Xenopus laevis occludin. Identification of in vitro phosphorylation sites by protein kinase CK2 and association with cingulin.

Occludin is a protein component of the membrane domain of tight junctions, and has been shown to be phosphorylated in vivo in cultured cells and Xenopus laevis embryos. However, nothing is known about the identity of specific occludin kinase(s) and occludin phosphorylation site(s). Furthermore, nothing is known about the interaction of occludin with cingulin, a cytoplasmic plaque component of tight junctions. Here we report the isolation and sequencing of a complete X. laevis occludin cDNA, and experiments aimed at mapping X. laevis occludin in vitro phosphorylation site(s) and characterizing occludin interaction with cingulin. The sequence of Xenopus occludin is homologous to that of occludins from other species, with identities ranging from 41% to 58%. Bacterially expressed domain E of Xenopus occludin (amino acids 247-493) was a good substrate for protein kinase CK2 (stoichiometry 10.8%, Km 8.4 microM) but not for CK1 kinase, protein kinase A, cdc2 kinase, MAP kinase or syk kinase. Residues Thr375 and Ser379 were identified as potential CK2 phosphorylation sites in this region based on sequence analysis. Mutation of Ser379 to aspartic acid or alanine reduced phosphorylation by CK2 by approximately 50%, and double mutation of Ser379 into aspartic acid and Thr375 into aspartic acid essentially abolished phosphorylation. Glutathione S-transferase (GST) pull-down experiments using extracts of Xenopus A6 epithelial cells showed that constructs of GST fused to wild-type and mutant forms of the C-terminal region of X. laevis occludin associate with several polypeptides, and immunoblot analysis showed that one of these polypeptides is cingulin. GST pull-down experiments using in vitro translated, full-length Xenopus cingulin indicated that cingulin interacts directly with the C-terminal region of occludin.

Toxicity of organotin compounds on embryos of a marine invertebrate (Styela plicata; tunicata).

In order to clarify the interaction mechanism between organotin compounds and organisms, the effects of these compounds on the development of a benthonic filter-feeding invertebrate were studied. Embryos of the ascidian Styela plicata were obtained in laboratory by cross-fertilization and their development was followed in vivo after incubation with 0.1, 1, and 10 microM organotin compounds for various exposure times. Moreover, embryos selected at opportune stages after incubation with 10 microM tributyltin (TBT) or triphenyltin (TPT) for 1 hr were observed at the electron microscope to recognize cell alterations. Results indicate that organotins significantly affect all stages of ascidian development in a dose- and time-dependent manner and the most sensitive stages are gastrula and neurula. These compounds are able to block development, giving rise to anomalous embryos with irreversible effects. The order of inhibition appears to be strongly dependent on the organotin liposolubility: TBT > dibutyltin (DBT) > monobutyltin (MBT) and TPT > tricyclohexyltin (TCHT). The mitosis block of blastomeres in the early stages may be related to an inhibition of the microtubule polymerization. Observations with light and electron microscopes reveal globeshaped blastomeres with large intercellular spaces in the morula and gastrula stages, suggesting a toxic damage with alteration of the cytoskeleton. Moreover, the occurrence of electron-dense precipitates of organotins in the inner membrane of mitochondria and morphological changes of their cristae suggest an inhibitory effect on oxidative phosphorylation which is conspicuous in the gastrula stage. In this stage, the size of the electron-dense aggregates grow from 50-70 to 110-170 nm, while at the same time the alteration of the cristae increases.

Two different forms of gap junctions within the same organism, one with cytoskeletal attachments, in tunicates.

The cells of the intestinal tract and the stigmatal cells of the branchial basket have been studied in a range of tunicates including phlebobranch, aplousobranch and stolidobranch ascidians, as well as the doliolid and pyrosomatid thaliaceans. The intercellular gap junctions between gut cells appear conventional in thin section as do those found in the lower part of adjacent stigmatal cells. However, save for the stolidobranchs, the stigmatal cells also have a second kind of gap junction which exhibit an unusual fibrous density in association with their junctional cytoplasmic surfaces; these are found in the apical region of the cells. The fibrous density is particularly well demonstrated in specimens treated with tannic acid during fixation, and subsequent en bloc uranyl acetate staining. In the branchial basket the position of these apical gap junctions is at regular intervals between adhaering junctions, which have a more substantial paramembranous fibrous mat; these two kinds of junctions alternate along deeply undulating membrane appositions. With freeze-fracture, after chemical or cryo-fixation, the gap junctions of the gut and those of the lower part of the stigmatal cells appear typical, with P-face connexons, while in the apical part of cells of the branchial basket the two faces of the gap junctions are very difficult to cleave apart. Frequently the P- and E-faces are found to adhere together in replicas, so that in these apical gap junctional regions, plaques of E-face with pits overlie the PF particles. In addition, regions of cytoplasm, into which the dense fibres project, often cleave over these adhaering E-faces of the apical gap junctions. The presence of these unusual gap junctional features in the apical region of the stigmata in the vicinity of cilia is discussed as regards their functional role.

