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Oxidative stress and NO signalling in the root apex as an early response to changes in gravity conditions.

Mugnai S, Pandolfi C, Masi E, Azzarello E, Monetti E, Comparini D, Voigt B, Volkmann D, Mancuso S - Biomed Res Int (2014)

Bottom Line: The same results were obtained by ROS measurement.The detrimental effect of D'orenone, disrupting the polarised auxin transport, on the onset of the oxygen peaks during the microgravity period was also evaluated.Results indicates an active role of NO and ROS as messengers during the gravitropic response, with probable implications in the auxin redistribution.

View Article: PubMed Central - PubMed

Affiliation: DISPAA, University of Florence, Viale delle Idee 30, 50019 Sesto Fiorentino, Italy ; HSO-USB, ESTEC, European Space Agency, Keplerlaan 1, 2200 AG Noordwijk, The Netherlands.

ABSTRACT
Oxygen influx showed an asymmetry in the transition zone of the root apex when roots were placed horizontally on ground. The influx increased only in the upper side, while no changes were detected in the division and in the elongation zone. Nitric oxide (NO) was also monitored after gravistimulation, revealing a sudden burst only in the transition zone. In order to confirm these results in real microgravity conditions, experiments have been set up by using parabolic flights and drop tower. The production of reactive oxygen species (ROS) was also monitored. Oxygen, NO, and ROS were continuously monitored during normal and hyper- and microgravity conditions in roots of maize seedlings. A distinct signal in oxygen and NO fluxes was clearly detected only in the apex zone during microgravity, with no significant changes in normal and in hypergravity conditions. The same results were obtained by ROS measurement. The detrimental effect of D'orenone, disrupting the polarised auxin transport, on the onset of the oxygen peaks during the microgravity period was also evaluated. Results indicates an active role of NO and ROS as messengers during the gravitropic response, with probable implications in the auxin redistribution.

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Typical nitric oxide curve measured in the oximeter chamber during a drop in the ESA Drop Tower campaign.
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fig12: Typical nitric oxide curve measured in the oximeter chamber during a drop in the ESA Drop Tower campaign.

Mentions: Finally, the production of NO was detected and evaluated during an ESA Drop Tower campaign (Figure 12). Interestingly, a burst of NO was clearly evident after 2 seconds from the start of the microgravity period, which then started to decline, resembling the behaviour of the gravistimulated roots on ground. Oximeter chambers without roots showed no bursts or signal detected by the microelectrode (data not shown).


Oxidative stress and NO signalling in the root apex as an early response to changes in gravity conditions.

Mugnai S, Pandolfi C, Masi E, Azzarello E, Monetti E, Comparini D, Voigt B, Volkmann D, Mancuso S - Biomed Res Int (2014)

Typical nitric oxide curve measured in the oximeter chamber during a drop in the ESA Drop Tower campaign.
© Copyright Policy
Related In: Results  -  Collection

License
Show All Figures
getmorefigures.php?uid=PMC4150467&req=5

fig12: Typical nitric oxide curve measured in the oximeter chamber during a drop in the ESA Drop Tower campaign.
Mentions: Finally, the production of NO was detected and evaluated during an ESA Drop Tower campaign (Figure 12). Interestingly, a burst of NO was clearly evident after 2 seconds from the start of the microgravity period, which then started to decline, resembling the behaviour of the gravistimulated roots on ground. Oximeter chambers without roots showed no bursts or signal detected by the microelectrode (data not shown).

Bottom Line: The same results were obtained by ROS measurement.The detrimental effect of D'orenone, disrupting the polarised auxin transport, on the onset of the oxygen peaks during the microgravity period was also evaluated.Results indicates an active role of NO and ROS as messengers during the gravitropic response, with probable implications in the auxin redistribution.

View Article: PubMed Central - PubMed

Affiliation: DISPAA, University of Florence, Viale delle Idee 30, 50019 Sesto Fiorentino, Italy ; HSO-USB, ESTEC, European Space Agency, Keplerlaan 1, 2200 AG Noordwijk, The Netherlands.

ABSTRACT
Oxygen influx showed an asymmetry in the transition zone of the root apex when roots were placed horizontally on ground. The influx increased only in the upper side, while no changes were detected in the division and in the elongation zone. Nitric oxide (NO) was also monitored after gravistimulation, revealing a sudden burst only in the transition zone. In order to confirm these results in real microgravity conditions, experiments have been set up by using parabolic flights and drop tower. The production of reactive oxygen species (ROS) was also monitored. Oxygen, NO, and ROS were continuously monitored during normal and hyper- and microgravity conditions in roots of maize seedlings. A distinct signal in oxygen and NO fluxes was clearly detected only in the apex zone during microgravity, with no significant changes in normal and in hypergravity conditions. The same results were obtained by ROS measurement. The detrimental effect of D'orenone, disrupting the polarised auxin transport, on the onset of the oxygen peaks during the microgravity period was also evaluated. Results indicates an active role of NO and ROS as messengers during the gravitropic response, with probable implications in the auxin redistribution.

Show MeSH
Related in: MedlinePlus