Toshiaki Takezawa

Culture Period-Dependent Changes in the Uptake of Transporter Substrates in Sandwich-Cultured Rat and Human Hepatocytes

Sandwich-cultured hepatocytes (SCH) are a useful tool for evaluating hepatobiliary drug transport in vitro. Some studies have investigated the in vitro-in vivo correlations of the biliary clearance of drugs using SCH. In most cases, the biliary clearance observed in vivo correlated well with the predicted clearance, but the predicted absolute values were underestimated when based on in vitro experiments with SCH. We hypothesized that the down-regulated function of uptake transporters is one of the causes of this underestimation. Therefore, the uptake of taurocholate, digoxin, pravastatin, and rosuvastatin was investigated in sandwich-cultured rat hepatocytes (SCRH) cultured for 5, 24, 48, and 96 h, and the predicted hepatic clearance from in vitro uptake clearance (CLH, vitro) was calculated with a dispersion model. In SCRH cultured for 96 h, the saturable uptake of taurocholate, digoxin, pravastatin, and rosuvastatin decreased to 7.5, 3.3, 64, and 23%, respectively, of their uptake in hepatocytes cultured for 5 h, and a better prediction of in vivo hepatic clearance (CLH, vivo) was achieved when based on CLH, vitro of 5-h-cultured hepatocytes. These results suggest that the uptake activity is considerably reduced in cell culture, even in a sandwich-culture format. In a similar study, we also examined taurocholate and rosuvastatin in sandwich-cultured human hepatocytes (SCHH). Unlike in SCRH, the saturable uptake of these compounds did not differ markedly in SCHH cultured for 5 or 96 h. Thus, the uptake activity in SCHH was maintained relatively well compared with that in SCRH.

Collagen vitrigel membranes for the in vitro reconstruction of separate corneal epithelial, stromal, and endothelial cell layers

The goal of this study was to evaluate the potential suitability of collagen Vitrigel (CV) membrane as a substrate for the separate reconstruction of the three main cellular layers of the cornea. Limbal explants, keratocytes, and endothelial cells were cultured on transparent membranes made of type I collagen. The resulting cell sheets were evaluated using RT-PCR, in addition to light and electron microscopy. Tensile testing was also performed to examine the mechanical properties of CV. Limbal explant cultures resulted in partially stratified epithelial sheets with upregulation of the putative stem cell marker p63. Keratocytes cultured in serum on CV exhibited stellate morphology along with a marked increase in expression of corneal crystallin ALDH and keratocan, (a keratan sulphate proteoglycan: KSPG), compared to identical cultures on tissue culture plastic. Endothelial cells formed dense monolayers with uniform cell size, tight intercellular junctions, and expression of voltage-dependent anion channels VDAC2 and VDAC3, chloride channel protein CLCN2, and sodium bicarbonate transporter NBC1. Epithelial and endothelial cells exhibited adhesive structures (desmosomes and hemidesmosomes) and evidence of apical specialization (microplicae), while endothelial cells also produced a Descemets membrane-like basal lamina. CV was found to possess ultimate tensile strengths of 6.8 +/- 1.5 MPa when hydrated and 28.6 +/- 7.0 MPa when dry. Taken together, these results indicate that CV holds promise as a substrate for corneal reconstruction.

Integration and application of vitrified collagen in multilayered microfluidic devices for corneal microtissue culture

This paper describes the fabrication and application of microfluidic devices containing collagen vitrigel (CV) used as both a functional and sacrificial cell growth substrate for the development of corneal microtissue patches. Within the device, vacuum fixation of the CV in a dehydrated state enables quick integration with standard multilayer soft lithographic techniques, while on-chip rehydration results in a gel-like collagen substrate for microfluidic cell culture. Fluidic connectivity to both the apical and basal side of the CV permits bilayered culture of epithelium and supporting stromal cell layers. In addition, microfluidic introduction of a collagenase etching media enables sacrificial degradation of the supporting CV membrane for development of barrier tissue constructs containing minimal synthetic substrate. The utility of this platform was evaluated by miniaturizing the standard transepithelial permeability (TEP) assay in order to measure the integrity of an array of corneal tissue micropatches.

