Fibroblast receptor for cell-substratum adhesion: studies on the interaction of baby hamster kidney cells with latex beads coated by cold insoluble globulin (plasma fibronectin)

Studies were carried out on the interactions of uncharged latex beads (0.76 micrometer) with baby hamster kidney cells. Binding of beads to the cells occurred if the beads were coated by cold insoluble globulin (CIG) (plasma fibronectin) but not if the beads were coated by bovine albumin. Bovine albumin-coated beads did not bind to the cells even in the presence of excess CIG in the incubation medium. Binding of beads occurred randomly over the entire surfaces of cells in suspension. However, cell receptors for CIG beads were no longer detectable on the upper surface of cells spread onCIG-coated tissue culture dishes. Binding of CIG beads to cells occurred at all temperatures tested from 4 degrees to 37 degrees C but the rate was lowest at 4 degrees C. At 37 degrees C, binding was accompanied by endocytosis and the beads were found inside vesicles which appeared to be lysosomes. There was also release of radioactivity from radiolabeled CIG beads during incubation with the cells at 37 degrees C. Binding of CIG beads to cells did not require divalent cations. Finally, the cell receptor for CIG beads was lost after cell trypsinization. The data are discussed in terms of current ideas about the basis for cell adhesion.     

Lactococcus lactis release from calcium alginate beads.

Cell release during milk fermentation by Lactococcus lactis immobilized in calcium alginate beads was examined. Numbers of free cells in the milk gradually increased from 1 x 10(6) to 3 x 10(7) CFU/ml upon successive reutilization of the beads. Rinsing the beads between fermentations did not influence the numbers of free cells in the milk. Cell release was not affected by initial cell density within the beads or by alginate concentration, although higher acidification rates were achieved with increased cell loading. Coating alginate beads with poly-L-lysine (PLL) did not significantly reduce the release of cells during five consecutive fermentations. A double coating of PLL and alginate reduced cell release by a factor of approximately 50. However, acidification of milk with beads having the PLL-alginate coating was slower than that with uncoated beads. Immersing the beads in ethanol to kill cells on the periphery reduced cell release, but acidification activity was maintained. Dipping the beads in aluminum nitrate or a hot CaCl2 solution was not as effective as dipping them in ethanol. Ethanol treatment or heating of the beads appears to be a promising method for maintaining acidification activity while minimizing viable cell release due to loosely entrapped cells near the surface of the alginate beads.     

Lactococcus lactis release from calcium alginate beads.

Cell release during milk fermentation by Lactococcus lactis immobilized in calcium alginate beads was examined. Numbers of free cells in the milk gradually increased from 1 x 10(6) to 3 x 10(7) CFU/ml upon successive reutilization of the beads. Rinsing the beads between fermentations did not influence the numbers of free cells in the milk. Cell release was not affected by initial cell density within the beads or by alginate concentration, although higher acidification rates were achieved with increased cell loading. Coating alginate beads with poly-L-lysine (PLL) did not significantly reduce the release of cells during five consecutive fermentations. A double coating of PLL and alginate reduced cell release by a factor of approximately 50. However, acidification of milk with beads having the PLL-alginate coating was slower than that with uncoated beads. Immersing the beads in ethanol to kill cells on the periphery reduced cell release, but acidification activity was maintained. Dipping the beads in aluminum nitrate or a hot CaCl2 solution was not as effective as dipping them in ethanol. Ethanol treatment or heating of the beads appears to be a promising method for maintaining acidification activity while minimizing viable cell release due to loosely entrapped cells near the surface of the alginate beads.     

