Surface structures of the rumen holotrich protozoonIsotricha intestinalis with particular reference to the attachment zone

The cell surface ofIsotricha intestinalis was composed of predominantly longitudinal cytoplasmic ridges between the rows of cilia. On the dorsilateral surface these ridges were modified into sheet-like cytoplasmic processes extending up to 9 m from the cell surface, and up to 35 m long, forming a ridge projecting from the cell surface. The ridge was visible in living cells examined under phase contrast microscopy, and became more prominent after fixation with glutaraldehyde. This region of the cell surface was used for the attachment of the cell to surfaces. The cytoplasmic processes coalesced and bifurcated at points distal from the cell surface; underlying the plasma membrane of these processes was an extensive sheet of microtubules. Fixation of attached cells normally resulted in a separation of the cells from the substratum.     

Scanning electron microscopy of the surface of normal and implantation-delayed mouse blastocysts during development in vitro

Mouse blastocysts undergo developmental steps in culture analogous to those occurring during implantation in utero. We examined cultured blastocysts by scanning electron microscopy (SEM) as they passed through these stages. From the time of hatching to the acquisition of adhesiveness, most blastocysts were exhanded, with flattened cells possessing relatively small numbers of microvilli, centrally raised areas (presumably reflecting the location of the nuclei) and intercellular ridges often possessing microvilli. At, or shortly before, the trophoblast outgrowth stage, blastocysts appeared to contract; the cells bulged noticeably, microvilli covered the entire surface of most cells and intercellular ridges were no longer observable. Blastocysts removed from uteri on the seventh day of ovariectomy delay possessed a variety of morphologies and shapes. The blastocoel was frequently collapsed and cell outlines were difficult to discern. These blastocysts were initially adhesive in vitro, but subsequently disengaged from the substratum before becoming permanently adherent several hours later. During the initial phase of adhesiveness, blastocysts were elongated and had prominent intercellular ridges, particularly in the equatorial region. Detached blastocysts contained bulging cells with contours which obscured the intercellular ridges. Surface ultrastructure during subsequent phases resembled non-delayed blastocysts during attachment and outgrowth. On the basis of our studies, we propose that intercellular ridges play some role in blastocyst adhesiveness. However, we must conclude that there are other factors involved in the acquisition of adhesiveness by the blastocyst which are at least equally important but of a nature too subtle to be identified by our SEM analyses. Insofar as delayed blastocysts are concerned, we find that, within limits, the surface alterations that take place when blastocysts are activated in culture mirror those observed following reversal of delay in vivo by administration of hormones. Since delayed blastocysts placed in saline also undergo morphological changes resembling those seen at the onset of activation in utero, we suggest that reversal of implantation delay requires initially neither direct contact with steroid or macromolecular inducers nor an exogenous supply of metabolites.     

Scanning electron microscopy of rat maturation ameloblasts

Summary Post-secretory, maturation-phase ameloblasts were studied by scanning electron microscopy of freeze-fractured or dry-dissected rat incisors. These cells are in contact with the enamel which they secreted at an earlier time and which undergoes a process of continuing mineralization. The lateral intercellular compartment between maturation ameloblasts is sometimes continuous with the intercellular space of the papillary layer of the enamel organ, but often closed by basal ring contacts which correspond to terminal bars seen in transmission electron microscopy. The distal poles of the cells sometimes possess striated borders. Lateral cell surfaces may show longitudinal gutter-like depressions between ridges from which numerous intercellular connections arise; or a maze of lateral folds and ridges; or they may have mostly microvillous surface projections bordering a minimal intercellular space compartment. Preliminary correlations of groupings of basal, lateral and distal cell features indicate that basal-closed plus distal striated border cells may show every type of lateral surface. Cells without a striated border, whether open or closed basally, have ridge or maze lateral surfaces bordering a wide intercellular compartment. Basal-open plus striated border cells have microvillous or maze-like surfaces. These combinations of features are encountered a few times along the length of the maturation zone of individual incisors and suggest the existence of cyclical changes in the type of activity of maturation ameloblasts.     

