Dongjoo Kim

Role of gap junction communication in hepatocyte/fibroblast co-cultures: Implications for hepatic tissue engineering

The success of cell-based therapies for treatment of liver disease hinges on the phenotypic stability of isolated hepatocytes; however, primary hepatocytes rapidly lose many liver-specific functions following enzymatic isolation from the liver. Previous studies have demonstrated that liver-specific functions can be stabilized by cocultivation with non-parenchymal cells. Although the precise mechanisms underlying these effects have not yet been elucidated, it is believed that gap junctional intercellular communication plays an important role in cell-cell communication. In this study, indirect immunofluorescence was used to identify connexin 32 and 26 as homotypic gap junction proteins that were present between hepatocytes during co-culture with 3T3 fibroblasts, but not in pure hepatocyte cultures. Additionally, dye transfer of Lucifer yellow revealed that these gap junctions were functionally coupled. Although previous studies reported abundant connexin 43 expression in 3T3 fibroblasts and functional coupling by dye transfer, we did not observe heterotypic gap junction (connexin 43) expression or its functional coupling by either immunofluorescence or dye transfer. Incubation with a gap junction inhibitor, 18β-glycyrrhetinic acid, in hepatocyte co-culture diminished the level of liverspecific markers such as albumin production and P450 activity relative to control co-cultures. Overall, these findings suggest that homotypic gap junctions are present in hepatocytes co-cultured with fibroblasts and might play a functional role in homotypic hepatocyte communication. In conclusion, homotypic gap junctional communication may be important to phenotypic stability of isolated hepatocytes in co-culture and crucial to the design of tissue-engineered therapies for treatment of liver failure.

Enhanced nasal drug delivery efficiency by increasing mechanical loading using hypergravity

Nasal route drug administration for local and systemic delivery of many therapeutics has received attention because the nasal cavity is highly vascularized and provides a large surface area for drug absorption. However, nasal mucosa exhibits limited permeability to polar molecules. In this study, we developed a novel method for improving absorption efficiency of polar drugs by applying hypergravity. RPMI 2650 cells and primary human nasal epithelial cells were exposed three times to a 20 min hypergravitational condition (10 × g) with a 20 min rest period after each exposure. The applied hypergravity induced a decrease in transepithelial electrical resistance without significant loss of cellular metabolic activity, and cellular permeability of fluorescein sodium salt (MW 376 Da; NaFI) and FITC-labeled dextran (average MW 4,000 Da; FD-4) increased by 19% and 16%, respectively. Immunostaining and RT-qPCR results demonstrated that hypergravity conditions affected cytoskeletal structures and tight junctions, leading to weakening of the cell barrier function and increasing the cellular permeability of polar molecules. Our results indicate that hypergravity could be used as a new strategy for enhancing the efficiency of drug absorption via the nasal route.

Characteristics and Responses of Human Vocal Fold Cells in a Vibrational Culture Model: Vocal Folds Cells in a Vibratory Environment

This study was conducted to provide a vibrational culture model to investigate the effects of mechanical environments on cellular functions, and elucidate physiological characteristics of two different types of cells in vocal folds under static and vibrational conditions.

Mechanical load increase-induced changes in cytoskeletal structure and cellular barrier function in human cerebral endothelial cells: KIM and KWON

Globally, approximately a billion patients are estimated to suffer from neurological disorders. Although there are many therapeutic candidates for the central nervous system, treatment of brain disorders is restricted by the blood–brain barrier (BBB), which is a highly selective membrane that protects the brain from exogenous substances. This study was undertaken to develop a novel strategy to overcome the BBB and improve the efficiency of drug delivery to the brain by mechanical load increase using hypergravity. Human cerebral microvascular endothelial cells were exposed three times to 20 min hypergravity (10g), with a 20‐min rest period between each exposure. The applied hypergravity reversibly decreased the cellular metabolic activity and increased the permeation rate of fluorescein sodium salt, fluorescein isothiocyanate–labeled dextran (FD‐4), and fluorescein‐labeled jacalin. Following the exposure to hypergravity, we also observed structural changes of the cytoskeleton and tight junctions, and an alteration in the expression levels of related genes. These results indicate that increased mechanical load due to the applied hypergravity affects the cytoskeletal arrangement and tight junctions, thereby weakening the cell barrier function and enhancing the permeability of the paracellular pathway. Thus, the mechanical load increase by hypergravity has the potential of being used as a novel strategy to overcome the BBB for brain drug delivery.

Rice callus extracts for enhancing skin wound healing

Enhanced cell migration in the course of wound healing is required to repair damaged skin. We investigated the effects of rice callus extracts on the migration of skin keratinocytes. Rice callus extracts were obtained by using three different methods: pressurized hot water, crude ethanol, and liquid-liquid extractions. The extract obtained by using crude ethanol extraction was more effective in the migration of skin cells than that obtained by pressurized hot water extraction (PHWE). The crude ethanol extract (CEE) was further partitioned by performing liquid-liquid extraction. As phenolics are inhibitory compounds affecting cell migration, we analyzed the total phenolic content of the rice callus extracts. The level of phenolics in the n-hexane partitioned extract (n-HPE) of CEE was lower than that in all other partitioned extracts. The n-HPE was most effective in enhancing cell migration. We analyzed wound healingrelated factors including platelet derived growth factor B (PDGF-B), transforming growth factor beta 1 (TGF-β1), heparin-binding epidermal growth factor (HB-EGF), and fibroblast growth factor 2 (FGF-2) after the treatment of n-HPE. Most of the expressions of cell migration-related growth factors increased, but HB-EGF dramatically increased (6.5-fold) in keratinocytes treated with n-HPE. The results indicate that n-HPE contains more stimulating growth factors or proteins and less cell migration inhibiting factors than the other tested extracts; thus, n-HPE treatment produced the greatest enhancement of cell migration.

Enhanced production of recombinant proteins by a small molecule protein synthesis enhancer in combination with an antioxidant in recombinant Chinese hamster ovary cells

The improvement in the production of recombinant proteins has been linked in a number of small molecules such as carboxylic acids to the inhibition of histone deacetylase, leading to increased transcription of genes. However, carboxylic acids such as pentanoic acid and butanoic acid have been shown to promote an apoptotic response in Chinese hamster ovary (CHO) cell culture. Supplementation of cultures with antioxidants has shown the ability to reduce the apoptotic response of carboxylic acid supplementation, leading to increased therapeutic protein production. In this study, we showed that pentanoic acid reduced the number of cells entering early apoptosis relative to butanoic acid by 15.4%. Additionally, supplementation of butanoic acid- and pentanoic acid-treated cultures with N-acetyl cysteine (NAC) reduced the population of cells entering early apoptosis by 5.3 and 10.0%, respectively, while increasing productivity by 19.5% in the presence of pentanoic acid and NAC. Conversely, a decrease of 5.7% in production was observed in response to combined butanoic acid and N-acetyl cysteine treatment. The results presented herein provide evidence that a culture supplementation method is critical for optimization of biopharmaceutical manufacturing processes.