Stomatal conductance of forest species after long‐term exposure to elevated CO<sub>2</sub> concentration: a synthesis

Medlyn, Belinda E.; Barton, Craig V. M.; Broadmeadow, M. S. J.; Ceulemans, R.; Angelis, Paolo De; Forstreuter, Manfred; Freeman, Michael L.; Jackson, S. B.; Kellomäki, Seppo; Laitat, Eric; Rey, Ana; Roberntz, Peter; Sigurðsson, Bjarni D.; Strassemeyer, Jörn; Wang, K.; Curtis, Peter S.; Jarvis, P. G.

doi:10.1046/j.1469-8137.2001.00028.x

Cited by 634 publications

(559 citation statements)

References 57 publications

(156 reference statements)

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“…49. For this simulation, we made two assumptions: first, that A was in the CO 2 -limited region of the A-C i curve for the chronology, i.e., atmospheric CO 2 was never at saturating concentrations (11), and second, that there was little photosynthetic acclimation to CO 2 by the trees over the chronology, consistent with results from Free Air CO 2 Enrichment experiments and CO 2 meta-analyses (11,(50)(51)(52). The meta-analysis by Ainsworth and Rogers (11) indicates that, of all plant functional types, trees have shown the least potential for photosynthetic acclimation in experiments when CO 2 is doubled from current-day concentrations.…”

Section: Simulation Of Photosynthesis and Stomatal Conductance Over Tmentioning

confidence: 62%

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

Thomas

Spal

Smith

et al. 2013

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

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Using dendroisotopic techniques, we show the recovery of Juniperus virginiana L. (eastern red cedar) trees in the Central Appalachian Mountains from decades of acidic pollution. Acid deposition over much of the 20th century reduced stomatal conductance of leaves, thereby increasing intrinsic water-use efficiency of the Juniperus trees. These data indicate that the stomata of Juniperus may be more sensitive to acid deposition than to increasing atmospheric CO 2 . A breakpoint in the 100-y δ 13 C tree ring chronology occurred around 1980, as the legacy of sulfur dioxide emissions declined following the enactment of the Clean Air Act in 1970, indicating a gradual increase in stomatal conductance (despite rising levels of atmospheric CO 2 ) and a concurrent increase in photosynthesis related to decreasing acid deposition and increasing atmospheric CO 2 . Tree ring δ 34 S shows a synchronous change in the sources of sulfur used at the whole-tree level that indicates a reduced anthropogenic influence. The increase in growth and the δ 13 C and δ 34 S trends in the tree ring chronology of these Juniperus trees provide evidence for a distinct physiological response to changes in atmospheric SO 2 emissions since ∼1980 and signify the positive impacts of landmark environmental legislation to facilitate recovery of forest ecosystems from acid deposition.carbon isotopes | sulfur isotopes | carbon cycle

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Section: Simulation Of Photosynthesis and Stomatal Conductance Over Tmentioning

confidence: 62%

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

Thomas

Spal

Smith

et al. 2013

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

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“…One of the mechanisms by which increased atmospheric CO 2 affects plants is CO 2 regulation of stomatal apertures. Reports show that a doubling of atmospheric [CO 2 ] causes significant stomatal closure by 20-40% in diverse plant species (7)(8)(9).…”

mentioning

confidence: 99%

CO ₂ signaling in guard cells: Calcium sensitivity response modulation, a Ca ²⁺ -independent phase, and CO ₂ insensitivity of the gca2 mutant

