Your search keyword '"Oliveira, Alex"' showing total 13 results

1. Amazonia trees have limited capacity to acclimate plant hydraulic properties in response to long-term drought.

Author

Bittencourt PRL, Oliveira RS, da Costa ACL, Giles AL, Coughlin I, Costa PB, Bartholomew DC, Ferreira LV, Vasconcelos SS, Barros FV, Junior JAS, Oliveira AAR, Mencuccini M, Meir P, and Rowland L

Subjects

Brazil, Plant Leaves, Rainforest, Water, Droughts, Trees

Abstract

The fate of tropical forests under future climate change is dependent on the capacity of their trees to adjust to drier conditions. The capacity of trees to withstand drought is likely to be determined by traits associated with their hydraulic systems. However, data on whether tropical trees can adjust hydraulic traits when experiencing drought remain rare. We measured plant hydraulic traits (e.g. hydraulic conductivity and embolism resistance) and plant hydraulic system status (e.g. leaf water potential, native embolism and safety margin) on >150 trees from 12 genera (36 species) and spanning a stem size range from 14 to 68 cm diameter at breast height at the world's only long-running tropical forest drought experiment. Hydraulic traits showed no adjustment following 15 years of experimentally imposed moisture deficit. This failure to adjust resulted in these drought-stressed trees experiencing significantly lower leaf water potentials, and higher, but variable, levels of native embolism in the branches. This result suggests that hydraulic damage caused by elevated levels of embolism is likely to be one of the key drivers of drought-induced mortality following long-term soil moisture deficit. We demonstrate that some hydraulic traits changed with tree size, however, the direction and magnitude of the change was controlled by taxonomic identity. Our results suggest that Amazonian trees, both small and large, have limited capacity to acclimate their hydraulic systems to future droughts, potentially making them more at risk of drought-induced mortality., (© 2020 John Wiley & Sons Ltd.)

Published

2020

2. Drought stress and tree size determine stem CO 2 efflux in a tropical forest.

Author

Rowland L, da Costa ACL, Oliveira AAR, Oliveira RS, Bittencourt PL, Costa PB, Giles AL, Sosa AI, Coughlin I, Godlee JL, Vasconcelos SS, Junior JAS, Ferreira LV, Mencuccini M, and Meir P

Subjects

Cell Respiration, Seasons, Carbon Dioxide metabolism, Droughts, Forests, Plant Stems metabolism, Stress, Physiological, Trees anatomy & histology, Tropical Climate

Abstract

CO 2 efflux from stems (CO 2_stem ) accounts for a substantial fraction of tropical forest gross primary productivity, but the climate sensitivity of this flux remains poorly understood. We present a study of tropical forest CO 2_stem from 215 trees across wet and dry seasons, at the world's longest running tropical forest drought experiment site. We show a 27% increase in wet season CO 2_stem in the droughted forest relative to a control forest. This was driven by increasing CO 2_stem in trees 10-40 cm diameter. Furthermore, we show that drought increases the proportion of maintenance to growth respiration in trees > 20 cm diameter, including large increases in maintenance respiration in the largest droughted trees, > 40 cm diameter. However, we found no clear taxonomic influence on CO 2_stem and were unable to accurately predict how drought sensitivity altered ecosystem scale CO 2_stem , due to substantial uncertainty introduced by contrasting methods previously employed to scale CO 2_stem fluxes. Our findings indicate that under future scenarios of elevated drought, increases in CO 2_stem may augment carbon losses, weakening or potentially reversing the tropical forest carbon sink. However, due to substantial uncertainties in scaling CO 2_stem fluxes, stand-scale future estimates of changes in stem CO 2 emissions remain highly uncertain., (© 2018 The Authors New Phytologist © 2018 New Phytologist Trust.)

