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Sakashita, Tetsuya; Suzuki, Michiyo; Hamada, Nobuyuki*; Shimozawa, Yoko; Fukamoto, Kana*; Yokota, Yuichiro; Sora, Sakura*; Kakizaki, Takehiko*; Wada, Seiichi*; Funayama, Tomoo; et al.
Biological Sciences in Space, 26, p.21 - 25, 2012/10
High linear energy transfer (LET) radiation is important cosmic rays that has neurobiological effects: it is known to induce conditioned taste aversion, and suppress neurogenesis that may underlie cognitive impairment. However, the impact of high-LET radiation on other learning effects remains largely unknown. Here, we focus on kinetics of the radiation response for the salt chemotaxis learning (SCL) behavior in the nameatode, , because the SCL during the learning conditioning was modulated after low-LET 
-irradiation. Firstly, the SCL ability was examined following high-LET irradiation (
C, 18.3 MeV/u, LET = 113 keV/
m), revealing its dose-dependent decrease after high- and low-LET exposure. Next, we demonstrate that the SCL at the early phase of the learning conditioning is greatly affected by high- and low-LET irradiation, and interestingly, the magnitude of these effects by high-LET radiation was smaller than that by low-LET one. Moreover, the analysis of 
mutant showed that the G-protein subunit, GPC-1 is responsible for such early phase response. This study is the first to provide the evidence for the kinetics of changes in SCL after high-LET irradiation of C. 
.
against high-LET radiation exposureSakashita, Tetsuya; Suzuki, Michiyo; Hamada, Nobuyuki*; Shimozawa, Yoko; Fukamoto, Kana*; Yokota, Yuichiro; Sora, Sakura*; Kakizaki, Takehiko*; Wada, Seiichi*; Funayama, Tomoo; et al.
Biological Sciences in Space, 26, p.7 - 11, 2012/07
Here, we investigated the resistance to high-LET radiation exposure for two behaviors of the nematode, , which is known as a model organism for the nervous system. Tested behaviors were locomotion and chemotaxis to NaCl. In addition, egg hatchability was examined as an indicator of high-LET radiation sensitivity. Relative biological effectiveness (RBE) of high-LET radiation (C, 18.3 MeV/u, LET = 113 keV/m) relative to low-LET radiation for hatchability was 4.5, whereas RBEs for locomotion and chemotaxis were 1.4 and 1.1, respectively. This study shows that the behavioral system for locomotion and chemotaxis of 
is highly resistant to high-LET radiation exposure.
against high-LET radiation exposureSakashita, Tetsuya; Suzuki, Michiyo; Hamada, Nobuyuki*; Shimozawa, Yoko; Fukamoto, Kana*; Yokota, Yuichiro; Sora, Sakura*; Kakizaki, Takehiko*; Wada, Seiichi*; Funayama, Tomoo; et al.
no journal, ,
Effects of high linear energy transfer (LET) radiation on the functions of the nervous system is a potential risk in interplanetary manned space missions. However, little is known about how the nervous system is protected against high-LET radiation exposure. Here, we investigated the resistance to high-LET radiation exposure for two behaviors of the nematode, , which is known as a model organism for the nervous system. Tested behaviors were locomotion and chemotaxis to NaCl. In addition, egg hatchability was examined as an indicator of high-LET radiation sensitivity. Relative biological effectiveness (RBE) of high-LET radiation relative to low-LET radiation for hatchability was 4.5, whereas RBEs for locomotion and chemotaxis were 1.4 and 1.1, respectively. This study shows that the behavioral system for locomotion and chemotaxis of C. elegans is highly resistant to high-LET radiation exposure.
