9 inhibited the response of CD62L+ T-cell subset in human allogeneic MLR. Surprisingly, it was demonstrated that beta-SQAG9 bound to L- and P-selectin (CD62L and P) molecule in vitro. Meanwhile, beta-SQAG9 efficiently formed liposome structure and bound to L-selectin on the cell surface of CD62L+ T-cell subset but might not be incorporated into the cells. Because the immunosuppressive effects of beta-SQAG9 disappeared when beta-SQAG9 liposome was changed to soluble form by detergent, the liposome structure of beta-SQAG9 was presumed to be essential for these effects. These findings suggested beta-SQAG9 to be a novel drug with a unique immunosuppressive action.     

Association of the CD59 and CD55 cell surface glycoproteins with other membrane molecules.

mAb against human glycosyl-phosphatidylinositol-linked leucocyte surface Ag CD59 and CD55 immunoprecipitated from detergent lysates of HPB ALL cell line in addition to the respective Ag a common 80-kDa glycoprotein component and (glyco)lipids. The 80-kDa glycoprotein is different from otherwise similar CD44 Ag. The CD59 immunoprecipitate contained also a small amount of the CD55 glycoprotein and the CD55 immunoprecipitate minute amount of the CD59 Ag. These results are interpreted in terms of existence of noncovalent complexes resistant to dissociation by mild detergents and consisting of the 80-kDa glycoprotein, CD59 and CD55 glycoproteins, relatively tightly bound (glyco)lipids and possibly other so far unidentified components. These complexes contain probably also other glycosyl-phosphatidylinositol-linked Ag, as an anti-CD48 mAb immunoprecipitated also an apparently very similar complex. The complexes immunoprecipitated by mAb against the CD55, CD59, and CD48 Ag also contain a protein kinase activity. This type of complexes could not be demonstrated in several other cell types such as RBC, PBMC, and HeLa cells. However, a qualitatively very similar set of components was immunoprecipitated from the murine thymoma EL-4 cell line by an anti-Thy-1 mAb.     

The Nef protein of HIV-1 induces loss of cell surface costimulatory molecules CD80 and CD86 in APCs

The Nef protein of HIV-1 is essential for its pathogenicity and is known to down-regulate MHC expression on infected cell surfaces. We now show that Nef also redistributes the costimulatory molecules CD80 and CD86 away from the cell surface in the human monocytic U937 cell line as well as in mouse macrophages and dendritic cells. Furthermore, HIV-1-infected U937 cells and human blood-derived macrophages show a similar loss of cell surface CD80 and CD86. Nef colocalizes with MHC class I (MHCI), CD80, and CD86 in intracellular compartments, and binds to both mouse and human CD80 and CD86. Some Nef mutants defective in MHCI down-modulation, including one from a clinical isolate, remain capable of down-modulating CD80 and CD86. Nef-mediated loss of surface CD80/CD86 is functionally significant, because it leads to compromised activation of naive T cells. This novel immunomodulatory role of Nef may be of potential importance in explaining the correlations of macrophage-tropism and Nef with HIV-1 pathogenicity and immune evasion.