Concept for Organ Engineering: A Reconstruction Method of Rat Liver for in Vitro Culture

In the past decade, there have been remarkable advances in tissue engineering technology toward the goal of creating organoids in vitro from cells and cellular scaffolding. Indeed, tissue-engineered organoids such as skin and cartilage, each with comparatively simple architectures, are presently at the clinical stage. However, conventional tissue engineering techniques have not allowed for the reconstruction of an organoid that mimics an organ of complex architecture of abundant vascular networks. We established a method for organ engineering that can remodel a rat liver into a reconstructed organoid without separating the majority of liver cells by a continuous three-step perfusion. The liver was perfused through its vascular system with a buffered balanced salt solution to cleanse blood from the organ, with a collagenase/dispase medium to deconstruct cellular scaffolds, and with a culture medium containing collagen type I to reorganize the multicellular architecture. The reconstructed organoid was then prepared by excising the perfused liver from the rat and culturing it at 37 degrees C for 2 h. Histologically healthy parenchymal hepatocytes expressing albumin were observed in the excised organoid even after culture for 3 weeks. Furthermore, a fibroblast-implanted organoid was prepared by using a culture medium containing suspended fibroblasts in the third step of the perfusion procedure, demonstrating the efficacy of heterogeneous cells for the reconstruction of an organoid. This method may be applicable to the formation of organoids from other organs, such as kidney and spleen, each of which have abundant capillaries, and therefore the method provides a novel concept for the development of lab-grown organs, i. e., organ engineering.

Cryopreservation in situ of cell monolayers on collagen vitrigel membrane culture substrata: ready-to-use preparation of primary hepatocytes and ES cells.

Cryopreservation is generally performed on cells in suspension. In the case of adherent cells such as hepatocytes, a loss of their ability to attach is a more serious problem than a decreased viability after cryopreservation. We herein report a novel technology of direct in situ cryopreservation of cells cultured on collagen vitrigel membranes, which have excellent mechanical strength and can be easily handled by tweezers even when coated with cultured cells. Rat primary hepatocytes, mitomycin C-treated mouse fibroblasts (feeder cells for ES cells), and mouse ES cells on the feeder cells were cultured on collagen vitrigel membranes for 1 day. The membranes with cells attached were then plucked up from the dish, soaked in cryopreservation medium containing 10% dimethyl sulfoxide, frozen using a controlled-rate freezer, and transferred to liquid nitrogen. The cells cultured on plastic cell culture dishes were also frozen as controls. After storage in liquid nitrogen for periods from 1 week to 3 months, the cryopreserved membranes with the cells still attached were thawed by adding warmed culture medium. Cell viability estimated by morphology and functional staining with calcein showed significant improvement in comparison to cells cryopreserved without the collagen vitrigel membrane. The recoveries of living cells after cryopreservation were 26.7%, 76.2%, and 58.6% for rat hepatocytes, mitomycin C-treated mouse fibroblasts, and mouse ES cells on collagen vitrigel membranes, respectively. In contrast, essentially no cells at all remained on the plastic cell culture dishes after thawing. Because adherent cell storage under these conditions is very convenient, the use of this technique employing collagen vitrigel membranes should be generally applicable to the cryopreservation of adherent cells that are otherwise problematic to store as frozen stocks.

A Protein-Permeable Scaffold of a Collagen Vitrigel Membrane Useful for Reconstructing Crosstalk Models between Two Different Cell Types

Soft and turbid collagen gel disks were previously converted into strong and transparent gel membranes utilizing a concept for the vitrification of heat-denatured of proteins. This novel stable and transparent gel has been termed ‘vitrigel’. By encompassing the collagen vitrigel membrane in a nylon frame, it can be easily handled with tweezers, and functions as an excellent scaffold for three-dimensional cell culture models, as cells can be cultured on both sides. Here, we investigated the molecular permeability of the collagen vitrigel membrane in a time course-dependent manner using glucose and serum proteins. Glucose penetrated through the collagen vitrigel membrane to the opposite side, and concentrations on each side were found to be equilibrated within 24 h. Serum proteins up to a molecular weight >100 kDa also gradually passed through the collagen vitrigel membrane. In addition, human microvascular endothelial cells (HMVECs) were cultured on one surface of the collagen vitrigel membrane with a nylon frame, and human dermal fibroblasts (HDFs) or HT-29 (a human colon carcinoma cell line) cells were cocultured on the opposite surface. Histomorphological observations revealed the formation of three-dimensional crosstalk models composed of HMVECs and HDFs or HMVECs and HT-29 cells. Resulting data suggest that the protein-permeable scaffold composed of the collagen vitrigel membrane is useful for the reconstruction and/or modeling of ‘crosstalk’ between two different cells types. Hereafter, such crosstalk models in vitro could be applied to research not only of paracrine factors, but also to epithelial- or endothelial-mesenchymal transitions.

Upregulation of Tight-Junctional Proteins in Corneal Epithelial Cells by Corneal Fibroblasts in Collagen Vitrigel Cultures