Published

2018

3. Stand dynamics modulate water cycling and mortality risk in droughted tropical forest.

Author

da Costa ACL, Rowland L, Oliveira RS, Oliveira AAR, Binks OJ, Salmon Y, Vasconcelos SS, Junior JAS, Ferreira LV, Poyatos R, Mencuccini M, and Meir P

Subjects

Climate Change, Soil, Tropical Climate, Water, Water Cycle, Droughts, Rainforest, Trees physiology

Abstract

Transpiration from the Amazon rainforest generates an essential water source at a global and local scale. However, changes in rainforest function with climate change can disrupt this process, causing significant reductions in precipitation across Amazonia, and potentially at a global scale. We report the only study of forest transpiration following a long-term (>10 year) experimental drought treatment in Amazonian forest. After 15 years of receiving half the normal rainfall, drought-related tree mortality caused total forest transpiration to decrease by 30%. However, the surviving droughted trees maintained or increased transpiration because of reduced competition for water and increased light availability, which is consistent with increased growth rates. Consequently, the amount of water supplied as rainfall reaching the soil and directly recycled as transpiration increased to 100%. This value was 25% greater than for adjacent nondroughted forest. If these drought conditions were accompanied by a modest increase in temperature (e.g., 1.5°C), water demand would exceed supply, making the forest more prone to increased tree mortality., (© 2017 John Wiley & Sons Ltd.)

Published

2018

4. Differences in xylem and leaf hydraulic traits explain differences in drought tolerance among mature Amazon rainforest trees.

Author

Powell TL, Wheeler JK, de Oliveira AAR, da Costa ACL, Saleska SR, Meir P, and Moorcroft PR

Subjects

Brazil, Plant Leaves, Trees, Tropical Climate, Water, Xylem, Climate Change, Droughts, Rainforest

Abstract

Considerable uncertainty surrounds the impacts of anthropogenic climate change on the composition and structure of Amazon forests. Building upon results from two large-scale ecosystem drought experiments in the eastern Brazilian Amazon that observed increases in mortality rates among some tree species but not others, in this study we investigate the physiological traits underpinning these differential demographic responses. Xylem pressure at 50% conductivity (xylem-P 50 ), leaf turgor loss point (TLP), cellular osmotic potential (π o ), and cellular bulk modulus of elasticity (ε), all traits mechanistically linked to drought tolerance, were measured on upper canopy branches and leaves of mature trees from selected species growing at the two drought experiment sites. Each species was placed a priori into one of four plant functional type (PFT) categories: drought-tolerant versus drought-intolerant based on observed mortality rates, and subdivided into early- versus late-successional based on wood density. We tested the hypotheses that the measured traits would be significantly different between the four PFTs and that they would be spatially conserved across the two experimental sites. Xylem-P 50 , TLP, and π o , but not ε, occurred at significantly higher water potentials for the drought-intolerant PFT compared to the drought-tolerant PFT; however, there were no significant differences between the early- and late-successional PFTs. These results suggest that these three traits are important for determining drought tolerance, and are largely independent of wood density-a trait commonly associated with successional status. Differences in these physiological traits that occurred between the drought-tolerant and drought-intolerant PFTs were conserved between the two research sites, even though they had different soil types and dry-season lengths. This more detailed understanding of how xylem and leaf hydraulic traits vary between co-occuring drought-tolerant and drought-intolerant tropical tree species promises to facilitate a much-needed improvement in the representation of plant hydraulics within terrestrial ecosystem and biosphere models, which will enhance our ability to make robust predictions of how future changes in climate will affect tropical forests., (© 2017 John Wiley & Sons Ltd.)