Immobilization of Mucor javanicus lipase by entrapping in alginate-silica hybrid gel beads with simultaneous cross-linking with glutaraldehyde

Mucor javanicus lipase was entrapped in alginate-silica hybrid gel beads with or without simultaneous cross-linking with glutaraldehyde. The activity and recovery of activity on immobilization of the enzyme entrapped in the hybrid beads were 1.4 and 1.7 times higher than those of the enzyme entrapped in the simple alginate beads. Entrapment with simultaneous cross-linking in the hybrid beads further improved the enzyme activity (1.6 times) and activity recovery (1.7 times) compared to those of the enzyme entrapped in the hybrid beads without simultaneous cross-linking. The leakage of the enzyme entrapped in the hybrid beads with simultaneous cross-linking was only 50% that of the enzyme entrapped in the simple alginate beads.     

Immobilization of Mucor javanicus lipase by entrapping in alginate-silica hybrid gel beads with simultaneous cross-linking with glutaraldehyde

Mucor javanicus lipase was entrapped in alginate-silica hybrid gel beads with or without simultaneous cross-linking with glutaraldehyde. The activity and recovery of activity on immobilization of the enzyme entrapped in the hybrid beads were 1.4 and 1.7 times higher than those of the enzyme entrapped in the simple alginate beads. Entrapment with simultaneous cross-linking in the hybrid beads further improved the enzyme activity (1.6 times) and activity recovery (1.7 times) compared to those of the enzyme entrapped in the hybrid beads without simultaneous cross-linking. The leakage of the enzyme entrapped in the hybrid beads with simultaneous cross-linking was only 50% that of the enzyme entrapped in the simple alginate beads.     

Evaluation of alternatives to expanded polystyrene beads for mosquito control

Expanded polystyrene (EPS) beads have been shown to be an effective tool for controlling immature stages of mosquitoes, as well as preventing oviposition by adults. Polystyrene does not biodegrade quickly, resulting in some concerns about its effect on the environment. A potential solution is the use of biodegradable materials that cover the surface of mosquito breeding sites in the same way as EPS beads. Two candidates are polylactic acid (PLA) beads and corn starch shreds. Larval mortality and adult emergence of Culex quinquefasciatus Say (Diptera: Culicidae) were monitored in bowls with each of four treatments: EPS beads, PLA beads, corn starch shreds and a control. The PLA beads were as effective as EPS beads at preventing mosquito emergence, whereas the shredded corn starch treatment resulted in significantly higher rates of emergence to the control. Similarly, EPS and PLA beads resulted in 100% mortality after 10 days, while there was low mortality of larvae in the corn starch (9%) and control treatments (20%). PLA beads provided similar levels of mortality and reduction in adult emergence as EPS beads. However, the production requirements of PLA beads may limit its use in field conditions.     

Latex beads as probes of a neural crest pathway: effects of laminin, collagen, and surface charge on bead translocation

In the trunk region of avian embryos, neural crest cells migrate along two pathways: dorsally just under the ectoderm, and ventrally between the neural tube and the somites. Previous work from this laboratory has shown that uncoated latex beads are able to translocate along the ventral neural crest pathway after injection into young embryos; however, beads coated with fibronectin are restricted from the ventral route ( Bronner -Fraser, M.E., 1982, Dev. Biol., 91: 50-63). Here, we extend these observations to determine the effects of other macromolecules on bead distribution. The data show that laminin-coated beads, like fibronectin-coated beads, are restricted from the ventral pathway. In contrast, beads coated with type I collagen translocate ventrally after injection. Because macromolecules have characteristic charge properties, changes in surface charge caused by coating the beads may confound interpretation of the results. Electrostatic effects on bead movement were examined by coating the latex beads with polyamino acids in order to predictably alter the initial surface charge. The surface charge before injection was measured for beads coated with amino acid polymers or with various biologically important macromolecules; the subsequent translocation ability of these beads was then monitored in the embryo. Polylysine-coated beads (positively charged) were restricted from the ventral pathway as were fibronectin and laminin-coated beads, even though fibronectin and laminin beads were both negatively charged. In contrast, polytyrosine -coated beads ( neutrally charged) translocated ventrally as did negatively charged collagen-coated or uncoated beads. The results demonstrate that no correlation exists between the charge properties on the latex bead surface and their subsequent ability to translocate along the ventral pathway. Therefore, an adhesion mechanism independent of surface charge effects must explain the restriction or translocation of latex beads on a neural crest pathway.     

