Your search keyword '"Mark G. Tjoelker"' showing total 150 results

1. Aridity drives clinal patterns in leaf traits and responsiveness to precipitation in a broadly distributed Australian tree species

Author

Michael J. Aspinwall, Chris J. Blackman, Chelsea Maier, Mark G. Tjoelker, Paul D. Rymer, Danielle Creek, Jeff Chieppa, Robert J. Griffin‐Nolan, and David T. Tissue

Subjects

General Agricultural and Biological Sciences

Published

2023

2. Thermal acclimation of leaf respiration is consistent in tropical and subtropical populations of two mangrove species

Author

Jeff Chieppa, Ilka C Feller, Kylie Harris, Susannah Dorrance, Matthew A Sturchio, Eve Gray, Mark G Tjoelker, and Michael J Aspinwall

Subjects

Physiology, Plant Science

Abstract

Populations from different climates often show unique growth responses to temperature, reflecting temperature adaptation. Yet, whether populations from different climates differ in physiological temperature acclimation remains unclear. Here, we test whether populations from differing thermal environments exhibit different growth responses to temperature and differences in temperature acclimation of leaf respiration. We grew tropical and subtropical populations of two mangrove species (Avicennia germinans and Rhizophora mangle) under ambient and experimentally warmed conditions in a common garden at the species’ northern range limit. We quantified growth and temperature responses of leaf respiration (R) at seven time points over ~10 months. Warming increased productivity of tropical populations more than subtropical populations, reflecting a higher temperature optimum for growth. In both species, R measured at 25 °C declined as seasonal temperatures increased, demonstrating thermal acclimation. Contrary to our expectations, acclimation of R was consistent across populations and temperature treatments. However, populations differed in adjusting the temperature sensitivity of R (Q10) to seasonal temperatures. Following a freeze event, tropical Avicennia showed greater freeze damage than subtropical Avicennia, while both Rhizophora populations appeared equally susceptible. We found evidence of temperature adaptation at the whole-plant scale but little evidence for population differences in thermal acclimation of leaf physiology. Studies that examine potential costs and benefits of thermal acclimation in an evolutionary context may provide new insights into limits of thermal acclimation.

Published

2023

3. Belowground carbon allocation, root trait plasticity, and productivity during drought and warming in a pasture grass

Author

Manjunatha H Chandregowda, Mark G Tjoelker, Elise Pendall, Haiyang Zhang, Amber C Churchill, and Sally A Power

Subjects

Physiology, Plant Science

Abstract

Sustaining grassland production in a changing climate requires an understanding of plant adaptation strategies, including trait plasticity under warmer and drier conditions. However, our knowledge to date disproportionately relies on aboveground responses, despite the importance of belowground traits in maintaining aboveground growth, especially in grazed systems. We subjected a perennial pasture grass, Festuca arundinacea, to year-round warming (+3 °C) and cool-season drought (60% rainfall reduction) in a factorial field experiment to test the hypotheses that: (i) drought and warming increase carbon allocation belowground and shift root traits towards greater resource acquisition and (ii) increased belowground carbon reserves support post-drought aboveground recovery. Drought and warming reduced plant production and biomass allocation belowground. Drought increased specific root length and reduced root diameter in warmed plots but increased root starch concentrations under ambient temperature. Higher diameter and soluble sugar concentrations of roots and starch storage in crowns explained aboveground production under climate extremes. However, the lack of association between post-drought aboveground biomass and belowground carbon and nitrogen reserves contrasted with our predictions. These findings demonstrate that root trait plasticity and belowground carbon reserves play a key role in aboveground production during climate stress, helping predict pasture responses and inform management decisions under future climates.

Published

2023

4. Climate change increases global risk to urban forests

Author

Manuel Esperon-Rodriguez, Mark G. Tjoelker, Jonathan Lenoir, John B. Baumgartner, Linda J. Beaumont, David A. Nipperess, Sally A. Power, Benoît Richard, Paul D. Rymer, and Rachael V. Gallagher

Subjects

Environmental Science (miscellaneous), Social Sciences (miscellaneous)

Published

2022

5. Root trait shifts towards an avoidance strategy promote productivity and recovery in <scp> C 3 </scp> and <scp> C 4 </scp> pasture grasses under drought

Author

Manjunatha H. Chandregowda, Mark G. Tjoelker, Elise Pendall, Haiyang Zhang, Amber C. Churchill, and Sally A. Power

Subjects

Ecology, Evolution, Behavior and Systematics

Published

2022

6. Increasing aridity will not offset CO2fertilization in fast‐growing eucalypts with access to deep soil water

Author

Daniel Nadal-Sala, Belinda E. Medlyn, David T. Tissue, Craig V. M. Barton, David S. Ellsworth, Mark G. Tjoelker, Nadine K. Ruehr, Santi Sabaté, and Carles Gracia

Subjects

0106 biological sciences, Limiting factor, Global and Planetary Change, Irrigation, Eucalyptus saligna, 010504 meteorology & atmospheric sciences, Ecology, biology, Vapour Pressure Deficit, Primary production, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Nutrient, Agronomy, Soil water, Environmental Chemistry, Environmental science, Soil horizon, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Rising atmospheric [CO2 ] (Ca ) generally enhances tree growth if nutrients are not limiting. However, reduced water availability and elevated evaporative demand may offset such fertilization. Trees with access to deep soil water may be able to mitigate such stresses and respond more positively to Ca . Here, we sought to evaluate how increased vapor pressure deficit and reduced precipitation are likely to modify the impact of elevated Ca (eCa ) on tree productivity in an Australian Eucalyptus saligna Sm. plantation with access to deep soil water. We parameterized a forest growth simulation model (GOTILWA+) using data from two field experiments on E. saligna: a 2-year whole-tree chamber experiment with factorial Ca (ambient =380, elevated =620 μmol mol-1 ) and watering treatments, and a 10-year stand-scale irrigation experiment. Model evaluation showed that GOTILWA+ can capture the responses of canopy C uptake to (1) rising vapor pressure deficit (D) under both Ca treatments; (2) alterations in tree water uptake from shallow and deep soil layers during soil dry-down; and (3) the impact of irrigation on tree growth. Simulations suggest that increasing Ca up to 700 μmol mol-1 alone would result in a 33% increase in annual gross primary production (GPP) and a 62% increase in biomass over 10 years. However, a combined 48% increase in D and a 20% reduction in precipitation would halve these values. Our simulations identify high D conditions as a key limiting factor for GPP. They also suggest that rising Ca will compensate for increasing aridity limitations in E. saligna trees with access to deep soil water under non-nutrient limiting conditions, thereby reducing the negative impacts of global warming upon this eucalypt species. Simulation models not accounting for water sources available to deep-rooting trees are likely to overestimate aridity impacts on forest productivity and C stocks.

Published

2021

7. Crown dieback and mortality of urban trees linked to heatwaves during extreme drought

Author

Renée M. Marchin, Manuel Esperon-Rodriguez, Mark G. Tjoelker, and David S. Ellsworth

Subjects

Plant Leaves, Environmental Engineering, Climate Change, Environmental Chemistry, Forests, Pollution, Waste Management and Disposal, Droughts, Trees

Abstract

Cities have been described as 'heat islands' and 'dry islands' due to hotter, drier air in urban areas, relative to the surrounding landscape. As climate change intensifies, the health of urban trees will be increasingly impacted. Here, we posed the question: Is it possible to predict urban tree species mortality using (1) species climate envelopes and (2) plant functional traits? To answer these, we tracked patterns of crown dieback and recovery for 23 common urban tree and shrub species in Sydney, Australia during the record-breaking austral 2019-2020 summer. We identified 10 heat-tolerant species including five native and five exotic species, which represent climate-resilient options for urban plantings that are likely to continue to thrive for decades. Thirteen species were considered vulnerable to adverse conditions due to their mortality, poor health leading to tree removal, and/or extensive crown dieback. Crown dieback increased with increasing precipitation of the driest month of species climate of origin, suggesting that species from dry climates may be better suited for urban forests in future climates. We effectively grouped species according to their drought strategy (i.e., tolerance versus avoidance) using a simple trait-based framework that was directly linked with species mortality. The seven most climate-vulnerable species used a drought-avoidance strategy, having low wood density and high turgor loss points along with large, thin leaves with low heat tolerance. Overall, plant functional traits were better than species climate envelopes at explaining crown dieback. Recovery after stress required two mild, wet years for most species, resulting in prolonged loss of cooling benefits as well as economic losses due to replacement of dead/damaged trees. Hotter, longer, and more frequent heatwaves will require selection of more climate-resilient species in urban forests, and our results suggest that future research should focus on plant thermal traits to improve prediction models and species selection.