Published

2017

5. Limited acclimation in leaf anatomy to experimental drought in tropical rainforest trees.

Author

Binks O, Meir P, Rowland L, da Costa AC, Vasconcelos SS, de Oliveira AA, Ferreira L, and Mencuccini M

Subjects

Plant Leaves physiology, Trees anatomy & histology, Acclimatization, Droughts, Plant Leaves anatomy & histology, Rainforest, Trees physiology

Abstract

Dry periods are predicted to become more frequent and severe in the future in some parts of the tropics, including Amazonia, potentially causing reduced productivity, higher tree mortality and increased emissions of stored carbon. Using a long-term (12 year) through-fall exclusion (TFE) experiment in the tropics, we test the hypothesis that trees produce leaves adapted to cope with higher levels of water stress, by examining the following leaf characteristics: area, thickness, leaf mass per area, vein density, stomatal density, the thickness of palisade mesophyll, spongy mesophyll and both of the epidermal layers, internal cavity volume and the average cell sizes of the palisade and spongy mesophyll. We also test whether differences in leaf anatomy are consistent with observed differential drought-induced mortality responses among taxa, and look for relationships between leaf anatomy, and leaf water relations and gas exchange parameters. Our data show that trees do not produce leaves that are more xeromorphic in response to 12 years of soil moisture deficit. However, the drought treatment did result in increases in the thickness of the adaxial epidermis (TFE: 20.5 ± 1.5 µm, control: 16.7 ± 1.0 µm) and the internal cavity volume (TFE: 2.43 ± 0.50 mm 3 cm -2 , control: 1.77 ± 0.30 mm 3 cm -2 ). No consistent differences were detected between drought-resistant and drought-sensitive taxa, although interactions occurred between drought-sensitivity status and drought treatment for the palisade mesophyll thickness (P = 0.034) and the cavity volume of the leaves (P = 0.025). The limited response to water deficit probably reflects a tight co-ordination between leaf morphology, water relations and photosynthetic properties. This suggests that there is little plasticity in these aspects of plant anatomy in these taxa, and that phenotypic plasticity in leaf traits may not facilitate the acclimation of Amazonian trees to the predicted future reductions in dry season water availability., (© The Author 2016. Published by Oxford University Press.)

Published

2016

6. Plasticity in leaf-level water relations of tropical rainforest trees in response to experimental drought.

Author

Binks O, Meir P, Rowland L, da Costa AC, Vasconcelos SS, de Oliveira AA, Ferreira L, Christoffersen B, Nardini A, and Mencuccini M

Subjects

Linear Models, Models, Theoretical, Pressure, Probability, Seasons, Droughts, Plant Leaves physiology, Rainforest, Water physiology

Abstract

The tropics are predicted to become warmer and drier, and understanding the sensitivity of tree species to drought is important for characterizing the risk to forests of climate change. This study makes use of a long-term drought experiment in the Amazon rainforest to evaluate the role of leaf-level water relations, leaf anatomy and their plasticity in response to drought in six tree genera. The variables (osmotic potential at full turgor, turgor loss point, capacitance, elastic modulus, relative water content and saturated water content) were compared between seasons and between plots (control and through-fall exclusion) enabling a comparison between short- and long-term plasticity in traits. Leaf anatomical traits were correlated with water relation parameters to determine whether water relations differed among tissues. The key findings were: osmotic adjustment occurred in response to the long-term drought treatment; species resistant to drought stress showed less osmotic adjustment than drought-sensitive species; and water relation traits were correlated with tissue properties, especially the thickness of the abaxial epidermis and the spongy mesophyll. These findings demonstrate that cell-level water relation traits can acclimate to long-term water stress, and highlight the limitations of extrapolating the results of short-term studies to temporal scales associated with climate change., (© 2016 The Authors. New Phytologist © 2016 New Phytologist Trust.)

Published

2016

7. After more than a decade of soil moisture deficit, tropical rainforest trees maintain photosynthetic capacity, despite increased leaf respiration.

