High carbon dioxide concentrations in aerenchyma of Typha latifolia

Diurnal and seasonal patterns of CO2 concentration ([CO2]) in leaf gas spaces were measured to better understand the relationship of sediment-derived CO2 to photosynthesis in the emergent wetland species, Typha latifolia L. (cattail). Leaf [CO2] was above 2,000 microliters/liter at dawn on all but t...

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Bibliographic Details
Published in:American journal of botany 1992-04, Vol.79 (4), p.415-418
Main Authors: Constable, J.V.H. (Louisiana State University, Baton Rouge, LA), Grace, J.B, Longstreth, D.J
Format: Article
Language:English
Subjects:
ANALISIS CUANTITATIVO
ANALYSE QUANTITATIVE
Animal and plant ecology
Animal, plant and microbial ecology
Atmospherics
Autoecology
Biological and medical sciences
Botany
Carbon dioxide
COMPOSICION QUIMICA
COMPOSITION CHIMIQUE
DIOXIDO DE CARBONO
DIOXYDE DE CARBONE
Dyes
FEUILLE
Flowers & plants
FOTOSINTESIS
Fundamental and applied biological sciences. Psychology
Gases
HOJAS
Leaves
LOUISIANE
LUISIANA
Methane
PHOTOSYNTHESE
Photosynthesis
Physiology, Biochemistry, and Cell Biology
Plant roots
Plants
Plants and fungi
Rhizomes
RITMOS BIOLOGICOS
RYTHME BIOLOGIQUE
TYPHACEAE
VARIACION ESTACIONAL
VARIATION SAISONNIERE
Wetlands
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Summary:Diurnal and seasonal patterns of CO2 concentration ([CO2]) in leaf gas spaces were measured to better understand the relationship of sediment-derived CO2 to photosynthesis in the emergent wetland species, Typha latifolia L. (cattail). Leaf [CO2] was above 2,000 microliters/liter at dawn on all but the first sampling date. At all sampling dates, leaf [CO2] declined to near atmospheric [CO2] at midday and rose to well above atmospheric [CO2] in the late afternoon. The maximum leaf [CO2] varied with sampling date and was over 18 times atmospheric levels (over 6,300 microliters/liter) in August. Based on measurement of photon flux density and temperature, the diurnal pattern in leaf [CO2] may be generally controlled by expected photosynthetic rates. It is hypothesized that seasonal variation in leaf [CO2] may be a function of variation in microbial (soil) respiration. Using dye and slight pressurization, it was confirmed that gas spaces in rhizomes were interconnected with the gas spaces in leaves through the rhizome-shoot transition. From anatomical measurements, it was also estimated that over 50% of total leaf volume was occupied by gas spaces and that most of the total gas-space volume in plants was in the shoot. Photosynthetic rate in C3 plants, like cattail, can increase with increasing [CO2] under natural conditions. For this reason, cattail and other emergent wetland plants possessing continuous gas-space pathways appear to have a significant carbon supplement as compared to other C3 plants growing in well-aerated soils
ISSN:0002-9122
1537-2197
DOI:10.1002/j.1537-2197.1992.tb14568.x