Your search keyword '"Toyota, Masatsugu"' showing total 4 results

1. Cytoplasmic calcium increases in response to changes in the gravity vector in hypocotyls and petioles of Arabidopsis seedlings

Author

Toyota, Masatsugu, Furuichi, Takuya, Tatsumi, Hitoshi, and Sokabe, Masahiro

Subjects

Arabidopsis thaliana, Biological sciences, Science and technology

Published

2008

2. Salt stress-induced Ca2+ waves are associated with rapid, long-distance root-to-shoot signaling in plants.

Author

Won-Gyu Choi, Toyota, Masatsugu, Su-Hwa Kim, Hilleary, Richard, and Gilroy, Simon

Subjects

*ARABIDOPSIS, *PROPERTIES of matter, *ENDOCRINE glands, *ARABIDOPSIS thaliana, *SALT, *PLANTS

Abstract

Their sessile lifestyle means that plants have to be exquisitely sensitive to their environment, integrating many signals to appropriate developmental and physiological responses. Stimuli ranging from wounding and pathogen attack to the distribution of water and nutrients in the soil are frequently presented in a localized manner but responses are often elicited throughout the plant. Such systemic signaling is thought to operate through the redistribution of a host of chemical regulators including peptides, RNAs, ions, metabolites, and hormones. However, there are hints of a much more rapid communication network that has been proposed to involve signals ranging from action and system potentials to reactive oxygen species. We now show that plants also possess a rapid stress signaling system based on Ca2+ waves that propagate through the plant at rates of up to ∼400 μm/s. In the case of local salt stress to the Arabidopsis thaliana root, Ca2+ wave propagation is channeled through the cortex and endodermal cell layers and this movement is dependent on the vacuolar ion channel TPC1. We also provide evidence that the Ca2+ wave/TPC1 system likely elicits systemic molecular responses in target organs and may contribute to whole-plant stress tolerance. These results suggest that, although plants do not have a nervous system, they do possess a sensory network that uses ion fluxes moving through defined cell types to rapidly transmit information between distant sites within the organism. [ABSTRACT FROM AUTHOR]

Published

2014

3. GRAVITROPISM AND MECHANICAL SIGNALING IN PLANTS.

Author

Toyota, Masatsugu and Gilroy, Simon

Subjects

*PHYSIOLOGICAL stress, *PLANT growth, *PLANT mechanics, *GRAVITY, *ARABIDOPSIS thaliana, *PLANT cellular signal transduction

Abstract

Mechanical stress is a critical signal affecting morphogenesis and growth and is caused by a large variety of environmental stimuli such as touch, wind, and gravity in addition to endogenous forces generated by growth. On the basis of studies dating from the early 19th century, the plant mechanical sensors and response components related to gravity can be divided into two types in terms of their temporal character: sensors of the transient stress of reorientation (phasic signaling) and sensors capable of monitoring and responding to the extended, continuous gravitropic signal for the duration of the tropic growth response (tonic signaling), In the case of transient stress, changes in the concentrations of ions in the cytoplasm play a central role in mechanosensing and are likely a key component of initial gravisensing. Potential candidates for mechanosensitive channels have been identified in Arabidopsis thaliana and may provide clues to these rapid, ionic gravisensing mechanisms. Continuous mechanical stress, on the other hand, may be sensed by other mechanisms in addition to the rapidly adapting mechnaosensitive channels of the phasic system. Sustaining such long-term responses may be through a network of biochemical signaling cascades that would therefore need to be maintained for the many hours of the growth response once they are triggered. However, classical physiological analyses and recent simulation studies also suggest involvement of the cytoskeleton in sensing/responding to long-term mechanoresponse independently of the biochemical signaling cascades triggered by initial graviperception events. [ABSTRACT FROM AUTHOR]

Published

2013

4. Arabidopsis LAZY1 Family Plays a Key Role in Gravity Signaling within Statocytes and in Branch Angle Control of Roots and Shoots.

Author

Taniguchi, Masatoshi, Furutani, Masahiko, Nishimura, Takeshi, Nakamura, Moritaka, Fushita, Toyohito, Iijima, Kohta, Baba, Kenichiro, Tanaka, Hirokazu, Toyota, Masatsugu, Tasaka, Masao, and Morita, Miyo Terao

Subjects

*DISTRIBUTION (Probability theory), *GRAVITY, *ARABIDOPSIS thaliana, *CELLULAR signal transduction, *GEOTROPISM

Abstract

During gravitropism, the directional signal of gravity is perceived by gravity-sensing cells called statocytes, leading to asymmetric distribution of auxin in the responding organs. To identify the genes involved in gravity signaling in statocytes, we performed transcriptome analyses of statocyte-deficient Arabidopsis thaliana mutants and found two candidates from the LAZY1 family, AtLAZY1 / LAZY1-LIKE1 (LZY1) and AtDRO3 / AtNGR1 / LZY2. We showed that LZY1 , LZY2 , and a paralog AtDRO1/AtNGR2/LZY3 are redundantly involved in gravitropism of the inflorescence stem, hypocotyl, and root. Mutations of LZY genes affected early processes in gravity signal transduction without affecting amyloplast sedimentation. Statocyte-specific expression of LZY genes rescued the mutant phenotype, suggesting that LZY genes mediate gravity signaling in statocytes downstream of amyloplast displacement, leading to the generation of asymmetric auxin distribution in gravity-responding organs. We also found that lzy mutations reversed the growth angle of lateral branches and roots. Moreover, expression of the conserved C-terminal region of LZY proteins also reversed the growth direction of primary roots in the lzy mutant background. In lateral root tips of lzy multiple mutants, asymmetric distribution of PIN3 and auxin response were reversed, suggesting that LZY genes regulate the direction of polar auxin transport in response to gravity through the control of asymmetric PIN3 expression in the root cap columella. [ABSTRACT FROM AUTHOR]

Published

2017