The modulation of cell adhesion molecule expression and intercellular junction formation in the developing avian inner ear

The cells that constitute the membranous labyrinth in the vertebrate inner ear are all derived from a single embryonic source, namely, the otocyst. The mature inner ear epithelia contain different regions with highly differentiated cells, displaying a highly specialized cytoarchitecture. The present study was designed to determine the presence of adherens-type intercellular junctions in this tissue and study the expression of cell adhesion molecules (CAMs) associated with these junctions, namely, A-CAM and L-CAM, in the developing avian inner ear epithelia. The results presented here show that throughout the early otocyst, A-CAM is coexpressed with L-CAM. The formation of asymmetries between sensory and nonsensory areas in the epithelium is accompanied by the modulation of CAMs expression and the assembly of intercellular junctional complexes. A-CAM and L-CAM display reciprocal expression patterns, the former being expressed mostly in the mosaic sensory epithelium, while L-CAM becomes conspicuous in the nonsensory areas but its expression in the sensory region is markedly reduced. Adherens-type junctions and numerous desmosomes are found in the junctional complexes of early otocyst cells. The former persist to maturity of the various inner ear epithelia, whereas desmosomes disappear from junctional complexes of hair cells but remain in the intercellular junctional complexes of all other cell types in the membranous labyrinth. Thus, adherens type intercellular junctions comprise the only defined cytoskeleton-bound junction in mature hair cells. A-CAM-positive cells are also found in the region of the acoustic ganglion in early developmental stages but not in the mature neural elements.     

Formation of heterotypic adherens-type junctions between L-CAM-containing liver cells and A-CAM-containing lens cells

Cultured cells from either chicken lens or liver plated on solid substrates form flat epithelial sheets with adherens-type junctions between them. In lens cells these junctions contain A-CAM, while the same type of intercellular junctions in liver cells contain another cell adhesion molecule, L-CAM. Coculturing of lens and liver cells in the same dish resulted in the formation of mixed (heterotypic) adherens junctions. Double immunofluorescent labeling for both A-CAM and L-CAM indicated that the mixed junctions contained both molecules, each of which was present on one of the two partner cells. Moreover, the formation of the heterotypic junctions could be effectively inhibited by both anti-A-CAM and anti-L-CAM antibodies. It has thus been proposed that A-CAM and L-CAM share significant functional homology and may be involved in heterophilic interactions leading to the establishment of molecularly and cellularly asymmetrical adherens-type junctions.     

Expression sequences and distribution of two primary cell adhesion molecules during embryonic development of Xenopus laevis

Studies of chicken embryos have demonstrated that cell adhesion molecules are important in embryonic induction and are expressed in defined sequences during embryogenesis and histogenesis. To extend these observations and to provide comparable evidence for heterochronic changes in such sequences during evolution, the local distributions of the neural cell adhesion molecule (N-CAM) and of the liver cell adhesion molecule (L-CAM) were examined in Xenopus laevis embryos by immunohistochemical and biochemical techniques. Because of the technical difficulties presented by the existence of multiple polypeptide forms of CAMs and by autofluorescence of yolk-containing cells, special care was taken in choosing and characterizing antibodies, fluorophores, and embedding procedures. Both N-CAM and L-CAM were found at low levels in pregastrulation embryos. During gastrulation, N-CAM levels increased in the presumptive neural epithelium and decreased in the endoderm, but L-CAM continued to be expressed in all cells including endodermal cells. During neurulation, the level of N-CAM expression in the neural ectoderm increased considerably, while remaining constant in non-neural ectoderm and diminishing in the somites; in the notochord, N-CAM was expressed transiently. Prevalence modulation was also seen at all sites of secondary induction: both CAMs increased in the sensory layer of the ectoderm during condensation of the placodes. During organogenesis, the expression of L-CAM gradually diminished in the nervous system while N-CAM expression remained high. In all other organs examined, the amount of one or the other CAM decreased, so that by stage 50 these two molecules were expressed in non-overlapping territories. Embryonic and adult tissues were compared to search for concordance of CAM expression at later stages. With few exceptions, the tissue distributions of N-CAM and L-CAM were similar in the frog and in the chicken from early times of development. In contrast to previous observations in the chicken and in the mouse, N-CAM expression was found to be high in the adult liver of Xenopus, whereas L-CAM expression was low. In the adult brain, N-CAM was expressed as three components of apparent molecular mass 180, 140, and 120 kD, respectively; in earlier stages of development only the 140-kD component could be detected. In the liver, a single N-CAM band appears at 160 kD, raising the possibility that this band represents an unusual N-CAM polypeptide. L-CAM appeared at all stages as a 124-kD molecule.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of intercellular adhesion strength in fibroblasts

