Protease-insensitive sea urchin embryo cell adhesions become protease sensitive in the presence of azide or cytochalasin B

To understand the nature of the cell adhesions that must be modified during sea urchin embryo primary mesenchyme formation, we are studying the adhesive components of the hatched blastula stage embryo of Strongylocentrotus purpuratus. Pronase treatment conditions have been defined that leave the cells intact and able to recover from the effects of the protease upon its removal. Under these conditions, adhesion of the cells to tissue culture plates is totally eliminated, but cell-cell adhesion formation is only partially inhibited. Analysis of iodinated cell surface proteins indicates that most are affected by thepronase. Further studies of pronase effects found that sodium azide-treated cells are slightly adhesive and that pronase treatment of azidc-treated cells totally eliminates cell-cell adhesions.     

Different aggregation properties of sea urchin embryonic cells at different developmental stages. I. Stage specificity of aggregation factors solubilized by butanol

Surface proteins solubilized with butanol from purified plasma membranes of sea urchin embryos at different developmental stages were tested for their aggregation promoting activity on dissociated cells. Cells used for the assays were obtained either from blastulae or from embryos at the 16 cell stage. Results show that a strong enhancement of cell aggregation was produced only when extracted proteins and dissociated cells were obtained from embryos at the same developmental stage.     

Characterization of bep1 and bep4 antigens involved in cell interactions during Paracentrotus lividus development

We have identified and partially characterised two antigens, extracted with 3% butanol, from Paracentrotus lividus embryos dissociated at the blastula stage, and encoded by the cDNA clones previously described as bep1 and bep4 (bep-butanol extracted proteins). The cDNA fragments containing the specific central portions of bep1 and bep4 were expressed as MS2 polymerase fusion proteins in Escherichia coli. These two fusion proteins, called 1C1 (bep1) and 4A1 (bep4), were injected subcutaneously into rabbits and the corresponding polyclonal antibodies generated. Western blot analysis of proteins, extracted with 3% butanol, from sea urchin embryos at the blastula stage (b.e.p.), established that both antibodies recognize two 33 KDa proteins. Reducing and non-reducing electrophoretic conditions show that both antibodies against bep1 and bep4 related proteins react also with a protein band of a molecular weight 66 KDa, indicating that these two antigens probably exist as dimers. Immunolocalization with anti 1C1 and 4A1 antibodies shows the presence of the related antigens also on the cell surface. Fab fragments of the polyclonal antibodies against 1C1 and 4A1 inhibited reaggregation of sea urchin embryonic cells, dissociated from blastula stage embryos. This prevention of reaggregation indicates that these proteins probably play a role in cell interaction during sea urchin embryonic development.     

Reconstituting the kinetochore–microtubule interface: what, why, and how

The kinetochore is the proteinaceous complex that governs the movement of duplicated chromosomes by interacting with spindle microtubules during mitosis and meiosis. Faithful chromosome segregation requires that kinetochores form robust load-bearing attachments to the tips of dynamic spindle microtubules, correct microtubule attachment errors, and delay the onset of anaphase until all chromosomes have made proper attachments. To understand how this macromolecular machine operates to segregate duplicated chromosomes with exquisite accuracy, it is critical to reconstitute and study kinetochore–microtubule interactions in vitro using defined components. Here, we review the current status of reconstitution as well as recent progress in understanding the microtubule-binding functions of kinetochores in vivo.     

Introduction to the Symposium and Studies on the Surfaces of Separated and Synchronized Tumor and Embryonic Cell Populations

