The modulation of cellular contractility and adhesion by trypsin and EGTA

A novel method to align cells in a cardiac tissue-like construct fabricated by cell sheet-based tissue engineering

Fabrication of cardiac tissue from human induced pluripotent stem cell-derived cardiomyocytes (hiPS-CMs) has received great interest, but a major challenge facing researchers is the alignment of cardiomyocytes in the same direction to optimize force generation. We have developed a novel method of fabricating a cardiac tissue-like construct with aligned cells based on the unidirectional stretching of an hiPS-CM sheet. A square cell sheet was harvested from a temperature-responsive culture dish and placed on a silicone surface, and an extending force was imposed on the silicone to stretch the cell sheet along one direction. To enable evaluation of cardiomyocyte morphology in vitro, a cell sheet was constructed by coculture of hiPS-CMs and human adipose-derived stem cells. In separate experiments, a stretched double-layered cell sheet constructed from hiPS-CMs alone was transplanted onto the muscle of an athymic rat, and its features were compared with those of a nonstretched (control) cell sheet. Immediately after stretching, the stretched cell sheet was significantly longer than the control cell sheet. Immunohistological analysis revealed that the cardiomyocytes showed unidirectional alignment in the stretched cell sheet but random directionality in the control cell sheet. Two weeks after transplantation, immunohistology demonstrated that the stretched cell sheet had retained the unidirectionality of its myocardial fibers and had an orientation intensity that was higher than that of the control cell sheet after transplantation or the stretched cell sheet before transplantation. Our technique provides a simple method of aligning an hiPS-CM-derived cardiac tissue-like construct without the use of a scaffold.

β-Adrenergic inhibition of contractility in L6 skeletal muscle cells

The β-adrenoceptors (β-ARs) control many cellular processes. Here, we show that β-ARs inhibit calcium depletion-induced cell contractility and subsequent cell detachment of L6 skeletal muscle cells. The mechanism underlying the cell detachment inhibition was studied by using a quantitative cell detachment assay. We demonstrate that cell detachment induced by depletion of extracellular calcium is due to myosin- and ROCK-dependent contractility. The β-AR inhibition of L6 skeletal muscle cell detachment was shown to be mediated by the β₂-AR and increased cAMP but was surprisingly not dependent on the classical downstream effectors PKA or Epac, nor was it dependent on PKG, PI3K or PKC. However, inhibition of potassium channels blocks the β₂-AR mediated effects. Furthermore, activation of potassium channels fully mimicked the results of β₂-AR activation. In conclusion, we present a novel finding that β₂-AR signaling inhibits contractility and thus cell detachment in L6 skeletal muscle cells by a cAMP and potassium channel dependent mechanism.

Mechanics and regulation of cell shape during the cell cycle

Many cell types undergo dramatic changes in shape throughout the cell cycle. For individual cells, a tight control of cell shape is crucial during cell division, but also in interphase, for example during cell migration. Moreover, cell cycle-related cell shape changes have been shown to be important for tissue morphogenesis in a number of developmental contexts. Cell shape is the physical result of cellular mechanical properties and of the forces exerted on the cell. An understanding of the causes and repercussions of cell shape changes thus requires knowledge of both the molecular regulation of cellular mechanics and how specific changes in cell mechanics in turn effect global shape changes. In this chapter, we provide an overview of the current knowledge on the control of cell morphology, both in terms of general cell mechanics and specifically during the cell cycle.

