Ai Kushida

Decrease in culture temperature releases monolayer endothelial cell sheets together with deposited fibronectin matrix from temperature-responsive culture surfaces

Bovine aortic endothelial cells were cultured on surfaces grafted with a temperature-responsive polymer, poly(N-isopropylacrylamide) (PIPAAm), in the presence of serum. Cells adhered, spread, proliferated, and reached confluency as observed on ungrafted tissue culture polystyrene dishes. A decrease in culture temperature released cells only from the grafted surfaces without enzymatic or ethylenediaminetetraacetic acid treatment. Upon lowering temperature, the culture surfaces changed from hydrophobic to hydrophilic owing to the hydration of grafted PIPAAm and thus weakened the cell attachment to the dishes. Released cells maintained cell-cell junctions composing monolayer cell sheets. Immunoblotting and immunofluorescence microscopy revealed that fibronectin (FN) was deposited and accumulated on the grafted surfaces during the culture. Furthermore, the deposited FN matrix adhering to cell sheets was also recovered from temperature-responsive surfaces by low-temperature treatment, while trypsin treatment destroyed the matrix. The recovery of FN by low-temperature treatment was as high as by physical scraping with a rubber blade. Temperature-responsive surfaces can provide a novel method to use cultured confluent cell sheets for tissue engineering, and also to elucidate structure and function of deposited extracellular matrix during cell culture.

Thermo-Responsive Culture Dishes Allow the Intact Harvest of Multilayered Keratinocyte Sheets without Dispase by Reducing Temperature

To develop new technology for harvesting transplantable cultured epithelium without dispase treatment, human keratinocytes were plated on culture dishes grafted with a thermo-responsive polymer, poly(N-isopropylacrylamide). The grafted dish surfaces are slightly hydrophobic above 32 degrees C, but reversibly change to hydrophilic below this temperature. According to the method of Rheinwald and Green, keratinocytes proliferated and made a multilayer on the grafted surfaces at 37 degrees C, as on the nongrafted culture dishes. The multilayered keratinocyte sheets were detached from the grafted surfaces only by reducing temperature to 20 degrees C without need for dispase. No cell remnants were observed on the dishes. Such cell sheet detachment was not observed on nongrafted dishes. Immunoblotting of harvested keratinocyte sheets revealed that dispase treatment disrupted E-cadherin and laminin 5, while these molecules remained intact in the keratinocyte sheets harvested by only reducing temperature from the grafted dishes. Transmission electron microscopy revealed that desmosomes were destroyed in dispase treatment but retained in low-temperature treatment. Use of thermo-responsive dishes was examined as a new tool for tissue engineering to achieve the preparation of artificial epithelium for cell transplantation as well as for the investigation of intact multilayered keratinocyte sheets.

Temperature-responsive culture dishes allow nonenzymatic harvest of differentiated Madin-Darby canine kidney (MDCK) cell sheets

We have developed a temperature-responsive culture dish grafted with a poly(N-isopropylacrylamide) (PIPAAm). Various types of cells adhere, spread, and proliferate on the grafted dishes in the presence of serum at 37 degrees C. By reducing only temperature, these cells can be harvested noninvasively from the dishes according to rapid hydration of the grafted polymer. Because the harvest does not need enzymatic digestion, differentiated cell phenotypes are retained. In the present study, a renal epithelial cell line, Madin-Darby canine kidney (MDCK) cell, was cultured on the dishes, and cell behavior was examined. MDCK cells showed differentiated phenotypes such as dome formation during long-term culture, similar to on ungrafted dishes. After 1-week culture at 37 degrees C, trypsin digestion disrupted cell-cell junctions but failed to liberate cells from both ungrafted and grafted dishes. However, short-term incubation at 20 degrees C released confluent MDCK cells as a single contiguous cell sheet only from the polymer-grafted dishes because of selective disruption of the cell-surface binding. Immunocytochemistry with anti-beta-catenin antibody revealed that functional cell-cell junctions were organized even in the recovered cell sheets. Intriguingly, incubation time at 20 degrees C required for cell sheet detachment gradually shortened during long-term culture before reducing temperature. The acceleration of cell detachment was correlated to the decrease of a single cell area by means of cell contractile force. These findings suggest that cell sheet detachment from PIPAAm-grafted dishes should be accomplished by both PIPAAm hydration and cellular metabolic activity such as cell contraction.

