Oxygen radicals in influenza-induced pathogenesis and treatment with pyran polymer-conjugated SOD.

The pathogenicity of influenza virus infection in the mice involves, at least in part, overreaction of the immune responses of the host rather than a direct effect of virus multiplication. Xanthine oxidase, which is responsible for the generation of oxygen free radicals, was elevated in serum and lung tissue of mice infected with influenza virus. To test the theory that oxygen-free radicals are involved in pathogenesis, free radicals were removed by injecting superoxide dismutase (SOD), a specific superoxide radical scavenger, which was conjugated with a pyran copolymer. The conjugate protected mice against a potentially lethal influenza virus infection if administered 5 to 8 days after infection. These findings indicate that oxygen radicals are important in the pathogenesis of influenza virus infection, and that a polymer-conjugated SOD has therapeutic potential for this virus infection and other diseases associated with free radicals.

Galactose-carrying polymers as extracellular matrices for liver tissue engineering.

Extracellular matrix (ECM) plays important roles in tissue engineering because cellular growth and differentiation, in the two-dimensional cell culture as well as in the three-dimensional space of the developing organism, require ECM with which the cells can interact. Especially, the bioartificial liver-assist device or regeneration of the liver-tissue substitutes for liver tissue engineering requires a suitable ECM for hepatocyte culture because hepatocytes are anchorage-dependent cells and are highly sensitive to the ECM milieu for the maintenance of their viability and differentiated functions. Galactose-carrying synthetic ECMs derived from synthetic polymers and natural polymers bind hepatocytes through a receptor-mediated mechanism, resulting in enhanced hepatocyte functions. Attachment and functions of hepatocytes were affected by physico-chemical properties including ECM geometry as well as the type, density and orientation of galactose. Also, cellular environment, medium composition and dynamic culture system influenced liver-specific functions of hepatocytes beside ECM.

Tumor-targeting chemotherapy by a xanthine oxidase-polymer conjugate that generates oxygen-free radicals in tumor tissue.

Xanthine oxidase (XO) mediates anticancer activity because of its ability to generate cytotoxic reactive oxygen species (ROS), including superoxide anion radical and hydrogen peroxide. However, the high binding affinity of XO to blood vessels would cause systemic vascular damage and hence limits the use of native XO in clinical settings. We demonstrate here that chemical conjugation of XO with poly(ethylene glycol) (PEG; the conjugates hereafter referred to as PEG-XO) significantly enhanced the tumor-targeting efficacy and the antitumor activity of XO. By using a succinimide-activated PEG derivative, PEG was conjugated to epsilon-amino groups of lysine residues of XO, which play a crucial role in binding of XO to blood vessels. PEG-XO administered i.v. showed a 2.8-fold higher accumulation in solid tumor compared with that of native XO 24 h after injection, whereas a slight or negligible increase in accumulation of PEG-XO was observed in normal organs. The highest PEG-XO enzyme activity was detected in tumor compared with normal organs or tissues except blood; enzyme activity in tumor was 5.0, 3.9, and 9.4 times higher than that in liver, kidney, and spleen, respectively. Intratumor activity remained high for >48 h. Administration of hypoxanthine, a substrate of XO, at 33 mg/kg body weight i.p. 12 h after the administration of PEG-XO (0.6 unit/mouse, i.v.) resulted in significant suppression of tumor growth (P < 0.001), with no tumor growth even after 52 days. However, either PEG-XO or hypoxanthine alone, or native XO with hypoxanthine, showed no effect on the inhibition of tumor growth under present experimental conditions. These findings suggest that PEG-XO, which accumulates preferentially in tumor tissue, warrants further investigation as a novel anticancer agent.

Design of polymer materials enhancing nucleotide hybridization for anti-gene technology.