Adhesion and proliferation of human fibroblasts on sol-gel coated titania

The objective of this study was to evaluate growth and attachment of human gingival fibroblasts on nonresorbable sol-gel-derived nanoporous titania (TiO2) coated discs and noncoated commercially pure titania (cpTi) discs in vitro. The strength of attachment was evaluated using serial trypsinization. The number of cells detached from TiO2-substrates was 30% +/- 3%, whereas those detached from the cpTi was 58% +/- 4% indicating a stronger cell attachment on the coated surfaces. In scanning electron microscopy (SEM) images fewer cells, with more rounded shape, were seen with cpTi than with TiO2 after the detachment assay. Fibroblasts grew more efficiently on TiO2 than on cpTi substrates, showing significantly higher cell activities at all times. In transmission electron microscopy (TEM), a continuous layer of two to three cells thick covered the coated and noncoated discs after 7 days of culture. The plasma membrane of cells in contact with the coating was in close opposition and the cytoplasm was ultrastructurally similar to the cells grown on noncoated discs with well-preserved organelles. In conclusion, we demonstrated that the sol-gel-derived TiO2 coatings can facilitate cell growth and attachment of human gingival fibroblasts on titanium in vitro. This in vitro study is in line with our previous in vivo observations of improved soft tissue attachment of TiO2 coatings in comparison with cpTi.

Mechanical responses of single non-confluent epithelial cells to low extracellular calcium

Single non-confluent MDCK cells respond immediately to a sharp decrease in extracellular Ca2+ (< or = 5 microM) with an intense reversible retraction, along with an increase in cell height, correlating in overall rate and extent with initial cell size. Optical sectioning of individual cells by confocal microscopy showed that this structural response, observed in about 50% of the population, involves narrowing and even furrowing near the base of the cell by a thickened peripheral belt of actin filaments, which remains associated with the cortex instead of being internalized in the cytoplasm. Single cells retracted significantly in response to low Ca2+ under conditions that have been found largely inhibitory for retraction of confluent cells, such as Ca2+ replacement with Ba2+ and the substitution of Na+ with choline, a non-permeant cation. Conversely, the Na(+)-ionophore monensin applied in the normal-Ca2+ medium elicited by itself an earlier and much greater retraction in single cells than in confluent cultures. These observations indicate that single cells can retract more readily than those forming confluent cultures, suggesting that retraction in typical monolayers is resisted in part by the cell junctions. According to this view, inward actin-myosin mediated tension around the periphery of individual cells precedes and probably helps dissociation of E-cadherins in confluent cultures exposed to low Ca2+.

Actin cytoskeleton role in the structural response of epithelial (MDCK) cells to low extracellular Ca2+

Kinetic and stereometric assessment of the mechanical responses of epithelial cells to variations in the concentration of extracellular Ca2+ was carried out in vivo at the single cell level. Continuous monitoring of individual MDCK cells in subconfluent cultures attested to an intense, immediately relaxable, and cytochalasin D-sensitive contraction, equivalent to that seen in confluent monolayers following depletion of external Ca2+ (<0.1 mM). Increasingly greater and less readily reversible contractions were performed upon repeated stimulation with short-term cycles of alternating normal (30 min) and low Ca2+ (30 min) media. Constriction of a narrow horizontal girdle corresponding in position to the major ring-like bundle of actin filaments eventually develops into a deep lateral furrow in intensely contracted cells. Substantial membrane infolding in the contracted state is indicated also by stereometric estimates of apparent bounding surface area. Irrespective of the contracted or relaxed cell condition, rhodamine-phalloidin labeling showed a marginal position of the ring-like bundle of microfilaments and other components of the actin cytoskeleton. These results suggest, contrary to prevalent views, that the actin-myosin system stays associated to the cortex and retains contractile capability in epithelial cells deprived of external Ca2+. Hence, the mechanical responses to variations of Ca2+ may be an overstrained expression of a physiological mechanism.

Contraction of epithelial (MDCK) cells in response to low extracellular calcium is dependent on extracellular sodium

