Species-specific response of glucosinolate content to elevated atmospheric CO2

The carbon/nutrient balance hypothesis has recently been interpreted to predict that plants grown under elevated CO2 environments will allocate excess carbon to defense, resulting in an increase in carbon-based secondary compounds. A related prediction is that, because plant growth will be increasin...

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Published in:Journal of chemical ecology 1997-11, Vol.23 (11), p.2569-2582
Main Authors: Karowe, D.N. (Western Michigan University, Kalamazoo, MI.), Seimens, D.H, Mitchell-Olds, T
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Autoecology
Biological and medical sciences
BRASSICA CAMPESTRIS
BRASSICA NAPUS
CARBON
CARBON DIOXIDE
CHEMICAL COMPOSITION
DEFENSE
Ecological effects
Flowers & plants
Fundamental and applied biological sciences. Psychology
GLUCOSINOLATES
LEAVES
NITROGEN
NUTRIENT BALANCE
Nutrient content
NUTRITION PHYSIOLOGY
PLANT DEFENSE
Plant growth
Plants and fungi
RAPHANUS SATIVUS
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container_issue 11
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creator Karowe, D.N. (Western Michigan University, Kalamazoo, MI.)
Seimens, D.H
Mitchell-Olds, T
description The carbon/nutrient balance hypothesis has recently been interpreted to predict that plants grown under elevated CO2 environments will allocate excess carbon to defense, resulting in an increase in carbon-based secondary compounds. A related prediction is that, because plant growth will be increasingly nitrogen-limited under elevated CO2 environments, plants will allocate less nitrogen to defense, resulting in decreased levels of nitrogen-containing secondary compounds. We present the first evidence of decreased investment in nitrogen-containing secondary compounds for a plant grown under elevated CO2. We also present evidence that plant response is species-specific and is not correlated with changes in leaf nitrogen content or leaf carbon-nitrogen ratio. When three crucifers were grown at 724 +/- 8 ppm CO2, total foliar glucosinolate content decreased significantly for mustard, but not for radish or turnip. Glucosinolate content of the second and fourth youngest mustard leaves decreased by 45% and 31%, respectively. In contrast, no significant change in total glucosinolate content was observed in turnip or radish leaves, despite significant decreases in leaf nitrogen content. Total glucosinolate content differed significantly among leaves of different age; however, the trend differed among species. For both mustard and turnip, glucosinolate content was significantly higher in older leaves, while the opposite was true for radish. No significant CO2 x leaf age interaction was observed, suggesting that intraplant patterns of allocation to defense will not change for these species. Changes in nitrogen allocation strategy are likely to be species-specific as plants experience increasing atmospheric CO2 levels. The ecological consequences of CO2-induced changes in plant defensive investment remain to be investigated
doi_str_mv 10.1023/B:JOEC.0000006667.81616.18
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When three crucifers were grown at 724 +/- 8 ppm CO2, total foliar glucosinolate content decreased significantly for mustard, but not for radish or turnip. Glucosinolate content of the second and fourth youngest mustard leaves decreased by 45% and 31%, respectively. In contrast, no significant change in total glucosinolate content was observed in turnip or radish leaves, despite significant decreases in leaf nitrogen content. Total glucosinolate content differed significantly among leaves of different age; however, the trend differed among species. For both mustard and turnip, glucosinolate content was significantly higher in older leaves, while the opposite was true for radish. No significant CO2 x leaf age interaction was observed, suggesting that intraplant patterns of allocation to defense will not change for these species. Changes in nitrogen allocation strategy are likely to be species-specific as plants experience increasing atmospheric CO2 levels. 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identifier ISSN: 0098-0331
ispartof Journal of chemical ecology, 1997-11, Vol.23 (11), p.2569-2582
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1573-1561
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source Springer Link
subjects Animal and plant ecology
Animal, plant and microbial ecology
Autoecology
Biological and medical sciences
BRASSICA CAMPESTRIS
BRASSICA NAPUS
CARBON
CARBON DIOXIDE
CHEMICAL COMPOSITION
DEFENSE
Ecological effects
Flowers & plants
Fundamental and applied biological sciences. Psychology
GLUCOSINOLATES
LEAVES
NITROGEN
NUTRIENT BALANCE
Nutrient content
NUTRITION PHYSIOLOGY
PLANT DEFENSE
Plant growth
Plants and fungi
RAPHANUS SATIVUS
title Species-specific response of glucosinolate content to elevated atmospheric CO2
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