Stabilization of nucleotide hybridization is considered important for improving gene therapy using oligonucleotides. We have designed comb-type copolymer consisting of polycation backbone (polylysine) and hydrophilic side chains as a stabilizer for double and triple helical DNAs. The copolymer considerably increased the thermal stability of triple helical structure but did not affect the reversible transition between triple helical and single-stranded DNA. An in vitro electrophoretic mobility shift assay revealed that the copolymer remarkably increased association constants of both Hoogsteen and reverse Hoogsteen-type triple helix formation. Moreover the triple helix-stabilizing efficiency of the copolymer was significantly higher than that of other oligocations like spermine and spermidine. Not only being good DNA triple helix stabilizer, it has also been shown to accelerate DNA strand exchange reactions between double helical DNA and its complementary oligonucleotides. From these, we conclude that this copolymer is capable of either 'stabilizing' or 'activating' DNA hybrids, and may useful for gene targeting employing oligonucleotides.

Preparation of nanoparticles bearing high density carbohydrate chains using carbohydrate-carrying polymers as emulsifier.

A novel method of preparing nanoparticles bearing high density carbohydrate chains on their surface is described. Carbohydrate-bearing nanoparticles of poly(lactic acid) or polystyrene were prepared by the solvent evaporation method using a carbohydrate-carrying polystyrene derivative which served as both an emulsifier and a surface coating. The diameter of the obtained nanoparticles ranged from 80 to 300 nm depending on the concentration of the polystyrene derivative. As the concentration of the polystyrene derivatives increased the nanoparticle diameter decreased, indicating that the polystyrene derivatives worked as an emulsifier. The obtained particles were specifically aggregated by carbohydrate-specific lectin, showing that the polystyrene derivative was retained on the particle surfaces and expressed carbohydrate residues. The density of carbohydrates on the particle surfaces was determined to be 3-5 molecules per square nanometre. The particles prepared by the present method were stably dispersed and hardly aggregated in aqueous media during storage and centrifugal treatment compared with the post-coated particles that were prepared by adsorbing polystyrene particles with the polystyrene derivative. In vitro study with isolated rat hepatocytes revealed that surface carbohydrate chains were recognized by hepatocytes.

Simple preparation of nanoparticles coated with carbohydrate-carrying polymers.

Nanoparticles bearing carbohydrate chains on the surface can be prepared by the simple diafiltration method. The nanoparticles prepared by the present method displayed high yield, no-aggregation formation, small size, narrow size distribution, and one-step procedure. Also, the high density carbohydrate chains on the particles can be recognized by liver cells.

Establishment of heterotropic liver tissue mass with direct link to the host liver following implantation of hepatocytes transfected with vascular endothelial growth factor gene in mice.

One of the major goals of tissue engineering is to establish an integrated organ in vivo. We have previously shown that transfection of vascular endothelial growth factor (VEGF) gene into hepatocytes promotes tissue formation by engrafted cells. Here we show that tissue growth was significantly enhanced by co-transplantation of hepatocyte growth factor (HGF) and tumor necrosis factor-alpha (TNF alpha) gene transfected hepatocytes with VEGF-gene transfected cells, but tissue islands were scattered nonspecifically in the abdomen of mice. The result brought us forward to the next step to establish an integrated mass and structural formation of liver tissue. We entrapped VEGF gene transfected hepatocytes in a nylon mesh bag and intraperitoneally engrafted close to the liver. Three weeks later, the bag was covered by a thick network of blood vessels, compared to the control. Histological examination showed that the blood vessels penetrated the parenchyma of the engrafted bag and formed a well-developed vessel network in the region. The use of hepatocytes from lacZ transgenic mice and PCR analysis demonstrated survival and albumin production by hepatocytes in the engrafted bag. Our model can potentially be developed into a heterotropic artificial liver with direct access to the host blood circulation.

Highly efficient transfection into primary cultured mouse hepatocytes by use of cation-liposomes: an application for immunization.