Like other cells of epithelial origin, MDCK cells respond with a reversible structural transformation to a diminution in the concentration of extracellular Ca2+. Upon deprivation of Ca2+ in the medium the cells undergo an active contraction mediated by the actin-myosin cytoskeleton, in parallel to detachment of the intercellular contacts and appearance of free spaces in the epithelium or monolayer (Castillo et al., 1998). We now present results indicating that the decrease of external Ca2+ plays an indirect and non-specific role in activating contraction, probably by allowing an influx of Na+. The omission of external Ca2+ had no effect when it was replaced by Mg2+, Ba2+ or Hg2+, and the addition of any of these divalent cations induced relaxation of cells previously contracted by exposure to low Ca2+. A null or weak response was observed also when Ca2+ was lowered in a solution where Na+ was replaced by choline or in the presence of amiloride (30 microM), which reduces the permeability of the plasma membrane to Na+. Restitution of Na+ or removal of amiloride were followed by contraction in the same cultures. Li+ proved an able substitute of Na+ as requisite for cell contraction in response to Ca2+ depletion. Monensin (0.1 mM) -an ionophore selective for Na+- and to a lesser extent ouabain (0.1 mM) -an inhibitor of Na+ extrusion across the plasma membrane- , both stimulated contraction in the presence of the normal level of external Ca2+. Decreasing by half the normal concentration of external K+ facilitated cell contraction, but typical responses were observed when K+ was increased to 40 mM by partial substitution for Na+. These findings attest that cell contraction in response to low Ca2+ is likely due to an increase in the permeability of the plasma membrane to Na+, though not to membrane depolarization as such. Evidences from other motile systems suggest that Na+ influx might in turn cause an elevation of cytoplasmic Ca2+, which activates the actin-myosin cytoskeleton.

Cytoskeletal and adhesive structural polarizations accompany IL-13-induced human macrophage fusion

During the inflammatory response to an implanted biomaterial, monocytes undergo a striking phenotypic progression of differentiation into macrophages, which may subsequently fuse to form foreign body giant cells (FBGCs). Taking advantage of an in vitro system of cytokine-induced FBGC formation together with the optical slicing capabilities of a confocal microscope, we investigated the cytoskeletal reorganization and adhesive structure development during this dramatic morphological progression. Human monocytes demonstrated diffuse cytoplasmic staining of adhesive structural proteins. Punctate filamentous (F)-actin structures appeared along the ventral cell membrane of macrophages and were identified as the core of podosome adhesive structures by the distinctive ring staining of vinculin, talin, and paxillin around the F-actin. Cytokine-induced FBGCs were characterized by a restriction of podosomes to the extreme periphery of the ventral cell surface. Although macrophages and FBGC contained equivalent amounts of F-actin, significantly more F-actin was located within 1 micron of the ventral plasma membrane in FBGCs compared to macrophages. Taken together, these results provide new information on the dynamic cytoskeletal reorganization and adhesive structure development that occur during phenotypic progression from human monocytes to macrophages to FBGC. Furthermore, they suggest the acquisition of functional specializations on FBGC formation, which may enhance our understanding of chronic inflammatory processes.

Signal transduction and cytoskeletal reorganization are required for cell detachment from cell culture surfaces grafted with a temperature-responsive polymer

We have developed a new cell culture substrate grafted with a temperature-responsive polymer, poly(N-isopropylacrylamide) (PIPAAm) using an electron beam irradiation method. These surfaces are hydrophobic in culture at 37 degrees C due to the hydration/dehydration changes intrinsic to PIPAAm at 32 degrees C, and they become highly hydrophilic below 32 degrees C. At 37 degrees C grafted and ungrafted surfaces showed no difference with regard to attachment, spreading, growth, confluent cell density, and morphology of bovine aortic endothelial cells. Stress fibers, peripheral bands, and focal contacts were established in similar ways. After the medium temperature was decreased to 20 degrees C, spread cells lost their flattened morphology, acquiring a rounded cell appearance similar to that of cells immediately after plating. After mild agitation cells floated free from the dish surface without trypsin treatment. Neither cell morphological changes nor cell detachment occurred on ungrafted surfaces. An ATP synthesis inhibitor, sodium azide, and a tyrosine kinase inhibitor, genistein, suppressed cell morphological changes and cell detachment while a protein synthesis inhibitor, cycloheximide, slightly enhanced cell detachment. An actin filament stabilizer, phalloidin, and its depolymerizer, cytochalasin D, also inhibited cell detachment. These findings suggest that cell detachment on grafted surfaces is mediated by intracellular signal transduction and reorganization of the cytoskeleton. While trypsinization causes damage to the cell membrane surface and extracellular matrix proteins, this alternative low temperature treatment is exceptionally noninvasive. The temperature-responsive cell culture surface also should prove useful for investigating the molecular machinery involved in cell-surface detachment.

