A meta-analysis of plant tissue O2 dynamics

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A meta-analysis of plant tissue O2 dynamics. / Herzog, Max; Pellegrini, Elisa; Pedersen, Ole.

I: Functional Plant Biology, Bind 50, Nr. 7, 2023.

Publikation: Bidrag til tidsskriftReviewForskningfagfællebedømt

Harvard

Herzog, M, Pellegrini, E & Pedersen, O 2023, 'A meta-analysis of plant tissue O2 dynamics', Functional Plant Biology, bind 50, nr. 7. https://doi.org/10.1071/FP22294

APA

Herzog, M., Pellegrini, E., & Pedersen, O. (2023). A meta-analysis of plant tissue O2 dynamics. Functional Plant Biology, 50(7). https://doi.org/10.1071/FP22294

Vancouver

Herzog M, Pellegrini E, Pedersen O. A meta-analysis of plant tissue O2 dynamics. Functional Plant Biology. 2023;50(7). https://doi.org/10.1071/FP22294

Author

Herzog, Max ; Pellegrini, Elisa ; Pedersen, Ole. / A meta-analysis of plant tissue O2 dynamics. I: Functional Plant Biology. 2023 ; Bind 50, Nr. 7.

Bibtex

@article{f6889fe0926e4ee79e0b5c88a71ebd5e,
title = "A meta-analysis of plant tissue O2 dynamics",
abstract = "Adequate tissue O2 supply is crucial for plant function. We aimed to identify the environmental conditions and plant characteristics that affect plant tissue O2 status. We extracted data and performed meta-analysis on >1500 published tissue O2 measurements from 112 species. Tissue O2 status ranged from anoxic conditions in roots to >53 kPa in submerged, photosynthesising shoots. Using information-theoretic model selection, we identified {\textquoteleft}submergence{\textquoteright}, {\textquoteleft}light{\textquoteright}, {\textquoteleft}tissue type{\textquoteright} as well as {\textquoteleft}light × submergence{\textquoteright} interaction as significant drivers of tissue O2 status. Median O2 status were especially low (<50% of atmospheric equilibrium) in belowground rhizomes, potato (Solanum tuberosum) tubers and root nodules. Mean shoot and root O2 were ~25% higher in light than in dark when shoots had atmospheric contact. However, light showed a significant interaction with submergence on plant O2, with a submergence-induced 44% increase in light, compared with a 42% decline in dark, relative to plants with atmospheric contact. During submergence, ambient water column O2 and shoot tissue O2 correlated stronger in darkness than in light conditions. Although use of miniaturised Clark-type O2 electrodes has enhanced understanding of plant O2 dynamics, application of non-invasive methods in plants is still lacking behind its widespread use in mammalian tissues.",
author = "Max Herzog and Elisa Pellegrini and Ole Pedersen",
year = "2023",
doi = "10.1071/FP22294",
language = "English",
volume = "50",
journal = "Australian Journal of Plant Physiology",
issn = "1445-4408",
publisher = "C S I R O Publishing",
number = "7",

}

RIS

TY - JOUR

T1 - A meta-analysis of plant tissue O2 dynamics

AU - Herzog, Max

AU - Pellegrini, Elisa

AU - Pedersen, Ole

PY - 2023

Y1 - 2023

N2 - Adequate tissue O2 supply is crucial for plant function. We aimed to identify the environmental conditions and plant characteristics that affect plant tissue O2 status. We extracted data and performed meta-analysis on >1500 published tissue O2 measurements from 112 species. Tissue O2 status ranged from anoxic conditions in roots to >53 kPa in submerged, photosynthesising shoots. Using information-theoretic model selection, we identified ‘submergence’, ‘light’, ‘tissue type’ as well as ‘light × submergence’ interaction as significant drivers of tissue O2 status. Median O2 status were especially low (<50% of atmospheric equilibrium) in belowground rhizomes, potato (Solanum tuberosum) tubers and root nodules. Mean shoot and root O2 were ~25% higher in light than in dark when shoots had atmospheric contact. However, light showed a significant interaction with submergence on plant O2, with a submergence-induced 44% increase in light, compared with a 42% decline in dark, relative to plants with atmospheric contact. During submergence, ambient water column O2 and shoot tissue O2 correlated stronger in darkness than in light conditions. Although use of miniaturised Clark-type O2 electrodes has enhanced understanding of plant O2 dynamics, application of non-invasive methods in plants is still lacking behind its widespread use in mammalian tissues.

AB - Adequate tissue O2 supply is crucial for plant function. We aimed to identify the environmental conditions and plant characteristics that affect plant tissue O2 status. We extracted data and performed meta-analysis on >1500 published tissue O2 measurements from 112 species. Tissue O2 status ranged from anoxic conditions in roots to >53 kPa in submerged, photosynthesising shoots. Using information-theoretic model selection, we identified ‘submergence’, ‘light’, ‘tissue type’ as well as ‘light × submergence’ interaction as significant drivers of tissue O2 status. Median O2 status were especially low (<50% of atmospheric equilibrium) in belowground rhizomes, potato (Solanum tuberosum) tubers and root nodules. Mean shoot and root O2 were ~25% higher in light than in dark when shoots had atmospheric contact. However, light showed a significant interaction with submergence on plant O2, with a submergence-induced 44% increase in light, compared with a 42% decline in dark, relative to plants with atmospheric contact. During submergence, ambient water column O2 and shoot tissue O2 correlated stronger in darkness than in light conditions. Although use of miniaturised Clark-type O2 electrodes has enhanced understanding of plant O2 dynamics, application of non-invasive methods in plants is still lacking behind its widespread use in mammalian tissues.

U2 - 10.1071/FP22294

DO - 10.1071/FP22294

M3 - Review

C2 - 37160400

VL - 50

JO - Australian Journal of Plant Physiology

JF - Australian Journal of Plant Physiology

SN - 1445-4408

IS - 7

ER -

ID: 346254104