Transfection methods for primary cultured mouse hepatocytes were examined. Of four conventional transfection methods examined, involving use of DEAE-dextran, calcium phosphate, cation-liposomes (lipofection), and cation-multilamellar liposomes, only cation-liposomes induced highly efficient transfection into primary cultured mouse hepatocytes. The highest transfection rate reached more than 60% of the total cells. Three other commonly used cell types (CHO-K1, COS-1, 3T3-L1) were also tested as target cells, but highly efficient transfection was observed specifically in primary cultured mouse hepatocytes. The transfection remained at a high level from 6 to 48 h after the start of incubation with the cation-liposome-DNA complex in the absence of serum, and the transfection rate decreased in inverse relation to the increase in cell density. The transfection was inhibited by free low density lipoprotein (LDL), EDTA, and an endocytosis inhibitor, cytochalasin B. These data suggest that the transfection is mediated not only by membrane fusion, as is generally accepted, but also by endocytosis. This information should be useful for research in hepatocyte biology and the development of gene therapy. As one of the applications, simple and successful immunization was achieved by administration of hepatocytes transfected with murine adhesion molecule, integrin VLA beta 1 subunit, genes into a Syrian hamster.

Specific interaction between erythrocytes and a glucose-carrying polymer mediated by the type-1 glucose transporter (GLUT-1) on the cell membrane.

A reducing glucose-carrying polymer, called poly [3-O-(4'-vinylbenzyl)-D-glucose] (PVG), interacted with erythrocytes carrying the type-1 glucose transporter (GLUT-1) on the cell membrane. The cooperative interaction between a number of GLUT-1s and a number of reducing 3-O-methyl-D-glucose moieties on a PVG polymer chain is responsible for the increase in the interaction with erythrocytes. In contrast to the PVG homopolymer, other sugar-carrying polymers showed lower interaction with erythrocytes. The affinity of erythrocytes and PVG was studied using FITC-labeled glycopolymers. The fluorescence intensity significantly changed, whereas a small change in fluorescence intensity was observed for other homopolymers. The specific interaction between GLUT-1 on erythrocytes and the PVG polymer carrying reducing glucose was suppressed by the inhibitors, phloretin, phloridzin, and cytochalasin B, and a monoclonal antibody to GLUT-1. Direct observation by confocal laser microscopy with the use of FITC-labeled PVG demonstrated that erythrocytes interacted with the soluble form of the PVG polymer via GLUT-1, while fluorescence labeling of the cell surface was prevented on pretreatment with the monoclonal antibody to GLUT-1.

Enhanced ability of heparin-carrying polystyrene (HCPS) to bind to heparin-binding growth factors and to inhibit growth factor-induced endothelial cell growth.

Heparin-carrying polystyrene (HCPS) consists of low-molecular-weight heparin chains enriched in trisulfated disaccharide structures linked to a polystyrene core. In this study, the interactions between HCPSs of various molecular weights and heparin-binding growth factors, VEGF(165), FGF-2, and HGF, were compared to the interactions of the same factors with native heparin, periodate-oxidized heparin (IO(4)-heparin) and periodate-oxidized alkaline-degraded heparin (IO(4)-LMW-heparin). The binding of each growth factor to heparin-agarose beads (heparin-beads) was more strongly inhibited by HCPSs in a molecular weight-dependent manner than by native heparin or the modified heparins, indicating a stronger interaction between HCPS and these growth factors. HCPSs also inhibit heparin-binding growth factor-induced endothelial cell growth in a molecular weight-dependent manner much more strongly than the native or modified heparins. However, HCPSs did not inhibit the mitogenic activity of VEGF(121), which has a non-heparin-binding nature. Thus, HCPSs exhibit enhanced abilities to interact with each of the heparin-binding growth factors studied and to inhibit heparin-binding growth factor-induced endothelial cell proliferation in a molecular weight-dependent manner. These effects might be ascribed to the heparin-clustering effect of HCPSs.

Development of a method for embedded-culture of pig pancreatic islet-like cell clusters in agarose containing maltose-carrying polystyrene (HEVM) and nicotinamide.

