Regenerative medicine has received a lot of attention as a novel strategy for injuries and diseases that are difficult to cure using current techniques. Cell production, which is vital for regenerative medicine, has undergone remarkable progress via breakthroughs in developmental biology and tissue engineering; currently, cell production requires numerous experimental operators performing manual, small-scale cell cultures. Other major obstacles for cell production and regenerative medicine include the variable quality of products based on the experimental procedure, the skills of operators, the level of labor required for production, and costs. Technological developments are required to overcome this, including automation instead of manual culture. Age-related macular regeneration (AMD) is a refractory ocular disease that causes severe deterioration in central vision due to senescence in the retinal pigment epithelium (RPE). Recently, we performed an autologous transplantation of induced pluripotent stem (iPS) cell-derived RPE cell sheets and started clinical research on allografts from RPE cell suspensions differentiated from iPS cells. The use of regenerative therapies for AMD using iPS cell-derived RPE is expected to become more widespread. In the present study, human iPS cell-derived RPE cells were cultured to form RPE cell sheets using equipment with a closed culture module. The quality of the automated cultured RPE cell sheets was confirmed by comparing their morphological and biological properties with those of manually generated RPE cell sheets. As a result, machine-cultured RPE sheets displayed the same quality as manually cultured RPE sheets, showing that iPS cell-derived RPE cell sheets were successfully cultured by an automated process.
Glycopolymers with a-galactose (a-Gal) and a-mannose (a-Man) were synthesized by means of living radical polymerization with a reversible addition-fragment chain transfer reagent, and the thin-layer formation of glycopolymers was investigated in terms of protein recognition abilities. Thiol-terminated glycopolymers formed a thin layer of about 2.5 nm in thickness on a gold substrate, and the glycopolymer thin layer showed specific interaction with sugar recognition proteins (lectins and Shiga toxins (Stxs)). The interactions were highly specific, and the signal-to-noise ratio of protein recognition was greater than 16. Glycopolymer-substituted gold nanoparticles (GNPs) also showed biorecognition abilities and protein-specific aggregation. The protein recognition abilities of the GNPs were also analyzed. The glycopolymer-substituted GNPs were utilized for signal amplification of surface plasmon resonance (SPR) to detect protein-saccharide recognition. The glycopolymer with a-Gal showed a strong interaction with Stxs according to SPR measurements, suggesting a possible application of a-Gal-substituted GNPs in Stx-1 biosensing.
The mechanism of amyloidosis of amyloid beta (1-42) (Abeta (1-42)) was investigated by the well-defined glycocluster interface. We prepared monovalent, divalent, and trivalent 6-sulfo-N-acetyl-d-glucosamine (6S-GlcNAc) immobilized substrates. The morphology and secondary structure of Abeta (1-42) aggregates on the substrates were investigated by dynamic-mode AFM and FTIR-RAS. Abeta (1-42) interactions with multivalent sugars were evaluated by surface plasmon resonance, and the cytotoxicity of Abeta (1-42) to HeLa cells was evaluated by MTT assay. Morphological images showed, interestingly, that Abeta (1-42) aggregates had a tendency to form globules rather than fibrils as the valency of 6S-GlcNAc on the substrate was increased. The SPR measurements indicated that this morphological change of Abeta (1-42) was related to the change of binding mode, and the binding mode was dependent on the multivalency of the sugar. Globular Abeta (1-42) was more toxic than fibrillar Abeta (1-42) to HeLa cells. These results suggested that the multivalency of sugars for the amyloidosis of Abeta (1-42) was significant in its morphology and aggregation effects at the surface of the cell membrane mimic.
Sugar microarrays were fabricated on various substrates via click chemistry. Acetylene-terminated substrates were prepared by forming self-assembled monolayers (SAMs) on a gold substrate with alkyl-disulfide and on silicon, quartz and glass substrates with a silane-coupling reagent. The gold substrates were subjected to surface plasmon resonance measurements, and the quartz and glass substrates were subjected to spectroscopy measurements and optical microscopy observation. The saccharide-immobilized substrate on the gold substrate showed specific interaction with the corresponding lectin, and the saccharides showed inert surface properties to other proteins with a high signal-to-noise ratio. We also focused on the saccharide-protein interaction on protein amyloidosis of Alzheimer amyloid β. Amyloid β peptide showed conformation transition on the saccharide-immobilization substrate into a β-sheet, and fibril formation and amyloid aggregates were found on the specific saccharides.
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