Your search keyword '"Taruno, Akiyuki"' showing total 8 results

1. Quercetin is a Useful Medicinal Compound Showing Various Actions Including Control of Blood Pressure, Neurite Elongation and Epithelial Ion Transport

Author

Marunaka, Yoshinori, Niisato, Naomi, Miyazaki, Hiroaki, Nakajima, Ken-­Ichi, Taruno, Akiyuki, Sun, Hongxin, Marunaka, Rie, Okui, Motoki, Yamamoto, Toshiro, Kanamura, Narisato, Kogiso, Haruka, Ikeuchi, Yukiko, Kashio, Makiko, Hosogi, Shigekuni, and Nakahari, Takashi

Abstract

Quercetin has multiple potential to control various cell function keeping our body condition healthy. In this review article, we describe the molecular mechanism on how quercetin exerts its action on blood pressure, neurite elongation and epithelial ion transport based from a viewpoint of cytosolic Cl- environments, which is recently recognized as an important signaling factor in various types of cells. Recent studies show various roles of cytosolic Cl- in regulation of blood pressure and neurite elongation, and prevention from bacterial and viral infection. We have found the stimulatory action of quercetin on Cl- transporter, Na+-K+-2Cl- cotransporter 1 (NKCC1; an isoform of NKCC), which has been recognized as one of the most interesting, fundamental actions of quercetin. In this review article, based on this stimulatory action of quercetin on NKCC1, we introduce the molecular mechanism of quercetin on: 1) blood pressure, 2) neurite elongation, and 3) epithelial Cl- secretion including tight junction forming in epithelial tissues. 1) Quercetin induces elevation of the cytosolic Cl- concentration via activation of NKCC1, leading to anti-hypertensive action by diminishing expression of epithelial Na+ channel (ENaC), a key ion channel involved in renal Na+ reabsorption, while quercetin has no effects on the blood pressure with normal salt intake. 2) Quercetin also has stimulatory effects on neurite elongation by elevating the cytosolic Cl- concentration via activation of NKCC1 due to tubulin polymerization facilitated through Cl--induced inhibition of GTPase. 3) Further, in lung airway epithelia quercetin stimulates Cl- secretion by increasing the driving force for Cl- secretion via elevation of the cytosolic Cl- concentration: this leads to water secretion, participating in prevention of our body from bacterial and viral infection. In addition to transcellular ion transport, quercetin regulates tight junction function via enhancement of tight junction integrity by modulating expression and assembling tight junction-forming proteins. Based on these observations, it is concluded that quercetin is a useful medicinal compound keeping our body to be in healthy condition.

Published

2018

2. A light-induced small G-protein gem limits the circadian clock phase-shift magnitude by inhibiting voltage-dependent calcium channels

Author

Matsuo, Masahiro, Seo, Kazuyuki, Taruno, Akiyuki, Mizoro, Yasutaka, Yamaguchi, Yoshiaki, Doi, Masao, Nakao, Rhyuta, Kori, Hiroshi, Abe, Takaya, Ohmori, Harunori, Tominaga, Keiko, and Okamura, Hitoshi

Abstract

Calcium signaling is pivotal to the circadian clockwork in the suprachiasmatic nucleus (SCN), particularly in rhythm entrainment to environmental light-dark cycles. Here, we show that a small G-protein Gem, an endogenous inhibitor of high-voltage-activated voltage-dependent calcium channels (VDCCs), is rapidly induced by light in SCN neurons via the calcium (Ca2+)-mediated CREB/CRE transcriptional pathway. Gem attenuates light-induced calcium signaling through its interaction with VDCCs. The phase-shift magnitude of locomotor activity rhythms by light, at night, increases in Gem-deficient (Gem−/−) mice. Similarly, in SCN slices from Gem−/−mice, depolarizing stimuli induce larger phase shifts of clock gene transcription rhythms that are normalized by the application of an L-type VDCC blocker, nifedipine. Voltage-clamp recordings from SCN neurons reveal that Ca2+currents through L-type channels increase in Gem−/−mice. Our findings suggest that transcriptionally activated Gem feeds back to suppress excessive light-evoked L-type VDCC activation, adjusting the light-induced phase-shift magnitude to an appropriate level in mammals.

Published

2022

3. Intracellular calcium plays a role as the second messenger of hypotonic stress in gene regulation of SGK1 and ENaC in renal epithelial A6 cells

Author

Taruno, Akiyuki, Niisato, Naomi, and Marunaka, Yoshinori

Abstract

In A6 cells, a renal cell line derived from Xenopus laevis, hypotonic stress stimulates the amiloride-sensitive Na+transport. Hypotonic action on Na+transport consists of two phases, a nongenomic early phase and a genomic delayed phase. Although it has been reported that, during the genomic phase, hypotonic stress stimulates transcription of Na+transport-related genes, such as serum- and glucocorticoid-inducible kinase 1 (SGK1) and subunits of the epithelial Na+channel (ENaC), increasing Na+transport, the mechanism remains unknown. We focused the present study on the role of intracellular Ca2+in hypotonicity-induced SGK1 and ENaC subunit transcription. Since hypotonic stress raises intracellular Ca2+concentration in A6 cells, we hypothesized that Ca2+-dependent signals participate in the genomic action. Using real-time quantitative RT-PCR and Western blot techniques and measuring short-circuit currents, we observed that 1) BAPTA-AM and W7 blunted the hypotonicity-induced expression of SGK1 mRNA and protein, 2) ionomycin dose dependently stimulated expression of SGK1 mRNA and protein under an isotonic condition and the time course of the stimulatory effect of ionomycin on SGK1 mRNA was remarkably similar to that of hypotonic action on SGK1 mRNA, 3) hypotonic stress stimulated transcription of three ENaC subunits in an intracellular Ca2+-dependent manner, and 4) BAPTA-AM retarded the delayed phase of hypotonic stress-induced Na+transport but had no effect on the early phase. These observations indicate for the first time that intracellular Ca2+plays a role as the second messenger in hypotonic stress-induced Na+transport by stimulating transcription of SGK1 and ENaC subunits.