A method for embedded-culture of islet-like cell clusters (ICCs) from neonatal pig pancreas is described. The procedure is based on a sequential treatment of the pancreas with a proteolytic enzyme and ethylenediaminetetraacetate (EDTA). During the exposure to EDTA-Dispase, small pieces of pancreas were gradually digested, with gentle stirring. Under- and over-digested pancreatic cell clusters were separated from the pancreatic fragments by filtration, and formed whole islet-like cell clusters in RPMI 1640 containing 11.0 mM D-glucose and 10% fetal bovine serum (FBS). The ICCs were embedded in agarose with or without a gel containing a random copolymer hydroxethylmethacrylate-vinylbenzyl maltonamide (HEVM) of hydroxethylmethacrylate-(HEMA)-vinylbenzyl maltonamide (VMA) and nicotinamide. They remained morphologically intact and a physiological response to acute stimulation with glucose was obtained when they were embedded in the agarose containing HEVM and nicotinamide. These findings suggest that ICCs in agarose containing HEVM and nicotinamide could be a useful tool for morphological, biochemical and molecular biological studies, and also as a potential source of material for transplantation.

Matrices for tissue engineering-scaffold structure for a bioartificial liver support system.

This study proposes a new composite scaffold system. A woven polyethylenterephtalate (PET) fabric was coated on one side with a biodegradable PLGA film, in order to obtain a geometrically polarized scaffold structure for an bioartificial liver support system. The composite structure ensures the stability of the membrane during degradation of the membrane polymer. The mesh size of the composite does not significantly influence the degradation behavior. Hepatocyte culturing studies reveal that the formation of aggregates depends on the mesh size and on the pretreatment: The largest aggregates could be observed after 48 h when PVLA coating, large mesh size and EGF were combined. Thus, the combination of a geometrically structured, partially degradable scaffold with receptor-mediated cell attachment sites offers promising possibilities in liver tissue engineering.

Galactosylated chitosan-graft-poly(ethylene glycol) as hepatocyte-targeting DNA carrier.

Lactobionic acid bearing galactose group was coupled with chitosan for liver specificity, and poly(ethylene glycol) (PEG) was grafted to galactosylated chitosan (GC) for stability in water and enhanced cell permeability. Complex formation of galactosylated chitosan-graft-PEG (GCP)/DNA complexes was confirmed by agarose gel electrophoresis. Compared to GC/DNA complex, the stability of GCP/DNA complex could be enhanced. Particle sizes of GCP/DNA complexes decreased as the charge ratio of GCP to DNA increased and had a minimum value around 27 nm at the charge ratio of 5. Conformational change of DNA did not occur after complex formation with GCP compared to conformation of DNA itself. GCP/DNA complexes were only transfected into Hep G2 having asialoglycoprotein receptors (ASGR), indicative of specific interaction of ASGR on cells and galactose ligands on GCP.

Galactosylated chitosan (GC)-graft-poly(vinyl pyrrolidone) (PVP) as hepatocyte-targeting DNA carrier. Preparation and physicochemical characterization of GC-graft-PVP/DNA complex (1).

Galactosylated chitosan was conjugated with poly(vinyl pyrrolidone) (PVP) as a hydrophilic group. The complex formation of GC-graft-PVP (GCPVP)/DNA complexes was confirmed by agarose gel electrophoresis. The morphology of the complex observed by atomic force microscopy had a compact and spherical shape, around 40 nm particle sizes at a charge ratio of 3. The binding strength of GCPVP 10K/DNA complex measured by ethidium bromide binding assay was superior to that of the GCPVP 50K/DNA one, probably attributable to its higher flexibility due to the smaller size, whereas the DNase I protection of GCPVP 10K/DNA complex was inferior to that of the GCPVP 50K/DNA one. This indicated that effective complex formation required both higher binding strength and minimal molecular weight of polycation enough to induce the condensation of DNA. The DNA-binding property of GCPVP mainly depended on the molecular weight of chitosan and composition of PVP.

Receptor-mediated delivery of all trans-retinoic acid to hepatocyte using poly(L-lactic acid) nanoparticles coated with galactose-carrying polystyrene.

