Masato Nagaoka

Structure and anti-dengue virus activity of sulfated polysaccharide from a marine alga.

A sulfated polysaccharide, named fucoidan, from the marine alga Cladosiphon okamuranus is comprised of carbohydrate units containing glucuronic acid and sulfated fucose residues. Here we found this compound potently inhibits dengue virus type 2 (DEN2) infection. Viral infection was inhibited when DEN2, but not other serotypes, was pretreated with fucoidan. A carboxy-reduced fucoidan derivative in which glucuronic acid was converted to glucose did not inhibit viral infection. Elimination of the sulfated function group from fucoidan significantly attenuated the inhibitory activity on DEN2 infection with <1% fucoidan. DEN2 particles bound exclusively to fucoidan, indicating that fucoidan interacts directly with envelope glycoprotein (EGP) on DEN2. Structure-based analysis suggested that Arg323 of DEN2 EGP, which is conformationally proximal to one of the putative heparin binding residues, Lys310, is critical for the interaction with fucoidan. In conclusion, both the sulfated group and glucuronic acid of fucoidan account for the inhibition of DEN2 infection.

Hepatocyte-specific porous polymer-scaffolds of alginate/galactosylated chitosan sponge for liver-tissue engineering

Porous scaffolds of alginate/galactosylated chitosan (ALG/GC) sponges were prepared by lyophilization for liver-tissue engineering. Primary hepatocytes in ALG/GC sponges showed higher cell attachment and viability than in alginate alone owing to the specific interaction of the asialoglycoprotein receptors on hepatocyte with the galactose residues on ALG/GC sponges. Improvements in spheroid formation and long-term liver-specific functions of the immobilized hepatocyte were also observed in ALG/GC sponge.

Construction of a Novel Extracellular Matrix using a New Genetically Engineered Epidermal Growth Factor Fused to IgG-Fc

The design of artificial extracellular matrices has attracted much attention in tissue engineering as well as in cell biology research. An immobilized recombinant epidermal growth factor (EGF), fused to an immunoglobulin G (IgG) Fc region (abbreviated as EGF-Fc) has been constructed. Mouse fibroblast Swiss 3T3 cells adhered both to EGF-Fc-coated and collagen-coated surfaces. Phosphorylation of EGF receptor in A431 cells was induced by immobilized EGF-Fc as well as soluble EGF. Immobilized EGF-Fc continuously activated mitogen-activated protein kinase (MAPK) in A431 cells whereas MAPK activation induced by soluble EGF decreased rapidly with time. The cytoskeleton of A431 cells adhering onto immobilized EGF-Fc was filopodia whereas that of the cells adhering onto collagen in the presence of soluble EGF was lammellipodia.

Application of Recombinant Fusion Proteins for 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. Also, the development of new synthetic ECMs is very important because ECMs facilitate the localization and delivery of cells to the specific sites in the body. Therefore, the development of synthetic ECMs to replace the natural ECMs is increasingly essential and promising in tissue engineering. Recombinant genetic engineering method has enabled the synthesis of protein-based polymers with precisely controlled functionalities for the development of new synthetic ECMs. In this review, the design and construction of structure-based recombinant fusion proteins such as elastin-like polymers (ELPs) and silk-like polymers (SLPs), cell-bound growth factor-based recombinant fusion proteins such as basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF), hybrid system composed of recombinant protein and synthetic polymer, and E-cadherin-based fusion protein by recombinant genetic engineering were explained for application of the synthetic ECMs. Modulation of mechanical properties, stimuli-sensitivity, biodegradation and cell recognition can be achieved through precise control of sequence, length, hydrophobicity and cell binding domain by recombinant genetic engineering.

Design of the Artificial Acellular Feeder Layer for the Efficient Propagation of Mouse Embryonic Stem Cells

Embryonic stem (ES) cells are pluripotent-undifferentiated cells that have a great interest for the investigation of developmental biology. Murine ES cells maintain their pluripotency by the supplementation of the leukemia inhibitory factor (LIF). LIF is reported to act as a matrix-anchored form, and immobilized cytokines are useful to sustain their signaling on target cells. In this study, we used the immobilizable fusion protein composed of LIF and IgG-Fc region, which was used as a model of the matrix-anchored form of LIF to establish a novel system for ES cell culture and to investigate the effect of immobilized LIF on maintenance of ES cell pluripotency. Mouse ES cells maintained their undifferentiated state on the surface coated with LIF-Fc. Furthermore, when cultured on the co-immobilized surface with LIF-Fc and E-cadherin-Fc, mouse ES cells showed characteristic scattering morphologies without colony formation, and they could maintain their undifferentiated state and pluripotency without additional LIF supplementation. The activation of LIF signaling was sustained on the co-immobilized surface. These results indicate that immobilized LIF and E-cadherin can maintain mouse ES cells efficiently and that the immobilizable LIF-Fc fusion protein is useful for the investigation of signaling pathways of an immobilized form of LIF in the maintenance of ES cell pluripotency.