Published

2022

8. Ecotrons: Powerful and versatile ecosystem analysers for ecology, agronomy and environmental science

Author

George A. Kowalchuk, Jörg-Peter Schnitzler, Clément Piel, Wolfgang W. Weisser, Nicolas Brüggemann, Jean-François Le Galliard, Samuel Abiven, Stuart H Larsen, Teis Nørgaard Mikkelsen, Sarah Garré, Florent Massol, Hans J. De Boeck, Ivan Nijs, Joana Sauze, Bernard Longdoz, Alexandru Milcu, Natalie Beenaerts, Nico Eisenhauer, Timo Domisch, Matteo Dainese, Francois Rineau, Thomas Pütz, Richard L. Jasoni, Andrea Ghirardo, John A. Arnone, Leonardo H. Teixeira, Vincent Leemans, Alban Gebler, Georg Niedrist, Damien Landais, Craig V. M. Barton, J. Barbro Winkler, Olivier Ravel, Jacques Roy, Mark G. Tjoelker, Anja Schmidt, Écotron Européen de Montpellier, Centre National de la Recherche Scientifique (CNRS), CEREEP-Ecotron Ile de France (UMS 3194), Département de Biologie - ENS Paris, École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Institut d'écologie et des sciences de l'environnement de Paris (iEES Paris ), Institut de Recherche pour le Développement (IRD)-Sorbonne Université (SU)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Centre d’Ecologie Fonctionnelle et Evolutive (CEFE), Université Paul-Valéry - Montpellier 3 (UPVM)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud])-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Sub Ecology and Biodiversity, Ecology and Biodiversity, École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL), Institut de Recherche pour le Développement (IRD)-Sorbonne Université (SU)-Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Université Paul-Valéry - Montpellier 3 (UPVM)-École Pratique des Hautes Études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud])-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Institut Agro - Montpellier SupAgro, Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), and Université Paul-Valéry - Montpellier 3 (UPVM)-École pratique des hautes études (EPHE)

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Process (engineering), Ecology (disciplines), Biodiversity, 010603 evolutionary biology, 01 natural sciences, Natural (archaeology), Soil, experimentation, [SDV.EE.ECO]Life Sciences [q-bio]/Ecology, environment/Ecosystems, environmental simulations, Environmental Science(all), ddc:570, Environmental Chemistry, Ecosystem, controlled environment facilities, Biology, global change, biodiversity, 0105 earth and related environmental sciences, General Environmental Science, 2. Zero hunger, Global and Planetary Change, Ecology, [SDE.IE]Environmental Sciences/Environmental Engineering, business.industry, Environmental resource management, Research Review, Global change, 15. Life on land, research infrastructures, ecosystem process measurements, ddc, Variety (cybernetics), Chemistry, 13. Climate action, Controlled Environment Facilities, Ecosystem Functioning, Ecosystem Process Measurements, Environmental Simulations, Experimentation, Global Change, Research Infrastructures, ecosystem functioning, Complementarity (molecular biology), Environmental Science, Environmental science, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, business

Abstract

Ecosystems integrity and services are threatened by anthropogenic global changes. Mitigating and adapting to these changes require knowledge of ecosystem functioning in the expected novel environments, informed in large part through experimentation and modelling. This paper describes 13 advanced controlled environment facilities for experimental ecosystem studies, herein termed ecotrons, open to the international community. Ecotrons enable simulation of a wide range of natural environmental conditions in replicated and independent experimental units while measuring various ecosystem processes. This capacity to realistically control ecosystem environments is used to emulate a variety of climatic scenarios and soil conditions, in natural sunlight or through broad‐spectrum lighting. The use of large ecosystem samples, intact or reconstructed, minimizes border effects and increases biological and physical complexity. Measurements of concentrations of greenhouse trace gases as well as their net exchange between the ecosystem and the atmosphere are performed in most ecotrons, often quasi continuously. The flow of matter is often tracked with the use of stable isotope tracers of carbon and other elements. Equipment is available for measurements of soil water status as well as root and canopy growth. The experiments ran so far emphasize the diversity of the hosted research. Half of them concern global changes, often with a manipulation of more than one driver. About a quarter deal with the impact of biodiversity loss on ecosystem functioning and one quarter with ecosystem or plant physiology. We discuss how the methodology for environmental simulation and process measurements, especially in soil, can be improved and stress the need to establish stronger links with modelling in future projects. These developments will enable further improvements in mechanistic understanding and predictive capacity of ecotron research which will play, in complementarity with field experimentation and monitoring, a crucial role in exploring the ecosystem consequences of environmental changes., Experimentation and modelling are necessary to predict ecosystem functioning under future environments and to develop mitigating and adapting strategies. This paper describes 13 advanced controlled environment facilities, called ecotrons, open to the international community. An ecotron comprises a set of replicated enclosures designed to host ecosystems samples and enable realistic simulations of above‐ and belowground environmental conditions, while simultaneously and automatically measuring ecosystem processes. The characteristics of these infrastructures are given as well as examples of collaborative projects hosted so far.

Published

2021

9. Water availability drives fine root dynamics in a Eucalyptus woodland under elevated atmospheric CO 2 concentration

Author

Sally A. Power, Mark G. Tjoelker, John E. Drake, Raúl Ochoa-Hueso, and Juan Piñeiro

Subjects

Agronomy, Co2 concentration, Woodland, Biology, Eucalyptus, Water content, Ecology, Evolution, Behavior and Systematics, Carbon cycle

Published

2020

10. No evidence of homeostatic regulation of leaf temperature in Eucalyptus parramattensis trees: integration of CO 2 flux and oxygen isotope methodologies

Author

John E. Drake, Margaret M. Barbour, Richard Harwood, Craig V. M. Barton, Peter B. Reich, Mark G. Tjoelker, and Angelica Vårhammar

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Vapour Pressure Deficit, Chemistry, Plant Science, Thermoregulation, Photosynthesis, Atmospheric sciences, 01 natural sciences, Degree (temperature), Carbon cycle, 03 medical and health sciences, Light intensity, 030104 developmental biology, Poikilotherm, Homeothermy, 010606 plant biology & botany

Abstract

Thermoregulation of leaf temperature (Tleaf ) may foster metabolic homeostasis in plants, but the degree to which Tleaf is moderated, and under what environmental contexts, is a topic of debate. Isotopic studies inferred the temperature of photosynthetic carbon assimilation to be a constant value of c. 20°C; by contrast, leaf biophysical theory suggests a strong dependence of Tleaf on environmental drivers. Can this apparent disparity be reconciled? We continuously measured Tleaf and whole-crown net CO2 uptake for Eucalyptus parramattensis trees growing in field conditions in whole-tree chambers under ambient and +3°C warming conditions, and calculated assimilation-weighted leaf temperature (TL-AW ) across 265 d, varying in air temperature (Tair ) from -1 to 45°C. We compared these data to TL-AW derived from wood cellulose δ18 O. Tleaf exhibited substantial variation driven by Tair , light intensity, and vapor pressure deficit, and Tleaf was strongly linearly correlated with Tair with a slope of c. 1.0. TL-AW values calculated from cellulose δ18 O vs crown fluxes were remarkably consistent; both varied seasonally and in response to the warming treatment, tracking variation in Tair . The leaves studied here were nearly poikilothermic, with no evidence of thermoregulation of Tleaf towards a homeostatic value. Importantly, this work supports the use of cellulose δ18 O to infer TL-AW , but does not support the concept of strong homeothermic regulation of Tleaf.

Published

2020

11. Does root respiration in Australian rainforest tree seedlings acclimate to experimental warming?

Author

Stefan K. Arndt, Kristine Y. Crous, Mark G. Tjoelker, Zineb Choury, Peter B. Reich, Elise Pendall, Nam Jin Noh, Jinquan Li, and Craig V. M. Barton

Subjects

0106 biological sciences, Rainforest, Physiology, Cellular respiration, Acclimatization, Biome, Global warming, Australia, Temperature, Q10, Plant Science, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Trees, Degree (temperature), Plant Leaves, Horticulture, Seedlings, Respiration, 010606 plant biology & botany

Abstract

Plant respiration can acclimate to changing environmental conditions and vary between species as well as biome types, although belowground respiration responses to ongoing climate warming are not well understood. Understanding the thermal acclimation capacity of root respiration (Rroot) in relation to increasing temperatures is therefore critical in elucidating a key uncertainty in plant function in response to warming. However, the degree of temperature acclimation of Rroot in rainforest trees and how root chemical and morphological traits are related to acclimation is unknown. Here we investigated the extent to which respiration of fine roots (≤2 mm) of four tropical and four warm-temperate rainforest tree seedlings differed in response to warmer growth temperatures (control and +6 °C), including temperature sensitivity (Q10) and the degree of acclimation of Rroot. Regardless of biome type, we found no consistent pattern in the short-term temperature responses of Rroot to elevated growth temperature: a significant reduction in the temperature response of Rroot to +6 °C treatment was only observed for a tropical species, Cryptocarya mackinnoniana, whereas the other seven species had either some stimulation or no alteration. Across species, Rroot was positively correlated with root tissue nitrogen concentration (mg g−1), while Q10 was positively correlated with root tissue density (g cm−3). Warming increased root tissue density by 20.8% but did not alter root nitrogen across species. We conclude that thermal acclimation capacity of Rroot to warming is species-specific and suggest that root tissue density is a useful predictor of Rroot and its thermal responses in rainforest tree seedlings.

Published

2020

12. Nocturnal plant respiration is under strong non-temperature control

Author

Dan Bruhn, Freya Newman, Mathilda Hancock, Peter Povlsen, Martijn Slot, Stephen Sitch, John Drake, Graham P. Weedon, Douglas B. Clark, Majken Pagter, Richard J. Ellis, Mark G. Tjoelker, Kelly M. Andersen, Zorayda Restrepo Correa, Patrick C. McGuire, and Lina M. Mercado

Subjects

Plant Leaves, Multidisciplinary, Respiration, Temperature, General Physics and Astronomy, General Chemistry, Carbon Dioxide, Plants, Ecology and Environment, General Biochemistry, Genetics and Molecular Biology, Ecosystem, Trees

Abstract

Most biological rates depend on the rate of respiration. Temperature variation is typically considered the main driver of daily plant respiration rates, assuming a constant daily respiration rate at a set temperature. Here, we show empirical data from 31 species from temperate and tropical biomes to demonstrate that the rate of plant respiration at a constant temperature decreases monotonically with time through the night, on average by 25% after 8 h of darkness. Temperature controls less than half of the total nocturnal variation in respiration. A new universal formulation is developed to model and understand nocturnal plant respiration, combining the nocturnal decrease in the rate of plant respiration at constant temperature with the decrease in plant respiration according to the temperature sensitivity. Application of the new formulation shows a global reduction of 4.5 −6 % in plant respiration and an increase of 7-10% in net primary production for the present-day.

