Search results for "Terrestrial plant"

showing 4 items of 4 documents

Terrestrial plants and marine algae from the Late Jurassic lithographic limestone of the Causse Méjean (Lozère, southern France)

2016

International audience; A new Late Jurassic flora was discovered in the fossiliferous lithographic limestone of the Causse Méjean, Lozère (southern France). It consists of the first Kimmeridgian/Tithonian plants from this area. Fossil plants are represented by megaremains preserved as impressions. This flora shows a co-occurrence of terrestrial plants and marine algae. The land plants include vegetative remains ascribed to bennettitaleans (Zamites Brongniart, 1828), conifers (Brachyphyllum Brongniart, 1828), and pteridosperms (Cycadopteris Zigno, 1853). Marine algae were ascribed to dasyclads (Goniolina D’Orbigny, 1850). Lithological and palaeontological features suggest preservation in a f…

010506 paleontologyFloraved/biology.organism_classification_rank.speciesLate JurassicContext (language use)010502 geochemistry & geophysics01 natural sciencesBennettitaleansBrachyphyllumPaleontologyAlgaeTerrestrial plant14. Life underwaterPteridospermsDasycladales0105 earth and related environmental sciencesZamites[ SDU.STU.PG ] Sciences of the Universe [physics]/Earth Sciences/Paleontologybiologyved/biologyEcologyDasycladslcsh:QE1-996.5PtéridospermesGeologyVegetation15. Life on landbiology.organism_classificationConifèreslcsh:GeologyConifersHabitatJurassique terminalBennettitalesBassin des Causses.[SDU.STU.PG]Sciences of the Universe [physics]/Earth Sciences/PaleontologyCausses basin.GeologyCausses basin
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Ocean Acidification and the Loss of Phenolic Substances in Marine Plants

2012

Rising atmospheric CO(2) often triggers the production of plant phenolics, including many that serve as herbivore deterrents, digestion reducers, antimicrobials, or ultraviolet sunscreens. Such responses are predicted by popular models of plant defense, especially resource availability models which link carbon availability to phenolic biosynthesis. CO(2) availability is also increasing in the oceans, where anthropogenic emissions cause ocean acidification, decreasing seawater pH and shifting the carbonate system towards further CO(2) enrichment. Such conditions tend to increase seagrass productivity but may also increase rates of grazing on these marine plants. Here we show that high CO(2) …

0106 biological sciencesCymodocea nodosaved/biology.organism_classification_rank.speciesCarbonatesSecondary MetabolismMarine and Aquatic Scienceslcsh:MedicinePlant Science01 natural scienceschemistry.chemical_compoundGlobal Change Ecologylcsh:SciencePhysiological EcologyMultidisciplinaryAlismatalesbiologyEcologyEcologyPlant BiochemistryMarine EcologyOcean acidificationPotamogetonaceaeHydrogen-Ion ConcentrationSeagrassProductivity (ecology)ItalyCarbon dioxideCoastal EcologyResearch ArticleOceans and SeasMarine Biology010603 evolutionary biologyStatistics NonparametricHydrothermal VentsPhenolsPlant-Environment InteractionsTerrestrial plantSeawater14. Life underwaterocean acidification climate change mediterranean sea seagrassBiologyAnalysis of VarianceChemical EcologyMarylandved/biology010604 marine biology & hydrobiologyPlant Ecologyfungilcsh:R15. Life on landCarbon Dioxidebiology.organism_classificationSalinitychemistry13. Climate actionEarth Scienceslcsh:QRuppia maritima
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Medicinal and Aromatic Plant Research in the 21st Century

2012

It has been estimated that 250,000 terrestrial plants contribute to biodiversity on earth. The chemodiversity of plants, however, may be considered to be much larger due to the vast number of phytochemical constituents with their wide range of bioactivity as seen in medicinal and aromatic plants. The present review focuses on the potential of medicinal and aromatic plants for medicinal, nutritional and other purposes, but highlights also possible toxicities. Quality control for standardization of herbal products as well as advancements in molecular biological techniques will foster the progress of medicinal and aromatic plant research in the years to come.

Phytochemicalbusiness.industryved/biologyfungiTerrestrial plantved/biology.organism_classification_rank.speciesAromatic plantsBiodiversityfood and beveragesMedicinePharmacologybusinessBiotechnologyMedicinal & Aromatic Plants
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Inferring Phytoplankton, Terrestrial Plant and Bacteria Bulk δ¹³C Values from Compound Specific Analyses of Lipids and Fatty Acids.

2015

Stable isotope mixing models in aquatic ecology require δ13C values for food web end members such as phytoplankton and bacteria, however it is rarely possible to measure these directly. Hence there is a critical need for improved methods for estimating the δ13C ratios of phytoplankton, bacteria and terrestrial detritus from within mixed seston. We determined the δ13C values of lipids, phospholipids and biomarker fatty acids and used these to calculate isotopic differences compared to the whole-cell δ13C values for eight phytoplankton classes, five bacterial taxa, and three types of terrestrial organic matter (two trees and one grass). The lipid content was higher amongst the phytoplankton (…

ved/biology.organism_classification_rank.speciesta1172lcsh:MedicineAlgaeaquatic ecologyterrestrial plantsPhytoplanktonTerrestrial plantBotanyMetabolomics14. Life underwaterBiomasslcsh:Sciencevesiekologia2. Zero hungerBiomass (ecology)Carbon IsotopesMultidisciplinaryDetritusbiologyδ13CBacteriaved/biologyStable isotope ratioSestonFatty Acidsfungilcsh:R15. Life on landbiology.organism_classificationLipidsbacteria bulk13. Climate actionEnvironmental chemistryPhytoplanktonphytoplanktonta1181lcsh:QBiomarkersResearch ArticlePLoS ONE
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