Pleiomorphic mouse sarcoma S180 cells were transfected with cDNAs for the liver cell adhesion molecule (L-CAM), the neural cell adhesion molecule (N-CAM), or both CAMs. Transfected cells expressed the appropriate CAMs at their surface and those expressing L-CAM (S180L cells) changed from adjoining spindle or round shapes to a closely linked "epithelioid" sheet when grown to confluence. Cells transfected with cDNA for N-CAM (S180N cells) also expressed this CAM on the cell surfaces and bound brain vesicles containing N-CAM but showed no phenotypic change to an epithelioid state. In S180L cells and doubly transfected (S180L/N) cells, L-CAM was concentrated at regions of cell contact and was codistributed with cortical actin. In S180N cells, N-CAM was uniformly distributed on the cell surface. When S180L cells were cocultured with S180L/N cells, N-CAM was not concentrated at boundaries between the S180L and S180L/N cells but was concentrated at boundaries between pairs of S180L/N cells. Fab' fragments of anti-L-CAM dissociated the epithelioid sheets of S180L or S180L/N cells into cells with shapes resembling those of untransfected cells. Cells in epithelioid sheets were polygonal in shape but, unlike cells in true epithelia, had no basement membrane or polar structure; they also lacked tight junctions and desmosomes. Ultrastructural examination showed that, in contrast to the untransfected phenotype, cells in epithelioid sheets had large increases in adherens junctions and gap junctions. Dye coupling experiments indicated that the gap junctions were functional. The frequency of expression of both kinds of junctions was sharply decreased by treatment with anti-L-CAM Fab' fragments. These experiments provide support for the precedence hypothesis, which proposes that the linkage of cells by means of CAMs is a necessary event for the extensive expression of junctional structures.
We have developed a method for purifying L-CAM, the cell adhesion molecule from embryonic chicken liver cells, and have compared its properties with those of N-CAM, the neural cell adhesion molecule. L-CAM was released from membranes with trypsin, purified by a series of chemical techniques, and used to generate monoclonal antibodies which allowed the identification of the intact L-CAM molecule from membranes.
N-CAM, the neural cell-adhesion molecule, has previously been found to be expressed during several epochs of development and function, first as an early marker in embryo-genesis, later during organogenesis, and finally in adult life. L-CAM, the liver cell-adhesion molecule, has now been localized in embryonic and adult tissues of the chicken by fluorescent antibody techniques. In the early embryonic epoch, L-CAM and N-CAM appeared in epiblastic and hypoblastic tissues. L-CAM was distributed thereafter across all three germ layers. By the onset of neurulation, however, L-CAM disappeared in the region of the neural plate and N-CAM increased in amount in that region. L-CAM appeared strongly on all budding endodermal structures (liver, pancreas, lung, thyroid, parathyroid, thymus, and bursa of Fabricius) whereas N-CAM appeared most strongly in the neural plate, neural tube, and in cardiac mesoderm but was not found in endodermal derivatives. In placodes, both L-CAM and N-CAM were present until the formation of definitive neural structures, at which time L-CAM disappeared. In kidney precursors, the two CAMs followed a complex reciprocal pattern of appearance and disappearance. For the most part, however, the distributions of the two molecules did not overlap during organogenesis. Like N-CAM, L-CAM persisted in a distinctive pattern of expression in adult tissues. During embryonic development, the two different CAMs were distributed on tissues derived from more than two-thirds of the early embryonic surface. Interpretation of maps summarizing CAM distributions over a defined developmental epoch suggested a key role for both L-CAM and N-CAM in embryonic induction. Consistent with this interpretation and with the fact that the continuity of germ layers is lost when organ rudiments are formed, neither of the CAMs was limited in distribution to a single germ layer. The regions of the early epochal maps that lacked both L-CAM and N-CAM comprised some portions of the splanchnopleure and somatopleure. Certain adult tissues that derive from this lateral plate mesoderm such as smooth muscle also lacked L-CAM and N-CAM. Such observations suggest that at least one more CAM may exist in these and similarly derived tissues.
