Ichiro Harada

Galactosylated chitosan as a synthetic extracellular matrix for hepatocytes attachment.

Galactose moiety as the hepatocyte anchorage was covalently coupled with chitosan for the development of synthetic extracellular matrix. Hepatocytes adhesion to galactosylated chitosan (GC)-coated polystyrene (PS) dish became as high as 94.7% after 2 h incubation whereas the hepatocytes adhesion to chitosan-coated PS dish was 69.1%, indication of galactose-specific recognition between GC molecules and asialoglycoprotein receptors of hepatocytes. The DNA synthesis of the hepatocytes adhered to GC-coated dish was increased in the presence of epidermal growth factor (EGF) at low concentration of GC (0.05 microg/ml) whereas the DNA synthesis of the hepatocytes adhered to GC-coated dish was decreased in the presence of EGF at high concentration of GC (5 microg/ml). The spreading shapes of the hepatocytes adhered to the surface in the presence of EGF at low concentration of GC (0.05 microg/ml) were enhanced than in the absence of EGF. The hepatocytes adhered to the surface at high concentration of GC (5 microg/ml) showed round shapes and exhibited many spheroid formation after 24 h in the presence of EGF.

Kinetics of volume phase transition in poly(N-isopropylacrylamide) gels

Kinetics of volume phase transition in poly(N-isopropylacrylamide) (NIPA) gels jumped from a low-temperature swollen phase to a high-temperature shrunken phase was studied as functions of NIPA monomer and crosslinker concentrations. We found for the first time a clear kinematical boundary at which the shrinking relaxation time of gels changes discontinuously by 102–104 times, and that the profile of the boundary correlates with the sol-gel transition line and the contour line of turbidity of gels. A “morphological” boundary which characterizes the emergence of the bubble formation on gel surface was also determined. The theoretical calculation of the phase diagram on the basis of the mean field theory shows qualitatively that the shrinking speed of gels could be connected with the depth of the thermodynamic region of the spinodal instability (K+4μ/3=0) into which they are transferred where K and μ are the bulk and the shear moduli, respectively. A mechanism of discontinuous change of the shrinking speed i...

Dual Inhibition of Src and GSK3 Maintains Mouse Embryonic Stem Cells, Whose Differentiation Is Mechanically Regulated by Src Signaling

Recent studies reveal that the mechanical environment influences the behavior and function of various types of cells, including stem cells. However, signaling pathways involved in the mechanical regulation of stem cell properties remain largely unknown. Using polyacrylamide gels with varying Youngs moduli as substrates, we demonstrate that mouse embryonic stem cells (mESCs) are induced to differentiate on substrates with defined elasticity, involving the Src‐ShcA‐MAP kinase pathway. While the dual inhibition of mitogen‐activated protein (MAP) kinase and glycogen synthase kinase 3 (GSK3), termed “2i,” was reported to sustain the pluripotency of mESCs, we find it to be substrate elasticity dependent. In contrast, Src inhibition in addition to 2i allows mESCs to retain their pluripotency independent of substrate elasticity. The alternative dual inhibition of Src and GSK3 (“alternative 2i”) retains the pluripotency and self‐renewal of mESCs in vitro and is instrumental in efficiently deriving mESCs from preimplantation mouse embryos. In addition, the transplantation of mESCs, maintained under the alternative 2i condition, to immunodeficient mice leads to the formation of teratomas that include differentiation into three germ layers. Furthermore, mESCs established with alternative 2i contributed to chimeric mice production and transmitted to the germline. These results reveal a role for Src‐ShcA‐MAP kinase signaling in the mechanical regulation of mESC properties and indicate that alternative 2i is a versatile tool for the maintenance of mESCs in serum‐free conditions as well as for the derivation of mESCs. Stem Cells2012;30:1394–1404

Regulation of cellular morphology using temperature-responsive hydrogel for integrin-mediated mechanical force stimulation

A new culture substrate was developed for cells to be equibiaxially stretched using fibronectin (Fn)-immobilized temperature-responsive hydrogel. The cells cultured on the gel substrate were equibiaxially stretched with swelling of the gel, which was accompanied by slight changes of temperature. During gel swelling, changes of cell shape were clearly observed by optical microscopy because of high transparency of the gel. ERK was highly and transiently activated by mechanical stimulation whereas focal adhesion kinase (FAK) was not, indicating that mechanical signals were transduced into biochemical signals in cells. We found that cells formed filopodia-like structures in response to mechanical cues, suggesting that mechanical forces facilitated actin polymerization at the peripheral region. In the cytoplasm, paxillin-containing fibrous structures were formed along actin fibers. These results indicate that we can perform both analysis of intracellular signal transduction and observation of cell shapes at high magnification in our method.

Embryonic undifferentiated cells show scattering activity on a surface coated with immobilized E-cadherin

Rearrangement of cell–cell adhesion is a critical event in embryonic development and tissue formation. We investigated the regulatory function of E‐cadherin, a key adhesion protein, in the developmental process by using E‐cadherin/IgG Fc fusion protein as an adhesion matrix in cell culture. F9 embryonal carcinoma cells usually form colonies when cultured on gelatin or fibronectin matrices. However, F9 cells cultured on the E‐cadherin/IgG Fc fusion protein matrix formed a scattered distribution, with a different cytoskeletal organization and E‐cadherin‐rich protrusions that were regulated by Rac1 activity. The same scattering activity was observed in P19 embryonal carcinoma cells. In contrast, three types of differentiated cells, NMuMG mammary gland cells, MDCK kidney epithelial cells, and mouse primary isolated hepatocytes, did not show the scattering activity observed in F9 and P19 cells. These results suggest that migratory behavior on an E‐cadherin‐immobilized surface is only observed in embryonic cells, and that the regulatory mechanisms underlying E‐cadherin‐mediated cell adhesion vary with the state of differentiation. J. Cell. Biochem. 103: 296–310, 2008.