Ciliary specializations in branchial stigmatal cells of protochordates.

Tissues from the pharynx of five representative species of the protochordates (subphylum Tunicata, the three classes Ascidiacea, Thaliacea and Appendicularia, and subphylum Cephalochordata) were examined in both thin sections and freeze-fracture replicas. In all species, the stigmatal cilia of the branchial chamber are neatly arranged and move continuously to propel sea-water in a fixed direction for respiration and feeding of the organism. A number of specializations are found in the basal region of these cilia and are represented by: a) bridges connecting axonemal doublets numbers 5 and 6; b) dense fibrous material linking the doublet microtubules of the axoneme to the ciliary membrane, sometimes in the shape of longitudinal strands or as clusters of filaments; c) intramembrane particles (IMPs) associated with the P-face of the membrane, often arranged in clusters evenly aligned along the ciliary shaft in relation to the underlying axonemal doublets. Ciliary specializations are distributed along the plane of the effective stroke of the beat in both the ascidian Botryllus schlosseri and in the thaliacean Pyrosoma atlanticum and the amphioxus Branchiostoma lanceolatum, whereas in the thaliacean Doliolum nationalis and the appendicularian Oikopleura dioica a more uniform distribution of these specializations all around the basal portion of the cilia is observed. Whatever the disposition of the ciliary specializations in all the examined species, they are always present at the base of the water-propelling cilia. Some morphological evidence suggests that these specializations play a mechanical function in tethering the ciliary membrane to the axoneme. We propose that they help maintain the orientation of the cilia during beating, enhance their stiffness and improve their efficiency.

Actin localization at the tight junctions of invertebrate ciliated epithelia.

Indirect immunofluorescencc, rhodamine-phalloidin staining and immunoelectron microscopy performed with the on-grid postembedding immunostaining of Lowicryl K4M sections, were used to identify actin in the branchial epithelium of the lower chordate ascidians. The ciliated cells of these invertebrates present two distinct junctional patterns. One consists only of an extended tight junction whereas in the other the tight junction is accompanied by a prominent zonula adhaerens. Evidence is given of the localization of actin at the tight junction. The absence of reaction in the zonula adhaerens suggests that the definition of this junction in the model here presented must be reconsidered.

Different functions of tight junctions in the ascidian branchial basket.

The stigmatal cells in the branchial basket of ascidians from a number of genera have been examined as to the nature and distribution of their intercellular junctions. The branchial wall consists of ciliated and parietal cells; the ciliated cells are arranged in seven rows and are associated by junctions with other cells in the same row as well as with those in adjacent rows. They are also associated by junctions with peripheral parietal cells. Junctions between adjacent ciliated cells in all cases exhibit tight junctions or zonulae occludentes. However, these cell borders also possess fasciae or zonulae adhaerentes if they are in the same row and the ciliary rootlets insert-into these junctions. If the cells are in adjacent rows they exhibit adhaerentes junctions only in species belonging to the orders Phlebobranchiata and Aplousobranchiata. In contrast, if the cells in adjacent rows belong to the order Stolidobranchiata. they never exhibit any adhaerentes junctions and the ciliary rootlets of the basal bodies from the cilia insert instead into the tight junctions and the non-junctional membrane below them. At the homologous junctional borders between adjacent parietal cells and also at heterologous junctional borders between parietal and ciliated cells, tight junctions alone occur, with no co-existing adhaerentes junctions along their lateral borders. Again, fibrils from ciliary rootlets insert into zonulae occludentes. This shows that tight junctions are capable both of forming permeability barriers, in that they can be seen to prevent the entry of exogenous tracers such as lanthanum, and of acting as adhesive devices.

A comparative study of ciliary differentiations in the branchial stigmata of ascidians.

In a correlated thin sectioning and freeze-fracturing study, we have examined species belonging to the orders of the ascidian class: Stolidobranchiata (Botryllus schlosseri, Botrylloides leachi, Molgula socialis, Styela plicata), Phlebobranchiata (Ascidiella aspersa, Phallusia ingeria, Ciona intestinalis) and Aplousobranchiata (Clavelina lepadiformis). Though the branchial basket varies in the complexity and filtration efficiency in the three orders, the ciliated epithelia aroand the stigmata contain a common pattern of organization; seven rows of flattened cells, each bearing a single row of long cilia flanked by a single row of microvilli. All the species examined possess ciliary specializations represented by: (a) bridges connecting doublets number 5 and 6 as well as 9.1 and 2; (b) dense material lying between the above mentioned axonemal doublets (5-6 and 1-2) and the ciliary membrane, sometimes in the shape of longitudinal strands or often as lines of dots; (c) a fuzzy coat protruding from the ciliary membrane, consisting of tufts or scattered filaments; (d) intramembrane particles (IMPs) associated with the P-face of the membrane, often arranged in clusters and orderly alignments related to the anderlying axonemal doublets; these IMPs decorate the opposite sides of each cilium facing the adjacent cilia forming the ciliary rows of adjacent cells and are absent on the lateral sides. The stigmatal cilia propel water through the stigmata and their effective strokes follow a line at right angles to the row of cilia in each cell. The usual direction of the effective stroke is toward doublets 5-6. It is possible, therefore, to refer to structure in relation to the ciliary beat cycle. The importance of these specializations is unknown, but the structures appear to vary in the different species. A correlation between the richness of the specializations and the complexity of the branchial basket was not evidenced. It was suggested that the ciliary specializations relate to the peculiar organization of the stigmatal margin and that all are involved in the regulation of the ciliary activity.