The regulation of adherens junction formation in cells of mesenchymal lineage is of critical importance in tumorigenesis but is poorly characterized. As actin filaments are crucial components of adherens junction assembly, we studied the role of gelsolin, a calcium-dependent, actin severing protein, in the formation of N-cadherin-mediated intercellular adhesions. With a homotypic, donor-acceptor cell model and plates or beads coated with recombinant N-cadherin-Fc chimeric protein, we found that gelsolin spatially co-localizes to, and is transiently associated with, cadherin adhesion complexes. Fibroblasts from gelsolin-null mice exhibited marked reductions in kinetics and strengthening of N-cadherin-dependent junctions when compared with wild-type cells. Experiments with lanthanum chloride (250 microm) showed that adhesion strength was dependent on entry of calcium ions subsequent to N-cadherin ligation. Cadherin-associated gelsolin severing activity was required for localized actin assembly as determined by rhodamine actin monomer incorporation onto actin barbed ends at intercellular adhesion sites. Scanning electron microscopy showed that gelsolin was an important determinant of actin filament architecture of adherens junctions at nascent N-cadherin-mediated contacts. These data indicate that increased actin barbed end generation by the severing activity of gelsolin associated with N-cadherin regulates intercellular adhesion strength.     

ARHGAP10 is necessary for alpha-catenin recruitment at adherens junctions and for Listeria invasion

E-cadherin mediates the formation of adherens junctions between epithelial cells. It serves as a receptor for Listeria monocytogenes, a bacterial pathogen that enters epithelial cells. The L. monocytogenes surface protein, InlA, interacts with the extracellular domain of E-cadherin. In adherens junctions, this ectodomain is involved in homophilic interactions whereas the cytoplasmic domain binds beta-catenin, which then recruits alpha-catenin. alpha-catenin binds to actin directly, or indirectly, thus linking E-cadherin to the actin cytoskeleton. Entry of L. monocytogenes into cells and adherens junction formation are dynamic events that involve actin and membrane rearrangements. To understand these processes better, we searched for new ligands of alpha-catenin. Using a two-hybrid screen, we identified a new partner of alpha-catenin: ARHGAP10. This protein colocalized with alpha-catenin at cell-cell junctions and was recruited at L. monocytogenes entry sites. In ARHGAP10-knockdown cells, L. monocytogenes entry and alpha-catenin recruitment at cell-cell contacts were impaired. The GAP domain of ARHGAP10 has GAP activity for RhoA and Cdc42. Its overexpression disrupted actin cables, enhanced alpha-catenin and cortical actin levels at cell-cell junctions and inhibited L. monocytogenes entry. Altogether, our results show that ARHGAP10 is a new component of cell-cell junctions that controls alpha-catenin recruitment and has a key role during L. monocytogenes uptake.     