<Emphasis Type="Italic">Ignicoccus hospitalis</Emphasis> and <Emphasis Type="Italic">Nanoarchaeum equitans</Emphasis>: ultrastructure,cell–cell interaction,and 3D reconstruction from serial sections of freeze-substituted cells and by electron cryotomography

Ultrastructure and intercellular interaction of Ignicoccus hospitalis and Nanoarchaeum equitans were investigated using two different electron microscopy approaches, by three-dimensional reconstructions from serial sections, and by electron cryotomography. Serial sections were assembled into 3D reconstructions, for visualizing the unusual complexity of I. hospitalis, its huge periplasmic space, the vesiculating cytoplasmic membrane, and the outer membrane. The cytoplasm contains fibres which are reminiscent to a cytoskeleton. Cell division in I. hospitalis is complex, and different to that in Euryarchaeota or Bacteria. An irregular invagination of the cytoplasmic membrane is followed by separation of the two cytoplasms. Simultaneous constriction of cytoplasmic plus outer membrane is not observed. Cells of N. equitans show a classical mode of cell division, by constriction in the mid-plane. Their cytoplasm exhibits two types of fibres, elongated and ring-shaped. Electron micrographs of contact sites between I. hospitalis and N. equitans exhibit two modes of interaction. One is indirect and mediated by thin fibres; in other cells the two cell surfaces are in direct contact. The two membranes of I. hospitalis cells are frequently seen in direct contact, possibly a prerequisite for transporting metabolites or substrates from the cytoplasm of one cell to the other. Rarely, a transport based on cargo vesicles is observed between I. hospitalis and N. equitans.     

Ultrastructure of the tubular nephron of the lizard Podarcis (= Lacerta) Taurica

The proximal, intermediate, and distal convoluted tubules of the neprhon of Podarcis (= Lacerta) taurica were examined by electron microscopy. Proximal tubule cells have large, apical cytoplasmic protrusions and microvilli interpreted to function in urate secretion. Adjacent cells are bound apically by tight junctions and desmosomes but interdigitate in their basal region. This situation is repeated in the other tubules with significant differences in intercellular space width. The basal surfaces bear numerous cytoplasmic processes. The intermediate tubule has proximal and distal segments each with dark, ciliated, and light cells, the cuboidal dark cells with dense cytoplasm constituting the main bulk of the wall. As the cells of the proximal and distal segments resemble those of the proximal and distal convoluted tubules, respectively, the intermediate tubule is considered as a transition region. The ciliated cell body has two broad processes extending from the lumen, one to the basement membrane and one to a foot process of a light cell. The light cell is surrounded by dark and ciliated cells. It does not reach the lumen, but contacts the basement membrane through a process running below a ciliated cell to form a mushroom-shaped structure in tubule cross-section, the light cell process forming the stalk and a ciliated cell the cap. The cilia probably propel the glomerular filtrate towards the distal convoluted tubule. This latter tubule has initial, middle, and terminal zones, all nonciliated but with different lumen widths and cell shapes.     

A comparison of methods for morphological studies of cultured cells

Summary A number of fixation methods for different types of cells in culture were compared, and the best preservation of nuclear and cytoplasmic details was obtained by fixation with Bouin's solution for 15 min, prior to staining with hematoxylin and eosin. All of the fixatives, including Bouin's solution, damaged various structures, notably the peripheral glas-attached cytoplasm and the intercellular connections. Micrographs obtained by bright field, phase contrast, and interference contrast (Nomarski) microscopy are presented. Much more realistic pictures, bringing out details not observed after fixation and staining, were obtained by Nomarski microscopy of living, unfixed cultures. Most conspicuous were numerous thin, cytoplasmic, cilia-like extensions, concentrated on the glass-attached peripheral margins, which were also visible on other cell surfaces and as intercellular connections. These structures were most characteristic of SV40-transformed human amnion cells. Although fixation and staining emphasize certain cell components (for example, inclusion bodies), many aspects of cellular morphology are better demonstrated by observing living cells by interference microscopy or by Nomarski interference contrast microscopy. Surface features of unfixed cells, seen by Nomarski interference contrast microscopy, were similar to the surface features of glutaraldehyde-osmium tetroxide-fixed cells studied as metallic replicas in the electron microscope. Supported in part by National Cancer Institute Research Grant CA-08748 and contributions from the Albert Soiland Cancer Foundation.     