Retinal pigmented epithelium cultures on thermally responsive polymer porous substrates

A cross-linkable co-polymer of UV-sensitive 4-(N-cinnamoylcarbamide)methylstyrene (CCMS) and N-isopropylacrylamide (NIPAAm), was applied to porous tissue culture inserts. Surface chemical analyses of the inserts show an introduction of a thermally responsive polymer comparable to that on similarly incorporated non-porous polystyrene surfaces. Contact angle measurements as well as atomic force microscopy show a surface change in response to changing temperature in an aqueous environment, from hydrophilic, extended polymer chains below 32 degrees C to a dense hydrophobic film above 32 degrees C. Cell growth on porous inserts allowed measurement of cell expression, such as transepithelial resistance and fluid transport, which are not observable on cells from non-porous surfaces. Cultures of retinal pigmented epithelium (RPE) were able to restore an environment similar to in vivo by forming a tight junction barrier membrane upon confluence at 37 degrees C, as observed by changes in morphology, transepithelial resistance, and directionally-specific fluid transport. In addition, cells cultured on these surfaces detached as an oriented polarized sheet when the inserts were brought to 20 degrees C. This cell sheet was transplanted to other tissue culture surface without polymer detachment or dissolution, or cell damage caused by traditional detachment methods using proteolytic enzymes.

Cytosolic free calcium and cell spreading decrease in fibroblasts from aged and Alzheimer donors

Aging and Alzheimer disease lead to alterations in calcium homeostasis. The concentration of cytosolic free calcium in cultured skin fibroblasts during aging and Alzheimer disease was determined with the calcium-sensitive fluorescent dyes quin-2 and fura-2. The Alzheimer donors showed a decline of 70% when compared to age-matched controls (P less than 0.001) and 81% when compared to cells from young adult donors (P less than 0.001). This reduction in quin-2-calcium fluorescence does not appear to be due to quenching by heavy metals or alterations in intracellular pH. Similar decreases in free cytosolic calcium were observed with fura-2. In addition, cells from aged and Alzheimer donors spread more slowly than those from young donors, and this deficit can be partially reversed by treatment with the calcium ionophore A23187. These studies agree with accumulating evidence that, at the cellular level, Alzheimer disease is a systemic, as well as cerebral, disease. The precise molecular basis of the decreased cytosolic calcium in fibroblasts is unknown, but there is evidence that it may be pathophysiologically important.

Evidence that a Ca2+ chelator and a calmodulin blocker interfere with the structure of inter-Sertoli junctions

Ca2+ dependence of tight junction structure has been well documented in cultured epithelial tissues, and regulatory mechanisms have been identified. To analyse the possible control exerted on inter-Sertoli junctions, we exposed guinea-pig seminiferous tubules to the presence of a Ca2+ chelator (EGTA) and to a calmodulin blocker (Trifluoperazine, TFP) in vitro, for times ranging from 30 to 120 min. We observed the morphology of junctional complexes and the basal cytoplasmic regions in sections and replicas. Sertoli cell response to Ca2+ depletion involved several events: retraction of cells toward the base of the tubule and a consequent stretching of the points of fusion, augmented density of the cytoplasm, and destabilization of the array of intramembrane particles. Exposure of tubules to TFP resulted in disruption of the interactions between actin filaments and membrane junctional specialization, as well as a disorganization of other cytoskeletal elements. Thus, in vitro, junction integrity appears to be related to Ca2+ level, and Ca2+ depletion apparently interferes with Ca2+ distribution inside the cell and on microfilaments involved in junction regulation. Our results do not provide direct evidence for any particular mechanism of action of TFP, but a multiple effect is evident. TFP, which affects Ca2+ regulation and membrane fluidity, probably acts indirectly on junction-associated filaments. Both the experimental conditions tested suggest a Ca2+-mediated regulatory role of microfilaments of this complex junction.

