FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2018286192> ?p ?o ?g. }

• W2018286192 endingPage "60" @default.
• W2018286192 startingPage "49" @default.
• W2018286192 abstract "Growth and pigment composition of plants can be affected by both UV-radiation and availability of nutrients. Therefore, the UV-induction in a plant as a protective response against UV-B radiation may depend on the UV-B dose encountered and the nutritional state of a plant. To test this, young Scots pine (Pinus sylvestris) seedlings were grown under two nutrient levels (relative nutrient addition fates, RAR, of 4 and 6%) and exposed to six different daily doses of UV-radiation (UV-A and UV-B) for one growing season. Both the growth and the accumulation of photosynthetic pigments were positively affected by the availability of nutrients, while the accumulation of condensed tannins and its precursor, (+)-catechin decreased significantly under higher nutrient level, which may imply some trade-off between primary and secondary metabolites. However, nutrient level did not markedly affect the total accumulation of flavonols. Since there was no decrease in the growth of the seedlings and the content of photosynthetic pigments in needles under increased UV-B levels, the seedlings had apparently good protection against UV-B radiation. Protection was probably dependent on the UV-induction of flavonoid compounds in needles, which differed between the two nutrient levels used. Under moderate nutrient availability (RAR 4%), the accumulation of flavonols and also, chlorophylls was highest at the ambient or near to ambient levels of UV-radiation, the levels that pines are generally adapted in natural conditions. As the availability of nutrients and thereby, the resources in seedlings increased (RAR 6%), the UV-B levels higher than ambient increased specifically the accumulation of diacylated flavonols when dose responses were detected. Furthermore, the enhancement of UV-A radiation caused an accumulation of the dihydroflavonols, ampelopsin and taxifolin, under high nutrient availability. Since the flavonoid responses were very compound-specific, and in some cases were also dose-dependent and different between the two nutrient levels used, it can be suggested that the induction of secondary compounds in the flavonoid pathway is multi-step regulated by both environmental factors, UV-radiation and nutrients. Already the present variation in the ambient range of UV-B radiation at northern latitudes can influence the chemical composition of Scots pine seedlings and enhancement in nutrients may increase their responsiveness, particularly to high UV-intensities." @default.
• W2018286192 created "2016-06-24" @default.
• W2018286192 creator A5007837515 @default.
• W2018286192 creator A5021694553 @default.
• W2018286192 creator A5030575412 @default.
• W2018286192 creator A5077155710 @default.
• W2018286192 date "2003-02-01" @default.
• W2018286192 modified "2023-10-18" @default.
• W2018286192 title "Nutrient availability and the effect of increasing UV-B radiation on secondary plant compounds in Scots pine" @default.
• W2018286192 cites W1516328156 @default.
• W2018286192 cites W1572201689 @default.
• W2018286192 cites W169274260 @default.
• W2018286192 cites W1974802538 @default.
• W2018286192 cites W1976802041 @default.
• W2018286192 cites W1983998190 @default.
• W2018286192 cites W1986559700 @default.
• W2018286192 cites W1997076938 @default.
• W2018286192 cites W1999693007 @default.
• W2018286192 cites W2000379229 @default.
• W2018286192 cites W2009240405 @default.
• W2018286192 cites W2012013408 @default.
• W2018286192 cites W2018026012 @default.
• W2018286192 cites W2024461373 @default.
• W2018286192 cites W2040028890 @default.
• W2018286192 cites W2042859063 @default.
• W2018286192 cites W2043223880 @default.
• W2018286192 cites W2060545758 @default.
• W2018286192 cites W2071363727 @default.
• W2018286192 cites W2073317899 @default.
• W2018286192 cites W2078376793 @default.
• W2018286192 cites W2078520433 @default.
• W2018286192 cites W2079754556 @default.
• W2018286192 cites W2091707842 @default.
• W2018286192 cites W2094294200 @default.
• W2018286192 cites W2098724716 @default.
• W2018286192 cites W2125473485 @default.
• W2018286192 cites W2140916480 @default.
• W2018286192 cites W2142487579 @default.
• W2018286192 cites W2149038273 @default.
• W2018286192 cites W2152975634 @default.
• W2018286192 cites W2162824040 @default.
• W2018286192 cites W2324144844 @default.
• W2018286192 cites W2333174397 @default.
• W2018286192 cites W4229880569 @default.
• W2018286192 cites W4247831672 @default.
• W2018286192 cites W4249808379 @default.
• W2018286192 doi "https://doi.org/10.1016/s0098-8472(02)00057-6" @default.
• W2018286192 hasPublicationYear "2003" @default.
• W2018286192 type Work @default.
• W2018286192 sameAs 2018286192 @default.
• W2018286192 citedByCount "104" @default.
• W2018286192 countsByYear W20182861922012 @default.
• W2018286192 countsByYear W20182861922013 @default.
• W2018286192 countsByYear W20182861922014 @default.
• W2018286192 countsByYear W20182861922015 @default.
• W2018286192 countsByYear W20182861922016 @default.
• W2018286192 countsByYear W20182861922017 @default.
• W2018286192 countsByYear W20182861922018 @default.
• W2018286192 countsByYear W20182861922019 @default.
• W2018286192 countsByYear W20182861922020 @default.
• W2018286192 countsByYear W20182861922021 @default.
• W2018286192 countsByYear W20182861922022 @default.
• W2018286192 countsByYear W20182861922023 @default.
• W2018286192 crossrefType "journal-article" @default.
• W2018286192 hasAuthorship W2018286192A5007837515 @default.
• W2018286192 hasAuthorship W2018286192A5021694553 @default.
• W2018286192 hasAuthorship W2018286192A5030575412 @default.
• W2018286192 hasAuthorship W2018286192A5077155710 @default.
• W2018286192 hasConcept C137660486 @default.
• W2018286192 hasConcept C142796444 @default.
• W2018286192 hasConcept C144027150 @default.
• W2018286192 hasConcept C178790620 @default.
• W2018286192 hasConcept C183688256 @default.
• W2018286192 hasConcept C185592680 @default.
• W2018286192 hasConcept C18903297 @default.
• W2018286192 hasConcept C2778004101 @default.
• W2018286192 hasConcept C2779054382 @default.
• W2018286192 hasConcept C2779106036 @default.
• W2018286192 hasConcept C2779128174 @default.
• W2018286192 hasConcept C2780505102 @default.
• W2018286192 hasConcept C2910048773 @default.
• W2018286192 hasConcept C55493867 @default.
• W2018286192 hasConcept C59822182 @default.
• W2018286192 hasConcept C64584667 @default.
• W2018286192 hasConcept C86803240 @default.
• W2018286192 hasConceptScore W2018286192C137660486 @default.
• W2018286192 hasConceptScore W2018286192C142796444 @default.
• W2018286192 hasConceptScore W2018286192C144027150 @default.
• W2018286192 hasConceptScore W2018286192C178790620 @default.
• W2018286192 hasConceptScore W2018286192C183688256 @default.
• W2018286192 hasConceptScore W2018286192C185592680 @default.
• W2018286192 hasConceptScore W2018286192C18903297 @default.
• W2018286192 hasConceptScore W2018286192C2778004101 @default.
• W2018286192 hasConceptScore W2018286192C2779054382 @default.
• W2018286192 hasConceptScore W2018286192C2779106036 @default.
• W2018286192 hasConceptScore W2018286192C2779128174 @default.
• W2018286192 hasConceptScore W2018286192C2780505102 @default.
• W2018286192 hasConceptScore W2018286192C2910048773 @default.

• next