Gas Exchange, Leaf Nitrogen, and Growth Efficiency of Populus tremuloides in a CO 2 -Enriched Atmosphere

Vogel, Christoph S.; Wang, Xianzhong; Pregitzer, Kurt S.; Zak, Donald R.; Lussenhop, John; Kubiske, Mark E.; Teeri, James A.

doi:10.2307/2640982

Cited by 53 publications

(75 citation statements)

References 47 publications

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“…Similarly, leaf area increased under elevated CO 2 by 28% in high-N soil, but elevated CO 2 did not influence leaf area in low-N soil . Although leaf-level C assimilation increased to a much smaller extent from low-to high-N soil (e.g., 22%, Curtis et al 2000), greater C acquisition in high-N soil was facilitated by a much larger increase in leaf area (197%). Thus, greater rates of leaf-level C assimilation and leaf-area accumulation resulting from increases in atmospheric CO 2 and soil-N availability directly corresponded to differences in total biomass among our atmospheric-CO 2 -soil-N-availability treatments.…”

Section: Discussionmentioning

confidence: 99%

“…Leaf litter produced following the 1994 and 1995 growing seasons fell on the soil surface, where it resided during the remaining portion of our experiment. Additional details regarding plant growth conditions can be found in Curtis et al (2000).…”

Section: Biomass Harvestmentioning

confidence: 99%

“…Further details regarding our CO 2 -exposure system and its performance can be found in Curtis et al (2000).…”

Section: Biomass Harvestmentioning

confidence: 99%

“…Nitrogen mineralization rates in our experiment fall well within the range that this species encounters under field conditions. A complete summary of soil physical, chemical, and biological properties is presented in Curtis et al (2000) and Zak et al (2000).…”

Section: Biomass Harvestmentioning

confidence: 99%

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Atmospheric CO 2 , Soil-N Availability, and Allocation of Biomass and Nitrogen by Populus tremuloides

Zak¹,

Pregitzer²,

Vogel³

et al. 2000

Ecological Applications

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Abstract. Our ability to predict whether elevated atmospheric CO 2 will alter the cycling of C and N in terrestrial ecosystems requires understanding a complex set of feedback mechanisms initiated by changes in C and N acquisition by plants and the degree to which changes in resource acquisition (C and N) alter plant growth and allocation. To gain further insight into these dynamics, we grew six genotypes of Populus tremuloides Michx. that differ in autumnal senescence (early vs. late) under experimental atmospheric CO 2 (35.7 and 70.7 Pa) and soil-N availability (low and high) treatments. Atmospheric CO 2 concentrations were manipulated with open-top chambers, and soil-N availability was modified in open-bottom root boxes by mixing different proportions of native A and C horizon soil. Net N mineralization rates averaged 61 ng N·g Ϫ1 ·d Ϫ1 in low-N soil and 319 ng N·g Ϫ1 ·d Ϫ1in high-N soil. After 2.5 growing seasons, we harvested above-and belowground plant components in each chamber and determined total biomass, N concentration, N content, and the relative allocation of biomass and N to leaves, stems, and roots. Elevated CO 2 increased total plant biomass 16% in low-N soil and 38% in high-N soil, indicating that the growth response of P. tremuloides to elevated CO 2 was constrained by soil-N availability. Greater growth under elevated CO 2 did not substantially alter the allocation of biomass to above-or belowground plant components. At both levels of soil-N availability, elevated CO 2 decreased the N concentration of all plant tissues. Despite declines in tissue N concentration, elevated CO 2 significantly increased whole-plant N content in high-N soil (ambient ϭ 137 g N/chamber; elevated ϭ 155 g N/chamber), but it did not influence whole-plant N content in low-N soil (36 g N/chamber). Our results indicate that plants in high-N soil obtained greater amounts of soil N under elevated CO 2 by producing a proportionately larger fine-root system that more thoroughly exploited the soil. The significant positive relationship between fine-root biomass and total-plant N content we observed in high-N soil further supports this contention. In low-N soil, elevated CO 2 did not increase fine-root biomass or production, and plants under ambient and elevated CO 2 obtained equivalent amounts of N from soil. In high-N soil, it appears that greater acquisition of soil N under elevated CO 2 fed forward within the plant to increase rates of C acquisition, which further enhanced plant growth response to elevated CO 2 .

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Section: Discussionmentioning

confidence: 99%

Section: Biomass Harvestmentioning

confidence: 99%

“…Further details regarding our CO 2 -exposure system and its performance can be found in Curtis et al (2000).…”

Section: Biomass Harvestmentioning

confidence: 99%

Section: Biomass Harvestmentioning

confidence: 99%

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Atmospheric CO 2 , Soil-N Availability, and Allocation of Biomass and Nitrogen by Populus tremuloides

Zak¹,

Pregitzer²,

Vogel³

et al. 2000

Ecological Applications

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“…Dried extract was resuspended with 3 ml deionized water and 40 mg polyvinylpolypyrrolidone (PVPP) and thoroughly vortexed. PVPP was spun down using a centrifuge and a 0.5 ml aliquot removed and assayed enzymatically according to a colorimetric assay adapted from Jones et al [34] and modified for use on aspen tissues [35]. Soluble sugar recovery was >95%.…”

Section: Starch and Soluble Sugar Quantificationmentioning

confidence: 99%

Phenological and Temperature Controls on the Temporal Non-Structural Carbohydrate Dynamics of Populus grandidentata and Quercus rubra

Gough

Flower

Vogel

2010

Forests

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Temporal changes in plant tissue non-structural carbohydrates (NSC) may be sensitive to climate changes that alter forest phenology. We examined how temporal fluctuations in tissue NSC concentrations of Populus grandidentata and Quercus rubra relate to net and gross primary production (NPP, GPP) and their climatic drivers in a deciduous forest of Michigan, USA. Tissue NSC concentrations were coupled with NPP and GPP phenologies, declining from dormancy until GPP initiation and then increasing following NPP cessation. Warmer autumns extended the temporal gap between NPP and GPP cessation, prolonging the period of NSC accumulation. These results suggest that tissue NSC concentrations may increase with climate change.

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The Role of Rhizotrons and Minirhizotrons in Evaluating the Dynamics of Rhizoplane-Rhizosphere Microflora

McMichael¹,

Zak²

Soil Biology

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Gas Exchange, Leaf Nitrogen, and Growth Efficiency of Populus tremuloides in a CO 2 -Enriched Atmosphere

Cited by 53 publications

References 47 publications

Atmospheric CO 2 , Soil-N Availability, and Allocation of Biomass and Nitrogen by Populus tremuloides

Atmospheric CO 2 , Soil-N Availability, and Allocation of Biomass and Nitrogen by Populus tremuloides

Phenological and Temperature Controls on the Temporal Non-Structural Carbohydrate Dynamics of Populus grandidentata and Quercus rubra

The Role of Rhizotrons and Minirhizotrons in Evaluating the Dynamics of Rhizoplane-Rhizosphere Microflora

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