Chitosan coated alginate beads for the survival of microencapsulated Lactobacillus plantarum in pomegranate juice

This work studied the effect of multi-layer coating of alginate beads on the survival of encapsulated Lactobacillus plantarum in simulated gastric solution and during storage in pomegranate juice at 4°C. Uncoated, single and double chitosan coated beads were examined. The survival of the cells in simulated gastric solution (pH 1.5) was improved in the case of the chitosan coated beads by 0.5-2 logs compared to the uncoated beads. The cell concentration in pomegranate juice after six weeks of storage was higher than 5.5logCFU/mL for single and double coated beads, whereas for free cells and uncoated beads the cells died after 4 weeks of storage. In simulated gastric solution, the size of the beads decreased and their hardness increased with time; however, the opposite trend was observed for pomegranate juice, indicating that there is no correlation between cell survival and the hardness of the beads.     

Inhibition of gap-junctional intercellular communication and enhanced binding of fibronectin-coated latex beads by stimulation of DNA synthesis in quiescent 3T3-L1 cells

To clarify the modulation of intercellular communication via gap junctions, associated with the growth induction of quiescent 3T3-L1 cells, we investigated the gap-junctional intercellular communication in growth-stimulated cells that were able to bind fibronectin-coated beads. When quiescent 3T3-L1 cells were incubated with fibronectin-coated beads for the first 2 h after the addition of calf serum, 24.0% of the cells bound and phagocytosed beads. Among the cells with bound beads, the percentage of the cells labeled concurrently with bromodeoxyuridine was 63.7% when examined 13 h after the addition of calf serum. Transient reduction of dye-coupling, measured with Lucifer Yellow CH, was observed only in the cells with bound beads 2 h after addition of calf serum, but it was not observed in the cells without bound beads. When the quiescent cells were incubated with fibronectin-coated beads for 2 h from 4-6 h after the addition of calf serum, the percentage of cells with bound beads increased to 53.1%, but the decrease in dye-coupling among the cells with bound beads was slight. These results suggest that the induction of cell growth causes a transient reduction in gap-junctional intercellular communication in 3T3-L1 cells with bound fibronectin-coated beads.     

Diffusion characteristics of substrates in Ca-alginate gel beads

The diffusion characteristics of several substrates of varying molecular sizes into and from Ca-alginate gel beads in well-stirred solutions were investigated. The values of the diffusion coefficient (D) of substrates such as glucose, L-tryptophan, and alpha-lactoalbumin [with molecular weight (MW) less than 2 x 10(4)] into and from the gel beads agreed with those in the water system. Their substrates could diffuse freely into and from the gel beads without disturbance by the pores in the gel beads. The diffusion of their substrates into and from the gel beads was also not disturbed by increasing the Ca-alginate concentration in the beads and the CaCl(2) concentration used in the gel preparation. In the case of higher molecular weight substances such as albumin (MW = 6.9 x 10(4)), gamma-globulin (MW = 1.54 x 10(5)) and fibrinogen (MW = 3.41 x 10(5)), the diffusion behaviors of the substrates into and from the gel beads were very different. No diffusion of their substrates into the gel beads from solutions was observed, and only albumin was partly absorbed on the surface of the gel beads. The values of D of their substrates from the gel beads into their solutions were smaller than their values in the water system, but all their substrates could diffuse from the gel beads. The diffusion of high molecular weight substrates was limited more strongly by the increase of Ca-alginate concentration in the gel beads than by the increase of the CaCl(2) concentration used in the gel preparation. Using these results, the capacity of Ca-alginate gel as a matrix of immobilization was discussed.     