Unusual organization of the tropharium in the telotrophic ovarioles of an insect, Saldula saltatoria

The tropharium of the common shorebug Saldula saltatoria consists of 2 zones: the apical mitotic region and the distal one comprising numerous mononucleate nurse cells. Each individual nurse cell is connected to the centrally located trophic core by a thin cytoplasmic projection referred to as a trophic process. The accumulations of a dense material interpreted as the remnants of intercellular bridge rim are observed associated with the trophic process membrane. In the light of these results the establishment of telotrophic ovarioles in hemipterans is discussed.     

Evidence for a transcellular cisternal route across the caecal epithelium of an insect

Summary The cells of the mesenteric caeca in the midgut of certain insects possess a labyrinth of transepithelial cisternae. Their existence can be seen in thin sections of lanthanum-incubated tissue, where the tracer enters not only the intercellular clefts but also membranous cisternae which are inpocketings from, and, in continuity with, both the lateral clefts and basal membrane. These infoldings, which are numerous, run from the basal or lateral surfaces into the perinuclear region of the cells, where they are found, laden with lanthanum, as smooth cisternae or vesicles in the peripheral cytoplasm near the plasma membrane. These can be followed in serial sections and are quite distinct from other sub-surface cisternae of the lateral borders which are studded with ribosomes on the cytoplasmic surface. Near the luminal surface, tracer-laden structures in the form of vesicles and granules become increasingly predominant over those in the form of cisternae. Freeze-fracture replicas confirm the above observations, in that the plasma membrane of the intercellular cleft can be characterized as such unequivocally, since it exhibits smooth septate junctional E face grooves and P face ridges. Lateral infoldings, cisternae and vesicles can be seen arising directly from these junction-bearing membranes. The transepithelial cisternae and vesicles may be the morphological basis of an insect transcellular transport system, comparable to the tubulocisternal endoplasmic reticulum present in the transporting secretory and absorptive epithelia of vertebrate tissues. However, in insect midgut caecal epithelia, the cisternae appear to be, albeit presumably transiently, in direct continuity with the extracellular space, forming a plasma membrane reticular system which seems not to be the case with the tubulo-cisternal endoplasmic reticulum which terminates in subsurface cisternae.     

FINE STRUCTURE AND MORPHOGENIC MOVEMENTS IN THE GASTRULA OF THE TREEFROG, HYLA REGILLA

The blastoporal groove of the early gastrula of the treefrog, Hyla regilla, was examined with the electron microscope. The innermost extension of the groove is lined with invaginating flask- and wedge-shaped cells of entoderm and mesoderm. The distal surfaces of these cells bear microvilli which are underlain with an electron-opaque layer composed of fine granular material and fibrils. The dense layer and masses of vesicles proximal to it fill the necks of the cells. In flask cells bordering the forming archenteron the vesicles are replaced by large vacuoles surrounded by layers of membranes. The cells lining the groove are tightly joined at their distal ends in the region of the dense layer. Proximally, the cell bodies are separated by wide intercellular spaces. The cell body, which is migrating toward the interior of the gastrula, contains the nucleus plus other organalles and inclusions common to amphibian gastrular cells. A dense layer of granular material, vesicles, and membranes lies beneath the surface of the cell body and extends into pseudopodium-like processes and surface undulations which cross the intercellular spaces. A special mesodermal cell observed in the dorsal lining of the groove is smaller and denser than the surrounding presumptive chordamesodermal cells. A long finger of cytoplasm, filled with a dense layer, vesicles and membranes, extends from its distal surface along the edge of the groove, ending in a tight interlocking with another mesodermal cell. Some correlations between fine structure and the mechanics of gastrulation are discussed, and a theory of invagination is proposed, based on contraction and expansion of the dense layer and the tight junctions at distal cell surfaces.     