Young

Mehta²,

Israelsson³

et al. 2006

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

174

243

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. These changes in leaf CO 2 concentrations occur as a result of photosynthesis and respiration. Furthermore, atmospheric CO 2 is predicted to double in the present century (1). Many studies have been carried out to determine the effects of atmospheric CO 2 increases on plant gas exchange, carbon fixation, and growth and the resulting impact this will have on natural and agricultural ecosystems (2-6). One of the mechanisms by which increased atmospheric CO 2 affects plants is CO 2 regulation of stomatal apertures. Reports show that a doubling of atmospheric [CO 2 ] causes significant stomatal closure by 20-40% in diverse plant species (7-9).Stomata experience diurnal changes in [CO 2 ] inside the leaf during light͞dark transitions. In the dark, CO 2 is produced in leaves by cellular respiration. The [CO 2 ] shifts caused by illumination changes are rapid and large, with [CO 2 ] in the stomatal cavity ranging from 200 to 650 ppm (10).Stomatal aperture is controlled by the turgor pressure in the guard cells surrounding the stomatal pore. Guard cell turgor pressure is mediated by the ion and organic solute concentration in guard cells. Elevated CO 2 has been shown to enhance potassium efflux channel and S type anion channel activities that mediate extrusion of ions during stomatal closure (11,12). In correlation with these findings, chloride release from guard cells is triggered by CO 2 elevation (13), and high CO 2 causes depolarization of guard cells (14, 15). Furthermore, CO 2 activation of R type anion channel currents was found in a subset of Vicia faba guard cells (12).Little is known about the CO 2 signal transduction mechanisms that function upstream of ion channels in guard cells (16)(17)(18)(19). CO 2 -induced stomatal movements were previously found to be absent in two mutants that affect the stomatal closure signaling network for the drought stress hormone abscisic acid (ABA): abi1-1 and abi2-1 (20). Conditional CO 2 responsiveness was reported in these mutants by using different experimental conditions (21,22 (16-18, 24, 26-32). Furthermore, some studies have also indicated a role for calcium increases in the opposing response of stomatal opening (33)(34)(35). It is unclear how these opposite responses could be directed via elevations in the same second messenger, Ca 2ϩ .CO 2 is a particularly interesting stomatal stimulus with respect to cytosolic Ca 2ϩ responses, as demonstrated in the present study. CO 2 can induce stomatal opening or closing depending on its concentration (36). Studies in animal and plant cells have shown that different patterns of repetitive calcium transients modulate responses (29,(37)(38)(39). Although previous studies have shown a role for calcium in CO 2 signaling in guard cells (24,25), changes in repetitive calcium transient patterns have not yet been studied in guard cells in response to CO 2 . The present study demonstrates CO 2 modulation of repetitive calcium transient patterns in Arabidopsis guard cells and characterizes roles of Ca 2ϩ in CO 2 -regulated stomatal ope...

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“…Under normal conditions, stomata of most land plants close in response to high carbon dioxide (CO 2 ) concentrations and open at low CO 2 concentration. The continuing rise in atmospheric CO 2 concentration reduces stomatal apertures across diverse plant species and alters plant metabolism on a global scale 1 . However, the mechanism by which CO 2 controls stomatal movements remains unclear.…”

mentioning

confidence: 99%

A molecular pathway for CO2 response in Arabidopsis guard cells

et al. 2015

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Increasing carbon dioxide (CO 2 ) levels in the atmosphere have caused global metabolic changes in diverse plant species. CO 2 is not only a carbon donor for photosynthesis but also an environmental signal that regulates stomatal movements and thereby controls plant-water relationships and carbon metabolism. However, the mechanism underlying CO 2 sensing in stomatal guard cells remains unclear. Here we report characterization of Arabidopsis RESISTANT TO HIGH CO 2 (RHC1), a MATE-type transporter that links elevated CO 2 concentration to repression of HT1, a protein kinase that negatively regulates CO 2 -induced stomatal closing. We also show that HT1 phosphorylates and inactivates OST1, a kinase which is essential for the activation of the SLAC1 anion channel and stomatal closing. Combining genetic, biochemical and electrophysiological evidence, we reconstituted the molecular relay from CO 2 to SLAC1 activation, thus establishing a core pathway for CO 2 signalling in plant guard cells.

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Stomatal conductance of forest species after long‐term exposure to elevated CO₂ concentration: a synthesis

Cited by 634 publications

References 57 publications

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

CO ₂ signaling in guard cells: Calcium sensitivity response modulation, a Ca ²⁺ -independent phase, and CO ₂ insensitivity of the gca2 mutant

A molecular pathway for CO2 response in Arabidopsis guard cells

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Stomatal conductance of forest species after long‐term exposure to elevated CO2 concentration: a synthesis

Cited by 634 publications

References 57 publications

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

Evidence of recovery of Juniperus virginiana trees from sulfur pollution after the Clean Air Act

CO 2 signaling in guard cells: Calcium sensitivity response modulation, a Ca 2+ -independent phase, and CO 2 insensitivity of the gca2 mutant

A molecular pathway for CO2 response in Arabidopsis guard cells

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Stomatal conductance of forest species after long‐term exposure to elevated CO₂ concentration: a synthesis

CO ₂ signaling in guard cells: Calcium sensitivity response modulation, a Ca ²⁺ -independent phase, and CO ₂ insensitivity of the gca2 mutant