Microinjected carboxylated beads move predominantly poleward in sea urchin eggs

Observations on living mitotic cells have suggested that material in the spindle moves poleward during mitosis. In order to investigate this movement, sea urchin eggs have been microinjected with 0.25-micron diameter carboxylated fluorescent beads. When fluorescent beads were injected into unfertilized Lytechinus variegatus eggs, no motility was detected. When injected into mitotic cells, beads moved to the spindle poles. Individual beads moved rapidly, in a saltatory fashion, and followed generally linear paths. Beads appeared to move along astral fibers, were generally excluded from the spindle proper, and accumulated at the spindle poles. Some dispersion of the beads away from the pole was observed as cells completed mitosis, but the majority of beads retained a polar location. After depolymerization of spindle microtubules with nocodazole, some dispersion of beads into the cytoplasm was also observed. Beads moved along taxol-induced astral microtubules and accumulated at astral centers. These observations reveal that negatively charged beads accumulate rapidly at mitotic centers, moving toward the minus end of the microtubules. Neither the bidirectional motility of similar beads in interphase cells nor the plus-end-directed bead motility seen in axons was observed in these mitotic cells.     

Cell surface action of thrombin is sufficient to initiate division of chick cells

Thrombin covalently linked to carboxylate-modified polystyrene beads initiated division of quiescent chick embryo (CE) cells either in medium containing low levels of serum or in serum-free medium. Release of thrombin was monitored by measuring acid-precipitable radioactivity released from 125I-thrombin beads into the medium during incubation with cells. Even if all of the acid-precipitable material released from the beads were active thrombin, it was not sufficient to account for any of the observed cell division, and was 10-30 fold less than the amount necessary to produce the increase in cell number caused by the thrombin beads. Two other kinds of experiments also showed that material released into the medium did not account for the observed initiation of cell division. First, medium taken from cultures incubated with thrombin beads did not initiate cell division when added to new quiescent cultures. Second, in coverslip experiments where populations of cells with an without thrombin feads shared the same medium, only bead-contacted cells divided. Several results suggested that the material which was released from the thrombin beads resulted from cell-associated proteolysis rather than from "leakage" of intact thrombin from the beads. For example, after incubating 125I-thrombin beads with or without CE cells, we were unable to detect any intact thrombin released into the medium. In addition, most of the material released from the beads was acid-soluble and was only released in the presence of CE cells. A few thrombin beads were endocytosed by CE cells, but they were surrounded by an intact plasma membrane. Thus they did not directly interact with the cytoplasm. The close association of many of the beads with the cell surface and the presence of a few beads in endocytic vesicles made it important to consider the possibility that thrombin might be released from the beads directly into the cells. This possibility was explored using ultrastructural (EM) autoradiography. With this technique (where one grain represented 700--900 thrombin molecules), we found that beads inside the cells had approximately the same number of grains as beads not in contact with cells. This suggested that little, if any, additional radioactive material had been released from the beads which were in contact with the cells. In addition, we were unable to detect any grains in the cytoplasm which could be attributed to released thrombin, even using an amount of 125I-thrombin beads which was 8 fold greater than the amount which produced maximal cell division. Taken together, these results provide direct evidence that thrombin action at the cell surface is sufficient to initiate division of CE cells.     

Bacterial cellulose-chitosan composite hydrogel beads for enzyme immobilization

In this work, we report the preparation of bacterial cellulose (BC)-chitosan composite hydrogel beads by co-dissolution of BC and chitosan in 1-ethyl-3-methylimidazolium acetate and subsequent reconstitution with distilled water. The BC-chitosan hydrogel beads were used as enzyme supports for immobilizing Candida rugosa lipase by physical adsorption and covalent cross-linking. BC-chitosan hydrogel beads immobilized lipase more efficiently than microcrystalline cellulose (MCC)-chitosan hydrogel beads. The amount of protein adsorbed onto BCchitosan beads was 3.9 times higher than that adsorbed onto MCC-chitosan beads, and the catalytic activity of lipase was 1.9 times higher on the BC-chitosan beads. The lipase showed the highest thermal and operational stability when covalently cross-linked on BC-chitosan hydrogel beads. The half-life time of the lipase cross-linked on BC-chitosan bead at 60°C was 22.7 times higher than that of free lipase. Owing to their inherent biocompatibility and biodegradability, the BC-chitosan composite hydrogel beads described here could be used to immobilize proteins for various biomedical, environmental, and biocatalytic applications.     

