Populus tremuloides photosynthesis and crown architecture in response to elevated CO2 and soil N availability

Kubiske, Mark E.; Pregitzer, Kurt S.; Mikan, Carl J.; Zak, Donald R.; Maziasz, Jennifer L.; Teeri, A.

doi:10.1007/pl00008813

Cited by 37 publications

(30 citation statements)

References 43 publications

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“…These results are similar to the 9-23% reduction in photosynthetic capacity observed during the fourth growing season in field-grown Betui!a pendula exposed to elevated CO, (Rey and Jarvis 1998) and in middle canopy leaves of Popzdus trenudoides (Kubiske et al 1997). …”

Section: Discussionsupporting

confidence: 83%

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Tissue¹,

Griffin²,

Ball³

1998

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Summary Photosynthesis oftreeseedlings isgenerdly enhaced dutingshofi-tem exposure to elevated atmospheric C02, but longer-term photosynthetic responses are often more variable because they are affected by morphological, biochemical and physiological feedback mechanisms that regulate carbon assimilation to meet sink demand. In order to examine potential biochemical and morphological factors that might regulate the longterm photosynthetic response of field-grown trees to elevated C02, we grew ponderosa pine (Pinus ponderosa) trees in open-top chambers for six years in native soil at ambient C02 (35 Pa) and elevated CO, (70 Pa) at a site near Placerville, CA. Trees were well watered and exposed to natural light and ambient temperature. Net photosynthesis was enhanced 53% in ponderosa pine trees grown in elevated COZat the end of the sixth growing season, despite reductions in photosynthetic capacity. The positive net photosynthetic response of ponderosa pine trees to elevated CO, reflected greater relative increases in Rubisco sensitivity than decreases due to biochemical adjustments.Reductions in photosynthetic capacity of elevated C02 trees were evident as analyses of ACi curves indicated significant reductions in maximum photosynthetic rate (A.=, 20%), Rubisco carboxylation capacity (VCmW, 36%), and electron transport capacity (J~=,21%).In addition, the reduction in photosynthetic capacity due to growth in elevated CO, was accompanied by reductions in various photosynthetic components, including total chlorophyll (24%), Rubisco protein content (38%), and mass-based leaf nitrogen concentration (14%). Net photosynthesis was unaffected by morphological adjustments since there was no change in leaf mass per unit area in elevated C02. An apparent positive response of photosynthetic adjustment in elevated C02 was the redistribution of N within the photosynthetic system to balance Rubisco carboxylation and electron Tissue -2 DISCLAIMER

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Section: Discussionsupporting

confidence: 83%

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Tissue¹,

Griffin²,

Ball³

1998

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“…For various hybrid poplar genotypes, growth enhancements of either stem diameter or plant height between 5 and 33% have been reported in response to elevated CO 2 treatments [4,10]. However, in chamber studies on small Populus tremuloides genotypes [22] and Populus grandidentata [6] no significant growth responses were observed. The volume index, which is a useful indicator of stem biomass [30], was enhanced by FACE treatment by 79%, 77% and 54% for P. nigra, P. x euramericana and P. alba respectively, mainly caused by an increase in diameter.…”

Section: Discussionmentioning

confidence: 99%

Growth performance of Populus exposed to "Free Air Carbon dioxide Enrichment" during the first growing season in the POPFACE experiment

