MOESM1 of The combination of gas-phase fluorophore technology and automation to enable high-throughput analysis of plant respiration

Scafaro, Andrew; Negrini, A.; O’Leary, Brendan; Rashid, F.; Hayes, Lucy; Fan, Yuzhen; Zhang, You; Chochois, Vincent; Badger, Murray; Millar, A.; Atkin, Owen

doi:10.6084/m9.figshare.c.3723052_D1.v1

13007_2017_169_MOESM1_ESM.pdf (2.79 MB)

MOESM1 of The combination of gas-phase fluorophore technology and automation to enable high-throughput analysis of plant respiration

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posted on 2017-03-21, 05:00 authored by Andrew Scafaro, A. Negrini, Brendan O’Leary, F. Rashid, Lucy Hayes, Yuzhen Fan, You Zhang, Vincent Chochois, Murray Badger, A. Millar, Owen Atkin

Additional file 1: Table S1. Technical reproducibility of the fluorophore instrument in measuring the chemical oxidation of cysteine. Figure S1. The measured and expected depletion of O2 though replacement of air with known volumes of pure CO2 gas. Figure S2. A representative 46-day-old wheat plant harvested for whole-plant respiration analysis. Figure S3. Derived respiration rates in the dark (Rdark) calculated from measurements between 5 and 20 min from experiment initiation using the various techniques.

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Centre of Excellence in Plant Energy Biology, Australian Research Council

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Dark respiration Fluorophore Gas-exchange High-throughput Oxygen consumption Oxygen electrodes Respiration Respiratory flux Respiratory quotient

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MOESM1 of The combination of gas-phase fluorophore technology and automation to enable high-throughput analysis of plant respiration

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Centre of Excellence in Plant Energy Biology, Australian Research Council

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