Published

2022

13. Tree crown traits and planting context contribute to reducing urban heat

Author

Mahmuda Sharmin, Mark G. Tjoelker, Sebastian Pfautsch, Manuel Esperon-Rodriguez, Paul D. Rymer, and Sally A. Power

Subjects

Ecology, Soil Science, Forestry

Published

2023

14. Tree Traits and Microclimatic Conditions Determine Cooling Benefits of Urban Trees

Author

Mahmuda Sharmin, Mark G. Tjoelker, Sebastian Pfautsch, Manuel Esperón-Rodriguez, Paul D. Rymer, and Sally A. Power

Subjects

air temperature, Australia, solar irradiance, tree species, urban heat, vapor pressure deficit, Atmospheric Science, Environmental Science (miscellaneous)

Abstract

Trees play a key role in mitigating urban heat by cooling the local environment. This study evaluated the extent to which street trees can reduce sub-canopy air temperature relative to ambient conditions (ΔT), and how ΔT relates to tree traits and microclimatic variables. Air temperature under the canopies of 10 species was recorded within residential areas in Western Sydney, Australia, during summer 2019–2020. Tree and canopy traits, namely tree height, specific leaf area, leaf dry matter content, leaf area index, crown width and the Huber value (the ratio of sapwood area to leaf area) were then measured for all species. Species differed significantly in their ΔT values, with peak cooling (maximum ΔT −3.9 °C) observed between 9–10 am and sub-canopy warming (i.e., positive ΔT values) typically occurring during afternoon and overnight. Trees with high LAI and wider canopies were associated with the greatest daytime cooling benefits and lower levels of nighttime warming. ΔT was also negatively related to windspeed and vapor pressure deficit, and positively to solar irradiance. This study provides valuable information on how tree characteristics and microclimate influence potential cooling benefits that may aid planning decisions on the use of trees to mitigate heat in urban landscapes.

Published

2023

15. Drought and warming alter gross primary production allocation and reduce productivity in a widespread pasture grass

Author

Manjunatha H. Chandregowda, Mark G. Tjoelker, Sally A. Power, and Elise Pendall

Subjects

Plant Leaves, Physiology, Plant Science, Biomass, Carbon Dioxide, Plants, Poaceae, Carbon, Ecosystem, Carbon Cycle, Droughts

Abstract

Carbon allocation determines plant growth, fitness and reproductive success. However, climate warming and drought impacts on carbon allocation patterns in grasses are not well known, particularly following grazing or clipping. A widespread C

Published

2022

16. Extreme heat increases stomatal conductance and drought-induced mortality risk in vulnerable plant species

Author

Alessandro Ossola, David S. Ellsworth, Michelle R. Leishman, Mark G. Tjoelker, Diana Backes, and Renée M. Marchin

Subjects

0106 biological sciences, Stomatal conductance, thermal safety margin, ved/biology.organism_classification_rank.species, Turgor pressure, Biology, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, Shrub, heatwave, Xylem, Environmental Chemistry, Leaf size, leaf critical temperature, high temperature tolerance, General Environmental Science, Global and Planetary Change, Ecology, ved/biology, fungi, Crown (botany), drought stress, food and beverages, Water, Extreme Heat, Plant Transpiration, 15. Life on land, Evergreen, Biological Sciences, Droughts, Plant Leaves, water deficit experiment, Agronomy, Clean Water and Sanitation, 13. Climate action, Plant Stomata, Environmental Sciences, 010606 plant biology & botany

Abstract

Tree mortality during global-change-type drought is usually attributed to xylem dysfunction, but as climate change increases the frequency of extreme heat events, it is necessary to better understand the interactive role of heat stress. We hypothesized that some drought-stressed plants paradoxically open stomata in heatwaves to prevent leaves from critically overheating. We experimentally imposed heat (>40°C) and drought stress onto 20 broadleaf evergreen tree/shrub species in a glasshouse study. Most well-watered plants avoided lethal overheating, but drought exacerbated thermal damage during heatwaves. Thermal safety margins (TSM) quantifying the difference between leaf surface temperature and leaf critical temperature, where photosynthesis is disrupted, identified species vulnerability to heatwaves. Several mechanisms contributed to high heat tolerance and avoidance of damaging leaf temperatures-small leaf size, low leaf osmotic potential, high leaf mass per area (i.e., thick, dense leaves), high transpirational capacity, and access to water. Water-stressed plants had smaller TSM, greater crown dieback, and a fundamentally different stomatal heatwave response relative to well-watered plants. On average, well-watered plants closed stomata and decreased stomatal conductance (gs ) during the heatwave, but droughted plants did not. Plant species with low gs , either due to isohydric stomatal behavior under water deficit or inherently low transpirational capacity, opened stomata and increased gs under high temperatures. The current paradigm maintains that stomata close before hydraulic thresholds are surpassed, but our results suggest that isohydric species may dramatically increase gs (over sixfold increases) even past their leaf turgor loss point. By actively increasing water loss at high temperatures, plants can be driven toward mortality thresholds more rapidly than has been previously recognized. The inclusion of TSM and responses to heat stress could improve our ability to predict the vulnerability of different tree species to future droughts.

Published

2022

17. Tropical rainforest species have larger increases in temperature optima with warming than warm-temperate rainforest trees

Author

Zineb Choury, Agnieszka Wujeska‐Klause, Aimee Bourne, Nikki P. Bown, Mark G. Tjoelker, Belinda E. Medlyn, and Kristine Y. Crous

Subjects

Plant Leaves, Tropical Climate, Rainforest, Physiology, Acclimatization, Australia, Temperature, Plant Science, Carbon Dioxide, Photosynthesis, Trees

Abstract

While trees can acclimate to warming, there is concern that tropical rainforest species may be less able to acclimate because they have adapted to a relatively stable thermal environment. Here we tested whether the physiological adjustments to warming differed among Australian tropical, subtropical and warm-temperate rainforest trees. Photosynthesis and respiration temperature responses were quantified in six Australian rainforest seedlings of tropical, subtropical and warm-temperate climates grown across four growth temperatures in a glasshouse. Temperature-response models were fitted to identify mechanisms underpinning the response to warming. Tropical and subtropical species had higher temperature optima for photosynthesis (T

Published

2022

18. Pastures and Climate Extremes: Impacts of Cool Season Warming and Drought on the Productivity of Key Pasture Species in a Field Experiment

Author

Amber C. Churchill, Haiyang Zhang, Kathryn J. Fuller, Burhan Amiji, Ian C. Anderson, Craig V. M. Barton, Yolima Carrillo, Karen L. M. Catunda, Manjunatha H. Chandregowda, Chioma Igwenagu, Vinod Jacob, Gil Won Kim, Catriona A. Macdonald, Belinda E. Medlyn, Ben D. Moore, Elise Pendall, Jonathan M. Plett, Alison K. Post, Jeff R. Powell, David T. Tissue, Mark G. Tjoelker, and Sally A. Power

Subjects

Plant Science

Abstract

Shifts in the timing, intensity and/or frequency of climate extremes, such as severe drought and heatwaves, can generate sustained shifts in ecosystem function with important ecological and economic impacts for rangelands and managed pastures. The Pastures and Climate Extremes experiment (PACE) in Southeast Australia was designed to investigate the impacts of a severe winter/spring drought (60% rainfall reduction) and, for a subset of species, a factorial combination of drought and elevated temperature (ambient +3°C) on pasture productivity. The experiment included nine common pasture and Australian rangeland species from three plant functional groups (C3 grasses, C4 grasses and legumes) planted in monoculture. Winter/spring drought resulted in productivity declines of 45% on average and up to 74% for the most affected species (Digitaria eriantha) during the 6-month treatment period, with eight of the nine species exhibiting significant yield reductions. Despite considerable variation in species’ sensitivity to drought, C4 grasses were more strongly affected by this treatment than C3 grasses or legumes. Warming also had negative effects on cool-season productivity, associated at least partially with exceedance of optimum growth temperatures in spring and indirect effects on soil water content. The combination of winter/spring drought and year-round warming resulted in the greatest yield reductions. We identified responses that were either additive (Festuca), or less-than-additive (Medicago), where warming reduced the magnitude of drought effects. Results from this study highlight the sensitivity of diverse pasture species to increases in winter and spring drought severity similar to those predicted for this region, and that anticipated benefits of cool-season warming are unlikely to be realized. Overall, the substantial negative impacts on productivity suggest that future, warmer, drier climates will result in shortfalls in cool-season forage availability, with profound implications for the livestock industry and natural grazer communities.

Published

2021

19. The temperature optima for tree seedling photosynthesis and growth depend on water inputs

Author

Belinda E. Medlyn, Angelica Vårhammar, Dushan Kumarathunge, Sebastian Pfautsch, Rosana López, Mark G. Tjoelker, and John E. Drake

Subjects

0106 biological sciences, Global and Planetary Change, Biomass (ecology), 010504 meteorology & atmospheric sciences, Ecology, biology, Specific leaf area, Global warming, Plant physiology, Photosynthesis, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Indirect effect, Agronomy, Seedling, Respiration, Environmental Chemistry, Environmental science, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Understanding how tree growth is affected by rising temperature is a key to predicting the fate of forests in future warmer climates. Increasing temperature has direct effects on plant physiology, but there are also indirect effects of increased water limitation because evaporative demand increases with temperature in many systems. In this study, we experimentally resolved the direct and indirect effects of temperature on the response of growth and photosynthesis of the widely distributed species Eucalyptus tereticornis. We grew E. tereticornis in an array of six growth temperatures from 18 to 35.5°C, spanning the climatic distribution of the species, with two watering treatments: (a) water inputs increasing with temperature to match plant demand at all temperatures (Wincr ), isolating the direct effect of temperature; and (b) water inputs constant for all temperatures, matching demand for coolest grown plants (Wconst ), such that water limitation increased with growth temperature. We found that constant water inputs resulted in a reduction of temperature optima for both photosynthesis and growth by ~3°C compared to increasing water inputs. Water limitation particularly reduced the total amount of leaf area displayed at Topt and intermediate growth temperatures. The reduction in photosynthesis could be attributed to lower leaf water potential and consequent stomatal closure. The reduction in growth was a result of decreased photosynthesis, reduced total leaf area display and a reduction in specific leaf area. Water availability had no effect on the response of stem and root respiration to warming, but we observed lower leaf respiration rates under constant water inputs compared to increasing water inputs at higher growth temperatures. Overall, this study demonstrates that the indirect effect of increasing water limitation strongly modifies the potential response of tree growth to rising global temperatures.

