Access the full text.
Sign up today, get DeepDyve free for 14 days.
O. Pedersen, S. Rich, T. Colmer (2009)
Surviving floods: leaf gas films improve O₂ and CO₂ exchange, root aeration, and growth of completely submerged rice.The Plant journal : for cell and molecular biology, 58 1
A. Winkel, T. Colmer, A. Ismail, O. Pedersen (2013)
Internal aeration of paddy field rice (Oryza sativa) during complete submergence---importance of light and floodwater O2.The New phytologist, 197 4
T. Madsen, K. Sand‐Jensen, S. Beer (1993)
Comparison of photosynthetic performance and carboxylation capacity in a range of aquatic macrophytes of different growth formsAquatic Botany, 44
T. Setter, I. Waters, I. Wallace, P. Bhekasut, H. Greenway (1989)
Submergence of Rice. I. Growth and Photosynthetic Response to CO2 Enrichment of FloodwaterAustralian Journal of Plant Physiology, 16
Dennis Konnerup, A. Winkel, M. Herzog, O. Pedersen (2017)
Leaf gas film retention during submergence of 14 cultivars of wheat (Triticum aestivum).Functional plant biology : FPB, 44 9
T. Colmer (2003)
Aerenchyma and an inducible barrier to radial oxygen loss facilitate root aeration in upland, paddy and deep-water rice (Oryza sativa L.).Annals of botany, 91 Spec No
I. Waters, W. Armstrong, C. Thompson, T. Setter, S. Adkins, J. Gibbs, H. Greenway (1989)
Diurnal changes in radial oxygen loss and ethanol metabolism in roots of submerged and non‐submerged rice seedlingsNew Phytologist, 113
A. Jassby, T. Platt (1976)
Mathematical formulation of the relationship between photosynthesis and light for phytoplanktonLimnology and Oceanography, 21
T. Colmer, O. Pedersen (2008)
Underwater photosynthesis and respiration in leaves of submerged wetland plants: gas films improve CO2 and O2 exchange.The New phytologist, 177 4
P. Verboven, O. Pedersen, Q. Ho, B. Nicolai, T. Colmer (2014)
The mechanism of improved aeration due to gas films on leaves of submerged rice.Plant, cell & environment, 37 10
C. Neinhuis, W. Barthlott (1997)
Characterization and Distribution of Water-repellent, Self-cleaning Plant SurfacesAnnals of Botany, 79
P. Vervuren, C. Blom, H. Kroon (2003)
Extreme flooding events on the Rhine and the survival and distribution of riparian plant speciesJournal of Ecology, 91
T. Colmer, Anders Winkel, Ole Pedersen (2011)
A perspective on underwater photosynthesis in submerged terrestrial wetland plantsAoB Plants, 2011
O. Pedersen, T. Colmer (2012)
Physical gills prevent drowning of many wetland insects, spiders and plantsJournal of Experimental Biology, 215
Ilya Raskin, H. Kende (1983)
How does deep water rice solve its aeration problem.Plant physiology, 72 2
G. Striker (2012)
Time is on our side: the importance of considering a recovery period when assessing flooding tolerance in plantsEcological Research, 27
A. Winkel, O. Pedersen, E. Ella, A. Ismail, T. Colmer (2014)
Gas film retention and underwater photosynthesis during field submergence of four contrasting rice genotypesJournal of Experimental Botany, 65
W. Armstrong (1980)
Aeration in Higher PlantsAdvances in Botanical Research, 7
I. Raskin (1983)
A Method for Measuring Leaf Volume, Density, Thickness, and Internal Gas VolumeHortScience
Sudhanshu Singh, D. Mackill, A. Ismail (2009)
Responses of SUB1 rice introgression lines to submergence in the field: yield and grain qualityField Crops Research, 113
A. Winkel, T. Colmer, O. Pedersen (2011)
Leaf gas films of Spartina anglica enhance rhizome and root oxygen during tidal submergence.Plant, cell & environment, 34 12
J. Wintermans, A. Mots (1965)
Spectrophotometric characteristics of chlorophylls a and b and their phenophytins in ethanolBiochimica et Biophysica Acta, 109