Cytoplasmic tails of beta 1, beta 2, and beta 7 integrins differentially regulate LFA-1 function in K562 cells.

The beta 2 integrin lymphocyte function-associated antigen 1 (LFA-1) mediates activation-dependent adhesion of lymphocytes. To investigate whether lymphocyte-specific elements are essential for LFA-1 function, we expressed LFA-1 in the erythroleukemic cell line K562, which expresses only the integrin very late antigen 5. We observed that LFA-1-expressing K562 cannot bind to intercellular adhesion molecule 1-coated surfaces when stimulated by phorbol 12-myristate 13-acetate (PMA), whereas the LFA-1-activating antibody KIM185 markedly enhanced adhesion. Because the endogenously expressed beta 1 integrin very late antigen 5 is readily activated by PMA, we investigated the role of the cytoplasmic domain of distinct beta subunits in regulating LFA-1 function. Transfection of chimeric LFA-1 receptors in K562 cells reveals that replacement of the beta 2 cytoplasmic tail with the beta 1 but not the beta 7 cytoplasmic tail completely restores PMA responsiveness of LFA-1, whereas a beta 2 cytoplasmic deletion mutant of LFA-1 is constitutively active. Both deletion of the beta 2 cytoplasmic tail or replacement by the beta 1 cytoplasmic tail alters the localization of LFA-1 into clusters, thereby regulating LFA-1 activation and LFA-1-mediated adhesion to intercellular adhesion molecule 1. These data demonstrate that distinct signaling routes activate beta 1 and beta 2 integrins through the beta-chain and hint at the involvement of lymphocyte-specific signal transduction elements in beta 2 and beta 7 integrin activation that are absent in the nonlymphocytic cell line K562.     

Absence of gap junctional complexes in two established renal epithelial cell lines (LLC-PK1 and MDCK)

The type of junctions present in the membranes of the two renal epithelial cell lines, LLC-PK1 and MDCK, and of subcultured porcine aortic endothelial (PAE) cells have been studied by freeze-fracture. No gap junctions were observed in the two renal cell lines, while they were numerous in the endothelial cells. Tight junctions were abundant in LLC-PK1 and MDCK cells and varied in numbers of ridges from one to ten. ONly a few simple tight junctions unconnected with gap junctions were observed in PAE cells. The occurrence of gap junctions in these cells correlates with their ability to form intercellular communicating channels.     

Rat intestinal galactoside-binding lectin L-36 functions as a structural protein in the superficial squamous cells of the esophageal epithelium

Using an affinity purified antibody raised against the RI-H fragment of rat intestinal lectin L-36, the latter protein has been identified within the esophageal epithelium by means of ultracryotomy followed by immunogold labeling. The epithelium consists of 4 morphologically distinct cell-types, namely, the basal, spiny, granular and squamous cells, and each of these exhibits a different immunolabeling pattern. The basal cells form a layer on the basal lamina, and in these a diffuse cytoplasmic staining is observed. This basal cell layer is overlaid by spiny cells that extend many cell processes into wide intercellular spaces. In these cells, immunogold particles are found only on small granular inclusions consisting of an electron-lucent homogeneous substance. The granular cells from a third layer over the spiny cells, and are characterized by a number of large granular inclusions with an electron-dense core rimmed by a less electron-dense substance. Immunogold labeling is found on these granules, both on the core and peripheral region. Squamous cell-types constitute the most superficial layer of the epithelium. They are without granular inclusions, and immunogold labeling is confined to the cytoplasmic surface of the thickened plasma membrane. These findings suggest that L-36 is produced in the basal cells as free cytosolic protein, then becomes progressively aggregated into the granular inclusions of the spiny and granular cells, and is eventually transferred onto the cytoplasmic surface of the squamous cell plasma membrane where it may interact with complementary glycoconjugate(s) located at this site. The membrane lining substance thus formed may play a role in stabilizing the squamous cell membranes, thereby maintaining the structural integrity of the epithelium against mechanical stress coming from the esophageal lumen.     