All trans-retinoic acid (RA)-loaded poly(L-lactic acid) (PLA) nanoparticles coated with galactose-carrying polymer, as hepatocyte-specific targeting material using galactose ligands as recognition signals to asialoglycoprotein receptors were prepared by the diafiltration method. Effects of released RA from its loaded nanoparticles on morphology and DNA synthesis of hepatocytes were studied. Receptor-mediated endocytosis of the nanoparticles was checked by fluorescence and confocal laser microscopy. It was found that the shapes of most hepatocytes attached onto polystyrene dish precoated with collagen solution were flat and spreading at low concentration of RA for the RA-loaded nanoparticles, whereas their shapes were round at even low concentration of RA when RA was mixed with the nanoparticles. From the fluorescence and confocal laser microscopic studies, it was suggested that the nanoparticles coated with galactose-carrying polymers were internalized by the hepatocytes through the receptor-mediated mechanism. The RA-loaded nanoparticles were more potent stimulators of hepatocyte DNA synthesis than the free RA system in the presence of epidermal growth factor (EGF) owing to the controlled release of RA from the RA-loaded nanoparticles.

Visualization of transfection of hepatocytes by galactosylated chitosan-graft-poly(ethylene glycol)/DNA complexes by confocal laser scanning microscopy.

Dual-labeled galactosylated chitosan-graft-poly(ethylene glycol) (PEG) (GCP)/DNA complexes were prepared and their hepatocyte-specific delivery and cellular distribution were investigated by confocal laser scanning microscopy (CLSM). The complexes were transfected into hepatocyte through specific interaction of galactose moiety of the GCP and asialoglycoprotein receptors (ASGPR) of the hepatocytes. The GCP/DNA complexes taken up by the hepatocytes were rapidly released into the cytoplasm, but nuclear trafficking of the released complexes was slow and rate-limiting process. The more efficient transfection of the complex occurred in the human-derived HepG2 cells than in primary hepatocytes.

[A preview of the practical application of hybrid artificial liver].

In order to replace the liver function, the development of the system where natural hepatocytes are immobilized in a matrix polymer might be considered as the best way. Each hepatocyte has a number of specific receptors for several ligards. We noticed that the hepatocyte recognizes the structure of oligosaccharides via asialoglycoprotein receptors and synthesizes lactose-carrying styrene polymer (PVLA) as a asialoglycoprotein model. On PVLA-coated dish, the specific functions as well as attachment of hepatocyte were successfully maintained. Moreover, cultured hepatocytes on PVLA substratum started gradual movement, and then remarkably formed multilayer aggregations which had long-term survival. Hepatocytes in the aggregation exhibited better maintenance of specific hepatocyte-functions such as the synthesis of albumin and secretion of bile acid, and retained mitochondrial enzyme activity than those in the monolayer culture on collagen and fibronectin. Furthermore, we found that DNA synthesis in cultured hepatocytes was correlated to the cell-shape which could be controlled by the concentration of PVLA substratum. These results also suggested that the PVLA could potentiate the regulation of the differentiation and proliferation of hepatocytes.

Adsorption behaviors of recombinant E-cadherin-IgG Fc fusion protein on polystyrene surface.

Adsorption behaviors of recombinant E-cadherin-IgG Fc (E-cad-Fc) fusion protein and mutated E-cad-Fcs on the polystyrene (PS) surface were investigated using a 27 MHz quartz-crystal microbalance (QCM) and ELISA. The amount of adsorbed E-cad-Fc on PS surface was increased with an increase of E-cad-Fc concentration as a Langmuir-type in a monolayer. Adsorbed E-cad-Fc on PS surface was stable even after washing if calcium ions are absent in the washing solution due to the calcium ion dependence in the adsorption. E-cadherin homophilic adhesion among E-cadherins during adsorption of E-cad-Fc was involved. Deglycosylation of the E-cad in the E-cad-Fc did not affect adsorption of E-cad-Fc on the PS surface although deglycosylation of the E-cad in the E-cad-Fc enhanced cell adhesion compared with E-cad-Fc.