Tumor and embryonic cell surfaces are examined in this symposiumwith respect to their roles in cell-cell interactions and inearly development and malignancy. Three sets of studies havebeen recently performed in my laboratory to help elucidate thenature of tumor and embryonic cell surfaces and the means bywhich these cells adhere to each other. We separated an in vivo129/J ascites mouse teratoma into specific subpopuladons ofcells by velocity sedimentation in shallow density gradients.The teratoma consistently separated into two major populations:"large" and "small" cells. Only the large cells displayed "malignant-like"surface characteristics in terms of their agglutinability withcarbohydrate binding lectins. The teratoma cells were also synchronizedin culture with thymidine plus colcemid. In these synchronizedcultures, cellular adhesiveness and glutamine synthetase specificactivity displayed oscillatory patterns with peaks of glutaminesynthetase specific activity occurring just prior to peaks ofadhesivenesss. Also, both glutamine synthetase specific activityand cellular adhesiveness were enhanced by two compounds: actinomycinD and hydrocortisone. Based upon previous work that implicatesL-glutamine in intercellular adhesion, it is not unreasonableto speculate that glutamine synthetase specific activity andcellular adhesiveness may be causally related. The problem ofaltered tumor cell adhesiveness is important because it seems,in part, to be responsible for tumor spread. Finally, the seaurchin embryo system was utilized to identify specific cellsurface carbohydrates that may be involved in intercellularadhesion. In 15 separate experiments with each sugar and with15 different saccharides, D-galactose and N-acetyl-D-galactosaminewere the best inhibitors of rotation-medicated reaggregationof 24-hr sea urchin embryo cells dissociated by removal of divalentcations. ß-galactosidase also inhibited reaggregationof these cells. These results implicate galactopyranosyl-likeresidues in the adhesion of 24-hr sea urchin embryo cells witheach other.     

New bioengineering insights into human neural precursor cell expansion in culture

Understanding initial cell growth, interactions associated with the process of expansion of human neural precursor cells (hNPCs), and cellular events pre- and postdifferentiation are important for developing bioprocessing protocols to reproducibly generate multipotent cells that can be used in basic research or the treatment of neurodegenerative disorders. Herein, we report the in vitro responses of telencephalon hNPCs grown in a serum-free growth medium using time-lapse live imaging as well as cell-surface marker, aggregate size, and immunocytochemical analyses. Time-lapse analysis of hNPC initial expansion indicated that cell-surface attachment in stationary culture and the frequency of cell-cell interaction in suspension conditions are important for subsequent aggregate formation and hNPC growth. In the absence of cell-surface attachment in low-attachment stationary culture, large aggregates of cells were formed and expansion was adversely affected. The majority of the telencephalon hNPCs expressed CD29, CD90, and CD44 (cell surface markers involved in cell-ECM and cell-cell interactions to regulate biological functions such as proliferation), suggesting that cell-surface attachment and cell-cell interactions play a significant role in the subsequent formation of cell aggregates and the expansion of hNPCs. Before differentiation, about 90% of the cells stained positive for nestin and expressed two neural precursor cells surface markers (CD133 and CD24). Upon withdrawal of growth cytokines, hNPCs first underwent cell division and then differentiated preferentially towards a neuronal rather than a glial phenotype. This study provides key information regarding human NPC behavior under different culture conditions and favorable culture conditions that are important in establishing reproducible hNPC expansion protocols.     

Species-specific dissociation into single cells of live sea urchin embryos by fab against membrane components of Paracentrotus lividus and Arbacia lixula

The species and stage specificities of membrane components active in promoting reaggregation of cells dissociated from embryos of the two Mediterranean sea urchin species Paracentrotus lividus and Arbacia lixula have been examined. Membrane proteins extracted with butanol either from purified membranes or from dissociated cells without significant reduction of viability promoted reaggregation of both the homologous and heterologous species. Extracts from plutei and blastulae were equally effective in promoting reaggregation of blastula cells. By contrast, Fab's prepared from IgG raised against these extracts or purified membranes are strictly species specific because they prevent reaggregation of cells and actively dissociate live embryos of only the homologous species. No corresponding stage specificity of the Fab was observed: Fab against extracts from blastula embryos also caused dissociation of plutei. Antigenic analysis of the extracts by the Ouchterlony test revealed the presence of components specific for each species as well as others common to both.     

Alteration of sea urchin embryo cell surface properties by mycostatin, a sterol binding antibiotic

Sea urchin embryos incubated in sea water containing mycostatin (MST), a polyene antibiotic, dissociate into single cells. Reaggregation of dissociated sea urchin embryo cells, and uptake of labeled precursors by these cells are also greatly inhibited although O₂ consumption is only slightly affected by this compound. It is known that mycostatin binds primarily to membrane sterols and affects only cells containing membrane sterols. Sea urchin cell membranes contain sterols. The effects of mycostatin on cell adhesion, reaggregation, and permeability seen in this study may be a result of an interaction with cell membrane sterols or sterol-associated molecules.     