Release of adsorbed fibronectin from temperature-responsive culture surfaces requires cellular activity

We have previously developed a temperature-responsive cell culture surface by grafting poly(N-isopropylacrylamide) that changes its surface hydrophobicity in response to temperature. While this surface shows similar hydrophobicity to that of commercial polystyrene cell culture surfaces and facilitates cell adhesion and proliferation at 37 degrees C, grafted polymer becomes hydrophilic below 32 degrees C and releases spread cultured cells without trypsin. Temperature-regulated cell detachment requires cell metabolic activity requiring ATP consumption, signal transduction, and cytoskeleton reorganziation. Precoating these surfaces with fibronectin (FN) improves spreading of less adhesive cultured hepatocytes and reducing culture temperature releases cultured cells from FN-adsorbed grafted surfaces. Immunostaining with anti-FN antibody revealed that only FN located beneath cultured cells is removed from culture surfaces after reducing temperature. FN adsorbed to surface areas lacking direct cell attachment remained surface-bound after reducing temperature. A novel concept of active cell detachment is also discussed.

Two-dimensional manipulation of differentiated Madin-Darby canine kidney (MDCK) cell sheets: the noninvasive harvest from temperature-responsive culture dishes and transfer to other surfaces.

A renal epithelial cell line, Madin-Darby canine kidney (MDCK) cells, adheres, spreads, and proliferates to confluency on our developed temperature-responsive culture dishes grafted with a poly(N-isopropylacrylamide) (PIPAAm) at 37 degrees C. In addition to other cell types, including hepatocytes and endothelial cells, MDCK cell sheets noninvasively were harvested from PIPAAm-grafted dishes merely by reducing the temperature. However, during the early stage of culture (up to 3 weeks), confluent MDCK cell detachment is greatly repressed. In the present study, we succeeded in the rapid harvest of confluent MDCK cell sheets and intact transfer to other culture dishes by utilizing hydrophilically modified poly(vinylidene difluoride) (PVDF) membranes as supporting materials. Immunocytochemistry with anti-beta-catenin antibody revealed that the functional cell-cell junctions were well organized in the transferred MDCK cell sheets. The viability assay showed that the transferred cells were not damaged during the two-dimensional cell-sheet manipulation. By transmission electron microscopy it was confirmed that the harvested MDCK cells retained differentiated phenotypes and had many microvilli and tight junctions at the apical and lateral plasma membranes, respectively. This two-dimensional cell-sheet manipulation technique promises to be useful in tissue engineering as well as in the investigation of epithelial cell sheets.

Two-dimensional cell sheet manipulation of heterotypically co-cultured lung cells utilizing temperature-responsive culture dishes results in long-term maintenance of differentiated epithelial cell functions

Here we report two-dimensional cell sheet manipulation (2D CSM) of heterotypically co-cultured lung cell sheets and the maintenance of differentiated phenotypes of lung epithelial cells over prolonged periods of up to 70 days. This was facilitated by poly(N-isopropylacrylamide) (PIPAAm)-grafted tissue culture dishes. PIPAAm-grafted dishes are responsive to temperature changes and offer a unique surface on which cells adhere and multiply like on ordinary tissue culture dishes under the permissive temperature of 37 degrees C, but on lowering of temperature resulting in changes in hydration of the polymer the cells spontaneously detach from the surface without use of enzymes like trypsin which is the common procedure. It has been well documented that type II pneumocytes of the lung lose many of their special features rapidly in culture. The culture system detailed here comprises random co-culture of epithelial and mesenchymal cells of lung. The heterotypic cell culture system promotes cell-cell interactions maintaining a harmonized physiology. When this heterotypic monolayer on PIPAAm-grafted dishes was subjected to lower temperature of 20 degrees C and 2D CSM we were able to transfer the monolayer as a single contiguous sheet with cell-cell connections intact to other surfaces. This non-invasive transfer of cell sheet resulted in shrinkage of the monolayer, enabling the type II cells to regain their cuboidal morphology and specialized characters like Maclura pomifera lectin binding and surfactant protein A (SP-A) expression. The active dome formation also observed subsequent to transfer reaffirms the uniqueness of the culture conditions and 2D CSM in future for developing tissue like architecture in vitro.