Immobilized E-cadherin model can enhance cell attachment and differentiation of primary hepatocytes but not proliferation

E-Cadherin is an intercellular adhesion molecule that regulates cell functions such as differentiation and proliferation of cells. To clarify the potential of E-cadherin-mediated adhesion to induce differentiation, we constructed an adsorbable recombinant E-cadherin molecule by fusing with an immunoglobulin G (IgG) Fc region (E-cad-Fc). Hepatocytes could adhere to the fusion protein-coated surface by a homophilic interaction of E-cadherins and showed differentiated phenotypes such as low DNA synthesizing activity and maintenance of tryptophan oxygenase expression, similar to those of spheroid-formed hepatocytes that are known as a highly differentiated tissue-like cell aggregation. These results suggest that E-cadherin is a key molecule for maintaining differentiation of primary hepatocytes.

Embryonic undifferentiated cells show scattering activity on a surface coated with immobilized E-cadherin

Rearrangement of cell–cell adhesion is a critical event in embryonic development and tissue formation. We investigated the regulatory function of E‐cadherin, a key adhesion protein, in the developmental process by using E‐cadherin/IgG Fc fusion protein as an adhesion matrix in cell culture. F9 embryonal carcinoma cells usually form colonies when cultured on gelatin or fibronectin matrices. However, F9 cells cultured on the E‐cadherin/IgG Fc fusion protein matrix formed a scattered distribution, with a different cytoskeletal organization and E‐cadherin‐rich protrusions that were regulated by Rac1 activity. The same scattering activity was observed in P19 embryonal carcinoma cells. In contrast, three types of differentiated cells, NMuMG mammary gland cells, MDCK kidney epithelial cells, and mouse primary isolated hepatocytes, did not show the scattering activity observed in F9 and P19 cells. These results suggest that migratory behavior on an E‐cadherin‐immobilized surface is only observed in embryonic cells, and that the regulatory mechanisms underlying E‐cadherin‐mediated cell adhesion vary with the state of differentiation. J. Cell. Biochem. 103: 296–310, 2008.

Analysis of cell viability and differential activity of mouse hepatocytes under 3D and 2D culture in agarose gel

Three-dimensional (3D) and two-dimensional (2D) cultures of hepatocytes in various concentrations (0.3–0.7%) of agarose gel revealed that the hepatocytes under 3D cultures in 0.3% agarose gel possess long-term (>3 weeks) viability, significant self-assembly to form tissue like aggregates, low lactate dehydrogenase release and high albumin synthesis. These were in contrast to 2D culture of hepatocytes. Our results suggest that the 3D culture of hepatocytes in agarose gel favors aggregate formation of functionally active cells and would be useful for liver transplantation as well as to analyze hepatocytes biology.

Control of Singular Cell Cycle Synchronization of Mouse ES Cells for Hepatocyte Differentiation on E-Cadherin Substratum

Stem cells have enormous potential for therapeutic applications due to their ability to differentiate into diverse cell types. However, preparation of specific lineages at high purity from embryonic stem cells remains a challenge. We have previously reported that embryonic stem (ES) cells on E-cadherin substratum form single-cell scattering morphology. In this study, we report the effect of the hydroxyurea on singular ES cell cycle synchronization to achieve homogeneous population of differentiated cells on E-cadherin substratum. ES cells were successfully arrested in G1 phase with the administration of hydroxyurea and subsequently induced to differentiate into hepatocyte-like cells. The homogeneous population of cells on E-cadherin substratum from synchronized ES cells have higher capability to differentiate into hepatocytes-like cells than unsynchronized ES cells. Moreover, synchronized cells re-enter into the normal cell cycle with the elimination of hydroxyurea for differentiation. Our strategy for ES cell cycle synchronization before differentiation induction possibly helps to increase the yield of hepatocyte-like cells under homogeneous culture condition.