We report here that unlike what was suggested for many vertebrate neurons, synaptic transmission in Lymnaea stagnalis occurs independent of a physical interaction between presynaptic calcium channels and a functional complement of SNARE proteins. Instead, synaptic transmission in Lymnaea requires the expression of a C-terminal splice variant of the Lymnaea homolog to mammalian N- and P/Q-type calcium channels. We show that the alternately spliced region physically interacts with the scaffolding proteins Mint1 and CASK, and that synaptic transmission is abolished following RNA interference knockdown of CASK or after the injection of peptide sequences designed to disrupt the calcium channel-Mint1 interactions. Our data suggest that Mint1 and CASK may serve to localize the non-L-type channels at the active zone and that synaptic transmission in invertebrate neurons utilizes a mechanism for optimizing calcium entry, which occurs independently of a physical association between calcium channels and SNARE proteins.
The liver cell adhesion molecule (L-CAM) appears on non-neural epithelial tissues and mediates calciumdependent adhesion in these tissues both in the embryo and in the adult. It appears on cell surfaces as a glycoprotein of Mr 124,000 but is synthesized as a precursor of Mr 135,000. We have isolated and determined the nucleic acid sequence of a cDNA clone (XL320) encoding chicken L-CAM. The 5' end of this clone has an open reading frame extending for 2520 base pairs, followed by an 850-base-pair untranslated region terminating with a polyadenylylation site at its 3' end. Protein sequence analysis of intact L-CAM and of cyanogen bromide fragments of the protein confirmed the reading frame and indicated that XL320 encodes the complete sequence of L-CAM as it is expressed on the cell surface as well as the bulk of the precursor. The sequence includes a hydrophobic segment of 31 amino acids, supporting our earlier conclusion that L-CAM is an intrinsic membrane protein. There are five potential asparagine glycosylation sites on the extracellular part of the molecule and an intracellular domain that is phosphorylated in vivo. The mature L-CAM polypeptide consists of 727 amino acids, with a calculated Mr of 79,900 for the carbohydrate-free protein. The L-CAM sequence is not homologous to other known protein sequences, including those of the neural cell adhesion molecule (N-CAM) and other members of the immunoglobulin superfamily, but the L-CAM molecule does contain three contiguous segments (113 amino acids each) that are homologous to each other. The similarities among these segments suggest that at least part of the L-CAM molecule arose by gene duplication.
Abstract. The liver cell adhesion molecule (L-CAM) and N-cadherin or adherens junction-specific CAM (A-CAM) are structurally related cell surface glycoproteins that mediate calcium-dependent adhesion in different tissues. We have isolated and characterized a full-length cDNA clone for chicken N-cadherin and used this clone to transfect S180 mouse sarcoma cells that do not normally express N-cadherin. The transfected cells (S180cadN cells) expressed N-cadherin on their surfaces and resembled S180 cells transfected with L-CAM (S180L cells) in that at confluence they formed an epithelioid sheet and displayed a large increase in the number of adherens and gap junctions. In addition, N-cadherin in S180cadN cells, like L-CAM in S180L ceils, accumulated at cellular boundaries where it was colocalized with cortical actin. In S180L ceils and S180cadN cells, L-CAM and N-cadherin were seen at sites of adherens junctions but were not restricted to these areas. Adhesion mediated by either CAM was inhibited by treatment with cytochalasin D that disrupted the actin network of the transfected cells. Despite their known structural similarities, there was no evidence of interaction between L-CAM and N-cadherin.Doubly transfected cells (S180L/cadN) also formed epithelioid sheets. In these cells, both N-cadherin and L-CAM colocalized at areas of cell contact and the presence of antibodies to both CAMs was required to disrupt the sheets of cells. Studies using divalent antibodies to localize each CAM at the cell surface or to perturb their distributions indicated that in the same cell there were no interactions between L-CAM and N-cadherin molecules.These data suggest that the Ca++-dependent CAMs are likely to play a critical role in the maintenance of epithelial structures and support a model for the segregation of epithelia based on differences in specificity of CAM mediated binding. They also provide further support for the so-called precedence hypothesis that proposes that expression and homophilic binding of CAMs are necessary for formation of junctional structures in epithelia.
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