Simple chitin-based cell culture platform for production of biopharmaceuticals.

OBJECTIVES: Gene therapy using viral vectors and antibody-based therapies continue to expand within the pharmaceutical market. We evaluated whether Cellhesion® VP, a chitin-based material, can be used as 3D culture platform for cell lines used for the production of antibodies and viral vectors. RESULTS: The results of Cell Counting Kit-8 assay and LDH assay revealed that Cellhesion® VP had no adverse effect to Human Embryonic Kidney (HEK) 293, A549 and Chinese hamster ovary (CHO) DG44-Interferon-ß (IFN) cells. Cell growth analyses showed that Cellhesion® VP supported the 3D culture of HEK293, A549 and CHO DG44- IFN-ß cells with a spherical morphology. Importantly, subculture of these cell lines on Cellhesion® VP was easily performed without trypsinization because cells readily transferred to newly added scaffold. Our data also suggest that CHO DG44-IFNß, cultured on Cellhesion® VP secreted IFNß stably and continuously during the culture period. CONCLUSIONS: Cellhesion® VP provides a simple and streamlined expansion culture system for the production of biopharmaceuticals.

Reversible suspension culture of human vascular smooth muscle cells using the functional biopolymer FP003.

Human vascular smooth muscle cells (SMCs) are adherent cells, and they cannot survive without scaffolds in suspension culture. Here, we aimed to establish a suspension culture of SMCs using the functional biopolymer FP003 and to investigate the proliferation status of the cells. When SMCs were suspension cultured with FP003, their proliferation was inhibited with a viability of 75% until day 15. When SMCs were re-plated on plastic plates after suspension culture with FP003 for 48 h, the SMCs proliferated as in a normal plate culture. The SMCs cultured in suspension with FP003 showed a relatively low phosphorylation of retinoblastoma protein, low expression of cyclin D1, high proportion of G0/G1 phase cells, low proportion of S phase cells, and no obvious signs of apoptosis, indicating that this culture system inhibited progression from the G1 to S phase. This growth arrest was a reversible property that showed no significant changes in the expressions of the marker proteins α-smooth muscle actin and smooth muscle myosin heavy chain. These results suggest that human SMCs can be stably cultured in suspension with FP003 without losing their characteristics when they are cultured on plastic plates again.

Suspension culture of human induced pluripotent stem cell-derived intestinal organoids using natural polysaccharides.

Currently, there are many challenges in the culture of human induced pluripotent stem (iPS) cell-derived intestinal organoids (HIOs) for use in drug discovery, disease research, and regenerative medicine. For example, the main culture method, embedding culture, makes industrial large-scale culture difficult, and Matrigel, which is used for almost all HIO cultures, is not respected for its application in regenerative medicine. To overcome these challenges, we herein propose a new culture method using low concentrations of natural polysaccharides in a suspension culture. In the present study, five natural polysaccharides free from heterologous animal-derived components were used, and HIOs were successfully cultured in suspension with FP001 and FP003, which are microbial exopolysaccharide analogs of gellan gum. The fabricated HIOs were similar to living intestinal tracts with respect to their gene expression, microstructure, and protein expression. The observed activities of the drug metabolizing enzymes and drug transporters in the generated HIOs suggested that they have pharmacokinetic functions. We believe that suspension culture of HIOs using FP001 or FP003 can be widely applied to not only drug discovery research but also disease research and regenerative medicine.

Protection of human induced pluripotent stem cells against shear stress in suspension culture by Bingham plastic fluid.

Suspension culture is an important method used in the industrial preparation of pluripotent stem cells (PSCs), for regenerative therapy and drug screening. Generally, a suspension culture requires agitation to keep PSC aggregates suspended and to promote mass transfer, but agitation also causes cell damage. In this study, we investigated the use of a Bingham plastic fluid, supplemented with a polysaccharide-based polymer, to preserve PSCs from cell damage in suspension culture. Rheometric analysis showed that the culture medium gained yield stress and became a Bingham plastic fluid, after supplementation with the polymer FP003. A growth/death analysis revealed that 2 days of aggregate formation and 2 days of suspension in the Bingham plastic medium improved cell growth and prevented cell death. After the initial aggregation step, whereas strong agitation (120 rpm) of a conventional culture medium resulted in massive cell death, in the Bingham plastic fluid we obtained the same growth as the normal culture with optimal agitation (90 rpm). This indicates that Bingham plastic fluid protected cells from shear stress in suspension culture and could be used to enhance their robustness when developing a large-scale.

Ran-GTP Is Non-essential to Activate NuMA for Mitotic Spindle-Pole Focusing but Dynamically Polarizes HURP Near Chromosomes.