Author

Rowland L, Lobo-do-Vale RL, Christoffersen BO, Melém EA, Kruijt B, Vasconcelos SS, Domingues T, Binks OJ, Oliveira AA, Metcalfe D, da Costa AC, Mencuccini M, and Meir P

Subjects

Brazil, Carbon Cycle, Climate Change, Plant Leaves physiology, Plant Transpiration, Seasons, Soil chemistry, Tropical Climate, Droughts, Photosynthesis, Rainforest, Trees physiology

Abstract

Determining climate change feedbacks from tropical rainforests requires an understanding of how carbon gain through photosynthesis and loss through respiration will be altered. One of the key changes that tropical rainforests may experience under future climate change scenarios is reduced soil moisture availability. In this study we examine if and how both leaf photosynthesis and leaf dark respiration acclimate following more than 12 years of experimental soil moisture deficit, via a through-fall exclusion experiment (TFE) in an eastern Amazonian rainforest. We find that experimentally drought-stressed trees and taxa maintain the same maximum leaf photosynthetic capacity as trees in corresponding control forest, independent of their susceptibility to drought-induced mortality. We hypothesize that photosynthetic capacity is maintained across all treatments and taxa to take advantage of short-lived periods of high moisture availability, when stomatal conductance (gs ) and photosynthesis can increase rapidly, potentially compensating for reduced assimilate supply at other times. Average leaf dark respiration (Rd ) was elevated in the TFE-treated forest trees relative to the control by 28.2 ± 2.8% (mean ± one standard error). This mean Rd value was dominated by a 48.5 ± 3.6% increase in the Rd of drought-sensitive taxa, and likely reflects the need for additional metabolic support required for stress-related repair, and hydraulic or osmotic maintenance processes. Following soil moisture deficit that is maintained for several years, our data suggest that changes in respiration drive greater shifts in the canopy carbon balance, than changes in photosynthetic capacity., (© 2015 John Wiley & Sons Ltd.)

Published

2015

8. Effect of 7 yr of experimental drought on vegetation dynamics and biomass storage of an eastern Amazonian rainforest.

Author

da Costa AC, Galbraith D, Almeida S, Portela BT, da Costa M, Silva Junior Jde A, Braga AP, de Gonçalves PH, de Oliveira AA, Fisher R, Phillips OL, Metcalfe DB, Levy P, and Meir P

Subjects

Brazil, Plant Stems growth & development, Soil, Time Factors, Trees classification, Wood growth & development, Biomass, Droughts, Rain, Trees growth & development

Abstract

*At least one climate model predicts severe reductions of rainfall over Amazonia during this century. Long-term throughfall exclusion (TFE) experiments represent the best available means to investigate the resilience of the Amazon rainforest to such droughts. *Results are presented from a 7 yr TFE study at Caxiuanã National Forest, eastern Amazonia. We focus on the impacts of the drought on tree mortality, wood production and above-ground biomass. *Tree mortality in the TFE plot over the experimental period was 2.5% yr(-1), compared with 1.25% yr(-1) in a nearby control plot experiencing normal rainfall. Differences in stem mortality between plots were greatest in the largest (> 40 cm diameter at breast height (dbh)) size class (4.1% yr(-1) in the TFE and 1.4% yr(-1) in the control). Wood production in the TFE plot was c. 30% lower than in the control plot. Together, these changes resulted in a loss of 37.8 +/- 2.0 Mg carbon (C) ha(-1) in the TFE plot (2002-2008), compared with no change in the control. *These results are remarkably consistent with those from another TFE (at Tapajós National Forest), suggesting that eastern Amazonian forests may respond to prolonged drought in a predictable manner.

Published

2010

9. The response of carbon assimilation and storage to long‐term drought in tropical trees is dependent on light availability.