N-cadherin and Cx43alpha1 gap junctions modulates mouse neural crest cell motility via distinct pathways

Our previous studies showed an essential role for connexin 43 or alpha1 connexin (Cx43alpha1) gap junctions in the modulation of neural crest cell motility. Cx43alpha1 gap junctions and N-cadherin containing adherens junctions are expressed in migrating cardiac neural crest cells. Analysis of the N-cadherin knockout (KO) mouse model revealed that N-cadherin is essential for gap junction mediated dye coupling but not for expression of Cx43alpha1 gap junctions in neural crest cells. Time lapse videomicroscopy and motion analysis showed that the motility of N-cadherin KO neural crest cells were altered, but the motility changes differed compared to Cx43alpha1 KO neural crest cells. These observations suggest that the role of N-cadherin in cell motility is not simply mediated via the modulation of Cx43alpha1 mediated cell-cell communication. This was confirmed by a parallel analysis of wnt-1 deficient neural crest cells, which also showed a reduction in dye coupling, and yet no change in cell motility. Analysis of p120 catenin (p120ctn), an Amardillo family protein known to play a role in cell motility, showed that it is colocalized with N-cadherin and Cx43alpha1 in migrating neural crest cells. This subcellular distribution was altered in the N-cadherin and Cx43alpha1 KO neural crest cells. Given these results, we propose that N-cadherin and Cx43alpha1 may modulate neural crest cell motility by engaging in a dynamic cross-talk with the cell's locomotory apparatus through p120ctn signaling.     

Expression of cell-adhesion molecules in embryonic induction. II. Morphogenesis of adult feathers

The developmental appearance of cell-adhesion molecules (CAMs) was mapped during the morphogenesis of the adult chicken feather. Neural CAM (N-CAM), liver CAM (L-CAM), and neuron-glia CAM (Ng-CAM), as well as substrate molecules (laminin and fibronectin), were compared in newborn chicken skin by immunohistochemical means. N-CAM was found to be enriched in the dermal papilla, which was closely apposed to L-CAM-positive papillar ectoderm. The two CAMs were then co-expressed in cells of the collar epithelium. Subsequently generated barb epithelia expressed only L-CAM, but N-CAM reappeared periodically on cells between developing barbs and barbules. N-CAM first appeared on a single L-CAM-positive basilar cell located in each valley flanked by two adjacent barb ridges. Subsequently, the expression of N-CAM extended one cell after another to include the whole basilar layer. N-CAM also appeared in the L-CAM-positive axial-plate epithelia, beginning in a single cell located at the ridge base. The two collectives of N-CAM-positive epithelia constituting the marginal and axial plates then disintegrated, leaving interdigitating spaces between keratinized structures that had previously expressed L-CAM. The morphological transformation from an epithelial cylinder to a three-level branched feather pattern is thus achieved by coupling alternating CAM expression in linked cell collectives with specific differentiation events, such as keratinization. During all of these morphogenetic processes, laminin and fibronectin formed a continuous basement membrane separating pulp from feather epithelia, and were excluded from the sites involved in periodic appearances of N-CAM. The same staining pattern described for developing chickens persisted in the feather follicles of adult chicken tissue that have gone through several cycles of molting. Cyclic expression of the two different CAMs underlies each of the different morphological events that are generated epigenetically during feather morphogenesis.     

Regulation of ezrin localization by Rac1 and PIPK in human epithelial cells

Regulation of ezrin and other ERM proteins is not completely understood, but the involvement of Rho GTPases seems crucial. In this work, expression plasmids encoding full-length, deleted or truncated ezrin were constructed and coexpressed with Rac1 GTPase in HeLa human epithelial cells in order to elucidate the mechanisms of ezrin activation and function. We observed induction of actin stress fiber formation by ezrin constructs harboring the F-actin binding site but devoid of sequences required for intra- or intermolecular binding. Stress fiber-inducing ezrin mutants were localized in adherens junctions containing N-cadherin but no E-cadherin, and also colocalized with F-actin in stress fibers. This localization required the activity of Rac1 and phosphatidylinositol-4-phosphate 5-kinase and involved RhoA. We suggest that localization of ezrin in adherens junctions is regulated by Rac in a manner involving PIPK.     

Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions

Alibardi, L. 2011. Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions. —Acta Zoologica (Stockholm) 92 : 89–100. The present ultrastructural and immunocytochemical study analyzes the cell junctions joining barb/barbule cells versus cell junctions connecting supportive cells in forming feathers. Differently from the epidermis or the sheath, desmosomes are not the prevalent junctions among feather cells. Numerous adherens junctions, some gap junctions and fewer tight junctions are present among differentiating barb/barbule cells during early stages of their differentiation. Adherens junctions are frequent also among differentiating supportive cells and show weak immunolabeling for both N‐cadherin and neural‐cell adhesion molecule (N‐CAM). Differentiating barb and barbule cells do not show labeled junctions for N‐cadherin and N‐CAM. The labeling occurs at patches in the cytoplasm of supportive cells but is more frequently seen in the external cytoplasm and along the extra‐cellular space (glycocalix) covering the plasma membrane of supportive cells. Labeling for N‐cadherin is also found in medium‐dense 0.1‐ to 0.3‐μm granules present in supportive cells and sometimes is associated with coarse filaments or periderm granules. The study indicates that adherens junctions form most of the transitional connections among supportive cells before their degeneration. Keratinizing barb and barbule cells loose the labeling for adherens junctions (N‐CAM and N‐chaderin) while their adhesion is strengthened by the incorporation of cell junctions in the corneous mass forming the barbules.     

N-Cadherin and Cx43α1 Gap Junctions Modulates Mouse Neural Crest Cell Motility via Distinct Pathways

Our previous studies showed an essential role for connexin 43 or α₁ connexin (Cx43α1) gap junctions in the modulation of neural crest cell motility. Cx43α1 gap junctions and N-cadherin containing adherens junctions are expressed in migrating cardiac neural crest cells. Analysis of the N-cadherin knockout (KO) mouse model revealed that N-cadherin is essential for gap junction mediated dye coupling but not for expression of Cx43α1 gap junctions in neural crest cells. Time lapse videomicroscopy and motion analysis showed that the motility of N-cadherin KO neural crest cells were altered, but the motility changes differed compared to Cx43α1 KO neural crest cells. These observations suggest that the role of N-cadherin in cell motility is not simply mediated via the modulation of Cx43α1 mediated cell-cell communication. This was confirmed by a parallel analysis of wnt-1 deficient neural crest cells, which also showed a reduction in dye coupling, and yet no change in cell motility. Analysis of p 120 catenin (p 120ctn), an Amardillo family protein known to play a role in cell motility, showed that it is colocalized with N-cadherin and Cx43α1 in migrating neural crest cells. This subcellular distribution was altered in the N-cadherin and Cx43α1 KO neural crest cells. Given these results, we propose that N-cadherin and Cx43α1 may modulate neural crest cell motility by engaging in a dynamic cross-talk with the cell's locomotory apparatus through p120ctn signaling.     

Modulation of N-cadherin junctions and their role as epicenters of differentiation-specific actin regulation in the developing lens

Extensive elongation of lens fiber cells is a central feature of lens morphogenesis. Our study investigates the role of N-cadherin junctions in this process in vivo. We investigate both the molecular players involved in N-cadherin junctional maturation and the subsequent function of these junctions as epicenters for the assembly of an actin cytoskeleton that drives morphogenesis. We present the first evidence of nascent cadherin junctions in vivo, and show that they are a prominent feature along lateral interfaces of undifferentiated lens epithelial cells. Maturation of these N-cadherin junctions, required for lens cell differentiation, preceded organization of a cortical actin cytoskeleton along the cells' lateral borders, but was linked to recruitment of α-catenin and dephosphorylation of N-cadherin-linked β-catenin. Biochemical analysis revealed differentiation-specific recruitment of actin regulators cortactin and Arp3 to maturing N-cadherin junctions of differentiating cells, linking N-cadherin junctional maturation with actin cytoskeletal assembly during fiber cell elongation. Blocking formation of mature N-cadherin junctions led to reduced association of α-catenin with N-cadherin, prevented organization of actin along lateral borders of differentiating lens fiber cells and blocked their elongation. These studies provide a molecular link between N-cadherin junctions and the organization of an actin cytoskeleton that governs lens fiber cell morphogenesis in vivo.     