Cytoskeletal events during calcium- or EGF-induced initiation of DNA synthesis in cultured cells. Role of protein phosphorylation and clues in the transformation process

The possible relationship between cytoskeletal events and growth regulation in response to stimulation by calcium and by growth factors such as EGF can be summarized as follows: An elaborate interaction exists between calcium and serum growth factors, such as EGF, in the initiation of DNA synthesis in quiescent cells. This implies that many processes between the external signals delivered at the cell surface and the sequential intracellular events that lead to chromosomal replication, and ultimately to cell division, must be coordinated in a reproducible manner. It is now apparent that because of its possible role as a dynamic integrator of the cytoplasm, the cytoskeleton could represent the coordinator of the events that lead to replication. Calcium (with its intracellular acceptor, calmodulin) and cAMP (which can act by opposing mechanisms) are extensively involved in the control of the integrity of the cytoskeleton. Distinct protein kinases are activated by calcium/calmodulin, EGF, and cAMP as aspects of the prereplicative response, and many of the substrates for phosphorylation are cytoskeletal proteins. The emerging picture seems to include a direct involvement of these protein kinases in the cascade of regulatory events that leads to the initiation of DNA synthesis. Thus, the cytoskeleton has a direct role in the transmission of proliferative signals from external receptor sites to the nucleus. A means by which neoplastic cells can bypass the normal regulatory pathways is proposed in the light of recent data showing that the product of oncogenes are protein kinases or proteins that intimately interact with cellular protein kinases.

Differential effects of calcium deprivation on the cytoskeleton of non-tumorigenic and tumorigenic rat liver cells in culture

Normal rat liver T51B epithelial cells and Morris no. 7795 hepatoma cells growing exponentially were exposed for 24 h to standard medium containing low (0.02 mM) calcium, a concentration which drastically reduces the proliferation of normal but not tumour cells. Cell surface morphology was examined by scanning electron microscopy (SEM); and the distribution and organization of microtubules, cytokeratin and vimentin filaments, and microfilaments were analysed by indirect immunofluorescence microscopy using specific antibodies. Calcium deprivation caused the loss of intercellular cohesion in both cell types and the appearance of some microvilli and blebs, particularly on tumour cells. However, marked differential (normal vs tumour cells) effects on the organizational integrity of the cytoskeleton fibrillar network were observed. Extracellular calcium deprivation led to a particular rearrangement of microtubules, and a perinuclear accumulation of cytokeratin and vimentin filaments in normal, but not in tumour cells. A massive concentration of actin-containing microfilaments was observed in the cell periphery and blebs of hepatoma cells. In the light of the possible involvement of calcium in controlling cytoskeleton assembly, the differing cytoskeletal changes of the two cell types may be linked to their different proliferative capabilities in low-calcium medium.

Altered cell spreading in cytochalasin B: a possible role for intermediate filaments

Trypsinized chicken embryo dermal fibroblasts plated in the presence of cytochalasin B (CB) quickly attached to the substrate and within 24 h obtained an arborized morphology. This morphology is the result of the pushing out of pseudopodial processes along the substrate from the round central cell body. There were no microfilament bundles in the processes of these cells plated in the presence of CB; however, the processes were packed with highly oriented, parallel-aligned intermediate filaments. Only a few scattered microtubules were seen in these processes. These results demonstrated that in CB, cells are capable of a form of movement, i.e., the extension of pseudopodial processes, without the presence of the microfilament structures usually associated with extensions of the cytoplasm and pseudopodial movements. We also found that arborization did not depend on fibronectin since cells plated in CB did not have fibronectin fibers associated with the processes. Chicken fibroblasts transformed with tsLA24A, a Rous sarcoma virus which is temperature sensitive for pp60src, formed arborized cells with properties similar to those of uninfected fibroblasts when plated in the presence of CB at the nonpermissive temperature (41 degrees C). At the permissive temperature for transformation (36 degrees C), the cells attached to the substrate but remained round. These round cells were not only deficient in microfilament bundles but also lacked the highly organized intermediate filaments found in the processes of the arborized cells at 41 degrees C. Although both microfilament bundles and the fibronectin matrix were decreased after transformation with Rous sarcoma virus, neither was involved in the formation of processes in normal cells plated in CB. Therefore, the inability of the transformed cells to form or maintain processes in CB must be the result of another structural alteration in the transformed cells, such as that of the intermediate filaments.

