Your search keyword '"Takeuchi, Jun"' showing total 7 results

1. Important cardiac transcription factor genes are accompanied by bidirectional long non-coding RNAs

Author

Hori, Yutaro, Tanimoto, Yoko, Takahashi, Satoru, Furukawa, Tetsushi, Koshiba-Takeuchi, Kazuko, and Takeuchi, Jun K.

Published

2018

2. Distinct Function of 2 Chromatin Remodeling Complexes That Share a Common Subunit, Williams Syndrome Transcription Factor (WSTF)

Author

Yoshimura, Kimihiro, Kitagawa, Hirochika, Fujiki, Ryoji, Tanabe, Masahiko, Takezawa, Shinichiro, Takada, Ichiro, Yamaoka, Ikuko, Yonezawa, Masayoshi, Kondo, Takeshi, Furutani, Yoshiyuki, Yagi, Hisato, Yoshinaga, Shin, Masuda, Takeyoshi, Fukuda, Toru, Yamamoto, Yoko, Ebihara, Kanae, Li, Dean Y., Matsuoka, Rumiko, Takeuchi, Jun K., Matsumoto, Takahiro, Kato, Shigeaki, and Groudine, Mark T.

Published

2009

3. Sall1 transiently marks undifferentiated heart precursors and regulates their fate

Author

Morita, Yuika, Andersen, Peter, Hotta, Akitsu, Sasagawa, Noriko, Kurokawa, Junko, Tsukahara, Yuko, Hayashida, Naoko, Koga, Chizuko, Nishikawa, Misato, Evans, Sylvia M., Furukawa, Tetsushi, Koshiba-Takeuchi, Kazuko, Nishinakamura, Ryuichi, Yoshida, Yoshinori, Kwon, Chulan, and Takeuchi, Jun K.

Subjects

0301 basic medicine, medicine.medical_specialty, Mesoderm, Heart Ventricles, Biology, Regenerative medicine, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Cardiac development, Internal medicine, medicine, SALL1, Animals, Humans, Transcription factor, Molecular Biology, Heart development, Regeneration (biology), Myocardium, Stem Cells, Gene Expression Regulation, Developmental, Cell Differentiation, ES/iPS cells, In vitro, Cell biology, Cardiac progenitor, 030104 developmental biology, Endocrinology, medicine.anatomical_structure, Ventricle, Cardiac transcription factors, Cardiology and Cardiovascular Medicine, 030217 neurology & neurosurgery, Transcription Factors

Abstract

Cardiac progenitor cells (CPCs) are a crucial source of cells in cardiac development and regeneration. However, reported CPCs are heterogeneous, and no gene has been identified to transiently mark undifferentiated CPCs throughout heart development. Here we show that Spalt-like gene 1 (Sall1), a zing-finger transcription factor, is expressed in undifferentiated CPCs giving rise to both left and right ventricles. Sall1 was transiently expressed in precardiac mesoderm contributing to the first heart field (left ventricle precursors) but not in the field itself. Similarly, Sall1 expression was maintained in the second heart field (outflow tract/right ventricle precursors) but not in cardiac cells. In vitro, high levels of Sall1 at mesodermal stages enhanced cardiomyogenesis, whereas its continued expression suppressed cardiac differentiation. Our study demonstrates that Sall1 marks CPCs in an undifferentiated state and regulates cardiac differentiation. These findings provide fundamental insights into CPC maintenance, which can be instrumental for CPC-based regenerative medicine.

Published

2016

4. Cardiac septation in heart development and evolution.

Author

Katano, Wataru, Moriyama, Yuuta, Takeuchi, Jun K., and Koshiba‐Takeuchi, Kazuko

Subjects

HEART development, HEART evolution, BLOOD circulation, PULMONARY circulation, GLOBAL environmental change

Abstract

The heart is one of the vital organs and is functionalized for blood circulation from its early development. Some vertebrates have altered their living environment from aquatic to terrestrial life over the course of evolution and obtained circulatory systems well adapted to their lifestyles. The morphology of the heart has been changed together with the acquisition of a sophisticated respiratory organ, the lung. Adaptation to a terrestrial environment requires the coordination of heart and lung development due to the intake of oxygen from the air and the production of the large amount of energy needed for terrestrial life. Therefore, vertebrates developed pulmonary circulation and a septated heart (four‐chambered heart) with venous and arterial blood completely separated. In this review, we summarize how vertebrates change the structures and functions of their circulatory systems according to environmental changes. This figure shows the bulbus arteriosus (BA) formation mechanism by elnb in teleost cardiac development. BA is a unique cardiac organ in teleosts. The teleosts are thought to be well adapt to the aquatic environment through obtaining the BA (Modified from Moriyama et al.,). [ABSTRACT FROM AUTHOR]

Published

2019

5. Epigenetic factors and cardiac development.

Author

van Weerd, Jan Hendrick, Koshiba-Takeuchi, Kazuko, Kwon, Chulan, and Takeuchi, Jun K.