Quantitative agglutination of specific populations of sea urchin embryo cells with concanavalin A

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated 32/64 cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

A histological and ultrastructural analysis of developmental defects produced by the mutation,lethal(1)myospheroid,in Drosophila melanogaster

The recessive embryonic lethal, lethal(1)myospheroid, is located at 21.7 map units on the X chromosome in Drosophila melanogaster. Embryos hemizygous for this mutation appear to develop normally until the time of the first muscular contractions. Due to the physical stress of these initial contractions, dramatic tissue separations occur, which characterize the phenotype of this mutation. The dorsal suture separates with the herniation of midgut and nervous tissue, and the somatic and visceral muscles retract from their sites of attachment. An ultrastructural examination of the development of the muscle attachment sites in these embryos indicates that in 1(1)mys embryos there is a delay in the formation of normal cell-cell attachments. At the muscle-tendon cell junction, the deposition of the apparently normal extracellular matrix of this desmosomal attachment occurs considerably later in development than normal. The 1(1)mys locus apparently makes a product which is either defective, made more slowly, or produced in smaller amounts than normal. The 1(1)mys product is probably necessary for the production of a component of the extracellular matrix of cell-cell attachments.     

Primary culture of Caenorhabditis elegans developing embryo cells for electrophysiological, cell biological and molecular studies

Cell culture is an invaluable tool for investigation of basic biological processes. However, technical hurdles including low cell yield, poor cell differentiation and poor attachment to the growth substrate have limited the use of this tool for studies of the genetic model organism Caenorhabditis elegans. This protocol describes a method for the large-scale culture of C. elegans embryo cells. We also describe methods for in vitro RNA interference, fluorescence-activated cell sorting of embryo cells and imaging of cultured cells for patch-clamp electrophysiology studies. Developing embryos are isolated from gravid adult worms. After eggshell removal by enzymatic digestion, embryo cells are dissociated and plated onto glass substrates. Isolated cells terminally differentiate within 24 h. Analysis of gene expression patterns and cell-type frequency suggests that in vitro embryo cell cultures recapitulate the developmental characteristics of L1 larvae. Cultured embryo cells are well suited for physiological analysis as well as molecular and cell biological studies. The embryo cell isolation protocol can be completed in 5-6 h.     

Survival and maturation of cerebral neurons on poly(l-lysine) surfaces in the absence of serum

Several phenotypic properties of dissociated rat embryo cerebral cells cultivated in the absence of serum on poly(l-lysine) coated surfaces were investigated. A great enrichment of neuronal cells is attained after 3–4 weeks in culture as a result of cessation of nonneuronal cell proliferation. The monolayer pattern of cell-cell reassociation and neuritic sprouting is promoted by poly(l-lysine) and it is independent of serum presence or the existence of a layer of nonneuronal cells. Synaptic profiles and typical regions of neuropil are prominent. The neuronal plasma membrane is often characterized by irregular foldings at points of cell-cell contacts. A few biochemical parameters investigated lend support to the suggestion that the cerebral neurons acquire a certain state of functional maturation. It is proposed that substances secreted by the cells or released as a result of cell death may be conspicuous components for long-term survival of the cerebral neurons.     

Effect of central myelin on the proliferation and differentiation into O4+ oligodendrocytes of GFP-NSCs

Cell adhesion is an important process during morphogenesis, differentiation, and homeostasis in cell biology. The role of vascular endothelial growth factor (VEGF) in cell adhesion of keratinocytes is unclear. In our study, a human keratinocyte cell line, HaCaT cells, which mimics various properties of normal epidermal keratinocytes, was included to elucidate the effect of VEGF on cell-cell adhesion and cell-plate adhesion. Expression of adhesion molecules account for cell adhesion and signal transduction pathways involved in the effect of VEGF on adhesion of HaCaT cells were further investigated. Significant increase of cell-cell adhesion but decrease of the cell-plate adhesion of HaCaT cells induced by VEGF(165) was detected. VEGF increases expression of E-cadherin, but inhibits expression of integrin α6β4 subunit. VEGF(165) at 100?ng/ml activates extracellular signal-regulated kinase. These changes of cell adhesion induced by VEGF were blocked by ERK and VEGFR-2 inhibitor. Our findings suggest that VEGF may modulate cell adhesion of HaCaT cells partly through activation of VEGFR-2/ERK1/2 signaling pathways.     

