Oxygen influx showed a gravity-regulated asymmetry in the transition zone (TZ) when root orientation varied from vertical to horizontal on ground. Nitric oxide was also monitored during ground gravistimulation, revealing a sudden burst in NO production only at root transition zone level. As NO is widely considered one of the first and most important signalling molecule in the stress-response pathway, this result focused on the role of this gaseous molecule in the graviperception. In order to confirm these results in real microgravity conditions, an experiment has been set up during an ESA parabolic flight campaign. Oxygen and nitric oxide concentration in the solution where roots of Zea mays were placed have been constantly monitored during normal, hyper- and microgravity conditions. An evident burst in oxygen and NO fluxes started just 2.0 ± 0.5 s after the imposition of microgravity conditions. No significant changes were noticed neither in normal nor in hypergravity conditions. Moreover, oxygen bursts were detected only in the apex zone The significance of these results on the nature of the graviperception will be discussed.
Electrical network activity in plant roots under gravity-changing conditions / E.Masi; S.Mugnai; E.Azzarello; M.Ciszak; C.Pandolfi; L.Renna; G.Stefano; B.Voigt; D.Volkmann; S.Mancuso. - ELETTRONICO. - (2008), pp. 1-1. (Intervento presentato al convegno Symposium “Life in Space for Life on Earth”. Angers (F), 22th-27th Ju tenutosi a Angers (Francia) nel 22-27 July).
Electrical network activity in plant roots under gravity-changing conditions.
MASI, ELISA;MUGNAI, SERGIO;AZZARELLO, ELISA;PANDOLFI, CAMILLA;G. Stefano;MANCUSO, STEFANO
2008
Abstract
Oxygen influx showed a gravity-regulated asymmetry in the transition zone (TZ) when root orientation varied from vertical to horizontal on ground. Nitric oxide was also monitored during ground gravistimulation, revealing a sudden burst in NO production only at root transition zone level. As NO is widely considered one of the first and most important signalling molecule in the stress-response pathway, this result focused on the role of this gaseous molecule in the graviperception. In order to confirm these results in real microgravity conditions, an experiment has been set up during an ESA parabolic flight campaign. Oxygen and nitric oxide concentration in the solution where roots of Zea mays were placed have been constantly monitored during normal, hyper- and microgravity conditions. An evident burst in oxygen and NO fluxes started just 2.0 ± 0.5 s after the imposition of microgravity conditions. No significant changes were noticed neither in normal nor in hypergravity conditions. Moreover, oxygen bursts were detected only in the apex zone The significance of these results on the nature of the graviperception will be discussed.
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