Abstract
BackgroundThe polyphyletic group of seagrasses shows an evolutionary history from early monocotyledonous land plants to the marine environment. Seagrasses form important coastal ecosystems worldwide and large amounts of seagrass detritus washed on beaches might also be valuable bioeconomical resources. Despite this importance and potential, little is known about adaptation of these angiosperms to the marine environment and their cell walls.ResultsWe investigated polysaccharide composition of nine seagrass species from the Mediterranean, Red Sea and eastern Indian Ocean. Sequential extraction revealed a similar seagrass cell wall polysaccharide composition to terrestrial angiosperms: arabinogalactans, pectins and different hemicelluloses, especially xylans and/or xyloglucans. However, the pectic fractions were characterized by the monosaccharide apiose, suggesting unusual apiogalacturonans are a common feature of seagrass cell walls. Detailed analyses of four representative species identified differences between organs and species in their constituent monosaccharide composition and lignin content and structure. Rhizomes were richer in glucosyl units compared to leaves and roots. Enhalus had high apiosyl and arabinosyl abundance, while two Australian species of Amphibolis and Posidonia, were characterized by high amounts of xylosyl residues. Interestingly, the latter two species contained appreciable amounts of lignin, especially in roots and rhizomes whereas Zostera and Enhalus were lignin-free. Lignin structure in Amphibolis was characterized by a higher syringyl content compared to that of Posidonia.ConclusionsOur investigations give a first comprehensive overview on cell wall composition across seagrass families, which will help understanding adaptation to a marine environment in the evolutionary context and evaluating the potential of seagrass in biorefinery incentives.
Highlights
The polyphyletic group of seagrasses shows an evolutionary history from early monocotyledonous land plants to the marine environment
Preliminary results with β-glucosyl-Yariv reagent, a specific dye for AGPs, supported the presence of AGPs in this fraction in all investigated seagrass species (Pfeifer and Classen, unpublished data)
Lignin in different seagrasses Our results highlight the sensitivity of the 13C labelled lignin internal standards (13C-IS) pyrolysis-GC–MS technique for evaluating lignin contents, and given this sensitivity our analyses show that E. acoroides contains a negligible amount of lignin
Summary
The polyphyletic group of seagrasses shows an evolutionary history from early monocotyledonous land plants to the marine environment. Seagrasses form important coastal ecosystems worldwide and large amounts of seagrass detritus washed on beaches might be valuable bioeconomical resources Despite this importance and potential, little is known about adaptation of these angiosperms to the marine environment and their cell walls. Seagrasses are an evolutionary unique, polyphyletic group of angiosperm plants, which evolved early in the evolution of monocotyledonous plants, and colonized the sea more than 100 million years ago [1] This adaptation to the marine environment was performed in three to four independent lineages [2], which gave rise. Seagrasses are the dominant primary producers in coastal waters They provide structural habitat and feeding grounds for diverse and abundant biological communities, including threatened organisms like dugongs, turtles and sea horses [9,10,11]. Seagrasses could, form an interesting alternative feedstock for utilization in a biobased economy, not competing for arable land, that could support production of biofuels and chemicals [12]
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