Spatial periodicity of Escherichia coli K-12 biofilm microstructure initiates during a reversible, polar attachment phase of development and requires the polysaccharide adhesin PGA

Using fast Fourier transform (FFT) analysis, we previously observed that cells within Escherichia coli biofilm are organized in nonrandom or periodic spatial patterns. Here, we developed a gravity displacement assay for examining cell adherence and used it to quantitatively monitor the formation of two distinct forms of cell attachment, temporary and permanent, during early biofilm development. Temporarily attached cells were mainly surface associated by a cell pole; permanent attachments were via the lateral cell surface. While temporary attachment precedes permanent attachment, both forms can coexist in a population. Exposure of attached cells to gravity liberated an unattached population capable of rapidly reassembling a new monolayer, composed of temporarily attached cells, and possessing periodicity. A csrA mutant, which forms biofilm more vigorously than its wild-type parent, exhibited an increased proportion of permanently attached cells and a form of attachment that was not apparent in the parent strain, permanent polar attachment. Nevertheless, it formed periodic attachment patterns. In contrast, biofilm mutants with altered lipopolysaccharide synthesis (waaG) exhibited increased cell-cell interactions, bypassed the polar attachment step, and produced FFT spectra characteristic of aperiodic cell distribution. Mutants lacking the polysaccharide adhesin beta-1,6-N-acetyl-d-glucosamine (DeltapgaC) also exhibited aperiodic cell distribution, but without apparent cell-cell interactions, and were defective in forming permanent attachments. Thus, spatial periodicity of biofilm microstructure is genetically determined and evident during the formation of temporary cell surface attachments.     

Extracellular Matrix Surface Network During Plant Regeneration in Wheat Anther Culture

Androgenic plant regeneration from wheat anther callus was accompanied by the formation of a conspicuous extracellular matrix surface network (ECMSN) around the induced callus cells and young embryo-like structures. Microscopic observations at the onset of regeneration revealed the presence of two distinct types of cells on the callus surface: large, loosely attached parenchymatous cells and small tightly packed meristematic cells arranged in multicellular clusters. Parenchyma cells of the callus had smooth surface, while on the surface and between the cells of multicellular clusters numerous fine fibrils of ECMSN were observed. The structural arrangement of the ECMSN changed during culture. On the surface of globular embryo-like structures, before protoderm formation, the ECMSN was the most abundant and arranged as a compact layer of secretion with wide strands visible at the cell junctions. Further development of globular embryos was disturbed, giving rise to branched structures outlined by continuous epidermis. The development of such regenerants was accompanied by gradual degradation of the extracellular network and finally its complete disappearance. Digestion with protease did not destroy the network. Treatment of the calluses with chloroform and washing with ether–methanol led to partial destruction of the network, while digestion with pectinase removed the network completely and resulted in the collapse of surface embryo cells.     

Polyadenylation of nascent RNA during the embryogenesis of Ilyanassa obsoleta.

It has been demonstrated that specific changes in carbohydrate-containing cell surface lectin receptor sites occur with differentiation and maturation of sea urchin embryo cells. In this study, evidence is presented, using a quantitative electronic particle counter assay to measure agglutination, which indicates that concanavalin A (Con A) mediated agglutination of dissociated $\text{32}\text{64}$ cell sea urchin embryos differs dramatically with respect to specific cell populations. The migratory cell type, the micromere, is significantly more agglutinable with Con A than the other cell types and colchicine treatment markedly increases sea urchin embryo cell agglutinability. The results indicate that like many malignant cells which display extensive migratory behavior, specific migratory populations of embryonic cells are agglutinable with Con A. The results are discussed with respect to the possible nature of lectin receptor sites on specific populations of embryonic cells and the possible role of colchicine-sensitive structures in controlling the display patterns of these sites.     