Identification of a novel intermediate filament-linked N-cadherin/gamma-catenin complex involved in the establishment of the cytoarchitecture of differentiated lens fiber cells

Tissue morphogenesis and maintenance of complex tissue architecture requires a variety of cell-cell junctions. Typically, cells adhere to one another through cadherin junctions, both adherens and desmosomal junctions, strengthened by association with cytoskeletal networks during development. Both β- and γ-catenins are reported to link classical cadherins to the actin cytoskeleton, but only γ-catenin binds to the desmosomal cadherins, which links them to intermediate filaments through its association with desmoplakin. Here we provide the first biochemical evidence that, in vivo, γ-catenin also mediates interactions between classical cadherins and the intermediate filament cytoskeleton, linked through desmoplakin. In the developing lens, which has no desmosomes, we discovered that vimentin became linked to N-cadherin complexes in a differentiation-state specific manner. This newly identified junctional complex was tissue specific but not unique to the lens. To determine whether in this junction N-cadherin was linked to vimentin through γ-catenin or β-catenin we developed an innovative “double” immunoprecipitation technique. This approach made possible, for the first time, the separation of N-cadherin/γ-catenin from N-cadherin/β-catenin complexes and the identification of multiple members of each of these isolated protein complexes. The study revealed that vimentin was associated exclusively with N-cadherin/γ-catenin junctions. Assembly of this novel class of cadherin junctions was coincident with establishment of the unique cytoarchitecture of lens fiber cells. In addition, γ-catenin had a distinctive localization to the vertices of these hexagonally shaped differentiating lens fiber cells, a region devoid of actin; while β-catenin co-localized with actin at lateral cell interfaces. We believe this novel vimentin-linked N-cadherin/γ-catenin junction provides the tensile strength necessary to establish and maintain structural integrity in tissues that lack desmosomes.     

The roles of nectins in cell adhesions: cooperation with other cell adhesion molecules and growth factor receptors

Nectins are Ca(2+)-independent Ig-like cell adhesion molecules (CAMs) which homophilically and heterophilically interact in trans with nectins and form cell-cell adhesion. This cell-cell adhesion is involved in the formation of many types of cell-cell junctions such as adherens junctions, tight junctions, and synaptic junctions, cooperatively with other CAMs such as cadherins and claudins. Nectins transduce signals cooperatively with integrin alpha(v)beta(3), and regulate formation of cell-cell junctions. In addition, nectin interacts in cis with PDGF receptor and regulates its signaling for anti-apoptosis. Furthermore, nectin interacts in trans with nectin-like molecule-5 (Necl-5) and regulate cell movement and proliferation. We describe cooperative roles of nectins with other CAMs and growth factor receptors.     

Expression of cell adhesion molecules during embryonic induction. III. Development of the otic placode

During embryonic development, the inner ear develops from a placode into a richly differentiated structure with defined borders between neural and non-neural elements. In an effort to define the origin of such differentiation boundaries from the time of appearance of the placode, immunocytochemical methods have been used to map the developmental distributions of the cell adhesion molecules, N-CAM, L-CAM, and Ng-CAM, and the extracellular matrix molecules, cytotactin and fibronectin, in the cochlea of the chicken embryo. As the otic placode was induced by the underlying N-CAM-containing rhombencephalon and mesoderm, the placode expressed both N-CAM and L-CAM. During the period when the otic vesicle differentiated to give rise to the acoustic ganglion and to the differentiated structures of the cochlea, N-CAM increased in the innervated sensory regions while L-CAM increased in the non-sensory areas of the auditory epithelium adjacent to the sensory regions. During subsequent development, the differential expression of N-CAM and L-CAM again formed striking borders within the epithelium between the five morphologically and functionally distinct regions of the cochlea. This pattern of CAM expression is consistent with previous observations suggesting that primary CAMs of different binding specificities are expressed in two different modes to form borders at all sites of embryonic induction and at sites of further cytodifferentiation (K. L. Crossin, C -M. Chuong, and G. M. Edelman, 1985, Proc. Natl. Acad. Sci. USA 82, 6942-6946). Unlike inductive sites involving mesenchyme, however, the placode showed only changes in which an epithelium containing both CAMs loses one or the other or remains unchanged. As differentiation occurred during innervation of the sensory region, the secondary Ng-CAM appeared. Ng-CAM-positive fibers penetrated into the basilar papilla and Ng-CAM and the matrix protein cytotactin appeared within the epithelium in a radial pattern that was consistent with the previously described roles of these molecules in neurite movement. Immunoblot analyses confirmed the identity and biochemical properties of the CAMs and also revealed that N-CAM underwent embryonic to adult conversion during inner ear formation. These studies support the idea that CAMs are expressed in specific modal patterns in the cell collectives participating in inductive events, and strongly suggest that cellular regulation of these patterns is correlated with border formation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential phosphorylation of the gap junction protein connexin43 in junctional communication-competent and -deficient cell lines

