Hajime Sawada scite author profile

Bone marrow stromal cells (MSCs) are multipotent stem cells that have the potential to differentiate into bone, cartilage, fat and muscle. We now demonstrate that MSCs can be induced to differentiate into cells with Schwann cell characteristics, capable of eliciting peripheral nervous system regeneration in adult rats. MSCs treated with beta-mercaptoethanol followed by retinoic acid and cultured in the presence of forskolin, basic-FGF, PDGF and heregulin, changed morphologically into cells resembling primary cultured Schwann cells and expressing p75, S-100, GFAP and O4. The MSCs were genetically engineered by transduction with retrovirus encoding green fluorescent protein (GFP), and then differentiated by treatment with factors described above. They were transplanted into the cut ends of sciatic nerves, which then responded with vigorous nerve fibre regeneration within 3 weeks of the operation. Myelination of regenerated fibers by GFP-expressing MSCs was recognized using confocal and immunoelectron microscopy. The results suggest that MSCs are able to differentiate into myelinating cells, capable of supporting nerve fibre re-growth, and they can therefore be applied to induce nerve regeneration.

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Specific induction of neuronal cells from bone marrow stromal cells and application for autologous transplantation

Dezawa

et al. 2004

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Bone marrow stromal cells (MSCs) have the capability under specific conditions of differentiating into various cell types such as osteocytes, chondrocytes, and adipocytes. Here we demonstrate a highly efficient and specific induction of cells with neuronal characteristics, without glial differentiation, from both rat and human MSCs using gene transfection with Notch intracellular domain (NICD) and subsequent treatment with bFGF, forskolin, and ciliary neurotrophic factor. MSCs expressed markers related to neural stem cells after transfection with NICD, and subsequent trophic factor administration induced neuronal cells. Some of them showed voltage-gated fast sodium and delayed rectifier potassium currents and action potentials compatible with characteristics of functional neurons. Further treatment of the induced neuronal cells with glial cell line-derived neurotrophic factor (GDNF) increased the proportion of tyrosine hydroxylase-positive and dopamine-producing cells. Transplantation of these GDNF-treated cells showed improvement in apomorphine-induced rotational behavior and adjusting step and paw-reaching tests following intrastriatal implantation in a 6-hydroxy dopamine rat model of Parkinson disease. This study shows that a population of neuronal cells can be specifically generated from MSCs and that induced cells may allow for a neuroreconstructive approach.

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Specific induction of neuronal cells from bone marrow stromal cells and application for autologous transplantation

Dezawa¹,

Kanno²,

Hoshino³

et al. 2004

J. Clin. Invest.

551

276

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Interaction between PAR-3 and the aPKC–PAR-6 complex is indispensable for apical domain development of epithelial cells

et al. 2009

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The evolutionarily conserved polarity proteins PAR-3, atypical protein kinase C (aPKC) and PAR-6 critically regulate the apical membrane development required for epithelial organ development. However, the molecular mechanisms underlying their roles remain to be clarified. We demonstrate that PAR-3 knockdown in MDCK cells retards apical protein delivery to the plasma membrane, and eventually leads to mislocalized apical domain formation at intercellular regions in both twodimensional and three-dimensional culture systems. The defects in PAR-3 knockdown cells are efficiently rescued by wild-type PAR-3, but not by a point mutant (S827/829A) that lacks the ability to interact with aPKC, indicating that formation of the PAR-3-aPKC-PAR-6 complex is essential for apical membrane development. This is in sharp contrast with tight junction maturation, which does not necessarily depend on the aPKC-PAR-3 interaction, and indicates that the two fundamental processes essential for epithelial polarity are differentially regulated by these polarity proteins. Importantly, highly depolarized cells accumulate aPKC and PAR-6, but not PAR-3, on apical protein-containing vacuoles, which become targeted to PAR-3-positive primordial cell-cell contact sites during the initial stage of the repolarization process. Therefore, formation of the PAR-3-aPKC-PAR-6 complex might be required for targeting of not only the aPKC-PAR-6 complex but also of apical protein carrier vesicles to primordial junction structures. Supplementary material available online at

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Peripheral nerve regeneration by transplantation of bone marrow stromal cell—derived Schwann cells in adult rats