Local cell interactions and the control of gastrulation in the sea urchin embryo

The sea urchin embryo is a good model system for studying the role of mechanical and cell-cell interactions during epithelial invagination, cell rearrangement and mesenchymal patterning in the gastrula. The mechanisms underlying the initial invagination of the archenteron have been surprisingly elusive; several possible mechanisms are discussed. In contrast to its initial invagination, the cellular basis for the elongation of the archenteron is better understood: both autonomous epithelial cell rearrangement and further rearrangement driven by secondary mesenchyme cells appear to be involved. Experiments indicate that patterning of freely migrating primary mesenchyme cells and secondary mesenchyme cells residing in the tip of the archenteron relies to a large extent on information resident in the ectoderm. Interactions between cells in the early embryo and later cell-cell interactions are both required for the establishment of ectodermal pattern information. Surprisingly, in the case of the oral ectoderm the fixation of pattern information does not occur until immediately prior to gastrulation.     

Involvement of Collagen Synthesis in Tissue Reconstitution by Dissociated Sponge Cells

Cells dissociated from the sponge Haliclona permollis reconstituted a new body by the following three consecutive processes: (1) Reaggregation, cells aggregate as a spheroidal mass. (2) Spreading, aggregates flatten and spread. (3) Reconstruction, aggregates coalesce into a reconstituted body. Cells in the process of reconstitution incorporated ¹⁴C-proline into proteins, converting 17% of it to hydroxyproline and synthesize collagen molecules during this process. Inhibitors of collagen biosynthesis did not affect the reaggregation, but caused incomplete morphogenesis in the processes of spreading and reconstruction: cycloheximide and 2,2'-dipyridyl inhibited spreading while 3-aminopropionitrile induced incomplete reconstruction. These findings suggested that spreading and reconstruction, but not reaggregation require both synthesis and cross-linking of collagens. Three polypeptides with molecular weights of 58 K, 160 K and 180 K were identified in sponge cells as collagens by immunoblot analysis with antibodies against sea urchin collagen and studies on susceptibilities to collagenase and pepsin. The 58 KDa polypeptide appeared in reconstituted bodies but not in dissociated cells, suggesting its importance in tissue reconstitution by dissociated cells.     

The Effects of Chemical Animalizing and Vegetalizing Agents and of Cell Dissociation on the Synthesis of 5S RNA and Transfer RNA in Cleaving Sea Urchin Embryos

The effect of altering normal cell associations and interactions on the synthesis of 5S RNA and transfer RNA (tRNA) was studied in cleaving embryos of the sea urchin, Arbacia punctulata. Cell interactions were altered: (1) by culturing cleaving embryos in the animalizing agent, Evans Blue, and in the vegetalizing agent, Li⁺ as LiCl and (2) by culturing dissociated cells. Control and experimental embryos each were labeled from 3 h to 6 h post fertilization with [8-³H]-guanosine. Sixteen-cell embryos, whose GTP precursor pools had been preloaded, were dissociated, labeled and cultured under conditions which prevent reaggregation. Quantitative measurements of rates of accumulation of newly synthesized 5S RNA and tRNA showed that these rates are similar in cleaving sea urchin embryos and in corresponding embryos cultured in the presence of Evans Blue and of Li⁺. In addition, cells dissociated from cleavage embryos and maintained under conditions which prevent reaggregation retained the ability to synthesize 5S RNA and tRNA. These results suggest that normal cell associations and interactions are not necessary for the synthesis of 5S RNA and tRNA to occur in cleaving sea urchin embryos.     

Liposomes inhibit intercellular attachment

Phosphatidylcholine liposomes bound to the surface of L cells inhibit cell attachment to L-cell monolayers or to lipid films. Aggregation of L cells or of mouse embryo fibroblasts is also diminished upon treatment with liposomes. However, they neither inhibit cell attachment to glass or cellulose acetate substrata, nor diminish conA-mediated cell aggregation. It is supposed that liposome-binding sites on the cell surface described earlier are involved in cell-cell attachment.