Published

2020

20. An extreme heatwave enhanced the xanthophyll de-epoxidation state in leaves of Eucalyptus trees grown in the field

Author

Namraj Dhami, John E. Drake, Mark G. Tjoelker, David T. Tissue, and Christopher I Cazzonelli

Subjects

0106 biological sciences, 0301 basic medicine, chemistry.chemical_classification, Physiology, Global warming, Plant physiology, Plant Science, 15. Life on land, Biology, Photosynthesis, 01 natural sciences, Acclimatization, Zeaxanthin, 03 medical and health sciences, chemistry.chemical_compound, Horticulture, 030104 developmental biology, chemistry, 13. Climate action, Xanthophyll, Molecular Biology, Carotenoid, 010606 plant biology & botany, Violaxanthin

Abstract

Heatwaves are becoming more frequent with climate warming and can impact tree growth and reproduction. Eucalyptus parramattensis can cope with an extreme heatwave in the field via transpiratory cooling and enhanced leaf thermal tolerance that protected foliar tissues from photo-inhibition and photo-oxidation during natural midday irradiance. Here, we explored whether changes in foliar carotenoids and/or the xanthophyll cycle state can facilitate leaf acclimation to long-term warming and/or an extreme heatwave event. We found that leaves had similar carotenoid levels when grown for one year under ambient and experimental long-term warming (+ 3 °C) conditions in whole tree chambers. Exposure to a 4-day heatwave (> 43 °C) significantly altered the xanthophyll de-epoxidation state of carotenoids revealing one mechanism by which trees could minimise foliar photo-oxidative damage. The levels of zeaxanthin were significantly higher in both young and old leaves during the heatwave, revealing that violaxanthin de-epoxidation and perhaps de novo zeaxanthin synthesis contributed to enhancement of the xanthophyll cycle state. In a future climate of long-term warming and increased heatwave events, leaves of E. parramattensis will be able to utilise biochemical strategies to alter the xanthophyll cycle state and cope with extreme temperatures under natural solar irradiation.

Published

2020

21. No evidence for triose phosphate limitation of light‐saturated leaf photosynthesis under current atmospheric CO2concentration

Author

Mark G. Tjoelker, Dushan Kumarathunge, John E. Drake, Alistair Rogers, and Belinda E. Medlyn

Subjects

0106 biological sciences, 0301 basic medicine, biology, Physiology, ved/biology, ved/biology.organism_classification_rank.species, RuBisCO, Biosphere, Plant Science, Phosphate, Photosynthesis, 01 natural sciences, Tundra, C3 photosynthesis, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Co2 concentration, Environmental chemistry, Terrestrial plant, biology.protein, 010606 plant biology & botany

Abstract

The triose phosphate utilization (TPU) rate has been identified as one of the processes that can limit terrestrial plant photosynthesis. However, we lack a robust quantitative assessment of TPU limitation of photosynthesis at the global scale. As a result, TPU, and its potential limitation of photosynthesis, is poorly represented in terrestrial biosphere models (TBMs). In this study, we utilized a global data set of photosynthetic CO2 response curves representing 141 species from tropical rainforests to Arctic tundra. We quantified TPU by fitting the standard biochemical model of C3 photosynthesis to measured photosynthetic CO2 response curves and characterized its instantaneous temperature response. Our results demonstrate that TPU does not limit leaf photosynthesis at the current ambient atmospheric CO2 concentration. Furthermore, our results showed that the light-saturated photosynthetic rates of plants growing in cold environments are not more often limited by TPU than those of plants growing in warmer environments. In addition, our study showed that the instantaneous temperature response of TPU is distinct from temperature response of the maximum rate of Rubisco carboxylation. The new formulations of the temperature response of TPU derived in this study may prove useful in quantifying the biochemical limits to terrestrial plant photosynthesis and improve the representation of plant photosynthesis in TBMs.

Published

2019

22. Assessing the vulnerability of Australia’s urban forests to climate extremes

Author

Hugh M. Burley, Mark G. Tjoelker, Dayenari Caballero-Rodríguez, Manuel Esperón-Rodríguez, Paul D. Rymer, Sally A. Power, and Linda J. Beaumont

Subjects

lcsh:GE1-350, landscape planting, Species selection, species selection, business.industry, Tree inventory, species composition, Environmental resource management, Species distribution, Vulnerability, Climate change, Forestry, Plant Science, Horticulture, lcsh:QK1-989, climate change, Geography, Urban planning, climate niche, lcsh:Botany, species distribution, business, Climate extremes, lcsh:Environmental sciences, Ecology, Evolution, Behavior and Systematics

Abstract

Societal Impact Statement Urban forests are recognized for the multiple benefits they provide to city‐dwellers. However, climate change will affect tree species survival and persistence in urban ecosystems. Tree failures will cause economic losses and jeopardize the delivery of societal benefits. The impacts of climate change will depend on the species’ resilience and adaptive capacity, as well as management actions which may ameliorate some of the negative impacts. Here, we assessed the potential vulnerability of Australia's urban forests to climate extremes. Our results can be used for future urban planning aiming to incorporate species that are well‐adapted to the hotter, drier climates expected with climate change. Summary Urban forests (UFs) are recognized for the multiple benefits they provide to city‐dwellers. However, global climate change—particularly predicted increases in the frequency and intensity of heatwaves and drought—will affect tree species’ performance and survival in urban ecosystems. Here, we assessed species composition and potential vulnerability of UFs in 22 Australian significant urban areas (SUAs) to heat and/or moisture stress. We quantified species’ realized climatic niches across their known distribution, and assessed the extent to which baseline climate in the SUAs where a particular species is planted fell within its niche. We used three environmental variables to group species based on their potential climate vulnerability. UFs varied in species composition and climate vulnerability across the continent. In general, neither climate similarity nor geographical proximity were good predictors of species composition among UFs. Of 1,342 tree species assessed (68.4% natives), 53% were considered potentially vulnerable to heat and/or moisture stress in at least one city where they are currently planted. Our results highlight the climate vulnerability of current plantings across Australian SUAs and can be used to direct future species selection that considers the species’ climate of origin and climatic niche. UF planning can incorporate species from SUAs with similar climates and with low vulnerability to contemporary, as well as future climate conditions. Species with high climate vulnerability, in contrast, may require more intensive management to avoid failure under future hotter, drier climate conditions.

Published

2019

23. Climate warming and tree carbon use efficiency in a whole‐tree 13 <scp>CO</scp> 2 tracer study

Author

Elise Pendall, Craig V. M. Barton, John E. Drake, Yolima Carrillo, Mark G. Tjoelker, and Morgan E. Furze

Subjects

2. Zero hunger, 0106 biological sciences, 0301 basic medicine, Biomass (ecology), Physiology, Global warming, Heterotrophic respiration, chemistry.chemical_element, Primary production, Plant Science, 15. Life on land, 01 natural sciences, Acclimatization, 03 medical and health sciences, 030104 developmental biology, chemistry, Agronomy, 13. Climate action, TRACER, Respiration, Environmental science, Carbon, 010606 plant biology & botany

Abstract

Autotrophic respiration is a major driver of the global C cycle and may contribute a positive climate warming feedback through increased atmospheric concentrations of CO2 . The extent of this feedback depends on plants' ability to acclimate respiration to maintain a constant carbon use efficiency (CUE). We quantified respiratory partitioning of gross primary production (GPP) and CUE of field-grown trees in a long-term warming experiment (+3°C). We delivered a 13 C-CO2 pulse to whole tree crowns and chased that pulse in the respiration of leaves, whole crowns, roots, and soil. We also measured the isotopic composition of soil microbial biomass and the respiration rates of leaves and whole crowns. We documented homeostatic respiratory acclimation of foliar and whole-crown respiration rates; the trees adjusted to experimental warming such that leaf-level respiration rates were not increased. Experimental warming had no detectable impact on respiratory partitioning or mean residence times. Of the 13 C label acquired by the trees, aboveground respiration consumed 10%, belowground respiration consumed 40%, and the remaining 50% was retained. Experimental warming of +3°C did not alter respiratory partitioning at the scale of entire trees, suggesting that complete acclimation of respiration to warming is likely to dampen a positive climate warming feedback.

Published

2019

24. Radially transmitted changes in hydraulic and osmotic pressures help explain reversible and irreversible patterns of tree stem expansion

Author

Michael J. Aspinwall, Maurizio Mencuccini, Drake J, David T. Tissue, Mark G. Tjoelker, Barton C, Dios VRd, Patrick Meir, and Sebastian Pfautsch

Subjects

Tree (data structure), Biological system, Mathematics

Abstract

It is easy to measure annual growth of a tree stem. It is hard to measure its daily growth. The reason for this difficulty is the microscopic scale and the need to separate processes that simultaneously result in reversible and irreversible stem expansion. Here we present a model that separates reversible from irreversible cell expansion. Our model is novel, because it explains reversible expansion as consequence of longitudinally and, importantly, radially transmitted changes of hydraulic and osmotic pressures in xylem and bark. To capture and quantify these changes, we manipulated daily stem growth by applying a phloem girdle to stems of 9-m tall trees. The model was informed by measurements of radial movement in stem tissues and sap flow before and after and positions below and above the girdle. Additional measurements of whole-crown fluxes of H2O and CO2, leaf water potentials, non-structural carbohydrates and respiration were used to document the physiological impacts of girdling. This work sheds new light on the role of radial transport processes underpinning daily growth of tree stems. The model helps explain diel patterns of stem growth in trees.

