Atmospheric CO2 enrichment alters energy assimilation, investment and allocation in Xanthium strumarium

Atmospheric CO2 enrichment alters energy assimilation, investment and allocation in Xanthium strumarium

• Energy-use efficiency and energy assimilation, investment and allocation patterns are likely to influence plant growth responses to increasing atmospheric CO2 concentration ([ CO2]). Here, we describe the influence of elevated [ CO2] on energetic properties as a mechanism of growth responses in Xa...

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Bibliographic Details
Published in:The New phytologist Vol. 166; no. 2; pp. 513 - 523
Main Authors: Nagel, Jennifer M., Wang, Xianzhong, Lewis, James D., Fung, Howard A., Tissue, David T., Griffin, Kevin L.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Science 01-05-2005
Blackwell Science Ltd
Blackwell
Subjects:
allocation
Animal, plant and microbial ecology
Applied ecology
atmosphere
Atmosphere - chemistry
Atmospherics
Bioenergy
Biological and medical sciences
Biomass
Biomass energy production
Biomass production
Carbon dioxide
Carbon Dioxide - physiology
carbon dioxide enrichment
construction cost (CC)
Construction costs
Ecotoxicology, biological effects of pollution
Effects of pollution and side effects of pesticides on plants and fungi
elevated CO2
energy
energy assimilation
energy metabolism
Energy Metabolism - physiology
Fruit - physiology
Fundamental and applied biological sciences. Psychology
photosynthesis
photosynthetic energy-use efficiency
Plant Leaves - physiology
Plant roots
Plant Roots - physiology
Plant Stems - physiology
Plants
Stems
Xanthium - metabolism
Xanthium - physiology
Xanthium strumarium
Xanthium strumarium (common cocklebur)
allocation
construction cost (CC)
Growth
Resource allocation
Carbon dioxide
Biomass
Compositae
Cost benefit analysis
Xanthium strumarium
Energy balance
Medium enrichment
elevated CO2
Dicotyledones
Angiospermae
Spermatophyta
Models
Photosynthesis
Climate modification
Xanthium strumarium (common cocklebur)
energy
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Summary:• Energy-use efficiency and energy assimilation, investment and allocation patterns are likely to influence plant growth responses to increasing atmospheric CO2 concentration ([ CO2]). Here, we describe the influence of elevated [ CO2] on energetic properties as a mechanism of growth responses in Xanthium strumarium. • Individuals of X. strumarium were grown at ambient or elevated [ CO2] and harvested. Total biomass and energetic construction costs (CC) of leaves, stems, roots and fruits and percentage of total biomass and energy allocated to these components were determined. Photosynthetic energy-use efficiency (PEUE) was calculated as the ratio of total energy gained via photosynthetic activity (A total) to leaf CC. • Elevated [ CO2] increased leaf A total, but decreased CC per unit mass of leaves and roots. Consequently, X. strumarium individuals produced more leaf and root biomass at elevated [ CO2] without increasing total energy investment in these structures ( CC total). Whole-plant biomass was associated positively with PEUE. Whole-plant construction required 16.1% less energy than modeled whole-plant energy investment had CC not responded to increased [ CO2]. • As a physiological mechanism affecting growth, altered energetic properties could positively influence productivity of X. strumarium, and potentially other species, at elevated [ CO2].
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ISSN:0028-646X
1469-8137
DOI:10.1111/j.1469-8137.2005.01341.x