PURPOSE To investigate the effects of corneal fibroblasts on the differentiation of corneal epithelial cells in a coculture system based on a collagen vitrigel membrane. METHODS Simian virus 40-transformed human corneal epithelial (HCE) cells and human corneal fibroblasts were cultured on opposite sides of a collagen vitrigel membrane. The distribution of HCE cells and corneal fibroblasts on the collagen membrane was determined by immunofluorescence staining and immunoblot analysis of marker proteins. Expression of the tight-junctional proteins ZO-1, occludin, and claudin and of the adherens-junctional proteins E- and N-cadherin in HCE cells was determined at the mRNA and protein levels by reverse transcription-polymerase chain reaction analysis and immunoblot analysis, respectively. RESULTS The abundance of ZO-1, occludin, and claudin mRNA and proteins in HCE cells was markedly increased by coculture with corneal fibroblasts. The expression of E- or N-cadherin did not differ between HCE cells cultured with corneal fibroblasts and those cultured without them. PD98059, a specific inhibitor of signaling by extracellular signal regulated kinase (ERK), prevented the upregulation of tight-junctional proteins in HCE cells by corneal fibroblasts. CONCLUSIONS Human corneal fibroblasts regulated the expression of tight-junctional proteins in HCE cells, suggesting that corneal fibroblasts may play an important role in the differentiation of corneal epithelial cells.

Development and Evaluation of Porcine Atelocollagen Vitrigel Membrane With a Spherical Curve and Transplantable Artificial Corneal Endothelial Grafts

PURPOSE To develop a collagen vitrigel (CV) optimized as a corneal endothelial cell (CEC) carrier and create an artificial corneal endothelial graft. METHODS We first developed a flat-shaped collagen vitrigel for regenerative medicine (CV-RM) using porcine atelocollagen and ultraviolet (UV) irradiation. The optimal UV amount was determined by measuring the CV-RM transparency under various irradiating conditions. The collagen vitrigel for corneal endothelial regenerative treatment (CV-CERT), a transparent porcine atelocollagen with a curved shape, was made using spherically curved molds and UV irradiation. The membrane permeability of the CV-CERT was tested in vitro. The biocompatibility, transparency, and adhesiveness of the CV-CERT were evaluated in rabbit eyes. We also developed a culture technique for distributing human CECs on the curved CV-CERT. RESULTS The optimal amount of UV irradiation for CV-RM transparency was 2400 mJ/cm(2). Membrane permeability of CV-CERT at day 5 was higher than that of commercially available CV (P = 0.032). The CV-CERT was transparent and biocompatible in rabbit corneas for up to 4 months. The CV-CERT remained attached to the rabbit corneal posterior surface, whereas the flat-shaped CV-RM, differing only in shape from the CV-CERT, dislocated soon after surgery. Human CECs seeded on the CV-CERT using our technique were evenly distributed with a single layer structure and a mean cell density of 2650 ± 100 cells/mm(2). CONCLUSIONS We developed a transparent and biocompatible porcine-derived atelocollagen vitrigel membrane with a spherical curvature. A transplantable artificial endothelial graft was created by combining cultured human CECs and the CV-CERT.

The bovine lactoferrin region responsible for promoting the collagen gel contractile activity of human fibroblasts

We have reported that bovine lactoferrin (bLf) promotes the contractile activity of collagen gels by WI-38 human fibroblasts via the phosphorylation of myosin light chain (MLC). To identify the region of bLf that is responsible for this activity, we prepared bLf fragments by limited proteolysis using trypsin and investigated the effects of each fragment on gel contractile activity. Lf consists of a single polypeptide chain containing two lobes that are independent globular structures termed the N- and C-lobes. The fragment corresponding to the C-lobe of bLf (amino acids 341-689) had a more prominent effect on collagen gel contractile activity than did that of either native bLf or its N-lobe (1-284). Further hydrolysis of the C-lobe with either pepsin or trypsin resulted in a loss of this activity. The effect of the C-lobe on collagen gel contraction by fibroblasts was dose-dependent and was associated with the elevation of MLC phosphorylation.

Non-skin mesenchymal cell types support epidermal regeneration in a mesenchymal stem cell or myofibroblast phenotype-independent manner

Skin‐derived fibroblasts, preadipocytes and adipocytes, and non‐skin‐derived bone marrow stromal cells support epidermal regeneration. It remains unclear, however, whether various organ‐derived mesenchymal cell (MC) types other than the aforementioned counterparts affect epidermal regeneration. Using a skin reconstruction model, it is shown here that heart‐, spleen‐, lung‐, liver‐ and kidney‐derived MC support epidermal regeneration by keratinocytes. Immunohistochemistry showed that these MC types described here allowed keratinocytes to express cytokeratin (CK) 10, CK14 and involucrin in a normal fashion, and to retain the epidermal progenitor cell marker, p63, within the basal layer. MC types constantly expressed vimentin, but they were heterogeneous in their expression of the mesenchymal stem cell markers, stage‐specific embryonic antigen‐4, CD105, CD90 and CD44, and the myofibroblast marker, α‐smooth muscle actin. The MC types expressed keratinocyte growth factor, stromal‐derived factor‐1 and interleukin‐6, which are all critical for dermal fibroblast–keratinocyte interaction. These results indicate that vimentin‐positive MC originating from the heart, spleen, lung, liver and kidney can support epidermal regeneration without the involvement of mesenchymal stem cell and myofibroblast phenotypes of MC.