Author

Rowland, Lucy, Costa, Antonio C. L., Oliveira, Rafael S., Bittencourt, Paulo R. L., Giles, André L., Coughlin, Ingrid, Britto Costa, Patricia, Bartholomew, David, Domingues, Tomas F., Miatto, Raquel C., Ferreira, Leandro V., Vasconcelos, Steel S., Junior, Joao A. S., Oliveira, Alex A. R., Mencuccini, Maurizio, Meir, Patrick, and Muller‐Landau, Helene

Subjects

FOREST declines, TREE mortality, MELANOPSIN, DROUGHTS, TROPICAL forests, FOREST microclimatology, TREES

Abstract

Whether tropical trees acclimate to long‐term drought stress remains unclear. This uncertainty is amplified if drought stress is accompanied by changes in other drivers such as the increases in canopy light exposure that might be induced by tree mortality or other disturbances.Photosynthetic capacity, leaf respiration, non‐structural carbohydrate (NSC) storage and stomatal conductance were measured on 162 trees at the world's longest running (15 years) tropical forest drought experiment. We test whether surviving trees have altered strategies for carbon storage and carbon use in the drier and elevated light conditions present following drought‐related tree mortality.Relative to control trees, the surviving trees experiencing the drought treatment showed functional responses including: (a) moderately reduced photosynthetic capacity; (b) increased total leaf NSC; and (c) a switch from starch to soluble sugars as the main store of branch NSC. This contrasts with earlier findings at this experiment of no change in photosynthetic capacity or NSC storage. The changes detected here only occurred in the subset of drought‐stressed trees with canopies exposed to high radiation and were absent in trees with less‐exposed canopies and also in the community average. In contrast to previous results acquired through less intensive species sampling from this experiment, we also observe no species‐average drought‐induced change in leaf respiration.Our results suggest that long‐term responses to drought stress are strongly influenced by a tree's full‐canopy light environment and therefore that disturbance‐induced changes in stand density and dynamics are likely to substantially impact tropical forest responses to climate change. We also demonstrate that, while challenging, intensive sampling is essential in tropical forests to avoid sampling biases caused by limited taxonomic coverage. A free Plain Language Summary can be found within the Supporting Information of this article. [ABSTRACT FROM AUTHOR]

Published

2021

10. Small tropical forest trees have a greater capacity to adjust carbon metabolism to long‐term drought than large canopy trees.

Author

Bartholomew, David C., Bittencourt, Paulo R. L., Costa, Antonio C. L., Banin, Lindsay F., Britto Costa, Patrícia, Coughlin, Sarah I., Domingues, Tomas F., Ferreira, Leandro V., Giles, André, Mencuccini, Maurizio, Mercado, Lina, Miatto, Raquel C., Oliveira, Alex, Oliveira, Rafael, Meir, Patrick, and Rowland, Lucy

Subjects

LEAF physiology, CARBON metabolism, TROPICAL forests, DROUGHTS, FOREST dynamics, PHENOTYPIC plasticity, WATER supply

Abstract

The response of small understory trees to long‐term drought is vital in determining the future composition, carbon stocks and dynamics of tropical forests. Long‐term drought is, however, also likely to expose understory trees to increased light availability driven by drought‐induced mortality. Relatively little is known about the potential for understory trees to adjust their physiology to both decreasing water and increasing light availability. We analysed data on maximum photosynthetic capacity (Jmax, Vcmax), leaf respiration (Rleaf), leaf mass per area (LMA), leaf thickness and leaf nitrogen and phosphorus concentrations from 66 small trees across 12 common genera at the world's longest running tropical rainfall exclusion experiment and compared responses to those from 61 surviving canopy trees. Small trees increased Jmax, Vcmax, Rleaf and LMA (71, 29, 32, 15% respectively) in response to the drought treatment, but leaf thickness and leaf nutrient concentrations did not change. Small trees were significantly more responsive than large canopy trees to the drought treatment, suggesting greater phenotypic plasticity and resilience to prolonged drought, although differences among taxa were observed. Our results highlight that small tropical trees have greater capacity to respond to ecosystem level changes and have the potential to regenerate resilient forests following future droughts. Small understory trees are able to modify their leaf functional traits under drought conditions to elevated light availability, including increasing photosynthetic capacity and respiration. Small trees are more responsive to prolonged drought than large canopy trees of the same taxa. At the world's longest running tropical forest throughfall exclusion experiment in Eastern Amazonia, mortality of large canopy trees has increased the light availability in the understory. Despite reduced water availability, trees in the understory show positive responses to increased light, including elevated photosynthetic capacity and respiration. This suggests small trees are able to adapt to drought conditions and could grow to become the next generation of canopy trees. [ABSTRACT FROM AUTHOR]