Published

2021

25. Climate-change risk analysis for global urban forests

Author

Rachael V. Gallagher, Jonathan Lenoir, John B. Baumgartner, Sally A. Power, Linda J. Beaumont, Mark G. Tjoelker, Manuel Esperón-Rodríguez, Paul D. Rymer, Richard B, and David A. Nipperess

Subjects

Risk analysis, Geography, Agroforestry, Plant species, Vulnerability, Climate change, Precipitation, Vegetation, Socioeconomic status, Latitude

Abstract

Urban forests (i.e. all vegetation present in urban areas), provide environmental and socio-economic benefits to more than half of the global population. Projected climate change threatens these benefits to society. Here, we assess vulnerability to climate change of 16,006 plant species present in the urban forests of 1,010 cities within 93 countries, using three vulnerability metrics: exposure, safety margin and risk. Exposure expresses the magnitude of projected changes in climate in a given area, safety margin measures species' sensitivity to climate change, and risk is the difference between exposure and safety margin. We identified 9,676 (60.5%) and 8,344 (52.1%) species exceeding their current climatic tolerance (i.e. safety margin) for mean annual temperature (MAT) and annual precipitation (AP), respectively. By 2050, 13,479 (84.2%) and 9,960 (62.2%) species are predicted to be at risk from projected changes in MAT and AP, respectively, with risk increasing in cities at lower latitudes. Our results can aid evaluation of the impacts of climate change on urban forests and identify the species most at risk. Considering future climates when selecting species for urban plantings will enhance the long-term societal benefits provided by urban forests, including their contribution to mitigating the magnitude and impacts of climate change.

Published

2021

26. Soil nitrogen and chronic ozone stress influence physiology, growth and nutrient status of Pinus taeda L. and Liriodendron tulipifera L. seedlings

Author

R. J. Luxmoore and Mark G. Tjoelker

Subjects

Stomatal conductance, Ozone, Physiology, Chemistry, fungi, food and beverages, Plant Science, Horticulture, chemistry.chemical_compound, Nutrient, Abscission, Dry weight, Botany, Shoot, Habit (biology), Dry matter

Abstract

summary The effects of soil nitrogen availability and chronic ozone stress on carbon and nutrient economy were investigated in loblolly pine (Pinus. taeda L.) and yellow-poplar (Liriodendron tulipifera L.). One-year-old seedlings were planted individually in pots in forest soil of low (58 μg g−1), medium (96 μg g−1) or high (172 μg g−1) initial concentrations of soluble nitrogen. The seedlings were exposed to ozone in open-top field chambers at sub-ambient (charcoal-filtered air), ambient, and elevated (ambient + 60 nl 1−1 O3) (32, 56, 108 nl 1−1 O3, 1 h seasonal mean, respectively) levels for 18 weeks. At final harvest loblolly pine dry matter increased by 50% at the highest soil K level relative to the low with the largest gains in new needle biomass. Elevated ozone reduced the biomass of current-year needles by 20% in plants grown at the highest N level. Higher soil N supply increased the concentration of nitrogen in needles, stimulated current-year needle photosynthesis and increased needle and whole-plant water-use efficiencies. Ozone treatment had no significant effect on photosynthesis or water-use efficiency in either species, although ozone exposure tended to reduce- stomatal conductance in loblolly pine. The low N treatment increased the proportion of dry matter allocated to fine roots in yellow-poplar, but whole-plant dry weight had not responded to N fertilization at the final harvest, suggesting other limitations on growth. Ozone exposure increased leaf abscission and doubled leaf turnover m yellow-poplar. Although yellow-poplar was highly sensitive to ozone-induced leaf abscission, final whole-plant dry weights were not affected. The indeterminate growth habit of yellow-poplar permitted compensatory leaf growth which may have ameliorated effects of chronic ozone stress on biomass gain. Ozone exposure also decreased shoot weight more than root weight, resulting in higher root:leaf ratios in loblolly pine and a similar trend m higher fine roor:leaf ratios in yellow-poplar. Greater proportional allocation of carbon to roots in response to nutrient deficiency may preclude an increased allocation to shoots often observed in response to air pollution stress. Interspecific differences in growth response to chronic ozone and nutrient stress may be influenced by differences in leaf growth habit.

Published

2021

27. Light environment alters response to ozone stress in seedlings of Acer saccharum Marsh, and hybrid Populus L.: II. Diagnostic gas exchange and leaf chemistry

Author

Mark G. Tjoelker, Peter B. Reich, John C. Volin, and Jacek Oleksyn

Subjects

Maple, Stomatal conductance, biology, Physiology, fungi, food and beverages, Plant Science, engineering.material, biology.organism_classification, Photosynthesis, chemistry.chemical_compound, Cutting, Horticulture, Salicaceae, chemistry, Aceraceae, Dry weight, Chlorophyll, Botany, engineering

Abstract

SUMMARY Hybrid poplar (Populus tristis Fisch. ×P. balsamifera L., cv. Tristis) and sugar maple (Acer saccharum Marsh.) seedlings were grown under contrasting light and ozone treatments to investigate the role of the light environment in their response to chronic ozone stress. In consecutive growth chamber experiments, cuttings of shade-intolerant poplar and 3-yr-old seedlings of shade-tolerant sugar maple were grown in pots for 6 and 10 wk, respectively, under shaded, low light irradiance (c. 2.5 mol m−2 d−1 PPFD or 7% of full sunlight) and six-fold greater irradiance (c. 16.6 mol m−2 d−1 PPFD or 45% of full sunlight) in combination with low (< 10 nl 1−1) and elevated levels of ozone (c. 99–115 nl 1−1). In unshaded poplar plants, ozone exposure reduced root dry mass by 33% at final harvest, while shaded plants had no such response. By comparison, sugar maple root dry mass was reduced by ozone in shaded plants by 10%, but was unaffected by ozone in unshaded plants. In poplar, leaf area: plant dry mass ratios were unaffected by ozone, whereas in sugar maple ozone-exposed plants had a 24% lower leaf area: plant dry mass ratio in the shaded treatment. In shade-grown sugar maple, ozone doubled dark respiration rates of leaves, but in unshaded seedlings ozone had no effect on respiration. In comparison, in poplar plants ozone exposure resulted in greater increases in dark respiration under unshaded than shaded conditions. In unshaded plants, ozone treatment resulted in lower in situ net photosynthesis in poplar, but not in sugar maple. Overall, shade-grown sugar maple appeared more sensitive to ozone stress than unshaded plants in terms of lower leaf area: plant dry mass ratio and root growth and higher leaf respiration. In poplar on the other hand, root growth, leaf respiration and photosynthesis were more affected by ozone in unshaded than in shaded plants. These findings suggest that shade-grown sugar maple and unshaded poplar may experience greater reductions in carbon gain and growth under elevated levels of ozone than plants under the opposite light conditions.

Published

2021

28. Concurrent Measurements of Soil and Ecosystem Respiration in a Mature Eucalypt Woodland: Advantages, Lessons, and Questions

Author

Eric A. Davidson, Stefan K. Arndt, Catriona A. Macdonald, Mark G. Tjoelker, Elise Pendall, Nam Jin Noh, J. E. Drake, Debjani Sihi, Alexandre A. Renchon, and Nina Hinko-Najera

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Ecology, Diurnal temperature variation, Eddy covariance, Paleontology, Soil Science, Forestry, Time resolution, Aquatic Science, Seasonality, medicine.disease, Atmospheric sciences, 01 natural sciences, Soil respiration, Respiration, medicine, Ecosystem respiration, Eucalypt woodland, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Understanding seasonal and diurnal dynamics of ecosystem respiration (Reco) in forests is challenging, because Reco can only be measured directly during night-time by eddy-covariance flux towers. Reco is the sum of soil respiration (Rsoil) and above-ground respiration (in theory, RAG = Reco − Rsoil). Rsoil can be measured day and night and can provide a check of consistency on Reco, as the difference in magnitude and time dynamic between Reco and Rsoil should be explained by RAG. We assessed the temporal patterns and climatic drivers of Rsoil and Reco in a mature eucalypt woodland, using continuous measurements (only at night for Reco) at half-hourly resolution over 4 years (2014–2017). Our data showed large seasonal and diurnal (overnight) variation of Reco, while Rsoil had a low diurnal amplitude and their difference (Reco − Rsoil, or RAG) had a low seasonal amplitude. This result implies at first glance that seasonal variation of Reco was mainly influenced by Rsoil while its diurnal variation was mainly influenced by RAG. However, our analysis suggests that the night-time Reco decline cannot realistically be explained by a decline of RAG. Chamber measurements of autotrophic components at half-hourly time resolution are needed to quantify how much of the Reco decline overnight is due to declines in leaf or stem respiration, and how much is due to missing storage or advection, which may create a systematic bias in Reco measurements. Our findings emphasize the need for reconciling bottom-up (via components measured with chambers) and direct estimates of Reco (via eddy-covariance method).