Connexin43 is a member of the highly homologous connexin family of gap junction proteins. We have studied how connexin monomers are assembled into functional gap junction plaques by examining the biosynthesis of connexin43 in cell types that differ greatly in their ability to form functional gap junctions. Using a combination of metabolic radiolabeling and immunoprecipitation, we have shown that connexin43 is synthesized in gap junctional communication-competent cells as a 42-kD protein that is efficiently converted to a approximately 46-kD species (connexin43-P2) by the posttranslational addition of phosphate. Surprisingly, certain cell lines severely deficient in gap junctional communication and known cell-cell adhesion molecules (S180 and L929 cells) also expressed 42-kD connexin43. Connexin43 in these communication-deficient cell lines was not, however, phosphorylated to the P2 form. Conversion of S180 cells to a communication-competent phenotype by transfection with a cDNA encoding the cell-cell adhesion molecule L-CAM induced phosphorylation of connexin43 to the P2 form; conversely, blocking junctional communication in ordinarily communication-competent cells inhibited connexin43-P2 formation. Immunohistochemical localization studies indicated that only communication-competent cells accumulated connexin43 in visible gap junction plaques. Together, these results establish a strong correlation between the ability of cells to process connexin43 to the P2 form and to produce functional gap junctions. Connexin43 phosphorylation may therefore play a functional role in gap junction assembly and/or activity.     

The Production of Arachidonic Acid Can Account for Calcium Channel Activation in the Second Messenger Pathway Underlying Neurite Outgrowth Stimulated by NCAM, N-Cadherin, and L1

Abstract: We have used monolayers of control 3T3 fibroblasts and 3T3 fibroblasts expressing transfected cell adhesion molecules (CAMs)—NCAM, N-cadherin, and L1—as a culture substrate for cerebellar neurones. The transfected CAMs promote neurite outgrowth by activating a second messenger pathway that culminates in calcium influx into neurones through N-and l -type calcium channels. We show that the same neurite outgrowth response can be directly induced by arachidonic acid (10 μ M ) and that this response can be inhibited by N-and l -type calcium channel antagonists. In cells, arachidonic acid can be generated by phospholipase A₂ or by the sequential activities of a phospholipase C (to generate diacylglycerol) and diacylglycerol lipase. In the present study we show the neurite outgrowth stimulated by CAMs (but not by various other agents) can be abolished by an inhibitor of diacylglycerol lipase acting at a site upstream from calcium channel activation. The results suggest that arachidonic acid and/or one of its metabolites is the second messenger that activates calcium channels in the CAM signalling pathway leading to axonal growth, and this is supported by recent evidence that shows the same concentrations of arachidonic acid can increase voltage-dependent calcium currents in cardiac myocytes.     

Roles and modes of action of nectins in cell–cell adhesion

Nectins are Ca²⁺-independent immunoglobulin (Ig)-like cell–cell adhesion molecules (CAMs), which comprise a family consisting of four members. Each nectin homophilically and heterophilically trans-interacts and causes cell–cell adhesion. Biochemical, cell biological, and knockout mice studies have revealed that nectins play important roles in formation of many types of cell–cell junctions and cell–cell contacts, including cadherin-based adherens junctions (AJs) and synapses. Mode of action of nectins in the formation of AJs has extensively been investigated. Nectins form initial cell–cell adhesion and recruit E-cadherin to the nectin-based cell–cell adhesion sites. In addition, nectins induce activation of Cdc42 and Rac small G proteins, which eventually enhances the formation of cadherin-based AJs through the reorganization of the actin cytoskeleton. Nectins furthermore heterophilically trans-interact with nectin-like molecules (Necls), other Ig-like CAMs, and assist or modify their various functions, such as cell adhesion, migration, and proliferation. We describe here the roles and modes of action of nectins as CAMs.     

