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47 results on '"Segawa, Katsumori"'

4. Visfatin: A Protein Secreted by Visceral Fat That Mimics the Effects of Insulin

Author

Fukuhara, Atsunori, Matsuda, Morihiro, Nishizawa, Masako, Segawa, Katsumori, Tanaka, Masaki, Kishimoto, Kae, Matsuki, Yasushi, Murakami, Mirei, Ichisaka, Tomoko, Murakami, Hiroko, Watanabe, Eijiro, Takagi, Toshiyuki, Akiyoshi, Megumi, Ohtsubo, Tsuguteru, Kihara, Shinji, Yamashita, Shizuya, Makishima, Makoto, Funahashi, Tohru, Yamanaka, Shinya, Hiramatsu, Ryuji, Matsuzawa, Yuji, and Shimomura, Iichiro

Published
2005

7. A sublethal ATP11A mutation associated with neurological deterioration causes aberrant phosphatidylcholine flipping in plasma membranes

Author

Segawa, Katsumori, Kikuchi, Atsuo, Noji, Tomoyasu, Sugiura, Yuki, Hiraga, Keita, Suzuki, Chigure, Haginoya, Kazuhiro, Kobayashi, Yasuko, Matsunaga, Mitsuhiro, Ochiai, Yuki, Yamada, Kyoko, Nishimura, Takuo, Iwasawa, Shinya, Shoji, Wataru, Sugihara, Fuminori, Nishino, Kohei, Kosako, Hidetaka, Ikawa, Masahito, Uchiyama, Yasuo, Suematsu, Makoto, Ishikita, Hiroshi, Kure, Shigeo, and Nagata, Shigekazu

Subjects
Gene mutations -- Research, Child development deviations -- Genetic aspects -- Development and progression, Glycerophospholipids -- Genetic aspects -- Health aspects, Adenosine triphosphatase -- Genetic aspects -- Health aspects, Nervous system diseases -- Genetic aspects -- Development and progression, Neurological research, Cell membranes -- Genetic aspects -- Health aspects, Developmental disabilities -- Genetic aspects -- Development and progression, Health care industry
Abstract

ATP11A translocates phosphatidylserine (PtdSer), but not phosphatidylcholine (PtdCho), from the outer to the inner leaflet of plasma membranes, thereby maintaining the asymmetric distribution of PtdSer. Here, we detected a de novo heterozygous point mutation of ATP11A in a patient with developmental delays and neurological deterioration. Mice carrying the corresponding mutation died perinatally of neurological disorders. This mutation caused an amino acid substitution (Q84E) in the first transmembrane segment of ATP11A, and mutant ATP11A flipped PtdCho. Molecular dynamics simulations revealed that the mutation allowed PtdCho binding at the substrate entry site. Aberrant PtdCho flipping markedly decreased the concentration of PtdCho in the outer leaflet of plasma membranes, whereas sphingomyelin (SM) concentrations in the outer leaflet increased. This change in the distribution of phospholipids altered cell characteristics, including cell growth, cholesterol homeostasis, and sensitivity to sphingomyelinase. Matrix-assisted laser desorption ionization-imaging mass spectrometry (MALDI-IMS) showed a marked increase of SM levels in the brains of Q84E-knockin mouse embryos. These results provide insights into the physiological importance of the substrate specificity of plasma membrane flippases for the proper distribution of PtdCho and SM., Introduction Lipids have various roles in cells, including that of energy source, membrane structural component, signaling molecule, and platform for the recruitment and activation of enzymes (1). Their backbone (glycerophospholipids, [...]

Published
2021
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8. Membrane structure-responsive lipid scrambling by TMEM63B to control plasma membrane lipid distribution

Author

Miyata, Yugo, Takahashi, Katsuya, Lee, Yongchan, Sultan, Cheryl S., Kuribayashi, Risa, Takahashi, Masatomo, Hata, Kosuke, Bamba, Takeshi, Izumi, Yoshihiro, Liu, Kehong, Uemura, Tomoko, Nomura, Norimichi, Iwata, So, Nagata, Shigekazu, Nishizawa, Tomohiro, and Segawa, Katsumori