Published

2020

11. Shock and stabilisation following long‐term drought in tropical forest from 15 years of litterfall dynamics.

Author

Rowland, Lucy, da Costa, Antonio C. L., Oliveira, Alex A. R., Almeida, Samuel S., Ferreira, Leandro V., Malhi, Yadvinder, Metcalfe, Dan B., Mencuccini, Maurizio, Grace, John, and Meir, Patrick

Subjects

TROPICAL forests, FOREST litter, DROUGHTS, PHOTOSYNTHESIS -- Environmental aspects, CLIMATE change

Abstract

Abstract: Litterfall dynamics in tropical forests are a good indicator of overall tropical forest function, indicative of carbon invested in both photosynthesising tissues and reproductive organs such as flowers and fruits. These dynamics are sensitive to changes in climate, such as drought, but little is known about the long‐term responses of tropical forest litterfall dynamics to extended drought stress. We present a 15‐year dataset of litterfall (leaf, flower and fruit, and twigs) from the world's only long‐running drought experiment in tropical forest. This dataset comprises one of the longest published litterfall time series in natural forest, which allows the long‐term effects of drought on forest reproduction and canopy investment to be explored. Over the first 4 years of the experiment, the experimental soil moisture deficit created only a small decline in total litterfall and leaf fall (12% and 13%, respectively), but a very strong initial decline in reproductive litterfall (flowers and fruits) of 54%. This loss of flowering and fruiting was accompanied by a de‐coupling of all litterfall patterns from seasonal climate variables. However, following >10 years of the experimental drought, flower and fruiting re‐stabilised at levels greater than in the control plot, despite high tree mortality in the drought plot. Litterfall relationships with atmospheric drivers were re‐established alongside a strong new apparent trade‐off between litterfall and tree growth. Synthesis. We demonstrate that this tropical forest went through an initial shock response during the first 4 years of intense drought, where reproductive effort was arrested and seasonal litterfall patterns were lost. However, following >10 years of experimental drought, this system appears to be re‐stabilising at a new functional state where reproduction is substantially elevated on a per tree basis; and there is a new strong trade‐off between investment in canopy production and wood production. [ABSTRACT FROM AUTHOR]

Published

2018

12. Drought stress and tree size determine stem CO2 efflux in a tropical forest.

Author

Rowland, Lucy, da Costa, Antonio C. L., Oliveira, Alex A. R., Oliveira, Rafael S., Bittencourt, Paulo L., Costa, Patricia B., Giles, Andre L., Sosa, Azul I., Coughlin, Ingrid, Godlee, John L., Vasconcelos, Steel S., Junior, João A. S., Ferreira, Leandro V., Mencuccini, Maurizio, and Meir, Patrick