Published

2021

29. Pastures and Climate Extremes: Impacts of cool season warming and drought on the productivity of key pasture species in a field experiment

Author

Ian C. Anderson, Alison K. Post, Amber C. Churchill, Chioma Igwenagu, Catriona A. Macdonald, Benjamin D. Moore, Belinda E. Medlyn, Karen L. M. Catunda, Yolima Carrillo, Vinod Jacob, Burhan Amiji, Sally A. Power, Jonathan M. Plett, Elise Pendall, David T. Tissue, Kathryn J. Fuller, Jeff R. Powell, Gil Won Kim, Haiyang Zhang, Manjunatha H. Chandregowda, Mark G. Tjoelker, and Craig V. M. Barton

Subjects

geography, Biomass (ecology), geography.geographical_feature_category, biology, biology.organism_classification, Pasture, Agronomy, Productivity (ecology), Environmental science, Digitaria eriantha, Ecosystem, Monoculture, Rangeland, Annual percentage yield

Abstract

Shifts in the timing, intensity and/or frequency of climate extremes, such as severe drought and heatwaves, can generate sustained shifts in ecosystem function with important ecological and economic impacts for rangelands and managed pastures. The Pastures and Climate Extremes experiment (PACE) in Southeast Australia was designed to investigate the impacts of a severe winter/spring drought (60% rainfall reduction) and, for a subset of species, a factorial combination of drought and elevated temperature (ambient +3 °C) on pasture productivity. The experiment included nine common pasture and Australian rangeland species from three plant functional groups (C3 grasses, C4 grasses and legumes) planted in monoculture. Winter/spring drought resulted in productivity declines of 45% on average and up to 74% for the most affected species (Digitaria eriantha) during the 6-month treatment period, with eight of the nine species exhibiting significant yield reductions. Despite considerable variation in species’ sensitivity to drought, C4 grasses were more strongly affected by this treatment than C3 grasses or legumes. Warming also had negative effects on cool-season productivity, associated at least partially with exceedance of optimum growth temperatures in spring and indirect effects on soil water content. The combination of winter/spring drought and year-round warming resulted in the greatest yield reductions. We identified responses that were either additive such that there was only as significant warming effect under drought (Festuca), or less-than-additive, where there was no drought effect under warming (Medicago), compared to ambient plots. Results from this study highlight the sensitivity of diverse pasture species to increases in winter and spring drought severity similar to those predicted for this region, and that anticipated benefits of cool-season warming are unlikely to be realised. Overall, the substantial negative impacts on productivity suggest that future, warmer, drier climates will result in shortfalls in cool-season forage availability, with profound implications for the livestock industry and natural grazer communities.

Published

2020

30. Increasing aridity will not offset CO

Author

Daniel, Nadal-Sala, Belinda E, Medlyn, Nadine K, Ruehr, Craig V M, Barton, David S, Ellsworth, Carles, Gracia, David T, Tissue, Mark G, Tjoelker, and Santi, Sabaté

Subjects

Plant Leaves, Soil, Fertilization, Australia, Water, Carbon Dioxide, Trees

Abstract

Rising atmospheric [CO

Published

2020

31. COSORE: A community database for continuous soil respiration and other soil‐atmosphere greenhouse gas flux data

Author

Dennis D. Baldocchi, Kadmiel Maseyk, Yuji Kominami, Nadine K. Ruehr, Patrick M. Crill, John E. Drake, Mioko Ataka, Anya M. Hopple, Haiming Kan, Samaneh Ashraf, Matthew Saunders, Zhuo Pang, Daphne Szutu, Stephanie C. Pennington, Whendee L. Silver, Scott T. Miller, Cecilio Oyonarte, David A. Lipson, Naishen Liang, Masahito Ueyama, Thomas Wutzler, Michael L. Goulden, Järvi Järveoja, Jiye Zeng, Wu Sun, Debjani Sihi, Takashi Hirano, Nina Buchmann, Amir AghaKouchak, Peter S. Curtis, Ruth K. Varner, Greg Winston, Munemasa Teramoto, Mark G. Tjoelker, Susan E. Trumbore, Kathleen Savage, Omar Gutiérrez del Arroyo, Asko Noormets, Mats Nilsson, Catriona A. Macdonald, Carolyn Monika Görres, M. Altaf Arain, Alexandre A. Renchon, Joseph Verfaillie, James W. Raich, Masahiro Takagi, Jason P. Kaye, Quan Zhang, Hamidreza Norouzi, Ulli Seibt, Melanie A. Mayes, Jinsong Wang, Juan J. Armesto, Marion Schrumpf, Tianshan Zha, Mirco Migliavacca, Chelcy Ford Miniat, Jin-Sheng He, Enrique P. Sánchez-Cañete, Michael Gavazzi, Tarek S. El-Madany, T. A. Black, H. Hughes, Elise Pendall, Christopher M. Gough, Jillian W. Gregg, Guofang Miao, Junliang Zou, Avni Malhotra, Russell L. Scott, D. S. Christianson, Marguerite Mauritz, Steve McNulty, Juying Wu, Jinshi Jian, K. C. Mathes, Tana E. Wood, Rodrigo Vargas, Jennifer Goedhart Nietz, Christoph S. Vogel, Claire L. Phillips, Mariah S. Carbone, Kentaro Takagi, Shih-Chieh Chang, Jorge F. Perez-Quezada, Richard P. Phillips, Hassan Anjileli, Eric A. Davidson, Ankur R. Desai, Christine S. O’Connell, Matthias Peichl, Bruce Osborne, Ben Bond-Lamberty, and Rachhpal S. Jassal

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Nitrous Oxide, Climate change, open data, computer.software_genre, Greenhouse gas, 010603 evolutionary biology, 01 natural sciences, Database design, soil respiration, Soil respiration, Greenhouse Gases, Soil, 11. Sustainability, greenhouse gases, open science, ddc:550, Environmental Chemistry, Biology, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, Database, Ecology, Atmosphere, carbon dioxide, methane, Respiration, Reproducibility of Results, 15. Life on land, Biological Sciences, Climate Action, Earth system science, Ancillary data, Chemistry, Earth sciences, Technical Advance, 13. Climate action, Soil water, Environmental science, Ecosystem respiration, computer, Environmental Sciences

Abstract

Globally, soils store two to three times as much carbon as currently resides in the atmosphere, and it is critical to understand how soil greenhouse gas (GHG) emissions and uptake will respond to ongoing climate change. In particular, the soil‐to‐atmosphere CO2 flux, commonly though imprecisely termed soil respiration (R S), is one of the largest carbon fluxes in the Earth system. An increasing number of high‐frequency R S measurements (typically, from an automated system with hourly sampling) have been made over the last two decades; an increasing number of methane measurements are being made with such systems as well. Such high frequency data are an invaluable resource for understanding GHG fluxes, but lack a central database or repository. Here we describe the lightweight, open‐source COSORE (COntinuous SOil REspiration) database and software, that focuses on automated, continuous and long‐term GHG flux datasets, and is intended to serve as a community resource for earth sciences, climate change syntheses and model evaluation. Contributed datasets are mapped to a single, consistent standard, with metadata on contributors, geographic location, measurement conditions and ancillary data. The design emphasizes the importance of reproducibility, scientific transparency and open access to data. While being oriented towards continuously measured R S, the database design accommodates other soil‐atmosphere measurements (e.g. ecosystem respiration, chamber‐measured net ecosystem exchange, methane fluxes) as well as experimental treatments (heterotrophic only, etc.). We give brief examples of the types of analyses possible using this new community resource and describe its accompanying R software package., Here we describe the lightweight, open source COSORE (COntinuous SOil REspiration) database and software. COSORE focuses on automated, continuous and long‐term greenhouse gas flux datasets, and is intended to serve as a community resource for earth sciences, climate change syntheses and model evaluation.

Published

2020

32. Whole-tree mesophyll conductance reconciles isotopic and gas-exchange estimates of water-use efficiency

Author

Craig V. M. Barton, Courtney E. Campany, Mark G. Tjoelker, Nerea Ubierna, John D. Marshall, John E. Drake, and Teresa E. Gimeno

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Plant Science, Photosynthesis, 01 natural sciences, Trees, 03 medical and health sciences, Respiration, Water cycle, Water-use efficiency, Carbon Isotopes, Direct effects, Conductance, Water, 15. Life on land, Carbon Dioxide, Eucalyptus, Plant Leaves, 030104 developmental biology, Agronomy, 13. Climate action, Environmental science, Phloem, Mesophyll Cells, 010606 plant biology & botany

Abstract

Photosynthetic water-use efficiency (WUE) describes the link between terrestrial carbon (C) and water cycles. Estimates of intrinsic WUE (iWUE) from gas exchange and C isotopic composition (δ13 C) differ due to an internal conductance in the leaf mesophyll (gm ) that is variable and seldom computed. We present the first direct estimates of whole-tree gm , together with iWUE from whole-tree gas exchange and δ13 C of the phloem (δ13 Cph ). We measured gas exchange, online 13 C-discrimination, and δ13 Cph monthly throughout spring, summer, and autumn in Eucalyptus tereticornis grown in large whole-tree chambers. Six trees were grown at ambient temperatures and six at a 3°C warmer air temperature; a late-summer drought was also imposed. Drought reduced whole-tree gm . Warming had few direct effects, but amplified drought-induced reductions in whole-tree gm . Whole-tree gm was similar to leaf gm for these same trees. iWUE estimates from δ13 Cph agreed with iWUE from gas exchange, but only after incorporating gm . δ13 Cph was also correlated with whole-tree 13 C-discrimination, but offset by -2.5 ± 0.7‰, presumably due to post-photosynthetic fractionations. We conclude that δ13 Cph is a good proxy for whole-tree iWUE, with the caveats that post-photosynthetic fractionations and intrinsic variability of gm should be incorporated to provide reliable estimates of this trait in response to abiotic stress.