Abstract

Phospholipids are asymmetrically distributed in the plasma membrane (PM), with phosphatidylcholine and sphingomyelin abundant in the outer leaflet. However, the mechanisms by which their distribution is regulated remain unclear. Here, we show that transmembrane protein 63B (TMEM63B) functions as a membrane structure-responsive lipid scramblase localized at the PM and lysosomes, activating bidirectional lipid translocation upon changes in membrane curvature and thickness. TMEM63B contains two intracellular loops with palmitoylated cysteine residue clusters essential for its scrambling function. TMEM63B deficiency alters phosphatidylcholine and sphingomyelin distributions in the PM. Persons with heterozygous mutations in TMEM63Bare known to develop neurodevelopmental disorders. We show that V44M, the most frequent substitution, confers constitutive scramblase activity on TMEM63B, disrupting PM phospholipid asymmetry. We determined the cryo-electron microscopy structures of TMEM63B in its open and closed conformations, uncovering a lipid translocation pathway formed in response to changes in the membrane environment. Together, our results identify TMEM63B as a membrane structure-responsive scramblase that controls PM lipid distribution and we reveal the molecular basis for lipid scrambling and its biological importance.

Published
2024
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11. Corrections to Coles, Vasconcelos, Chuck and Segawa

Author

Coles, Andrew H., Gannon, Hugh, Cerny, Anna, Kurt-Jones, Evelyn, Jones, Stephen N., Segawa, Katsumori, Suzuki, Jun, Nagata, Shigekazu, Vasconcelos, Nivaldo, Pantoja, Janaina, Belchior, Hindiael, Caixeta, Fäbio Viegas, Faber, Jean, Freire, Marco Aurelio M., Cota, Vinicius Rosa, de Macedo, Edson Anibal, Laplagne, Diego A., Gomes, Herman Martins, Ribeiro, Sidarta, Chuck, George S., Tobias, Christian, Sun, Lan, Kraemer, Florian, Li, Chenlin, Dibble, Dean, Arora, Rohit, Bragg, Jennifer N., Vogel, John P., Singh, Seema, Simmons, Blake A., Pauly, Markus, and Hake, Sarah

Published
2012

14. Retraction

Author

Fukuhara, Atsunori, Matsuda, Morihiro, Nishizawa, Masako, Segawa, Katsumori, Tanaka, Masaki, Kishimoto, Kae, Matsuki, Yasushi, Murakami, Mirei, Ichisaka, Tomoko, Murakami, Hiroko, Watanabe, Eijiro, Takagi, Toshiyuki, Akiyoshi, Megumi, Ohtsubo, Tsuguteru, Kihara, Shinji, Yamashita, Shizuya, Makishima, Makoto, Funahashi, Tohru, Yamanaka, Shinya, Hiramatsu, Ryuji, Matsuzawa, Yuji, and Shimomura, Iichiro

Published
2007

25. sublethal ATP11A mutation associated with neurological deterioration causes aberrant phosphatidylcholine flipping in plasma membranes.

Author

Segawa, Katsumori, Kikuchi, Atsuo, Noji, Tomoyasu, Sugiura, Yuki, Hiraga, Keita, Suzuki, Chigure, Haginoya, Kazuhiro, Kobayashi, Yasuko, Matsunaga, Mitsuhiro, Ochiai, Yuki, Yamada, Kyoko, Nishimura, Takuo, Iwasawa, Shinya, Shoji, Wataru, Sugihara, Fuminori, Nishino, Kohei, Kosako, Hidetaka, Ikawa, Masahito, Uchiyama, Yasuo, and Suematsu, Makoto

Abstract

ATP11A translocates phosphatidylserine (PtdSer), but not phosphatidylcholine (PtdCho), from the outer to the inner leaflet of plasma membranes, thereby maintaining the asymmetric distribution of PtdSer. Here, we detected a de novo heterozygous point mutation of ATP11A in a patient with developmental delays and neurological deterioration. Mice carrying the corresponding mutation died perinatally of neurological disorders. This mutation caused an amino acid substitution (Q84E) in the first transmembrane segment of ATP11A, and mutant ATP11A flipped PtdCho. Molecular dynamics simulations revealed that the mutation allowed PtdCho binding at the substrate entry site. Aberrant PtdCho flipping markedly decreased the concentration of PtdCho in the outer leaflet of plasma membranes, whereas sphingomyelin (SM) concentrations in the outer leaflet increased. This change in the distribution of phospholipids altered cell characteristics, including cell growth, cholesterol homeostasis, and sensitivity to sphingomyelinase. Matrix-assisted laser desorption ionization–imaging mass spectrometry (MALDI-IMS) showed a marked increase of SM levels in the brains of Q84E-knockin mouse embryos. These results provide insights into the physiological importance of the substrate specificity of plasma membrane flippases for the proper distribution of PtdCho and SM. [ABSTRACT FROM AUTHOR]

Published
2021
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31. Phospholipid flippase activities and substrate specificities of human type IV P-type ATPases localized to the plasma membrane.