Subjects

DROUGHTS, TREE size, EFFLUX (Microbiology), CLIMATE sensitivity, RAIN forests

Abstract

Summary: CO2 efflux from stems (CO2_stem) accounts for a substantial fraction of tropical forest gross primary productivity, but the climate sensitivity of this flux remains poorly understood. We present a study of tropical forest CO2_stem from 215 trees across wet and dry seasons, at the world's longest running tropical forest drought experiment site. We show a 27% increase in wet season CO2_stem in the droughted forest relative to a control forest. This was driven by increasing CO2_stem in trees 10–40 cm diameter. Furthermore, we show that drought increases the proportion of maintenance to growth respiration in trees > 20 cm diameter, including large increases in maintenance respiration in the largest droughted trees, > 40 cm diameter. However, we found no clear taxonomic influence on CO2_stem and were unable to accurately predict how drought sensitivity altered ecosystem scale CO2_stem, due to substantial uncertainty introduced by contrasting methods previously employed to scale CO2_stem fluxes. Our findings indicate that under future scenarios of elevated drought, increases in CO2_stem may augment carbon losses, weakening or potentially reversing the tropical forest carbon sink. However, due to substantial uncertainties in scaling CO2_stem fluxes, stand‐scale future estimates of changes in stem CO2 emissions remain highly uncertain. [ABSTRACT FROM AUTHOR]

Published

2018

13. Plasticity in leaf‐level water relations of tropical rainforest trees in response to experimental drought

Author

Maurizio Mencuccini, Antonio Carlos Lola da Costa, Alex A. R. Oliveira, Andrea Nardini, Lucy Rowland, Steel Silva Vasconcelos, Leandro Valle Ferreira, Oliver Binks, Patrick Meir, Bradley O. Christoffersen, Oliver Binks, University of Edinburgh, Patrick Meir, University of Edinburgh / Australian National University, Lucy Rowland, University of Edinburgh, Antonio Carlos Lola da Costa, UFPA, STEEL SILVA VASCONCELOS, CPATU, Alex Antonio Ribeiro de Oliveira, UFPA, Leandro Ferreira, MPEG, Bradley Christoffersen, Earth and Environmental Science, Los Alamos National Laboratory, Andrea Nardini, Universitá di Trieste, Maurizio Mencuccini, University of Edinburgh / ICREA at CREAF., Binks, Oliver, Meir, Patrick, Rowland, Lucy, da Costa, Antonio Carlos Lola, Vasconcelos, Steel Silva, de Oliveira, Alex Antonio Ribeiro, Ferreira, Leandro, Christoffersen, Bradley, Nardini, Andrea, and Mencuccini, Maurizio

Subjects

0106 biological sciences, Rainforest, Plasticity, Amazon rainforest, Physiology, Osmotic adjustment, Turgor pressure, experimental drought, Water relation, Climate change, Plant Science, Biology, Relações hídricas, 010603 evolutionary biology, 01 natural sciences, Spongy tissue, Pressure, Osmotic pressure, Water content, Probability, Full Paper, Leaf anatomy, Ecology, Research, fungi, Tropics, food and beverages, Water, osmotic adjustment, 15. Life on land, Full Papers, Models, Theoretical, Experimental drought, Droughts, Plasticidade, Plant Leaves, Agronomy, plasticity, Anatomia foliar, Linear Models, leaf anatomy, Seca experimental, Seasons, water relations, Water relations, 010606 plant biology & botany, Tropical rainforest

Abstract

Summary The tropics are predicted to become warmer and drier, and understanding the sensitivity of tree species to drought is important for characterizing the risk to forests of climate change. This study makes use of a long‐term drought experiment in the Amazon rainforest to evaluate the role of leaf‐level water relations, leaf anatomy and their plasticity in response to drought in six tree genera.The variables (osmotic potential at full turgor, turgor loss point, capacitance, elastic modulus, relative water content and saturated water content) were compared between seasons and between plots (control and through‐fall exclusion) enabling a comparison between short‐ and long‐term plasticity in traits. Leaf anatomical traits were correlated with water relation parameters to determine whether water relations differed among tissues.The key findings were: osmotic adjustment occurred in response to the long‐term drought treatment; species resistant to drought stress showed less osmotic adjustment than drought‐sensitive species; and water relation traits were correlated with tissue properties, especially the thickness of the abaxial epidermis and the spongy mesophyll.These findings demonstrate that cell‐level water relation traits can acclimate to long‐term water stress, and highlight the limitations of extrapolating the results of short‐term studies to temporal scales associated with climate change.

Published

2016