The role of the interaction of the vinculin proline-rich linker region with vinexin α in sensing the stiffness of the extracellular matrix.

ABSTRACT Although extracellular matrix (ECM) stiffness is an important aspect of the extracellular microenvironment and is known to direct the lineage specification of stem cells and affect cancer progression, the molecular mechanisms that sense ECM stiffness have not yet been elucidated. In this study, we show that the proline-rich linker (PRL) region of vinculin and the PRL-region-binding protein vinexin are involved in sensing the stiffness of ECM substrates. A rigid substrate increases the level of cytoskeleton-associated vinculin, and the fraction of vinculin stably localizing at focal adhesions (FAs) is larger on rigid ECM than on soft ECM. Mutations in the PRL region or the depletion of vinexin expression impair these responses to ECM stiffness. Furthermore, vinexin depletion impairs the stiffness-dependent regulation of cell migration. These results suggest that the interaction of the PRL region of vinculin with vinexin &agr; plays a crucial role in sensing ECM stiffness and in mechanotransduction.

p53-mediated activation of the mitochondrial protease HtrA2/Omi prevents cell invasion

The tumor suppressor p53 induces activation of the mitochondrial protease HtrA2/Omi and prevents Ras-driven invasion by modulating the actin cytoskeleton.

Substrate stiffness regulates temporary NF-κB activation via actomyosin contractions

Physical properties of the extracellular matrix (ECM) can control cellular phenotypes via mechanotransduction, which is the process of translation of mechanical stresses into biochemical signals. While current research is clarifying the relationship between mechanotransduction and cytoskeleton or adhesion complexes, the contribution of transcription factors to mechanotransduction is not well understood. The results of this study revealed that the transcription factor NF-κB, a major regulator for immunoreaction and cancer progression, is responsive to substrate stiffness. NF-κB activation was temporarily induced in H1299 lung adenocarcinoma cells grown on a stiff substrate but not in cells grown on a soft substrate. Although the activation of NF-κB was independent of the activity of integrin β1, an ECM-binding protein, the activation was dependent on actomyosin contractions induced by phosphorylation of myosin regulatory light chain (MRLC). Additionally, the inhibition of MRLC phosphorylation by Rho kinase inhibitor Y27632 reduced the activity of NF-κB. We also observed substrate-specific morphology of the cells, with cells grown on the soft substrate appearing more rounded and cells grown on the stiff substrate appearing more spread out. Inhibiting NF-κB activation caused a reversal of these morphologies on both substrates. These results suggest that substrate stiffness regulates NF-κB activity via actomyosin contractions, resulting in morphological changes.

Design and Construction of an Equibiaxial Cell Stretching System That Is Improved for Biochemical Analysis

We describe the design and validation of an equibiaxial stretching device in which cells are confined to regions of homogeneous strain. Using this device, we seek to overcome a significant limitation of existing equibiaxial stretching devices, in which strains are not homogeneous over the entire region of cell culture. We cast PDMS in a mold to produce a membrane with a cylindrical wall incorporated in the center, which was used to confine cell monolayers to the central membrane region subjected to homogeneous equibiaxial strain. We demonstrated that the presence of the wall to hold the culture medium did not affect strain homogeneity over the majority of the culture surface and also showed that cells adhered well onto the PDMS membranes. We used our device in cyclic strain experiments and demonstrated strain-dependent changes in extracellular signal-regulated kinase (ERK) and tyrosine phosphorylation upon cell stretching. Furthermore, we examined cell responses to very small magnitudes of strain ranging from 1% to 6% and were able to observe a graduated increase in ERK phosphorylation in response to these strains. Collectively, we were able to study cellular biochemical response with a high degree of accuracy and sensitivity to fine changes in substrate strain. Because we have designed our device along the lines of existing equibiaxial stretching technologies, we believe that our innovations can be incorporated into existing systems. This device would provide a useful addition to the set of tools applied for in vitro studies of cell mechanobiology.

Direct manipulation of intracellular stress fibres using a hook-shaped AFM probe.

Atomic force microscopy (AFM) is a highly successful technique for imaging nanometre-sized samples and measuring pico- to nano-newton forces acting between atoms and molecules. When it comes to the manipulation of larger samples with forces of tens and hundreds of nano-newtons, however, the present chemistry-based modification protocols for functionalizing AFM cantilevers to achieve the formation of covalent/non-covalent linkages between the AFM probe and the sample surface do not produce strong enough bonds. For the purpose of measuring the fracture strength and other mechanical properties of stress fibres (SFs) in living as well as semi-intact fibroblast cells, we fabricated an AFM probe with a hooking function by focused ion beam technology and used the AFM probe hook to capture, pull and eventually sever a chosen SF labelled with green or red fluorescent protein.