Author

40192679, 10345598, Takatsu, Hiroyuki, Tanaka, Gaku, Segawa, Katsumori, Suzuki, Jun, Nagata, Shigekazu, Nakayama, Kazuhisa, Shin, Hye-Won, 40192679, 10345598, Takatsu, Hiroyuki, Tanaka, Gaku, Segawa, Katsumori, Suzuki, Jun, Nagata, Shigekazu, Nakayama, Kazuhisa, and Shin, Hye-Won

Abstract

Type IV P-type ATPases (P4-ATPases) are believed to translocate aminophospholipids from the exoplasmic to the cytoplasmic leaflets of cellular membranes. The yeast P4-ATPases, Drs2p and Dnf1p/Dnf2p, flip nitrobenzoxadiazole-labeled phosphatidylserine at the Golgi complex and nitrobenzoxadiazole-labeled phosphatidylcholine (PC) at the plasma membrane, respectively. However, the flippase activities and substrate specificities of mammalian P4-ATPases remain incompletely characterized. In this study, we established an assay for phospholipid flippase activities of plasma membrane-localized P4-ATPases using human cell lines stably expressing ATP8B1, ATP8B2, ATP11A, and ATP11C. We found that ATP11A and ATP11C have flippase activities toward phosphatidylserine and phosphatidylethanolamine but not PC or sphingomyelin. By contrast, ATPase-deficient mutants of ATP11A and ATP11C did not exhibit any flippase activity, indicating that these enzymes catalyze flipping in an ATPase-dependent manner. Furthermore, ATP8B1 and ATP8B2 exhibited preferential flippase activities toward PC. Some ATP8B1 mutants found in patients of progressive familial intrahepatic cholestasis type 1 (PFIC1), a severe liver disease caused by impaired bile flow, failed to translocate PC despite their delivery to the plasma membrane. Moreover, incorporation of PC mediated by ATP8B1 can be reversed by simultaneous expression of ABCB4, a PC floppase mutated in PFIC3 patients. Our findings elucidate the flippase activities and substrate specificities of plasma membrane-localized human P4-ATPases and suggest that phenotypes of some PFIC1 patients result from impairment of the PC flippase activity of ATP8B1.

Published
2014

32. Caspase-mediated cleavage of phospholipid flippase for apoptotic phosphatidylserine exposure.

Author

50212220, Segawa, Katsumori, Kurata, Sachiko, Yanagihashi, Yuichi, Brummelkamp, Thijn R, Matsuda, Fumihiko, Nagata, Shigekazu, 50212220, Segawa, Katsumori, Kurata, Sachiko, Yanagihashi, Yuichi, Brummelkamp, Thijn R, Matsuda, Fumihiko, and Nagata, Shigekazu

Abstract

Phospholipids are asymmetrically distributed in the plasma membrane. This asymmetrical distribution is disrupted during apoptosis, exposing phosphatidylserine (PtdSer) on the cell surface. Using a haploid genetic screen in human cells, we found that ATP11C (adenosine triphosphatase type 11C) and CDC50A (cell division cycle protein 50A) are required for aminophospholipid translocation from the outer to the inner plasma membrane leaflet; that is, they display flippase activity. ATP11C contained caspase recognition sites, and mutations at these sites generated caspase-resistant ATP11C without affecting its flippase activity. Cells expressing caspase-resistant ATP11C did not expose PtdSer during apoptosis and were not engulfed by macrophages, which suggests that inactivation of the flippase activity is required for apoptotic PtdSer exposure. CDC50A-deficient cells displayed PtdSer on their surface and were engulfed by macrophages, indicating that PtdSer is sufficient as an "eat me" signal.