Published

2020

33. Acclimation of leaf respiration temperature responses across thermally contrasting biomes

Author

Patrick Meir, Lasantha K. Weerasinghe, Kevin L. Griffin, Danielle Creek, Mark G. Tjoelker, John J. G. Egerton, Lingling Zhu, Shinichi Asao, Keith J. Bloomfield, Vaughan Hurry, Michael J. Liddell, Matthew H. Turnbull, Lucy Hayes, Owen K. Atkin, Australia's national university, Western Sydney University, Laboratoire de Physique et Physiologie Intégratives de l’Arbre en environnement Fluctuant (PIAF), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Clermont Auvergne (UCA), Columbia University [New York], Swedish University of Agricultural Sciences (SLU), James Cook University (JCU), University of Kent [Canterbury], Australian Research Council / DP0986823, DP130101252, and CE140100008Australian Government

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, [SDV]Life Sciences [q-bio], Acclimatization, Biome, Irradiance, Plant Science, Rainforest, Solar irradiance, 01 natural sciences, phenotypic plasticity, thermal tolerance, 03 medical and health sciences, respiration modelling, Respiration, Climate change, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Ecosystem, Phenotypic plasticity, Thermal acclimation, Temperature, 15. Life on land, Evergreen, Plant Leaves, Horticulture, 030104 developmental biology, 13. Climate action, Environmental science, metabolism, 010606 plant biology & botany

Abstract

International audience; Short-term temperature response curves of leaf dark respiration (R-T) provide insights into a critical process that influences plant net carbon exchange. This includes how respiratory traits acclimate to sustained changes in the environment. Our study analysed 860 high-resolutionR-T(10-70 degrees C range) curves for: (a) 62 evergreen species measured in two contrasting seasons across several field sites/biomes; and (b) 21 species (subset of those sampled in the field) grown in glasshouses at 20 degrees C : 15 degrees C, 25 degrees C : 20 degrees C and 30 degrees C : 25 degrees C, day : night. In the field, across all sites/seasons, variations inR(25)(measured at 25 degrees C) and the leafTwhereRreached its maximum (T-max) were explained by growthT(mean air-Tof 30-d before measurement), solar irradiance and vapour pressure deficit, with growthThaving the strongest influence.R(25)decreased andT(max)increased with rising growthTacross all sites and seasons with the single exception of winter at the cool-temperate rainforest site where irradiance was low. The glasshouse study confirmed thatR(25)andT(max)thermally acclimated. Collectively, the results suggest: (1) thermal acclimation of leafRis common in most biomes; and (2) the highTthreshold of respiration dynamically adjusts upward when plants are challenged with warmer and hotter climates.

Published

2020

34. The partitioning of gross primary production for young Eucalyptus tereticornis trees under experimental warming and altered water availability

Author

Michael J. Aspinwall, Peter B. Reich, Mark G. Tjoelker, Craig V. M. Barton, Sebastian Pfautsch, and John E. Drake

Subjects

0106 biological sciences, 0301 basic medicine, Maintenance respiration, Physiology, Primary production, Plant Science, 15. Life on land, 01 natural sciences, Acclimatization, Accelerated Growth, 03 medical and health sciences, 030104 developmental biology, Agronomy, Soil water, Respiration, Environmental science, Ecosystem, Precipitation, 010606 plant biology & botany

Abstract

The allocation of carbon (C) is an important component of tree physiology that influences growth and ecosystem C storage. Allocation is challenging to measure, and its sensitivity to environmental changes such as warming and altered water availability is uncertain. We exposed young Eucalyptus tereticornis trees to +3°C warming and elimination of summer precipitation in the field using whole-tree chambers. We calculated C allocation terms using detailed measurements of growth and continuous whole-crown CO2 and water exchange measurements. Trees grew from small saplings to nearly 9 m height during this 15-month experiment. Warming accelerated growth and leaf area development, and it increased the partitioning of gross primary production (GPP) to aboveground respiration and growth while decreasing partitioning below ground. Eliminating summer precipitation reduced C gain and growth but did not impact GPP partitioning. Trees utilized deep soil water and avoided strongly negative water potentials. Warming increased growth respiration, but maintenance respiration acclimated homeostatically. The increasing growth in the warmed treatment resulted in higher rates of respiration, even with complete acclimation of maintenance respiration. Warming-induced stimulations of tree growth likely involve increased C allocation above ground, particularly to leaf area development, whereas reduced water availability may not stimulate allocation to roots.

Published

2019

35. Photosynthetic capacity and leaf nitrogen decline along a controlled climate gradient in provenances of two widely distributed Eucalyptus species

Author

Oula Ghannoum, Kristine Y. Crous, John E. Drake, Robert E. Sharwood, Michael J. Aspinwall, and Mark G. Tjoelker

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Nitrogen, Acclimatization, Climate, Climate Change, Ribulose-Bisphosphate Carboxylase, Climate change, Subtropics, Biology, Photosynthesis, 01 natural sciences, Trees, Temperate climate, Environmental Chemistry, 0105 earth and related environmental sciences, General Environmental Science, Eucalyptus, Global and Planetary Change, Ecology, Global warming, Temperature, Tropics, 15. Life on land, Environment, Controlled, Photosynthetic capacity, Plant Leaves, Agronomy, 13. Climate action, 010606 plant biology & botany

Abstract

Climate is an important factor limiting tree distributions and adaptation to different thermal environments may influence how tree populations respond to climate warming. Given the current rate of warming, it has been hypothesized that tree populations in warmer, more thermally stable climates may have limited capacity to respond physiologically to warming compared to populations from cooler, more seasonal climates. We determined in a controlled environment how several provenances of widely distributed Eucalyptus tereticornis and E. grandis adjusted their photosynthetic capacity to +3.5°C warming along their native distribution range (~16-38°S) and whether climate of seed origin of the provenances influenced their response to different growth temperatures. We also tested how temperature optima (Topt ) of photosynthesis and Jmax responded to higher growth temperatures. Our results showed increased photosynthesis rates at a standardized temperature with warming in temperate provenances, while rates in tropical provenances were reduced by about 40% compared to their temperate counterparts. Temperature optima of photosynthesis increased as provenances were exposed to warmer growth temperatures. Both species had ~30% reduced photosynthetic capacity in tropical and subtropical provenances related to reduced leaf nitrogen and leaf Rubisco content compared to temperate provenances. Tropical provenances operated closer to their thermal optimum and came within 3% of the Topt of Jmax during the daily temperature maxima. Hence, further warming may negatively affect C uptake and tree growth in warmer climates, whereas eucalypts in cooler climates may benefit from moderate warming.

Published

2018

36. Three years of soil respiration in a mature eucalypt woodland exposed to atmospheric CO2 enrichment

Author

Peter B. Reich, Catriona A. Macdonald, David S. Ellsworth, John E. Drake, Mark G. Tjoelker, Brajesh K. Singh, and Ian C. Anderson

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Q10, Primary production, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Carbon cycle, Soil respiration, chemistry.chemical_compound, chemistry, Soil water, Carbon dioxide, Environmental Chemistry, Environmental science, Ecosystem, Precipitation, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

The rate of CO2 diffusion from soils to the atmosphere (soil CO2 efflux, soil respiration; Rsoil) reflects the integrated activity of roots and microbes and is among the largest fluxes of the terrestrial global C cycle. Most experiments have demonstrated that Rsoil increases by 20–35% following the exposure of an ecosystem to an atmosphere enriched in CO2 (i.e., eCO2), but such experiments have largely been performed in young and N-limited ecosystems. Here, we exposed a mature and phosphorus-limited eucalypt woodland to eCO2 and measured Rsoil across three full years with a combination of manual surveys and automated measurements. We also implemented an empirical model describing the dependence of Rsoil on volumetric soil water content (θ) and soil temperature (Tsoil) to produce annual Rsoil flux estimates. Rsoil varied strongly with Tsoil, θ, and precipitation in complex and interacting ways. The realized long-term (weeks to years) temperature dependence (Q10) of Rsoil increased from ~ 1.6 at low θ up to ~ 3 at high θ. Additionally, Rsoil responded strongly and rapidly to precipitation events in a manner that depended on the conditions of θ and Tsoil at the beginning of the rain event; Rsoil increased by up to 300% within 30 min when rain fell on dry soil that had not experience rain in the preceding week, but Rsoil was rapidly reduced by up to 70% when rain fell on wet soil, leading to flooding. Repeated measures analysis of Rsoil observations over 3 years indicated no significant change in response to CO2 enrichment (P = 0.7), and elevated CO2 did not alter the dependence of Rsoil on Tsoil or θ. However, eCO2 increased Rsoil observations by ~ 10% under some constrained and moderate environmental conditions. Annual Rsoil flux sums estimated with an empirical model were ~ 7% higher in eCO2 plots than in aCO2 plots, but this difference was not statistically significant. The lack of a large eCO2 effect on Rsoil is consistent with recent evidence that aboveground net primary production was not stimulated by eCO2 in this ecosystem. The C budget of this mature woodland may be less affected by eCO2 than the young N-limited ecosystems that have been studied previously.

Published

2018

37. Contrasting heat tolerance of urban trees to extreme temperatures during heatwaves

Author

Manuel Esperón-Rodríguez, Paul D. Rymer, Sally A. Power, Renée M. Marchin, and Mark G. Tjoelker

Subjects

Heat tolerance, Stomatal conductance, Ecology, Agronomy, Vapour Pressure Deficit, Turgor pressure, Soil Science, Environmental science, Forestry, Introduced species, Evergreen, Photosynthesis, Tree species

Abstract

Extreme climate conditions, including more frequent and prolonged heatwaves, are increasing in many regions throughout the world. Urban trees can aid in mitigating the adverse impacts of climate extremes; however, their capacity to do so is limited by species differences in ability to maintain function and retain leaves to provide shade under extreme temperatures. To assess tree vulnerability to heatwaves, we used a common garden experiment in Western Sydney, Australia, which included four widely-planted tree species; two native evergreen and two exotic deciduous species. Data were collected during 2019 and 2020, the two hottest summers on local record with maximum air temperatures reaching 45 °C. We monitored plant physiological status as stomatal conductance (gS) and midday leaf water potential (Ψmid). We determined heat tolerance by measuring the leaf critical temperature (Tcrit) for photosynthesis and leaf turgor loss point (πtlp) as thresholds for loss of function and calculated the thermal safety margin. Plant performance was assessed by measuring tree growth and leaf damage after heatwaves. Species responded dynamically with gS decreasing as air temperature and vapor pressure deficit increased during heatwaves. Exotic species had higher gS, Tcrit and πtlp than native species. Leaf damage under heatwave conditions was overall lower in native species. Our results highlight the impact of heatwaves on urban trees and the value of physiological metrics to inform tree species selection to create more resilient urban environments.

