Climate forcing due to optimization of maximal leaf conductance in subtropical vegetation under rising CO
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Boer, Hugo J. de; Lammertsma, Emmy I.; Wagner-Cremer, Friederike; Dilcher, David L.; Wassen, Martin J.; Dekker, Stefan C.

doi:10.1073/pnas.1100555108

Cited by 147 publications

(105 citation statements)

References 50 publications

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“…This likely represents the plants' adaptation to increase iWUE by optimizing carbon gain to water loss (11,37). We demonstrate that adaptation of g smax is achieved by species-specific strategies to alter D and/or a max .…”

Section: Discussionmentioning

confidence: 99%

“…Current increase in CO 2 and the coinciding reduction in plant transpiration already results in increased continental run-off (46), and climate models predict surface temperature increases arising from reduced evaporative cooling (6,7). The mechanisms of optimization of carbon gain to water loss described here could be used to better estimate this physiological forcing for the past and future CO 2 but should be considered within the framework of species-specific phenotypic plasticity (37).…”

Section: Discussionmentioning

confidence: 99%

“…Both lines of evidence, however, fall beyond or below the timescales of the projected rate of continuing CO 2 increase, which is likely to surpass the time needed for adaptation via natural selection. Consequently, the adaptation within the phenotypic plasticity is likely to constrain epidermis structural adaptation in the near future when phenotypic response limits are reached (35,37). Current increase in CO 2 and the coinciding reduction in plant transpiration already results in increased continental run-off (46), and climate models predict surface temperature increases arising from reduced evaporative cooling (6,7).…”

Section: Discussionmentioning

confidence: 99%

“…Our results of structural adaptation from ≈280 ppm to 387 ppm CO 2 does not bear any evidence for a diverging response between plant lineages. Whether any g smax off-leveling will occur under continuing CO 2 enrichment, and at what CO 2 concentration this will happen, should be estimated by modeling exercises incorporating adaptation within the speciesspecific phenotypic plasticity (37).…”

Section: Discussionmentioning

confidence: 99%

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Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation

Lammertsma

Boer

Dekker

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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149

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A principle response of C3 plants to increasing concentrations of atmospheric CO 2 (CO 2 ) is to reduce transpirational water loss by decreasing stomatal conductance (g s ) and simultaneously increase assimilation rates. Via this adaptation, vegetation has the ability to alter hydrology and climate. Therefore, it is important to determine the adaptation of vegetation to the expected anthropogenic rise in CO 2 . Short-term stomatal opening-closing responses of vegetation to increasing CO 2 are described by free-air carbon enrichments growth experiments, and evolutionary adaptations are known from the geological record. However, to date the effects of decadal to centennial CO 2 perturbations on stomatal conductance are still largely unknown. Here we reconstruct a 34% (±12%) reduction in maximum stomatal conductance (g smax ) per 100 ppm CO 2 increase as a result of the adaptation in stomatal density (D) and pore size at maximal stomatal opening (a max ) of nine common species from Florida over the past 150 y. The species-specific g smax values are determined by different evolutionary development, whereby the angiosperms sampled generally have numerous small stomata and high g smax , and the conifers and fern have few large stomata and lower g smax . Although angiosperms and conifers use different D and a max adaptation strategies, our data show a coherent response in g smax to CO 2 rise of the past century. Understanding these adaptations of C3 plants to rising CO 2 after decadal to centennial environmental changes is essential for quantification of plant physiological forcing at timescales relevant for global warming, and they are likely to continue until the limits of their phenotypic plasticity are reached. cuticular analysis | subtropical vegetation L and plants play a crucial role in regulating our planet's hydrological and energy balance by transpiring water through the stomatal pores on their leaf surfaces. A fundamental response of C3 plants to increasing atmospheric CO 2 concentration (CO 2 ) is to minimize transpirational water loss by reducing diffusive stomatal conductance (g s ) and simultaneously increasing assimilation rates (1). The resulting increased intrinsic water-use efficiency (iWUE: the ratio of assimilation to g s ) improves the vegetation's drought resistance and reduces the cost associated with the leaf's water transport system like leaf venation (2, 3). On a regional to global scale, decreasing rates of transpiration concurrently affect climate through reduced cloud formation and precipitation (4) and with this exert a physiological feedback on climate and hydrology on top of the radiative forcing of increasing CO 2 (5-7). In the light of continuing anthropogenic climate change, it is therefore imperative to determine how plants adapt to rising atmospheric CO 2 .During their 400 million year history, land plants have been exposed to large variations in environmental conditions that prompted genetic adaptations toward mechanisms that optimize individual fitness. Over this period, plant ad...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation

Lammertsma

Boer

Dekker

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

224

149

View full text Add to dashboard Cite

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“…However, there are large uncertainties about the long-term response of the tropical forests to this effect (127), although modeling of this effect for the Amazon indicates that the impact of high degrees of climate change are attenuated, but not to the extent of avoiding forest loss (128). In a CO 2 -enriched environment, the plants can respond with stomatal closure to capture the same amount of CO 2 required for photosynthesis (129). As a consequence, transpiration rates could decrease, potentially returning a lower amount of vapor to the atmosphere, or, in other words, altering ET rates (130).…”

Section: Impacts Of Anthropogenic Drivers Of Change In the Amazonmentioning

confidence: 99%

Land-use and climate change risks in the Amazon and the need of a novel sustainable development paradigm

Nobre

Sampaio

Borma

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

670

449

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For half a century, the process of economic integration of the Amazon has been based on intensive use of renewable and nonrenewable natural resources, which has brought significant basin-wide environmental alterations. The rural development in the Amazonia pushed the agricultural frontier swiftly, resulting in widespread land-cover change, but agriculture in the Amazon has been of low productivity and unsustainable. The loss of biodiversity and continued deforestation will lead to high risks of irreversible change of its tropical forests. It has been established by modeling studies that the Amazon may have two "tipping points," namely, temperature increase of 4°C or deforestation exceeding 40% of the forest area. If transgressed, large-scale "savannization" of mostly southern and eastern Amazon may take place. The region has warmed about 1°C over the last 60 y, and total deforestation is reaching 20% of the forested area. The recent significant reductions in deforestation-80% reduction in the Brazilian Amazon in the last decade-opens up opportunities for a novel sustainable development paradigm for the future of the Amazon. We argue for a new development paradigm-away from only attempting to reconcile maximizing conservation versus intensification of traditional agriculture and expansion of hydropower capacity-in which we research, develop, and scale a high-tech innovation approach that sees the Amazon as a global public good of biological assets that can enable the creation of innovative high-value products, services, and platforms through combining advanced digital, biological, and material technologies of the Fourth Industrial Revolution in progress.Amazon tropical forests | Amazon sustainability | Amazon land use | Amazon savannization | climate change impacts

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The sensitivity of wet and dry tropical forests to climate change in Bolivia

et al. 2015

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Bolivia's forests contribute to the global carbon and water cycle, as well as to global biodiversity. The survival of these forests may be at risk due to climate change. To explore the associated mechanisms and uncertainties, a regionally adapted dynamic vegetation model was implemented for the Bolivian case, and forced with two contrasting climate change projections. Changes in carbon stocks and fluxes were evaluated, factoring out the individual contributions of atmospheric carbon dioxide ([CO2]), temperature, and precipitation. Impacts ranged from a strong increase to a severe loss of vegetation carbon (cv), depending on differences in climate projections, as well as the physiological response to rising [CO2]. The loss of cv simulated for an extremely dry projection was primarily driven by a reduction in gross primary productivity, and secondarily by enhanced emissions from fires and autotrophic respiration. In the wet forest, less precipitation and higher temperatures equally reduced cv, while in the dry forest, the impact of precipitation was dominating. The temperature‐related reduction of cv was mainly due to a decrease in photosynthesis and only to lesser extent because of more autotrophic respiration and less stomatal conductance as a response to an increasing atmospheric evaporative demand. Under an extremely dry projection, tropical dry forests were simulated to virtually disappear, regardless of the potential fertilizing effect of rising [CO2]. This suggests a higher risk for forest loss along the drier southern fringe of the Amazon if annual precipitation will decrease substantially.

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Climate forcing due to optimization of maximal leaf conductance in subtropical vegetation under rising CO ₂

Cited by 147 publications

References 50 publications

Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation

Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation

Land-use and climate change risks in the Amazon and the need of a novel sustainable development paradigm

The sensitivity of wet and dry tropical forests to climate change in Bolivia

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Climate forcing due to optimization of maximal leaf conductance in subtropical vegetation under rising CO 2

Cited by 147 publications

References 50 publications

Global CO 2 rise leads to reduced maximum stomatal conductance in Florida vegetation

Global CO 2 rise leads to reduced maximum stomatal conductance in Florida vegetation

Land-use and climate change risks in the Amazon and the need of a novel sustainable development paradigm

The sensitivity of wet and dry tropical forests to climate change in Bolivia

Contact Info

Product

Resources

About

Climate forcing due to optimization of maximal leaf conductance in subtropical vegetation under rising CO ₂

Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation

Global CO ₂ rise leads to reduced maximum stomatal conductance in Florida vegetation