Novel seed adaptations of a monocotyledon seagrass in the wavy sea

Returning to the sea, just like invasion of land, has occurred in many groups of animals and plants. For flowering plants, traits adapted to the terrestrial environments have to change or adopt a new function to allow the plants to survive and prosper in the sea where water motion tends to rotate an...

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Veröffentlicht in:	PloS one 2013-09, Vol.8 (9), p.e74143-e74143
Hauptverfasser:	Soong, Keryea, Chiu, Shau-Ting, Chen, Ching-Nen Nathan
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation Adaptation, Physiological Adaptations Botany Ecosystem biology Ecosystems Endangered & extinct species Experiments Flowering Fruit Germination Germination - radiation effects Granular materials Granules Grasses Hydrocharitaceae Hydrocharitaceae - physiology Hydrocharitaceae - radiation effects Iodine Light Light effects Marine biology Microscopy National parks Ocean floor Phenotype Physiology Plant sciences Posture Sand Seawater Sediments Seed germination Seedlings - radiation effects Seeds Seeds - physiology Seeds - radiation effects Starch Terrestrial ecosystems Terrestrial environments Thalassia hemprichii Water Movements
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description	Returning to the sea, just like invasion of land, has occurred in many groups of animals and plants. For flowering plants, traits adapted to the terrestrial environments have to change or adopt a new function to allow the plants to survive and prosper in the sea where water motion tends to rotate and move seeds. In this investigation, how seeds of the seagrass Thalassia hemprichii (Hydrocharitaceae), a common monocotyledon in the Indo-Pacific, adapt to the wavy environment was studied. Mature seeds were collected from Dongsha Atoll in South China Sea. The effects of light qualities on seed germination, the seed morphology, the unipolar distribution of starch granules in the endosperms and growth of root hair-like filamentous cells from basal surface of the seeds were all found to differ from those of terrestrial monocotyledons. Physiologically, germination of the seeds was stimulated by blue light rather than red light. Morphologically, the bell-shaped seeds coupled with the unipolar distribution of starch granules in the enlarged bases helped maintain their upright posture on the tidal seafloor. Growth of root hair-like filamentous cells from the basal surface of the seeds prior to primary root growth served to attach onto sediments, providing leverage and attachment required by the primary roots to insert into sediments. These filamentous cells grasped coral sand but not silicate sand, demonstrating a habitat preference of this species.
doi_str_mv	10.1371/journal.pone.0074143
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subjects	Adaptation Adaptation, Physiological Adaptations Botany Ecosystem biology Ecosystems Endangered & extinct species Experiments Flowering Fruit Germination Germination - radiation effects Granular materials Granules Grasses Hydrocharitaceae Hydrocharitaceae - physiology Hydrocharitaceae - radiation effects Iodine Light Light effects Marine biology Microscopy National parks Ocean floor Phenotype Physiology Plant sciences Posture Sand Seawater Sediments Seed germination Seedlings - radiation effects Seeds Seeds - physiology Seeds - radiation effects Starch Terrestrial ecosystems Terrestrial environments Thalassia hemprichii Water Movements
title	Novel seed adaptations of a monocotyledon seagrass in the wavy sea
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