Published

2008

4. Hypotonicity stimulates renal epithelial sodium transport by activating JNK via receptor tyrosine kinases

Author

Taruno, Akiyuki, Niisato, Naomi, and Marunaka, Yoshinori

Abstract

We previously reported that hypotonic stress stimulated transepithelial Na+transport via a pathway dependent on protein tyrosine kinase (PTK; Niisato N, Van Driessche W, Liu M, Marunaka Y. J Membr Biol175: 63–77, 2000). However, it is still unknown what type of PTK mediates this stimulation. In the present study, we investigated the role of receptor tyrosine kinase (RTK) in the hypotonic stimulation of Na+transport. In renal epithelial A6 cells, we observed inhibitory effects of AG1478 [an inhibitor of the EGF receptor (EGFR)] and AG1296 [an inhibitor of the PDGF receptor (PDGFR)] on both the hypotonic stress-induced stimulation of Na+transport and the hypotonic stress-induced ligand-independent activation of EGFR. We further studied whether hypotonic stress activates members of the MAP kinase family, ERK1/2, p38 MAPK, and JNK/SAPK, via an RTK-dependent pathway. The present study indicates that hypotonic stress induced phosphorylation of ERK1/2 and JNK/SAPK, but not p38 MAPK, that the hypotonic stress-induced phosphorylation of ERK1/2 and JNK/SAPK was diminished by coapplication of AG1478 and AG1296, and that only JNK/SAPK was involved in the hypotonic stimulation of Na+transport. A further study using cyclohexamide (a protein synthesis inhibitor) suggests that both RTK and JNK/SAPK contributed to the protein synthesis-independent early phase in hypotonic stress-induced Na+transport, but not to the protein synthesis-dependent late phase. The present study also suggests involvement of phosphatidylinositol 3-kinase (PI3-kinase) in RTK-JNK/SAPK cascade-mediated Na+transport. These observations indicate that 1) hypotonic stress activates JNK/SAPK via RTKs in a ligand-independent pathway, 2) the RTK-JNK/SAPK cascade acts as a mediator of hypotonic stress for stimulation of Na+transport, and 3) PI3-kinase is involved in the RTK-JNK/SAPK cascade for the hypotonic stress-induced stimulation of Na+transport.

Published

2007

5. N-Linked Glycosylation Regulates CALHM1 Channel Function and Subcellular Localization

Author

Taruno, Akiyuki, Sun, Hongxin, Kashio, Makiko, and Marunaka, Yoshinori

Published

2016

6. CALHM1 is an Extracellular Ca2+- and Voltage-Gated ATP Permeable Ion Channel

Author

Ma, Zhongming, Taruno, Akiyuki, Siebert, Adam P., Li, Ang, Civan, Mortimer M., and Foskett, J. Kevin

Published

2013

7. CALHM1 Ion Channel Mediates Purinergic Neurotransmission from Taste Buds to Gustatory Nerve Terminals during Sweet and Bitter Perception

Author

Taruno, Akiyuki, Li, Ang, Ma, Zhongming, Marambaud, Philippe, Ohmoto, Makoto, Matsumoto, Ichiro, Civan, Mortimer M., Tordoff, Michael G., and Foskett, J. Kevin

Published

2013

8. Regulation of Epithelial Sodium Transport via Epithelial Na+ Channel

Author

Marunaka, Yoshinori, Niisato, Naomi, Taruno, Akiyuki, Ohta, Mariko, Miyazaki, Hiroaki, Hosogi, Shigekuni, Nakajima, Ken-ichi, Kusuzaki, Katsuyuki, Ashihara, Eishi, Nishio, Kyosuke, Iwasaki, Yoshinobu, Nakahari, Takashi, and Kubota, Takahiro

Abstract

Renal epithelial Na+ transport plays an important role in homeostasis of our body fluid content and blood pressure. Further, the Na+ transport in alveolar epithelial cells essentially controls the amount of alveolar fluid that should be kept at an appropriate level for normal gas exchange. The epithelial Na+ transport is generally mediated through two steps: (1) the entry step of Na+ via epithelial Na+ channel (ENaC) at the apical membrane and (2) the extrusion step of Na+ via the Na+, K+-ATPase at the basolateral membrane. In general, the Na+ entry via ENaC is the rate-limiting step. Therefore, the regulation of ENaC plays an essential role in control of blood pressure and normal gas exchange. In this paper, we discuss two major factors in ENaC regulation: (1) activity of individual ENaC and (2) number of ENaC located at the apical membrane.

Published

2011