Mechanosensitive channels are activated by stress in the actin stress fibres, and could be involved in gravity sensing in plants

Mechanosensitive (MS) channels are expressed in a variety of cells. The molecular and biophysical mechanism involved in the regulation of MS channel activities is a central interest in basic biology. MS channels are thought to play crucial roles in gravity sensing in plant cells. To date, two mechan...

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Published in:	Plant biology (Stuttgart, Germany) Vol. 16; no. s1; pp. 18 - 22
Main Authors:	Tatsumi, H., Furuichi, T., Nakano, M., Toyota, M., Hayakawa, K., Sokabe, M., Iida, H.
Format:	Journal Article
Language:	English
Published:	England Blackwell Publishing Ltd 01-01-2014
Subjects:	Actin filament Actins - metabolism calcium gravistimulation Gravity Sensing Ion Channels - metabolism MCA1 MCA2 mechanosensitive channel Mechanotransduction, Cellular optical tweezers Plants - metabolism single 'molecule' imaging starch-statolith hypothesis Stress Fibers - metabolism Stress, Physiological Actin filament MCA1 MCA2 calcium gravistimulation optical tweezers single ‘molecule’ imaging mechanosensitive channel starch-statolith hypothesis
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Summary:	Mechanosensitive (MS) channels are expressed in a variety of cells. The molecular and biophysical mechanism involved in the regulation of MS channel activities is a central interest in basic biology. MS channels are thought to play crucial roles in gravity sensing in plant cells. To date, two mechanisms have been proposed for MS channel activation. One is that tension development in the lipid bilayer directly activates MS channels. The second mechanism proposes that the cytoskeleton is involved in the channel activation, because MS channel activities are modulated by pharmacological treatments that affect the cytoskeleton. We tested whether tension in the cytoskeleton activates MS channels. Mammalian endothelial cells were microinjected with phalloidin‐conjugated beads, which bound to stress fibres, and a traction force to the actin cytoskeleton was applied by dragging the beads with optical tweezers. MS channels were activated when the force was applied, demonstrating that a sub‐pN force to the actin filaments activates a single MS channel. Plants may use a similar molecular mechanism in gravity sensing, since the cytoplasmic Ca2+ concentration increase induced by changes in the gravity vector was attenuated by potential MS channel inhibitors, and by actin‐disrupting drugs. These results support the idea that the tension increase in actin filaments by gravity‐dependent sedimentation of amyloplasts activates MS Ca2+‐permeable channels, which can be the molecular mechanism of a Ca2+ concentration increase through gravistimulation. We review recent progress in the study of tension sensing by actin filaments and MS channels using advanced biophysical methods, and discuss their possible roles in gravisensing.
Bibliography:	TOYOBO Biotechnology Foundation Grants-in-Aid for Scientific Research - No. 20171720; No. 20171720; No. 21026009; No. 23120509 The Ministry of Education, Culture, Sports, Science, and Technology of Japan and a grant from the Japan istex:57E218F16B4A07B9728FEA5020BD29D919F50BA2 Grant-in-Aid for JSPS Fellows ark:/67375/WNG-GJJPCM73-2 ArticleID:PLB12095 Grant-in-Aid for JSPS Fellows for Research Abroad ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-3 content type line 23 ObjectType-Review-1
ISSN:	1435-8603 1438-8677
DOI:	10.1111/plb.12095