Expression of cell-adhesion molecules in embryonic induction. I. Morphogenesis of nestling feathers

The potential relationship of cell adhesion to embryonic induction during feather formation was examined by immunohistochemical analysis of the spatiotemporal distribution of three cell-adhesion molecules (CAMs), neural CAM (N-CAM), liver CAM (L-CAM), and neuron-glia CAM (Ng-CAM), and of substrate molecules (laminin and fibronectin) in embryonic chicken skin. The N-CAM found at sites of embryonic induction in the feather was found to be similar to brain N-CAM as judged by immuno-cross-reactivity, migratory position in PAGE, and the presence of embryonic to adult conversion. In contrast to the N-CAM found in the brain, however, only one polypeptide of Mr 140,000 was seen. N-CAM-positive dermal condensations were distributed periodically under L-CAM-positive feather placodes at those sites where basement membranes are known to be disrupted. After initiation of induction, L-CAM-positive placode cells became transiently N-CAM-positive. N-CAM was asymmetrically concentrated in the dorsal region of the feather bud, while fibronectin was concentrated in the ventral region. During feather follicle formation, N-CAM was expressed in the dermal papilla and was closely apposed to the L-CAM-positive papillar ectoderm, while the dermal papilla showed no evidence of laminin or fibronectin. The collar epithelium was both N-CAM- and L-CAM-positive. During the formation of the feather filament, N-CAM appeared periodically and asymmetrically on basilar cells located in the valleys between adjacent barb ridges. In contrast to the two primary CAMs, Ng-CAM was found only on nerves supplying the feather and the skin. These studies indicate that at each site of induction during feather morphogenesis, a general pattern is repeated in which an epithelial structure linked by L-CAM is confronted with periodically propagating condensations of cells linked by N-CAM.     

Assembly of adherens junctions is required for sphingosine 1-phosphate-induced matriptase accumulation and activation at mammary epithelial cell-cell contacts

Sphingosine 1-phosphate (S1P), a bioactive phospholipid, simultaneously induces actin cytoskeletal rearrangements and activation of matriptase, a membrane-associated serine protease in human mammary epithelial cells. In this study, we used a monoclonal antibody selective for activated, two-chain matriptase to examine the functional relationship between these two S1P-induced events. Ten minutes after exposure of 184 A1N4 mammary epithelial cells to S1P, matriptase was observed to accumulate at cell-cell contacts. Activated matriptase first began to appear as small spots at cell-cell contacts, and then its deposits elongated along cell-cell contacts. Concomitantly, S1P induced assembly of adherens junctions and subcortical actin belts. Matriptase localization was observed to be coincident with markers of adherens junctions at cell-cell contacts but likely not to be incorporated into the tightly bound adhesion plaque. Disruption of subcortical actin belt formation and prevention of adherens junction assembly led to prevention of accumulation and activation of the protease at cell-cell contacts. These data suggest that S1P-induced accumulation and activation of matriptase depend on the S1P-induced adherens junction assembly. Although MAb M32, directed against one of the low-density lipoprotein receptor class A domains of matriptase, blocked S1P-induced activation of the enzyme, the antibody had no effect on S1P-induced actin cytoskeletal rearrangement. Together, these data indicate that actin cytoskeletal rearrangement is necessary but not sufficient for S1P-induced activation of matriptase at cell-cell contacts. The coupling of matriptase activation to adherens junction assembly and actin cytoskeletal rearrangement may serve to ensure tight control of matriptase activity, restricted to cell-cell junctions of mammary epithelial cells.