Published
2014

33. Tim4- and MerTK-mediated engulfment of apoptotic cells by mouse resident peritoneal macrophages.

Author

Nishi, Chihiro, Toda, Satoshi, Segawa, Katsumori, Nagata, Shigekazu, Nishi, Chihiro, Toda, Satoshi, Segawa, Katsumori, and Nagata, Shigekazu

Abstract

Apoptotic cells are swiftly engulfed by macrophages to prevent the release of noxious materials from dying cells. Apoptotic cells expose phosphatidylserine (PtdSer) on their surface, and macrophages engulf them by recognizing PtdSer using specific receptors and opsonins. Here, we found that mouse resident peritoneal macrophages expressing Tim4 and MerTK are highly efficient at engulfing apoptotic cells. Neutralizing antibodies against either Tim4 or MerTK inhibited the macrophage engulfment of apoptotic cells. Tim4-null macrophages exhibited reduced binding and engulfment of apoptotic cells, whereas MerTK-null macrophages retained the ability to bind apoptotic cells but failed to engulf them. The incubation of wild-type peritoneal macrophages with apoptotic cells induced the rapid tyrosine phosphorylation of MerTK, which was not observed with Tim4-null macrophages. When mouse Ba/F3 cells were transformed with Tim4, apoptotic cells bound to the transformants but were not engulfed. Transformation of Ba/F3 cells with MerTK had no effect on the binding or engulfment of apoptotic cells; however, Tim4/MerTK transformants exhibited strong engulfment activity. Taken together, these results indicate that the engulfment of apoptotic cells by resident peritoneal macrophages proceeds in two steps: binding to Tim4, a PtdSer receptor, followed by MerTK-mediated cell engulfment.

Published
2014

39. Constitutive exposure of phosphatidylserine on viable cells.

Author

20542971, 30511894, 70114428, Segawa, Katsumori, Suzuki, Jun, Nagata, Shigekazu, 20542971, 30511894, 70114428, Segawa, Katsumori, Suzuki, Jun, and Nagata, Shigekazu

Abstract

Apoptotic cells are quickly recognized and engulfed by phagocytes to prevent the release of noxious materials from dying cells. Phosphatidylserine (PS) exposed on the surface of apoptotic cells is a proposed "eat-me" signal for the phagocytes. Transmembrane protein 16F (TMEM16F), a membrane protein with eight transmembrane segments, has the Ca-dependent phospholipid scramblase activity. Here we show that when lymphoma cells were transformed with a constitutively active form of TMEM16F, they exposed a high level of PS that was comparable to that observed on apoptotic cells. The PS-exposing cells were morphologically normal and grew normally. They efficiently responded to interleukin 3 and underwent apoptosis upon treatment with Fas ligand. The viable PS-exposing cells bound to peritoneal macrophages at 4 °C, but not at 25 °C. Accordingly, these cells were not engulfed by macrophages. When apoptotic cells were injected i.v. into mice, they were phagocytosed by CD11c(+)CD8(+) dendritic cells (DCs) in the spleen, but the PS-exposing living cells were not phagocytosed by these DCs. Furthermore, when PS-exposing lymphoma cells were transplanted s.c. into nude mice, they generated tumors as efficiently as parental lymphoma cells that did not expose PS. These results indicated that PS exposure alone is not sufficient to be recognized by macrophages as an eat-me signal.

Published
2011

41. The -1535 Promoter Variant of The Visfatin Gene Is Associated with Serum Triglyceride and HDL-cholesterol Levels in Japanese Subjects

Author

TOKUNAGA, Ayumi, primary, MIURA, Atsuko, additional, OKAUCHI, Yukiyoshi, additional, SEGAWA, Katsumori, additional, FUKUHARA, Atsunori, additional, OKITA, Kohei, additional, TAKAHASHI, Masahiko, additional, FUNAHASHI, Tohru, additional, MIYAGAWA, Jun-ichiro, additional, SHIMOMURA, Iichiro, additional, and YAMAGATA, Kazuya, additional

Published
2008
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45. Visfatin: A Protein Secreted by Visceral Fat That Mimics the Effects of Insulin

Author

Fukuhara, Atsunori, primary, Matsuda, Morihiro, additional, Nishizawa, Masako, additional, Segawa, Katsumori, additional, Tanaka, Masaki, additional, Kishimoto, Kae, additional, Matsuki, Yasushi, additional, Murakami, Mirei, additional, Ichisaka, Tomoko, additional, Murakami, Hiroko, additional, Watanabe, Eijoro, additional, Takagi, Toshiyuki, additional, Akiyoshi, Megumi, additional, Ohtsubo, Tsuguteru, additional, Kihara, Shinji, additional, Yamashita, Shizuya, additional, Makishima, Makoto, additional, Funahashi, Tohru, additional, Yamanaka, Shinya, additional, Hiramatsu, Ryuji, additional, Matsuzawa, Yuji, additional, and Shimomura, Iichiro, additional

Published
2005
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46. Clearance of Apoptotic Cells and Pyrenocytes.

