Journal of Experimental Botany

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© 1995 Oxford University Press

RESEARCH-ARTICLE

Responses of shoot and root gas exchange, leaf blade expansion and biomass production to pulses of elevated C0₂ in hydroponic wheat

Rudolf A. Christ and Christian Körner¹

Institute of Botany, University of Basel Schönbeinstr. 6, CH–4056 Basel, Switzerland

¹ To whom correspondence should be addressed: Fax: +41 61 267 35 04

Short-term effects of elevated CO₂ during the early life phase of plants may have long lasting consequences for growth and biomass in later periods. We exposed hydroponically grown wheat seedlings to 5 d pulses of elevated CO₂ while leaf expansion growth as well as shoot and root gas exchange were measured simultaneously and continuously. Shoot photosynthesis, night-time shoot respiration and below-ground respiration (largely by roots) roughly doubled when atmospheric CO₂ concentration was doubled. An interruption of CO₂ enrichment caused CO₂ assimilation and respiration to return to control levels. However, while the response of photosynthesis was immediate, that of respiration showed a hysteresis of about 3 d. Since shoot biomass increased at elevated CO₂ (with no change in allocation pattern) equal fluxes per shoot or root system after a return to control CO₂ concentrations indicate substantial downward adjustment of the capacity for CO₂ fixation and release in high-CO₂ grown plants. Leaf expansion growth was completely unaffected by CO₂ enrichment, whereas tiller initiation was significantly increased (doubled in 18 d). We conclude that leaf growth in these wheat plants was already carbon-saturated at ambient CO₂ concentration at optimum mineral nutrient supply. The stimulation of growth of whole plants was exclusively due to enhanced tillering during this very early part of the life of these wheat plants.

Key words: Allocation, atmospheric carbon dioxide enrichment, growth, photosynthesis, respiration, tillering, Triticum aestivum

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This article has been cited by other articles:

				J. Masle The Effects of Elevated CO2 Concentrations on Cell Division Rates, Growth Patterns, and Blade Anatomy in Young Wheat Plants Are Modulated by Factors Related to Leaf Position, Vernalization, and Genotype Plant Physiology, April 1, 2000; 122(4): 1399 - 1416. [Abstract] [Full Text]

Online ISSN 1460-2431 - Print ISSN 0022-0957

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