Subjects

HEART development, HEART abnormalities, HUMAN abnormalities, CARDIOLOGY, TRANSCRIPTION factors, GENETICS, DEVELOPMENTAL biology, CELL differentiation

Abstract

Congenital heart malformations remain the leading cause of death related to birth defects. Recent advances in developmental and regenerative cardiology have shed light on a mechanistic understanding of heart development that is controlled by a transcriptional network of genetic and epigenetic factors. This article reviews the roles of chromatin remodelling factors important for cardiac development with the current knowledge of cardiac morphogenesis, regeneration, and direct cardiac differentiation. In the last 5 years, critical roles of epigenetic factors have been revealed in the cardiac research field. [ABSTRACT FROM AUTHOR]

Published

2011

6. Tbx5 specifies the left/right ventricles and ventricular septum position during cardiogenesis.

Author

Takeuchi, Jun K., Ohgi, Makoto, Koshiba-Takeuchi, Kazuko, Shiratori, Hidetaka, Sakaki, Ichiro, Ogura, Keiko, Saijoh, Yukio, and Ogura, Toshihiko

Subjects

*LEFT heart ventricle, *HEART septum, *GENES, *GENE expression, *TRANSGENIC mice, *DEVELOPMENTAL biology

Abstract

Extensive misexpression studies were carried out to explore the roles played by Tbx5, the expression of which is excluded from the right ventricle (RV) during cardiogenesis. When Tbx5 was misexpressed ubiquitously, ventricular septum was not formed, resulting in a single ventricle. In such heart, left ventricle (LV)-specific ANF gene was induced. In search of the putative RV factor(s), we have found that chick Tbx20 is expressed in the RV, showing a complementary fashion to Tbx5. In the Tbx5-misexpressed heart, this gene was repressed. When misexpression was spatially partial, leaving small Tbx5-negative area in the right ventricle, ventricular septum was shifted rightwards, resulting in a small RV with an enlarged LV. Focal expression induced an ectopic boundary of Tbx5-positive and -negative regions in the right ventricle, at which an additional septum was formed. Similar results were obtained from the transient transgenic mice. In such hearts, expression patterns of dHAND and eHAND were changed with definitive cardiac abnormalities. Furthermore, we report that human ANF promoter is synergistically activated by Tbx5, Nkx2.5 and GATA4. This activation was abrogated by Tbx20, implicating the pivotal roles of interactions among these heart-specific factors. Taken together, our data indicate that Tbx5 specifies the identity of LV through tight interactions among several heart-specific factors, and highlight the essential roles of Tbx5 in cardiac development. [ABSTRACT FROM AUTHOR]

Published

2003

7. In vitro generation of functional murine heart organoids via FGF4 and extracellular matrix.

Author

Lee, Jiyoung, Sutani, Akito, Kaneko, Rin, Takeuchi, Jun, Sasano, Tetsuo, Kohda, Takashi, Ihara, Kensuke, Takahashi, Kentaro, Yamazoe, Masahiro, Morio, Tomohiro, Furukawa, Tetsushi, and Ishino, Fumitoshi

Subjects

EXTRACELLULAR matrix, FIBROBLAST growth factors, CARDIAC contraction, ORGANOIDS, SINOATRIAL node, HEART development, HEART, HEART atrium

Abstract

Our understanding of the spatiotemporal regulation of cardiogenesis is hindered by the difficulties in modeling this complex organ currently by in vitro models. Here we develop a method to generate heart organoids from mouse embryonic stem cell-derived embryoid bodies. Consecutive morphological changes proceed in a self-organizing manner in the presence of the laminin-entactin (LN/ET) complex and fibroblast growth factor 4 (FGF4), and the resulting in vitro heart organoid possesses atrium- and ventricle-like parts containing cardiac muscle, conducting tissues, smooth muscle and endothelial cells that exhibited myocardial contraction and action potentials. The heart organoids exhibit ultrastructural, histochemical and gene expression characteristics of considerable similarity to those of developmental hearts in vivo. Our results demonstrate that this method not only provides a biomimetic model of the developing heart-like structure with simplified differentiation protocol, but also represents a promising research tool with a broad range of applications, including drug testing. Our understanding of the development of the heart has been limited by a lack of in vitro cellular models. Here, the authors treat mouse embryonic stem cell-derived embryoid bodies with laminin-entactin (to mimic the developing microenvironment) and FGF4 to form heart organoids, with atrial and ventricular-like parts. [ABSTRACT FROM AUTHOR]

Published

2020