et al. 2001

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-Stem diameter, total plant height and number of sylleptic branches of three poplar (Populus) genotypes were followed during the first growing season of a high density intensively cultured plantation (in Central Italy) both under ambient CO 2 (Control) and under elevated atmospheric CO 2 (550 ppm) using the FACE technique. The three poplar genotypes belonged to different species of Populus alba L., Populus nigra L. and Populus x euramericana Dode (Guinier). All three genotypes responded by an enhanced growth performance but the extent of their response to the FACE treatment was different. A stem volume index was calculated considering the stem composed by a truncated cone in the lower part and by a cone in the upper part. At the end of the first growing season, stem volume index was increased in the FACE treatment by 54% to 79% as compared to Control treatment, depending on the genotype. This increased stem volume index was caused by an increase of basal stem diameter rather than by an enhancement of plant height. Number of sylleptic branches was stimulated by more than 35% in the P. nigra genotype. The results confirm the optimal performance of this new POPFACE experiment and show the positive response of this fast-growing tree species to elevated CO 2 conditions at an ecosystem scale even if considering the genotypic differences. elevated CO 2 / FACE / short-rotation intensive culture / Populus / growth Résumé -Performance de croissance de plants de Populus exposés à une atmosphère enrichie en dioxide de carbone durant la première saison de croissance dans l'expérimentation POPFACE. Le diamètre du tronc, la hauteur totale et le nombre des branches sylleptiques de trois génotypes de peuplier (Populus) ont été suivis durant la première saison de croissance d'une plantation de haute densité en culture intensive (en Italie Centrale), à la fois sous air ambiant (350 ppm, plantes témoins), et sous atmosphère enrichie en CO 2 (550 ppm) en utilisant la technique FACE. Les trois génotypes de peuplier utilisés font partie d'espèces différentes : Populus alba L., Populus nigra L. et Populus x euramericana Dode (Guinier). Les trois génotypes ont tous répondu au traitement FACE par une augmentation de la croissance, mais avec des intensité différentes. Un index de volume du tronc a été calculé en considérant le tronc comme étant composé d'un cône tronqué pour sa partie inférieure, et d'un cône pour la partie supérieure. À la fin de la saison de croissance, l'index de volume du tronc était supérieur de 54 % à 79 %, en fonction du génotype, pour le traitement FACE par rapport aux plants témoins. Cette augmentation de l'index de volume du tronc est principalement due à l'augmentation du diamètre basal des troncs, plus qu'à Ann. For. Sci. 58 (2001)

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“…This study is one in a series of experiments to examine the interactions between elevated atmospheric CO # and soil N availability on tree growth, and to study how trees mediate the cycling of C and N in forest ecosystems (Curtis & Teeri, 1992 ;Zak et al, 1993 ;Curtis et al, 1994Curtis et al, , 1995Pregitzer et al, 1995 ;Kubiske et al, 1997). The purposes of the present study were to measure the effect of elevated atmospheric CO # and soil N availability on the production and turnover of fine roots, and to determine the extent to which differences in autumnal leaf-fall phenology of Populus tremuloides genotypes might influence late-season C allocation to fine roots under elevated atmospheric CO # .…”

Section: mentioning

confidence: 99%

Growth and C allocation of Populus tremuloides genotypes in response to atmospheric CO₂ and soil N availability

et al. 1998

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We grew cuttings of two early (mid Oct.) and two late (early Nov.) leaf-fall Populus tremuloides Michx. genotypes (referred to as genotype pairs) for c. 150 d in open-top chambers to understand how twice-ambient (elevated) CO # and soil N availability would affect growth and C allocation. For the study, we selected genotypes differing in leaf area duration to find out if late-season photosynthesis influenced C allocation to roots. Both elevated CO # and high soil N availability significantly increased estimated whole-tree photosynthesis, but they did so in different ways. Elevated CO # stimulated leaf-level photosynthesis rates, whereas high soil N availability resulted in greater total plant leaf area. The early leaf-fall genotype pair had significantly higher photosynthesis rates per unit leaf area than the late leaf-fall genotype pair and elevated CO # enhanced this difference. The early leaf-fall genotype pair had less leaf area than the late leaf-fall genotype pair, and their rate of leaf area development decreased earlier in the season. Across both genotype pairs, high soil N availability significantly increased fine root length production and mortality by increasing both the amount of root length present, and by decreasing the life span of individual roots. Elevated CO # resulted in significantly increased fine root production and mortality in high N but not low N soil and did not affect fine root life span. The early leaf-fall genotype pair had significantly greater fine root length production than the late leaf-fall genotype pair across all CO # and N treatments. These differences in belowground C allocations are consistent with the hypothesis that belowground C and N cycling is strongly influenced by soil N availability and will increase under elevated atmospheric CO # . In addition, this study reinforces the need for better understanding of the variation in tree responses to elevated CO # , within and among species.

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Populus tremuloides photosynthesis and crown architecture in response to elevated CO2 and soil N availability

Cited by 37 publications

References 43 publications

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Growth performance of Populus exposed to "Free Air Carbon dioxide Enrichment" during the first growing season in the POPFACE experiment

Growth and C allocation of Populus tremuloides genotypes in response to atmospheric CO₂ and soil N availability

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Populus tremuloides photosynthesis and crown architecture in response to elevated CO2 and soil N availability

Cited by 37 publications

References 43 publications

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Photosynthetic adjustment in field-grown ponderosa pine trees after six years exposure to elevated CO{sub 2}

Growth performance of Populus exposed to "Free Air Carbon dioxide Enrichment" during the first growing season in the POPFACE experiment

Growth and C allocation of Populus tremuloides genotypes in response to atmospheric CO2 and soil N availability

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Growth and C allocation of Populus tremuloides genotypes in response to atmospheric CO₂ and soil N availability