Ryuji Kodama scite author profile

Recent progress in studies of development and differentiation has greatly stimulated analysis of transdifferentiation, and more cell types capable of transdifferentiation have been documented. Growth factors must be essential, key factors in the regulation of the transdifferentiation process, in cooperation with components of the extracellular matrix, which helps to stabilize the differentiated state of tissues. Trials to induce transdifferentiation artificially by transfection of genes have also begun.

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Demonstration of contractility of circumferential actin bundles and its morphogenetic significance in pigmented epithelium in vitro and in vivo.

Owaribe¹,

Kodama²,

Eguchi³

1981

155

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Each pigmented epithelial cell bears circumferential actin bundles at its apical level when the pigmented epithelium is established in eyes in situ or in culture in vitro. Welldifferentiated pigmented epithelia in culture were treated with a 50% glycerol solution containing 0.1 M KCI, 5 mM EDTA, and 10 mM sodium phosphate buffer, pH 7.2, for 24 h or more at 4°C. When the glycerinated epithelium was transferred to the ATP solution, each cell constituting the epithelium began to contract . The epithelium was cleaved into many cell groups as a result of contraction of each cell . The periphery of each cell group was lifted to form a cup or vesicle and eventually detached from the substratum . However, those cells that had not adhered tightly and not formed a monolager epithelium with typical polygonal cellular pattern contracted independently as observed in the glycerinated fibroblasts .Contraction of the glycerinated pigmented epithelial cells was inhibited by N-ethylmaleimide but not by cytochalasin B. ITP and UTP also effected the contraction of the glycerinated cells, but GTP and ADP did not. Ca t+ was not required . This contractile model of pigmented epithelium provides a useful experimental system for analyzing the function of actin in cellular morphogenesis.

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Sodium-level-sensitive sodium channel Na_x is expressed in glial laminate processes in the sensory circumventricular organs

Watanabe

Hiyama

Shimizu

et al. 2006

American Journal of Physiology-Regulatory, Integrative and Comp

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Na(x) is an atypical sodium channel that is assumed to be a descendant of the voltage-gated sodium channel family. Our recent studies on the Na(x)-gene-targeting mouse revealed that Na(x) channel is localized to the circumventricular organs (CVOs), the central loci for the salt and water homeostasis in mammals, where the Na(x) channel serves as a sodium-level sensor of the body fluid. To understand the cellular mechanism by which the information sensed by Na(x) channels is transferred to the activity of the organs, we dissected the subcellular localization of Na(x) in the present study. Double-immunostaining and immunoelectron microscopic analyses revealed that Na(x) is exclusively localized to perineuronal lamellate processes extended from ependymal cells and astrocytes in the organs. In addition, glial cells isolated from the subfornical organ, one of the CVOs, were sensitive to an increase in the extracellular sodium level, as analyzed by an ion-imaging method. These results suggest that glial cells bearing the Na(x) channel are the first to sense a physiological increase in the level of sodium in the body fluid, and they regulate the neural activity of the CVOs by enveloping neurons. Close communication between inexcitable glial cells and excitable neural cells thus appears to be the basis of the central control of the salt homeostasis.

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Ryuji Kodama

Transdifferentiation

Demonstration of contractility of circumferential actin bundles and its morphogenetic significance in pigmented epithelium in vitro and in vivo.

Sodium-level-sensitive sodium channel Na_x is expressed in glial laminate processes in the sensory circumventricular organs

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Ryuji Kodama

Transdifferentiation

Demonstration of contractility of circumferential actin bundles and its morphogenetic significance in pigmented epithelium in vitro and in vivo.

Sodium-level-sensitive sodium channel Nax is expressed in glial laminate processes in the sensory circumventricular organs

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Product

Resources

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Sodium-level-sensitive sodium channel Na_x is expressed in glial laminate processes in the sensory circumventricular organs