Effects of extracellular calcium depletion on membrane topography and occluding junctions of mammary epithelial cells in culture

Ca2+ dependence of occluding junction structure and permeability, well documented in explanted or cultured epithelial sheets, presumably reflects inherent control mechanisms. As an approach to identification of these mechanisms, we induced disassembly of zonulae occludentes in confluent monolayers of mouse mammary epithelial cells by exposure to low concentrations of the chelators, EGTA or sodium citrate. Stages in disassembly were monitored during treatment by phase-contrast microscopy and prepared for transmission and scanning electron microscopy. Cellular response included several events affecting occluding junctions: (a) Centripetal cytoplasmic contraction created tension on junction membranes and displaced intramembrane strands along lines determined by the axis of tension. (b) Destabilization of junction position, probably through increased membrane fluidity, augmented tension-induced movement of strands, resulting in fragmentation of the junction belt. (c) Active ruffling and retraction of freed peripheral membranes remodeled cell borders to produce many filopodia, distally attached by occluding-junction fragments to neighboring cell membranes. Filopodia generally persisted until mechanically ruptured, when endocytosis of the junction and adhering cytoplasmic bleb ensued. Junction disassembly thus resulted from mechanical tensions generated by initial centripetal contraction and subsequent peripheral cytoskeletal activity, combined with destabilization of the junction's intramembrane strand pattern.

Alterations of the cytoplasmic organization of WIRL cells induced by trifluoperazine

The antipsychotic drug trifluoperazine (TFP) causes a reversible rounding of cells of the rat liver epithelial cell line, WIRL. We have investigated the cytoplasmic organization of these cells after TFP treatment using SEM, TEM and immunofluorescence and have observed significant differences between the control and treated cells. Mitochondria are converted to the condensed configuration with distended cristae and the endoplasmic reticulum becomes tubular with distended cisternae. Intermediate filaments, visualized with a monoclonal antibody, are aggregated to a cap on the nucleus in an arrangement different from that induced by colcemid.

Altered cell spreading in cytochalasin B: a possible role for intermediate filaments

Trypsinized chicken embryo dermal fibroblasts plated in the presence of cytochalasin B (CB) quickly attached to the substrate and within 24 h obtained an arborized morphology. This morphology is the result of the pushing out of pseudopodial processes along the substrate from the round central cell body. There were no microfilament bundles in the processes of these cells plated in the presence of CB; however, the processes were packed with highly oriented, parallel-aligned intermediate filaments. Only a few scattered microtubules were seen in these processes. These results demonstrated that in CB, cells are capable of a form of movement, i.e., the extension of pseudopodial processes, without the presence of the microfilament structures usually associated with extensions of the cytoplasm and pseudopodial movements. We also found that arborization did not depend on fibronectin since cells plated in CB did not have fibronectin fibers associated with the processes. Chicken fibroblasts transformed with tsLA24A, a Rous sarcoma virus which is temperature sensitive for pp60src, formed arborized cells with properties similar to those of uninfected fibroblasts when plated in the presence of CB at the nonpermissive temperature (41 degrees C). At the permissive temperature for transformation (36 degrees C), the cells attached to the substrate but remained round. These round cells were not only deficient in microfilament bundles but also lacked the highly organized intermediate filaments found in the processes of the arborized cells at 41 degrees C. Although both microfilament bundles and the fibronectin matrix were decreased after transformation with Rous sarcoma virus, neither was involved in the formation of processes in normal cells plated in CB. Therefore, the inability of the transformed cells to form or maintain processes in CB must be the result of another structural alteration in the transformed cells, such as that of the intermediate filaments.