PCC4azal teratocarcinoma stem cell differentiation in culture: II. Morphological characterization

The ultrastructural morphology of the PCC4azal embryonal carcinoma cells and their differentiated counterparts, endoderm-like cells and giant cells, was characterized and compared with that of the cells of embryoid bodies. The ultrastructure of the PCC4azal embryonal carcinoma cells is similar to that of the embryonal carcinoma cells of the embryoid body. These cells are small, with a large nucleus and relatively few cytoplasmic organelles. Gap junctions and modified adherens junctions are formed at some areas of intercellular contact between the embryonal carcinoma cells. The differentiated PCC4azal endoderm-like cells have a more developed cytoplasm, containing an extensive endoplasmic reticulum with large Golgi regions. Most striking is the de novo appearance of epithelial-like junctional complexes which join the apical borders between the endoderm-like cells, thus polarizing the cell monolayer. The zonula occludens junctions of the junctional complex are extensive, consisting of six or more strands of tight junctional ridges. Terminal webs are present in the apical regions that are inserted into the zonula adherens region of the junctional complex. Gap junctions continue to join neighboring cells, and some gap junctions are intercalated within tight junctional ridges. The ultrastructure of the differentiated endodermal cells of the embryoid bodies is very similar to that of the PCC4azal endoderm-like cells. The embryoid body endodermal cells form similar junctional complexes which also contain continuous belts of tight junctions that are intercalated with gap junctions. As the PCC4azal endoderm-like cells are transformed to giant cells, a massive cytoskeleton is formed, consisting of a large complex system of 10-nm filaments, microtubules, and 7-nm microfilaments. The junctional complexes that were present during the endodermal stage are partially disassembled as the giant cells migrate apart. Thus, the differentiation process in this system is characterized by significant and distinctive morphological changes.     

Changes in the blood-brain barrier of the central nervous system in the blowfly during development, with special reference to the formation and disaggregation of gap and tight junctions. I. Larval development

In the central nervous system (CNS) of full-grown larvae of the blowfly Calliphora erythrocephala, the glial-ensheathed nerve cells are completely surrounded by a layer of perineurial cells which form a “blood-brain barrier” between the circulating haemolymph and the CNS. A variety of intercellular junctions, including gap and tight junctions, are found between adjacent perineurial cells and some also between apposing glial cells; these have been characterized by freeze-fracturing as well as by tracer studies and analysis of thin sections. They are found not to be present between such cells in the undifferentiated CNS in the newly hatched larvae, nor are the nerve cells encompassed by glial cells; ionic lanthanum can penetrate to the axonal surfaces at this stage. However, over the 5 days of larval growth and development the glial cells produce attentuated cytoplasmic processes that ensheath the nerve cells, and the perineurium is formed; junctional complexes are assembled and a larval blood-brain barrier is produced which excludes tracers. Freeze-fracture preparations suggest that the inverted gap junctions which develop have done so by migration of individual intramembranous EF particles to form, at first, linear arrays and small clusters and, ultimately, macular aggregations in the perineurium; these lie between the undulating rows of PF particles forming the septate junctions. These septate junctions are formed by the organization of arrays of PF particles into multiple rows. Extensive PF particles fusing into ridges with EF grooves to form perineurial “tight” junctions are also observed, seemingly in the process of development; entry of exogenous lanthanum followed by its exclusion parallels the completion of ridge formation. These ridges are simple linear arrays of particles which may be discontinuous, lying in parallel with one another and the surface. Clustered particle arrays as well as scattered short ridges on the axonal PF, however, appear to be present unchanged throughout larval life; their role may therefore be associated with neural membrane function although there are suggestions that some may form axo-glial junctions. This is the first report on the lateral migration of intramembranous particles as the mode of formation of gap junctions in the nervous system of an invertebrate.     