Mimura¹,

Dezawa²,

Kanno³

et al. 2004

174

114

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Extensible and Less-Extensible Domains of Connectin Filaments in Stretched Vertebrate Skeletal Muscle Sarcomeres as Detected by Immunofluorescence and Immunoelectron Microscopy Using Monoclonal Antibodies1

et al. 1988

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Two kinds of monoclonal antibodies (3B9 and SM1) against connectin, muscle elastic protein, reacted with both alpha- and beta-connectins. Immunofluorescence studies revealed that 3B9 stained both edges of the A band of chicken breast muscle myofibrils and remained as such upon stretching to a sarcomere length of 3.5 microns. On the other hand, SM1 stained the I band very close to the edges of the A band and the SM1-stained stripes moved considerably upon stretching to a sarcomere length of 3.5 microns. Immunoelectron microscopic observations with frog semitendinosus muscle revealed that three distinct stripes bound with 3B9 in the edges of the A band did not move on stretching up to 3.5 microns. On the other hand, the two stripes stained with SM1 in the I band clearly moved to the same extent as the stretching. However, when a sarcomere was stretched to 4.0 microns, all the stripes with 3B9 or SM1 disappeared and diffused deposits of the antibodies were observed. Thus it is concluded that connectin filaments in the I band region are more extensible than those at both edges of the A band.

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Characterization of the collagen in the hexagonal lattice of Descemet's membrane: its relation to type VIII collagen.

1990

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Abstract. To investigate the nature of the hexagonal lattice structure in Descemet's membrane, monoclonal antibodies were raised against a homogenate of bovine Descemet's membranes. They were screened by immunofluorescence microscopy to obtain antibodies that label Descemet's membrane. Some monoclonal antibodies labeled both Descemet's membrane and fine filaments within the stroma. In electron microscopy, with immunogold labeling on a critical point dried specimen, the antibodies labeled the hexagonal lattices and long-spacing structures produced by the bovine corneal endothelial cells in culture; 6A2 antibodies labeled the nodes of the lattice and 9H3 antibodies labeled the sides of the lattice. These antibodies also labeled the hexagonal lattice of Descemet's membrane in situ in ultrathin frozen sectioning. In immunofluorescence, these antibodies stained the sclera, choroid, and optic nerve sheath and its septum. They also labeled the dura mater of the spinal cord, and the perichondrium of the tracheal cartilage. In immunoblotting, the antibodies recognized 64-kD collagenous peptides both in tissue culture and in Descemet's membrane in vivo. They also recognized 50-kD pepsin-resistant fragments from Descemet's membranes that are related to type VIII collagen. However, they did not react either in immunoblotting or in immunoprecipitation with medium of subconfluent cultures from which type VIII collagen had been obtained. The results are discussed with reference to the nature of type VIII collagen, which is currently under dispute. This lattice collagen may be a member of a novel class of long-spacing fibrils.ESCEMET'S membrane (DM) ~ is the basement membrane of corneal endothelial cells. DMs of some animal species contain characteristic stacks of hexagonal lattices that are arranged parallel to the surface of the membrane (16). The lattice is composed of electron-dense nodes at the vertexes and rodlike structures that connect the nodes. This highly regular arrangement has aroused the interests of many researchers. Linearly-arranged long-spacing (LS) structures with similar periodicities are often found in the vicinity of various basement membranes (for review, see reference 11). In an in vitro culture experiment, it was shown that the lattice consists of dumbbell-shaped unit structures 160 nm in length (33). They adhere to each other at their round ends to form hexagonal lattices or linear LS structures of ,x,150 nm in periodicity. The component of the lattice has been regarded as collagenous (16,32). Type 11 collagen (15), type IV collagen (41), type VI collagen (6, 7), and type VIII collagen (18) have been postulated as candidates for the component of the lattice. However, in our previous immunoelecDr. Sawada's present address is the

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Treatment of retinal detachment resulting from myopic macular hole with internal limiting membrane removal

Kadonosono¹,

Yazama²,

Itoh³

et al. 2001

American Journal of Ophthalmology

149

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Hajime Sawada

Sciatic nerve regeneration in rats induced by transplantation of in vitro differentiated bone‐marrow stromal cells

Specific induction of neuronal cells from bone marrow stromal cells and application for autologous transplantation

Specific induction of neuronal cells from bone marrow stromal cells and application for autologous transplantation

Interaction between PAR-3 and the aPKC–PAR-6 complex is indispensable for apical domain development of epithelial cells

Peripheral nerve regeneration by transplantation of bone marrow stromal cell—derived Schwann cells in adult rats

Extensible and Less-Extensible Domains of Connectin Filaments in Stretched Vertebrate Skeletal Muscle Sarcomeres as Detected by Immunofluorescence and Immunoelectron Microscopy Using Monoclonal Antibodies1

Characterization of the collagen in the hexagonal lattice of Descemet's membrane: its relation to type VIII collagen.

Treatment of retinal detachment resulting from myopic macular hole with internal limiting membrane removal

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