Author

Toda S, Nishi C, Yanagihashi Y, Segawa K, and Nagata S

Subjects
Anemia metabolism, Anemia pathology, Animals, Arthritis metabolism, Arthritis pathology, Erythropoiesis, Humans, Immunity, Innate genetics, Lysosomes genetics, Lysosomes metabolism, Macrophages cytology, Molecular Biology methods, Phagocytes physiology, Phosphatidylserines metabolism, Receptors, Cell Surface metabolism, Signal Transduction, Apoptosis physiology, Erythrocytes physiology, Macrophages physiology
Abstract

Apoptotic cells are engulfed and digested by macrophages to maintain homeostasis in animals. If dead cells are not engulfed swiftly, they undergo secondary necrosis and release intracellular components that activate the immune system. Apoptotic cells are efficiently cleared due to phosphatidylserine (PtdSer) exposed on the cell surface that acts as an "eat me" signal. PtdSer is exposed through the activation of phospholipid scramblase and the inactivation of phospholipid flippase, which are both caspase-mediated events. Macrophages express a variety of molecules to recognize PtdSer, and use a sophisticated mechanism to engulf apoptotic cells. In red blood cells, the nucleus is lost when it is extruded as a pyrenocyte during definitive erythropoiesis. These pyrenocytes (nuclei surrounded by plasma membrane) also expose PtdSer on their surface and are efficiently engulfed by macrophages in a PtdSer-dependent manner. Macrophages transfer the engulfed apoptotic cell or pyrenocyte into lysosomes, where the components of the dead cell or pyrenocyte are degraded. If lysosomes cannot digest the DNA from apoptotic cells or pyrenocytes, the undigested DNA accumulates in the lysosome and activates macrophages to produce type I interferon (IFN) via a STING-dependent pathway; in embryos, this causes severe anemia. Here, we discuss how macrophages clear apoptotic cells and pyrenocytes., (© 2015 Elsevier Inc. All rights reserved.)

Published
2015
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47. Identification of a novel distal enhancer in human adiponectin gene.

Author

Segawa K, Matsuda M, Fukuhara A, Morita K, Okuno Y, Komuro R, and Shimomura I

Subjects
3T3 Cells, Adipocytes chemistry, Adipocytes metabolism, Adiponectin chemistry, Adiponectin genetics, Adiponectin metabolism, Animals, Base Sequence, Binding Sites, CCAAT-Enhancer-Binding Proteins genetics, Genes, Reporter, Humans, Mice, Molecular Sequence Data, Promoter Regions, Genetic, Protein Binding, Sequence Alignment, Transcription, Genetic, CCAAT-Enhancer-Binding Proteins metabolism, Enhancer Elements, Genetic, Gene Expression Regulation
Abstract

Adiponectin is exclusively expressed in adipose tissue and secreted from adipocytes, and shows anti-diabetic and anti-atherogenic properties. However, the precise transcriptional mechanism of adiponectin remains elusive. In this study, the 5' flanking promoter region of human adiponectin gene was analyzed using UCSC genome browser, and a 10 390-bp fragment, containing an evolutionally conserved region among species, was investigated. The luciferase reporter assay using this fragment identified a novel distal enhancer of human adiponectin gene. Promoter constructs with the distal enhancer exhibited high promoter activities in 3T3-L1 mature adipocytes. However, no such activity was observed in other types of cell lines. The distal enhancer is highly conserved, and contains two completely conserved CCAAT boxes. In 3T3-L1 mature adipocytes, deletion or each point mutation of these CCAAT boxes markedly reduced luciferase activity driven by adiponectin promoter. Knockdown of CCAAT/enhancer-binding protein alpha (CEBPA; also known as C/EBPalpha) using small interfering RNA diminished adiponectin mRNA expression and luciferase activity driven by adiponectin promoter with the distal enhancer. However, adiponectin promoter with each mutation of two CCAAT boxes in the distal enhancer did not respond to knockdown of CEBPA expression. Furthermore, CEBPA bound to the distal enhancer both in vitro and in vivo. We also identified a proximal promoter region responsible for transcriptional activation by the distal enhancer in human adiponectin gene. Our results indicate that CEBPA plays a pivotal role in the transcription of human adiponectin gene via the distal enhancer and proximal region in its promoter.

Published
2009
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