Orthogonal arrays of intramembrane particles in the supporting cells of the guinea-pig vestibular sensory epithelium

Membrane specializations of the contact region between afferent nerve endings and supporting cells of the sensory epithelia of guinea-pig vestibular endorgans were examined by thin-section and freeze-fracture electron microscopy. The calyx-type nerve endings (C-endings) are separated from supporting cells (SC) by a 25-30 nm space. At irregular intervals along the upper lateral surface of supporting cells, the intercellular space narrows markedly to form special close contacts between the C-ending and SC plasma membranes. Freeze-fracture replicas reveal membrane specializations--orthogonal arrays of particulate units--in the region where the close intercellular contacts were found in sections. Orthogonal arrays consisting of from 5 to 20 units were observed on the cytoplasmic (P) fracture face of the lateral SC plasma membrane. These particulate units from a 12 x 12-nm square, and each unit is composed of four 6-nm subunits. Possible roles of the orthogonal arrays are discussed.     

Ultrastructure of the endolymphatic sac in the larva of the Japanese red-bellied newt Cynops pyrrhogaster

The ultrastructure of the endolymphatic sac (ES) of the late stage larva of the Japanese red-bellied newt, Cynops pyrrhogaster (stage 57), was examined by light and transmission electron microscopy. The two endolymphatic sacs are located at the dorsal-medial side of the otic vesicle on the dorsal-lateral side of the midbrain in the cranial cavity. The wall of the sac is composed of a layer of cubical epithelial cells with loose, interposed intercellular spaces. The sac contains a large luminal cavity, in which endolymph and numerous otoconia are present. The epithelial cells of different portions of the sac have a similar structure. These cells contain an abundance of cytoplasmic organelles, including ribosomes, Golgi complexes, and numerous vesicles. Two types of vesicles are found in the epithelial cells: the “floccular” vesicle and the “granular” vesicle. The floccular vesicles are located in the supra- and lateral-nuclear cytoplasm and contain flocccular material. The granular vesicles have a fine granular substance and are usually situated apposed to the apical cell membrane. The granular vesicles are suggested to be secreted into the lumen, while the floccular vesicles are thought to be absorbed from the lumen and conveyed to the intercellular spaces by the epithelial cells. The apical surfaces of the epithelial cells bear numerous microvilli. Apparently floating cells, which bear long microvilli on the free surfaces, are observed in the lumen of the ES. Based on the fine structure, the function of the endolymphatic sac of the newt Cynops pyrrhogaster is discussed.     

Fine structure and its functional properties of the ependymal cell in the frog median eminence

Summary Intercellular canaliculi surrounded by several ependymal cells, having numerous microvilli and a few cilia on the apical surface, are present throughout the frog median eminence. The intercellular canaliculi penetrate deeply near the portal vessel from the third ventricle. They are separated from the pericapillary space only by the thin cytoplasm of the ependymal cell.The cytoplasmic protrusions containing a large number of clear vesicles are often found at the apical surface of ependymal cells facing the third ventricle or the lumen of intercellular canaliculus. The ependymal cell shows well developed Golgi apparatus and well developed rough endoplasmic reticulum in its cytoplasm. Dense granules of about 1200–1500 A diameter suggesting secretory materials are found in small number near the Golgi apparatus and abundantly in the ependymal process lying around the portal vessel.Synaptic contacts between the ependymal cell and two different types of the nerve endings, monoaminergic and peptidergic, are frequently observed. A few small flasklike caveolae suggesting micropinocytosis are found in the post-synaptic membrane as well as in the lateral and basal plasma membranes of the ependymal cell. The author consideres that the ependymal cell in this region has secretory and transport (absorption) activities.     