T. Colmer, H. Vos, H. Vos, Ole Pedersen, Ole Pedersen (2009)
Tolerance of combined submergence and salinity in the halophytic stem-succulent Tecticornia pergranulata.Annals of botany, 103 2
J. Bailey-Serres, S. Lee, Erin Brinton (2012)
Waterproofing Crops: Effective Flooding Survival Strategies1Plant Physiology, 160
O. Pedersen, A. Malik, T. Colmer (2010)
Submergence tolerance in Hordeum marinum: dissolved CO2 determines underwater photosynthesis and growthFunctional Plant Biology, 37
H. Frost-Christensen, K. Sand‐Jensen (1992)
The quantum efficiency of photosynthesis in macroalgae and submerged angiospermsOecologia, 91
S. Justin, W. Armstrong (1987)
THE ANATOMICAL CHARACTERISTICS OF ROOTS AND PLANT RESPONSE TO SOIL FLOODINGNew Phytologist, 106
M. Herzog, Dennis Konnerup, O. Pedersen, A. Winkel, T. Colmer (2018)
Leaf gas films contribute to rice (Oryza sativa) submergence tolerance during saline floods.Plant, cell & environment, 41 5
A. Winkel, E. Visser, T. Colmer, K. Brodersen, L. Voesenek, K. Sand‐Jensen, O. Pedersen (2016)
Leaf gas films, underwater photosynthesis and plant species distributions in a flood gradient.Plant, cell & environment, 39 7
Zhe Zhang, Z. Cheng, Lu Gan, Huan Zhang, Fu-qing Wu, Qiuyun Lin, Jiulin Wang, Jie Wang, Xiuping Guo, Xin Zhang, Zhichao Zhao, C. Lei, Shanshan Zhu, Chunming Wang, J. Wan (2016)
OsHSD1, a hydroxysteroid dehydrogenase, is involved in cuticle formation and lipid homeostasis in rice.Plant science : an international journal of experimental plant biology, 249
A. Malik, T. Colmer, H. Lambers, M. Schortemeyer (2003)
Aerenchyma formation and radial O2 loss along adventitious roots of wheat with only the apical root portion exposed to O2 deficiencyPlant Cell and Environment, 26
M. Herzog, G. Striker, T. Colmer, O. Pedersen (2016)
Mechanisms of waterlogging tolerance in wheat--a review of root and shoot physiology.Plant, cell & environment, 39 5
S. Maberly, T. Madsen (2002)
Freshwater angiosperm carbon concentrating mechanisms: processes and patterns.Functional plant biology : FPB, 29 3
W. Barthlott, C. Neinhuis (1997)
Purity of the sacred lotus, or escape from contamination in biological surfacesPlanta, 202
T. Madsen, K. Sand‐Jensen (1991)
Photosynthetic carbon assimilation in aquatic macrophytesAquatic Botany, 41
Submergence invokes a range of stressors to plants with impeded gas exchange between tissues and floodwater being the greatest challenge. Many terrestrial plants including wheat (Triticum aestivum L.), possess superhydrophobic leaf cuticles that retain a thin gas film when submerged, and the gas films enhance gas exchange with the floodwater. However, leaf hydrophobicity is lost during submergence and the gas films disappear accordingly. Here, we completely submerged wheat (with or without gas films) for up to 14 days and found that plants with gas films survived significantly longer (13 days) than plants without (10 days). Plants with gas films also had less dead tissue following a period of recovery. However, this study also revealed that reflections by gas films resulted in a higher light compensation point for underwater net photosynthesis for leaves with gas films compared with leaves without (IC=52 vs 35mol photons m2 s1 with or without gas films, respectively). Still, already at ~5% of full sunlight the beneficial effect of gas films overcame the negative under ecologically relevant CO2 concentrations. Our study showed that dryland crops also benefit from leaf gas films during submergence and that this trait should be incorporated to improve flood tolerance of wheat.
Functional Plant Biology – CSIRO Publishing
Published: Apr 26, 2017
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.