Oxygen dynamics in a salt-marsh soil and in Suaeda maritima during tidal submergence

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• 作者：Timothy D. Colmer^a ; ^{timothy.colmer@uwa.edu.au} ; Ole Pedersen^a ; ^b ; Anne M. Wetson^c ; Timothy J. Flowers^a ; ^c
• 关键词：Flooding ; Halophyte ; Tissue lactate ; Soil oxygen ; Underwater photosynthesis ; Wetland plant
• 刊名：Environmental and Experimental Botany
• 出版年：2013
• 出版时间：August, 2013
• 年：2013
• 卷：92
• 期：Complete
• 页码：73-82
• 全文大小：1958 K

文摘

Habitats occupied by many halophytes are not only saline, but are also prone to flooding and yet surprisingly few studies have evaluated submergence tolerance in halophytes. Sediment, floodwater, and intra-plant O₂ dynamics were evaluated during tidal submergence for the leaf-succulent halophyte Suaeda maritima (L.) Dum. For S. maritima growing in soil just above the mud flat in a UK salt marsh, the soil was only moderately hypoxic just prior to tidal inundation, presumably owing to drainage and O₂ entry facilitated by frequent, large cracks. O₂ declined to very low levels following high tide. By contrast, mud flat sediment remained waterlogged, lacked cracks, and was anoxic. Plant O₂ dynamics were investigated using field-collected plants in sediment blocks transported to a controlled-submergence system in a glasshouse. Submergence during night-time resulted in anoxia within leaves, whereas during day-time O₂ was produced by underwater photosynthesis. The thin lateral roots of S. maritima presumably access some O₂ from hypoxic sediments, but could also experience transient episodes of severe hypoxia/anoxia, especially as any internal O₂ movement from shoots would be small owing to the low gas-filled porosity in roots. Fermentative metabolism to lactate, producing some ATP in the absence of O₂, might contribute to tolerance of transient O₂ deficits. Lactate was high in root tissues, whereas ethanol production (tissue and incubation medium contents) was low, both in comparison with values reported for other species. Our findings demonstrate the importance of tolerance to transient waterlogging and submergence for the halophyte S. maritima growing in a tidal salt marsh.