Internal structure of the postcapillary high-endothelial venules of rodent lymph nodes and Peyer's patches and the transendothelial lymphocyte passage

Scanning electron microscopy (SEM) shows that the postcapillary high-endothelial venules of lymph nodes and Peyer's patches consist of two segments each with a different surface relief: a proximal segment with a cobblestone surface pattern and a distal segment of interlacing cytoplasmic plates. Both segments have deep adluminal crevices in which lymphocytes are lodged. The internal structural configuration of this endothelium has been examined by transmission electron microscopy (TEM) of serial sections of lymph nodes and Peyer's patches of mice, rats, and guinea pigs. The serial sections revealed that the endothelial cell bodies and their cytoplasmic extensions were disposed in a direction generally lateral to the luminal surface and intruded into the intercellular spaces of similarly disposed neighboring endothelial cells, resulting in a complex interlacing cellular pattern. Lymphocytes penetrated the endothelial cell body and secondarily followed an intracellular pathway through which they entered the extravascular compartment. At the exposed surfaces of the adluminal venule wall, recirculating lymphocytes were seen in SEM images to enter the endothelium by penetrating the endothelial cell body. The mode of migration of lymphocytes lodged in the endothelial crevices could be determined by SEM and has been examined by TEM of serial sections. At these locations as at the exposed surfaces, lymphocytes also entered the venule by penetrating the endothelial cell body. At both sites this transcellular pathway was followed by lymphocyte entry into the intercellular spaces from which they migrated into the extravascular compartment.     

Cytoskeletal integration in a highly ordered sensory epithelium in the organ of Corti: reponse to loss of cell partners in the Bronx waltzer mouse

This report is concerned with control of cell shaping, positioning, and cytoskeletal integration in a highly ordered cochlear neuroepithelium. It is largely based on investigations of events that occur during abnormal morphogenesis of the organ of Corti in the Bronx waltzer (bv/bv) mutant mouse. The organ's sensory hair cells and adjacent supporting cells ordinarily construct a spatially elaborate and supracellularly integrated cytoskeletal framework. Large microtubule bundles are connected to cytoskeletal components in neighbouring cells by actin-containing meshworks that link them to substantial arrays of adherens junctions. In bv/bv mice, degeneration and loss of most inner hair cells and outer pillar cells occurs during organ development. These cells flank each side of a row of inner pillar cells that respond by upregulating assembly of their actin-containing meshworks. This only occurs in surface regions where they no longer contact cell types involved in construction of the cytoskeletal framework. The meshworks are larger and exhibit a more extensive sub-surface deployment than is normally the case. Hence, assembly of intercellular cytoskeletal connecting components can proceed without contact with appropriate cell neighbours but termination of assembly is apparently subject to a negative feedback control triggered by successful completion of intercellular connection with the correct cell neighbours. In addition, inner pillar cells compensate for loss of cell neighbours by interdigitating and overlapping each other more extensively than is usually the case to increase opportunities for generating adherens junctions. Certain adherens junctions in the organs of +/+ and bv/bv mice exhibit features that distinguish them from all previously described cell junctions. The dense plaques on their cytoplasmic faces are composed of aligned ridges. We suggest that they are called ribbed adherens junctions. Perturbations of cell shaping and positioning indicate that loss of inner hair cells is the primary consequence of the bv mutation. Most of the other abnormalities can be understood in terms of a secondary sequence of morphogenetic aberrations (precipitated by loss of inner hair cells). These aberrations provide new information about the ways in which supporting cells help to control hair cell positioning.     

The role of E-cadherin in the differentiation of gallbladder cancer cells

The apical surface of the ommatidium plays a major role during development of the compound eye. Cell-cell contacts leading to induction seem to be initiated at this surface. The pupal eye of Drosophila was examined, using scanning electron microscopy, from a few hours after eversion of the imaginal disc (19 h after pupariation, 25 degrees C) until shortly after the onset of the corneal secretion (46 h after pupariation, 25 degrees C). At 19 h, the primary pigment cells are in the process of encircling the cone cells. At this time, tufts formed by the cone cell microvilli are the most prominent feature of the eye's surface. Shortly thereafter, the interommatidial cells become more prominent. Their surfaces are raised to form ridges that enclose primary pigment cells and cone cells. From 21 h onwards and lasting for 5-6 h, the interommatidial cells form slim cytoplasmic extensions that spread over the surfaces of the surrounding cells. These extensions contact neighbouring interommatidial or primary pigment cells, but also non-adjacent cells such as cone cells. The fates of these interommatidial cells presumably are determined during that time. The cell-cell interactions may play a role in determining cell fates, for example by providing positional information.