Effects of different fragments of the fibronectin molecule on latex bead translocation along neural crest migratory pathways

Previous studies from this laboratory have utilized latex beads as probes of embryonic migratory pathways. After microinjection into embryos at the time of neural crest migration, uncoated latex polystyrene beads were found to translocate to ventral sites and to settle in the vicinity of endogenous neural crest derivatives. However, latex beads coated with fibronectin did not translocate ventrally, but remained associated with cells surrounding the implantation site. Fibronectin is a large glycoprotein with a variety of biological activities and multiple binding domains. Here, the binding activities which might be responsible for immobilization of the fibronectin-coated beads are examined. Latex beads were coated with three types of fragments of the fibronectin molecule representing different functional domains: (i) a 66-kDa fragment containing collagen-binding activity; (ii) a mixture of 45- and 32-kDa fragments containing heparin-binding activity; and (iii) a 120-kDa fragment containing cell-binding activity. The beads coated with fibronectin fragments were injected into the newly formed trunk somites of avian embryos. After injection, beads coated with either the heparin- or the collagen-binding domain translocated ventrally and distributed analogously to uncoated latex beads. In contrast, the majority of beads coated with the fibronectin cell-binding domain did not translocate but remained associated with dermamyotomal cells surrounding the injection site. The cell-binding fragment, however, was not as effective as the intact fibronectin molecule in preventing translocation of the beads. The results suggest that the cell-binding domain is primarily responsible for restriction of fibronectin beads from the ventral neural crest pathway. Because intact fibronectin is more effective at immobilizing beads than is the cell-binding fragment, other binding domains of fibronectin, more efficient coating with intact fibronectin, or crosslinking of intact fibronectin molecules may also play some role in immobilization of the beads at the implantation site.     

Fibronectin-mediated binding and phagocytosis of polystyrene latex beads by baby hamster kidney cells

The binding and phagocytosis of fibronectin (pFN)-coated latex beads by baby hamster kidney (BHK) cells was studied as a function of fibronectin concentration and bead diameter. Cells were incubated with radioactive pFN-coated beads, and total bead binding (cell surface or ingested) was measured as total radioactivity associated with the cells. Of the bound beads, those that also were phagocytosed were distinguished by their insensitivity to release from the cells by trypsin treatment. In continuous incubations, binding of pFN-coated beads to cells occurred at 4 degrees C or 37 degrees C, but phagocytosis was observed only at 37 degrees C. In addition, degradation of 3H-pFN from ingested beads occurred at 37 degrees C, as shown by the release of trichloroacetic acid-soluble radioactivity into the incubation medium. When the fibronectin density on the beads was varied, binding at 4 degrees C and ingestion at 37 degrees C were found to have the same dose-response dependencies, which indicated that pFN densities that permitted bead binding were sufficient for phagocytosis to occur. The fibronectin density for maximal binding of ingestion was approximately 250 ng pFN/cm2. When various sized beads (0.085-1.091 micron), coated with similar densities of pFN, were incubated with cells at 4 degrees C, no variation in binding as a function of bead size was observed. Under these conditions, the absolute amount of pFN ranged from less than 100 molecules on the 0.085-micron beads to greater than 15,000 molecules on the 1.091-micron beads. Based upon these results it can be concluded that the critical parameter controlling fibronectin-mediated binding of latex beads by BHK cells is the spacing of the pFN molecules on the beads. Correspondingly, it can be suggested that the spacing between pFN receptors on the cell surface that is optimal for multivalent interactions to occur is approximately 18 nM. When phagocytosis of various sized beads was compared, it was found that the largest beads were phagocytosed slightly better (two fold) than the smallest beads. This occurred both in continuous incubations of cells with beads and when the beads were prebound to the cells. Finally, the kinetic constants for the binding of 0.085 microM pFN-coated beads to the cells were analyzed. There appeared to be approximately 62,000 binding sites and the KD was 4.03 X 10(-9) M. Assuming a bivalent interaction, it was calculated that BHK cells have approximately 120,000 pFN receptors/cell and the binding affinity between pFN and its receptor is approximately 6 X 10(-5) M.     

