Large variation in whole‐plant water‐use efficiency among tropical tree species

Cernusak, Lucas A.; Aranda, Jorge; Marshall, John D.; Winter, Klaus

doi:10.1111/j.1469-8137.2006.01913.x

Cited by 103 publications

(101 citation statements)

References 58 publications

(79 reference statements)

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“…This is consistent with previous results showing large variation in TE c among seven tropical tree species (Cernusak et al, 2007a). When the TE c for each individual plant was normalized according to its growth-weighted mean daytime vapor pressure deficit, D g , the variation among species was still apparent, suggesting that D g was not a primary control over TE c .…”

Section: Transpiration Efficiencysupporting

confidence: 80%

Conifers, Angiosperm Trees, and Lianas: Growth, Whole-Plant Water and Nitrogen Use Efficiency, and Stable Isotope Composition (δ 13C and δ 18O) of Seedlings Grown in a Tropical Environment

et al. 2008

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Seedlings of several species of gymnosperm trees, angiosperm trees, and angiosperm lianas were grown under tropical field conditions in the Republic of Panama; physiological processes controlling plant C and water fluxes were assessed across this functionally diverse range of species. Relative growth rate, r, was primarily controlled by the ratio of leaf area to plant mass, of which specific leaf area was a key component. Instantaneous photosynthesis, when expressed on a leaf-mass basis, explained 69% of variation in r (P , 0.0001, n 5 94). Mean r of angiosperms was significantly higher than that of the gymnosperms; within angiosperms, mean r of lianas was higher than that of trees. Whole-plant nitrogen use efficiency was also significantly higher in angiosperm than in gymnosperm species, and was primarily controlled by the rate of photosynthesis for a given amount of leaf nitrogen. Whole-plant water use efficiency, TE c , varied significantly among species, and was primarily controlled by c i /c a , the ratio of intercellular to ambient CO 2 partial pressures during photosynthesis. Instantaneous measurements of c i /c a explained 51% of variation in TE c (P , 0.0001, n 5 94). Whole-plant 13 C discrimination also varied significantly as a function of c i /c a (R 2 5 0.57, P , 0.0001, n 5 94), and was, accordingly, a good predictor of TE c . The 18O enrichment of stem dry matter was primarily controlled by the predicted 18 O enrichment of evaporative sites within leaves (R 2 5 0.61, P , 0.0001, n 5 94), with some residual variation explained by mean transpiration rate. Measurements of carbon and oxygen stable isotope ratios could provide a useful means of parameterizing physiological models of tropical forest trees.Tropical forest ecosystems have been subject to extensive perturbations associated with anthropogenic activity in recent decades, and such perturbations will likely continue into the foreseeable future (Laurance et al., 2004;Wright, 2005). Effective environmental management requires knowledge of how such perturbations impact upon cycling of carbon (C) and water between forest trees and the atmosphere, and how these C and water fluxes relate to plant nutrient status. A sound, mechanistic understanding of the physiological processes that control photosynthesis and transpiration in tropical trees is therefore essential for understanding and managing the human impact upon tropical forests. In this study, we analyzed the physiological controls over growth (the relative rate of C accumulation), nitrogen (N) use efficiency (NUE; the rate of C accumulation for a given N content), water use efficiency (the ratio of whole-plant C gain to water loss), and stable isotope composition (d 13

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Section: Transpiration Efficiencysupporting

confidence: 80%

Conifers, Angiosperm Trees, and Lianas: Growth, Whole-Plant Water and Nitrogen Use Efficiency, and Stable Isotope Composition (δ 13C and δ 18O) of Seedlings Grown in a Tropical Environment

et al. 2008

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“…7, C and D; Table I). This agrees with previous observations for a smaller number of species (Cernusak et al, 2007a(Cernusak et al, , 2008(Cernusak et al, , 2009b. When plants were grown in fertilized soil, the legume species appeared to lose their advantage in W P , as shown for the comparison between O. macrocalyx and S. macrophylla in this study (Fig.…”

supporting

confidence: 82%

“…Taking the nonnodulating legume S. parahyba as a reference plant (Pons et al, 2007) and assuming a discrimination of 1‰ during N 2 fixation (Yoneyama et al, 1986), we estimated the proportion of plant N acquired by N 2 fixation to be 84% for O. macrocalyx, 73% for A. adinocephala, 52% for D. retusa, 46% for I. punctata, and 0% for S. parahyba. However, these values should be considered as indicative only, because the non-N 2 -fixing species included in the study showed a relatively large range of plant d 15 N, similar to previous observations for non-N 2 -fixing tropical tree species (Guehl et al, 1998;Cernusak et al, 2007aCernusak et al, , 2009cPons et al, 2007). This introduces uncertainty into the estimate of d 15 N for soil-derived plant N (Shearer and Kohl, 1986).…”