Cell junctions in amphioxus (Cephalochordata): a thin section and freeze-fracture study.

Tissues from the epidermis, alimentary tract and notochord of the cephalochordate Branchiostoma lanceolatum have been examined in both thin sections and freeze-fracture replicas to ascertain the nature of the intercellular junctions that characterize their cell borders. The columnar epithelial cells from the branchial chamber (pharynx), as well as from the anterior and posterior intestine, all feature cilia and microvilli on their luminal surfaces. However, their lateral surfaces exhibit zonulae adhaerentes only. No gap junctions have been observed, nor any tight junctions (as are a feature of the gut of urochordates and higher vertebrates), nor unequivocal septate junctions (as are typical of the gut of invertebrates). The basal intercellular borders are likewise held together by zonulae adhaerentes while hemidesmosomes occur along the basal surface where the cells abut against the basal lamina. The lateral cell surfaces, where the adhesive junctions occur, at both luminal and basal borders, do not exhibit any specialized arrangement of intramembrane particles (IMPs), as visualized by freeze-fracture. The IMPs are scattered at random over the cell membranes, being particularly prevalent on the P-face. The only distinctive IMPs arrays are those found on the ciliary shafts in the form of ciliary necklaces and IMP clusters. With regard to these ciliary modifications, cephalochordates closely resemble the cells of the branchial tract of ascidians (urochordates). However, the absence of distinct junctions other than zonulae adhaerentes makes them exceptions to the situation generally encountered in both vertebrates and urochordates, as well as in the invertebrates. Infiltration with tracers such as lanthanum corroborates this finding; the lanthanum fills the extracellular spaces between the cells of the intestine since there are no junctions present to restrict its entry or to act even as a partial barrier. Junctions are likewise absent from the membranes of the notochord; the membranes of its lamellae and vesicles exhibit irregular clusters of IMPs which may be related to the association between the membranes and the notochordal filaments. Epidermis and glial cells from the nervous system possess extensive desmosomal-like associations or zonulae adhaerentes, but no other junctional type is obvious in thin sections, apart from very occasional cross-striations deemed by some previous investigators to represent 'poorly developed' septate junctions.

Tight and gap junctions in the intestinal tract of tunicates (Urochordata): a freeze-fracture study.

The intestinal tracts from seven different species of tunicates, some solitary, some colonial, were studied fine-structurally by freeze-fracture. These urochordates occupy an intermediate position phylogenetically between the vertebrates and the invertebrates. The various regions of their gut were isolated for examination and the junctional characteristics of each part investigated. All the species examined exhibited unequivocal vertebrate-like belts of tight-junctional networks at the luminal border of their intestinal cells. No septate junctions were observed. The tight junctions varied in the number of their component strands and the depth to which they extended basally, some becoming loose and fragmented towards that border. The junctions consisted of ridges or rows of intramembranous particles (IMPs) on the P face, with complementary, but offset, E face grooves into which IMPs sometimes fractured. Tracer studies show that punctate appositions, the thin-section correlate of these ridge/groove systems, are sites beyond which exogenous molecules do not penetrate. These junctions are therefore likely to represent permeability barriers as in the gut tract of higher chordates. Associated with these occluding zonular junctions are intermediate junctions, which exhibit no identifiable freeze-fracture profile, and macular gap junctions, characterized by a reduced intercellular cleft in thin section and by clustered arrays of P face particles in freeze-fractured replicas; these display complementary aggregates of E face pits. The diameters of these maculae are rarely very large, but in certain species (for example, Ciona), they are unusually small. In some tissues, notably those of Diplosoma and Botryllus, they are all of rather similar size, but very numerous. In yet others, such as Molgula, they are polygonal with angular outlines, as might be indicative of the uncoupled state. In many attributes, these various junctions are more similar to those found in the tissues of vertebrates, than to those in the invertebrates, which the adult zooid forms of these lowly chordates resemble anatomically.

BUdR as a tracer of the possible mutagenic activity of Pb++ in human lymphocyte cultures.

The method of SCE was used as an indicator of the possible mutagenic activity of lead acetate in in vitro cultures of human lymphocytes. After determining the optimal concentration of BUdR, the cultures were treated with increasing doses of the metal. The negative results obtained with this method led us to examine other parameters, in particular the classical cytogenetic aberrations.