Inhibition of fibronectin receptor function by antibodies against baby hamster kidney cell wheat germ agglutinin receptors

Previous studies suggest that the baby hamster kidney (BHK) cell fibronectin receptor is also a wheat germ agglutinin receptor (WGA-R). To analyze this possibility further, IgG and Fab fragments of antibodies produced against a BHK cell WGA-R preparation were tested to determine their effects on cell adhesion mediated by fibronectin, wheat germ agglutinin, concanavalin A, and polycationic ferritin. The WGA-R preparation was isolated by octylglucoside extraction of BHK cells followed by chromatography of the extract on WGA-agarose. The antibodies against the WGA-R preparation reacted primarily with polypeptides of molecular weights 48, 61, 83, 105, 120, 165, 210, and 230 kilodaltons (kdaltons). It was concluded that the antibodies interfered with BHK cell fibronectin receptors on the basis of the ability of anti-WGA-R IgG or Fab fragments to (a) inhibit cell spreading on fibronectin-coated substrata; (b) cause rounding and detachment of cells previously spread on fibronectin-coated substrata; and (c) inhibit binding of fibronectin-coated latex beads to the cells. Antibody activity was blocked by treatment of anti-WGA-R with the WGA-R preparation or by absorption of anti-WGA-R with intact BHK cells. The antibodies also appeared to prevent coupling of ligand-receptor complexes (involving concanavalin A or polycationic ferritin) with the cytoskeleton. Finally, cell rounding and detachment caused by the antibodies were found to require metabolic energy since it did not occur in the presence of azide or at 4 degrees C.

API ZYM system for identification of Bacteroides spp., Capnocytophaga spp., and spirochetes of oral origin

A total of 80 oral strains of Bacteroides gingivalis, B. asaccharolyticus, B. melaninogenicus subsp. intermedius, B. melaninogenicus subsp. melaninogenicus, Capnocytophaga, Treponema denticola, and T. vincentii were characterized with the API ZYM system for 19 enzyme activities. Comparison of anaerobic and aerobic incubation with nine reference strains of these organisms showed no important differences. The key differential tests for black-pigmented Bacteroides strains and treponemes of oral origin were trypsin, alpha-glucosidase, and N-acetyl-beta-glucosaminidase. All Capnocytophaga strains produced distinctive aminopeptidase activities but varied in their glycosidic capabilities. The presence of a trypsin-like activity in B. gingivalis, T. denticola, and a group of Capnocytophaga strains may contribute to tissue destruction in periodontal disease.

Contact relations and guidance of primordial germ cells on their migratory route in embryos of Xenopus laevis

This paper describes the relationship between primordial germ cells (p.g.cs) and the substrate over which they migrate in early embryos of the anuran amphibian Xenopus laevis. P.g.cs migrate from the embryonic gut to the dorsal body wall along the dorsal mesentery at the earliest swimming stage. Our earlier papers have described the way in which p.g.cs move in vitro. In this work we have studied the shape and cytoarchitecture of both p.g.cs and the coelomic epithelial cells (c.e.cs) over which they migrate. We have concentrated on three aspects of the morphology of these cells: first the shapes of the c.e.cs and the way that they affect the shapes of the p.g.cs; secondly the presence of adhesion plaques between the two types of cell; and thirdly the arrangement of cytoskeleton elements. The results show that c.e.cs in the dorsal mesentery are orientated cranio-caudally while those on the dorsal body wall and at the junction with the mesentery are arranged transversely, at 90 degrees to the cranio-caudal plane. P.g.cs are found in both elongated and rounded state. Where elongated, they are always in the same plane as the c.e.cs with which they are associated. The implications of this are discussed. Adhesion plaques between p.g.cs and c.e.cs are shown both by disaggregation studies and transmission electron microscope studies. Plaques are associated with the well defined microfilamentous cytoskeleton of c.e.cs, but only with a sparse array of filaments in p.g.cs. The only parts of p.g.cs where filaments are regularly found are their filopodia, which are generally seen on elongated p.g.cs in longitudinal section. We suggest on the basis of this work that p.g.cs have a dispersed cytoskeleton except during filopod extension, that they move by forming direct adhesion plaques with c.e.cs, and that c.e.cs provide a firm orientated support and possible guide to p.g.c. movement.