Spindle assembly is spatially regulated by a chromosome-derived Ran- GTP gradient. Previous work proposed that Ran-GTP activates spindle assembly factors (SAFs) around chromosomes by dissociating inhibitory importins from SAFs. However, it is unclear whether the Ran-GTP gradient equivalently activates SAFs that localize at distinct spindle regions. In addition, Ran's dual functions in interphase nucleocytoplasmic transport and mitotic spindle assembly have made it difficult to assess its mitotic roles in somatic cells. Here, using auxin-inducible degron technology in human cells, we developed acute mitotic depletion assays to dissect Ran's mitotic roles systematically and separately from its interphase function. In contrast to the prevailing model, we found that the Ran pathway is not essential for spindle assembly activities that occur at sites spatially separated from chromosomes, including activating NuMA for spindle-pole focusing or for targeting TPX2. On the other hand, Ran-GTP is required to localize HURP and HSET specifically at chromosome-proximal regions to set proper spindle length during prometaphase. We demonstrated that Ran-GTP and importin-ß coordinately promote HURP's dynamic microtubule binding-dissociation cycle, which maintains HURP near chromosomes during metaphase. Together, we propose that the Ran pathway acts on spindle assembly independently of its interphase functions in mitotic human cells but does not equivalently regulate all Ran-regulated SAFs. Ran-dependent spindle assembly is likely coupled with additional parallel pathways that activate SAFs distantly located from the chromosomes.

Gellan Gum Promotes the Differentiation of Enterocytes from Human Induced Pluripotent Stem Cells.

The evaluation of drug pharmacokinetics in the small intestine is critical for developing orally administered drugs. Caucasian colon adenocarcinoma (Caco-2) cells are employed to evaluate drug absorption in preclinical trials of drug development. However, the pharmacokinetic characteristics of Caco-2 cells are different from those of the normal human small intestine. Besides this, it is almost impossible to obtain primary human intestinal epithelial cells of the same batch. Therefore, human iPS cell-derived enterocytes (hiPSEs) with pharmacokinetic functions similar to human intestinal epithelial cells are expected to be useful for the evaluation of drug absorption. Previous studies have been limited to the use of cytokines and small molecules to generate hiPSEs. Dietary fibers play a critical role in maintaining intestinal physiology. We used gellan gum (GG), a soluble dietary fiber, to optimize hiPSE differentiation. hiPSEs cocultured with GG had significantly higher expression of small intestine- and pharmacokinetics-related genes and proteins. The activities of drug-metabolizing enzymes, such as cytochrome P450 2C19, and peptide transporter 1 were significantly increased in the GG treatment group compared to the control group. At the end point of differentiation, the percentage of senescent cells increased. Therefore, GG could improve the differentiation efficiency of human iPS cells to enterocytes and increase intestinal maturation by extending the life span of hiPSEs.

Mesoscopic heterogeneity in a nanocellulose-containing cell storage medium.

A nanocellulose (NC)-containing medium is a promising candidate for cell storage that allows cell floating without any stirring. We here found that the NC medium was spatially heterogeneous in terms of its rheological properties. The characteristic length of the heterogeneity was a few tens of micrometers and it decreased upon sonication treatment. The length scale of the heterogeneity affected the cell suspension; the NC medium having a smaller length scale suppressed the cell sedimentation effectively.

Three-dimensional culture of chicken primordial germ cells (cPGCs) in defined media containing the functional polymer FP003.

Scalable production of avian cell lines exhibits a valuable potential on therapeutic application by producing recombinant proteins and as the substrate for virus growth due to the special glycosylation occurs in avian species. Chicken primordial germ cells (cPGCs), a germinal pluripotent avian cell type, present the ability of self-renewal, an anchorage-independent cell growth and the ability to be genetically modified. This cell type could be an interesting bioreactor system for industrial purposes. This study sought to establish an expandable culture system with defined components for three-dimensional (3D) culture of cPGCs. cPGCs were cultured in medium supplemented with the functional polymer FP003. Viscoelasticity was low in this medium but cPGCs did not sediment in culture and efficiencies of space and nutrient utilization were thus enhanced and consequently their expansion was improved. The total number of cPGCs increased by 17-fold after 1 week of culture in 3D-FAot medium, an aseric defined medium containing FP003 polymer, FGF2 and Activin A as growth factors and Ovotransferrin as protein. Moreover, cPGC cell lines stably expressed the germline-specific reporter VASA:tdTOMATO, as well as other markers of cPGCs, for more than 1 month upon culture in 3D-FAot medium, indicating that the characteristics of these cells are maintained. In summary, this novel 3D culture system can be used to efficiently expand cPGCs in suspension without mechanical stirring, which is available for long-term culture and no loss of cellular properties was found. This system provides a platform for large-scale culture of cPGCs.