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confidence: 71%

Responses of Legume Versus Nonlegume Tropical Tree Seedlings to Elevated CO2 Concentration

et al. 2011

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We investigated responses of growth, leaf gas exchange, carbon-isotope discrimination, and whole-plant water-use efficiency (W P ) to elevated CO 2 concentration ([CO 2 ]) in seedlings of five leguminous and five nonleguminous tropical tree species. Plants were grown at CO 2 partial pressures of 40 and 70 Pa. As a group, legumes did not differ from nonlegumes in growth response to elevated [CO 2 ]. The mean ratio of final plant dry mass at elevated to ambient [CO 2 ] (M E /M A ) was 1.32 and 1.24 for legumes and nonlegumes, respectively. However, there was large variation in M E /M A among legume species (0.92-2.35), whereas nonlegumes varied much less (1.21-1.29). Variation among legume species in M E /M A was closely correlated with their capacity for nodule formation, as expressed by nodule mass ratio, the dry mass of nodules for a given plant dry mass. W P increased markedly in response to elevated [CO 2 ] in all species. The ratio of intercellular to ambient CO 2 partial pressures during photosynthesis remained approximately constant at ambient and elevated [CO 2 ], as did carbon isotope discrimination, suggesting that W P should increase proportionally for a given increase in atmospheric [CO 2 ]. These results suggest that tree legumes with a strong capacity for nodule formation could have a competitive advantage in tropical forests as atmospheric [CO 2 ] rises and that the water-use efficiency of tropical tree species will increase under elevated [CO 2 ].

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“…High variation in CID has been found across species (for example, Oliveras et al, 2003 for conifers;Cernusak et al, 2007 for tropical trees), as well as moderate narrowsense (h 2 ) heritability within-species (0.17 in maritime pine, Brendel et al, 2002; 0.09 across-sites in loblolly pine, Baltunis et al, 2008). As trees with higher WUE may sustain growth under water-limitation conditions and differences in WUE represent also different growing strategies, CID is an attractive trait for breeding, in particular in dry areas or in those regions in which the higher impact of the current process of global climate change will be felt.…”

Section: Discussionmentioning

confidence: 99%

Association genetics in Pinus taeda L. II. Carbon isotope discrimination

et al. 2008

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Dissection of complex traits that influence fitness is not only a central topic in evolutionary research but can also assist breeding practices for economically important plant species, such as loblolly pine (Pinus taeda L). In this study, 46 single nucleotide polymorphisms (SNPs) from 41 disease and abiotic stress-inducible genes were tested for their genetic association with carbon isotope discrimination (CID), a timeintegrated trait measure of stomatal conductance. A familybased approach to detect genotype/phenotype genetic association was developed for the first time in plants by applying the quantitative transmission disequilibrium test on an association population of 961 clones from 61 families (adopted from previous breeding programs) evaluated for phenotypic expression of CID at two sites. Two particularly promising candidates for their genetic effects on CID are: dhn-1, involved in stabilization of cell structures, and lp5-like, a glycine rich protein putatively related to cell wall reinforcement proteins, both of which were shown in previous studies to be water-deficit inducible. Moreover, association in lp5-like involves a nonsynonymous mutation in linkage disequilibrium with two other nonsynonymous polymorphisms that could, by acting together, enhance overall phenotypic effects. This study highlights the complexity of dissecting CID traits and provides insights for designing second-generation association studies based on candidate gene approaches in forest trees.

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Large variation in whole‐plant water‐use efficiency among tropical tree species

Cited by 103 publications

References 58 publications

Conifers, Angiosperm Trees, and Lianas: Growth, Whole-Plant Water and Nitrogen Use Efficiency, and Stable Isotope Composition (δ 13C and δ 18O) of Seedlings Grown in a Tropical Environment

Conifers, Angiosperm Trees, and Lianas: Growth, Whole-Plant Water and Nitrogen Use Efficiency, and Stable Isotope Composition (δ 13C and δ 18O) of Seedlings Grown in a Tropical Environment

Responses of Legume Versus Nonlegume Tropical Tree Seedlings to Elevated CO2 Concentration

Association genetics in Pinus taeda L. II. Carbon isotope discrimination

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