Development and characterization of simulant pancreatic islets

Insulin is stored in pancreatic islets as a zinc-insulin complex, and stimulating the islets results in the release of insulin and zinc. Simulant pancreatic islet beads have been developed using agarose beads (50-250 micro m diameter) derivatized with iminodiacetic acid that have been loaded with zinc. A qualitative comparison of the simulant beads with pancreatic islets has been made by staining with dithizone and a zinc-binding fluorescent dye, TSQ. The binding capacity of simulant beads was determined to be 34 micro mol Zn(2+)/g of dried beads using anodic stripping voltammetry. Hydrochloric acid was used to release zinc from beads to mimic the secretion of insulin from pancreatic islets and a release profile was established. The simulant beads can be used to optimize the islet isolation process and reduce the use of real islets in method development.     

Characterization of calcium alginate and chitosan-treated calcium alginate gel beads entrapping allyl isothiocyanate

Calcium alginate (CA), chitosan-coated calcium alginate (CCA-I), and chitosan–calcium alginate complex (CCA-II) gel beads, in which an oil-in-water emulsion containing allyl isothiocyanate (AITC) was entrapped, were prepared and characterized for efficient oral delivery of AITC. The AITC entrapment efficiency was 81% for CA gel beads, whereas about 30% lower values were determined for the chitosan-treated gel beads. Swelling studies showed that all the gel beads suddenly shrunk in simulated gastric fluid (pH 1.2). In simulated intestinal fluid (pH 7.4), CA and CCA-I gel beads rapidly disintegrated, whereas CCA-II gel beads highly swelled without degradation probably due to the strong chitosan–alginate complexation. Release studies revealed that most entrapped AITC was released during the shrinkage, degradation, or swelling of the gel beads, and the chitosan treatments, especially the chitosan–alginate complexation, were effective in suppressing the release. CCA-II gel beads showed the highest bead stability and AITC retention under simulated gastrointestinal pH conditions.     

A new method of synthesis of iron doped calcium alginate beads and determination of iron content by radiometric method

The present study describes a new method of synthesis of an anionic biopolymer, iron doped calcium alginate beads (Fe-CA). The beads were characterized in terms of size, porosity and surface area. The adsorption of the anionic species depends mainly on the iron content of the beads. Thus, iron content in the Fe-CA beads has been determined employing radiometric technique using ⁵⁹Fe radiotracer. It has been found that Fe-CA beads contain 37.8 mg Fe/g of wet alginate beads in the proposed method, which is much higher than the earlier reported methods, keeping the mechanical stability.     

Fabrication of hyaluronic acid hydrogel beads for cell encapsulation

Hyaluronic acid (HA) hydrogel beads were prepared by photopolymerization of methacrylated HA and N-vinylpyrrolidone using alginate as a temporal spherical mold. Various fabrication conditions for preparing the hydrogel beads, such as the concentration of methacrylated HA and UV irradiation time, were optimized to control swelling properties and enzymatic degradability. A new concept for cell encapsulation is proposed in this paper. Viable cells were directly injected into the hydrogel beads using a microinjection technique. When bovine articular chondrocytes were injected into HA hydrogel beads and cultivated for 1 week, the cells could proliferate well within the HA beads. HA hydrogel beads could be potentially used as injectable cell delivery vehicles for regenerating tissue defects.