Published

2021

38. Stomatal and non-stomatal limitations of photosynthesis for four tree species under drought: A comparison of model formulations

Author

Sally A. Power, Danielle Creek, Michael J. Aspinwall, Remko A. Duursma, Sebastian Pfautsch, Chelsea Maier, John E. Drake, Derek Eamus, Mark G. Tjoelker, Renee Smith, Belinda E. Medlyn, Brendan Choat, and David T. Tissue

Subjects

0106 biological sciences, Atmospheric Science, Global and Planetary Change, Stomatal conductance, 010504 meteorology & atmospheric sciences, Empirical modelling, Forestry, Biology, Rainout, Photosynthesis, Atmospheric sciences, 01 natural sciences, Photosynthetic capacity, Botany, Soil water, Ecosystem, Water-use efficiency, Agronomy and Crop Science, 010606 plant biology & botany, 0105 earth and related environmental sciences

Abstract

Drought strongly influences terrestrial C cycling via its effects on plant H2O and CO2 exchange. However, the treatment of photosynthetic physiology under drought by many ecosystem and earth system models remains poorly constrained by data. We measured the drought response of four tree species and evaluated alternative model formulations for drought effects on photosynthesis (A). We implemented a series of soil drying and rewetting events (i.e. multiple droughts) with four contrasting tree species in large pots (75 L) placed in the field under rainout shelters. We measured leaf-level gas exchange, predawn and midday leaf water potential (Ψpd and Ψmd), and leaf isotopic composition (δ13C) and calculated discrimination relative to the atmosphere (Δ). We then evaluated eight modeling frameworks that simulate the effects of drought in different ways. With moderate reductions in volumetric soil water content (θ), all species reduced stomatal conductance (gs), leading to an equivalent increase in water use efficiency across species inferred from both leaf gas exchange and Δ, despite a small reduction in photosynthetic capacity. With severe reductions in θ, all species strongly reduced gs along with a coincident reduction in photosynthetic capacity, illustrating the joint importance of stomatal and non-stomatal limitations of photosynthesis under strong drought conditions. Simple empirical models as well as complex mechanistic model formulations were equally successful at capturing the measured variation in A and gs, as long as the predictor variables were available from direct measurements (θ, Ψpd, and Ψmd). However, models based on leaf water potential face an additional challenge, as we found that Ψpd was substantially different from Ψsoil predicted by standard approaches based on θ. Modeling frameworks that combine gas exchange and hydraulic traits have the advantage of mechanistic realism, but sacrificed parsimony without an improvement in predictive power in this comparison. Model choice depends on the desired balance between simple empiricism and mechanistic realism. We suggest that empirical models implementing stomatal and non-stomatal limitations based on θ are highly predictive simple models. Mechanistic models that incorporate hydraulic traits have excellent potential, but several challenges currently limit their widespread implementation.

Published

2017

39. Night and day – Circadian regulation of night-time dark respiration and light-enhanced dark respiration in plant leaves and canopies

Author

Jorge del Castillo, Jordi Voltas, Josu G. Alday, Clément Piel, Lucía Galiano, Arthur Gessler, Matthias Haeni, Damien Landais, Mark G. Tjoelker, Sébastien Devidal, Paula Martín-Gómez, David T. Tissue, Alexandru Milcu, Juan Pedro Ferrio, Jacques Roy, Serajis Salekin, Karin Pirhofer-Walzl, Michael Bahn, Zachary Kayler, Olivier Ravel, Víctor Resco de Dios, Günter Hoch, Marcus Schaub, Sonia García-Muñoz, Leibniz-Zentrum für Agrarlandschaftsforschung = Leibniz Centre for Agricultural Landscape Research (ZALF), Écotron Européen de Montpellier, Centre National de la Recherche Scientifique (CNRS), Institute of Ecology, Technische Universität Berlin (TU), Centre d’Ecologie Fonctionnelle et Evolutive (CEFE), Centre National de la Recherche Scientifique (CNRS)-Université de Montpellier (UM)-École pratique des hautes études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Institut National de la Recherche Agronomique (INRA)-Université Paul-Valéry - Montpellier 3 (UPVM)-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut de Recherche pour le Développement (IRD [France-Sud]), Swiss Federal Institute for Forest, Snow and Landscape Research WSL, Institute of Pharmacology and Toxicology [Zurich], Universität Zürich [Zürich] = University of Zurich (UZH), Western Sydney University, Department of Crop and Forest Sciences, School of Agrifood and Forestry Science and Engineering (ETSEA), University of Lleida-Agrotecnio Center (UdL-Agrotecnio), University of Basel (Unibas), Écotron Européen de Montpellier - UPS 3248, Technische Universität Berlin (TUB), Institut de Recherche pour le Développement (IRD [France-Sud])-Centre National de la Recherche Scientifique (CNRS)-École pratique des hautes études (EPHE)-Université de Montpellier (UM)-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro)-Institut National de la Recherche Agronomique (INRA)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Université Paul-Valéry - Montpellier 3 (UM3), Swiss Federal Institute for Forest, Snow and Avalanche Research WSL, University of Zürich [Zürich] (UZH), and Western Sydney University (UWS)

Subjects

0106 biological sciences, 0301 basic medicine, Canopy, Constant light, [SDE.MCG]Environmental Sciences/Global Changes, Circadian clock, Plant Science, Constant darkness, Biology, 01 natural sciences, Scaling, 03 medical and health sciences, Circadian regulation, Botany, Respiration, Circadian rhythm, ComputingMilieux_MISCELLANEOUS, Ecology, Evolution, Behavior and Systematics, 2. Zero hunger, food and beverages, 15. Life on land, 030104 developmental biology, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Ecosystem respiration, Non-structural carbon compounds (NSC), Agronomy and Crop Science, 010606 plant biology & botany

Abstract

The potential of the vegetation to sequester C is determined by the balance between assimilation and respiration. Respiration is under environmental and substrate-driven control, but the circadian clock might also contribute. To assess circadian control on night-time dark respiration (RD) and on light enhanced dark respiration (LEDR) - the latter providing information on the metabolic reorganization in the leaf during light-dark transitions - we performed experiments in macrocosms hosting canopies of bean and cotton. Under constant darkness (plus constant air temperature and air humidity), we tested whether circadian regulation of RD scaled from leaf to canopy respiration. Under constant light (plus constant air temperature and air humidity), we assessed the potential for leaf-level circadian regulation of LEDR. There was a clear circadian oscillation of leaf-level RD in both species and circadian patterns scaled to the canopy. LEDR was under circadian control in cotton, but not in bean indicating species-specific controls. The circadian rhythm of LEDR in cotton might indicate variable suppression of the normal cyclic function of the tricarboxylic-acid-cycle in the light. Since circadian regulation is assumed to act as an adaptive memory to adjust plant metabolism based on environmental conditions from previous days, circadian control of RD may help to explain temporal variability of ecosystem respiration. This study benefited from the CNRS human and technical resources allocated to the ECOTRONS Research Infrastructures as well as from the state allocation ‘Investissement d'Avenir’ AnaEE-France ANR-11-INBS-0001, ExpeER Transnational Access program, Ramón y Cajal fellowships (RYC-2012-10970 to VRD and RYC-2008-02050 to JPF), the Erasmus Mundus Master Course MEDfOR, internal grants from UWS-HIE to VRD and ZALF to AG and Juan de la Cierva-fellowships (IJCI-2014-21393 to JGA). We remain indebted to E. Gerardeau, D. Dessauw, J. Jean, P. Prudent (Aïda CIRAD), J.-J. Drevon, C. Pernot (Eco&Sol INRA), B. Buatois, A. Rocheteau (CEFE CNRS), A. Pra, A. Mokhtar and the full Ecotron team, in particular C. Escape, for outstanding technical assistance.

Published

2017

40. Adaptation and acclimation both influence photosynthetic and respiratory temperature responses in Corymbia calophylla

Author

Collin W. Ahrens, Michael J. Aspinwall, Margaret Byrne, David T. Tissue, Paul D. Rymer, Angelica Vårhammar, Mark G. Tjoelker, and Chris J. Blackman

Subjects

0106 biological sciences, 0301 basic medicine, Mediterranean climate, Physiology, Acclimatization, Climate Change, Myrtaceae, Species distribution, Population, Q10, Plant Science, 01 natural sciences, 03 medical and health sciences, Photosynthesis, education, education.field_of_study, biology, Ecology, Australia, Temperature, Evergreen, biology.organism_classification, Adaptation, Physiological, 030104 developmental biology, Corymbia calophylla, 010606 plant biology & botany

Abstract

Short-term acclimation and long-term adaptation represent two ways in which forest trees can respond to changes in temperature. Yet, the relative contribution of thermal acclimation and adaptation to tree physiological responses to temperature remains poorly understood. Here, we grew two cool-origin and two warm-origin populations of a widespread broad-leaved evergreen tree species (Corymbia calophylla (Lindl.) K.D.Hill & L.A.S.Johnson) from a Mediterranean climate in southwestern Australia under two growth temperatures representative of the cool- and warm-edge of the species distribution. The populations selected from each thermal environment represented both high and low precipitation sites. We measured the short-term temperature response of leaf photosynthesis (A) and dark respiration (R), and attributed observed variation to acclimation, adaptation or the combination of both. We observed limited variation in the temperature optimum (Topt) of A between temperature treatments or among populations, suggesting little plasticity or genetic differentiation in the Topt of A. Yet, other aspects of the temperature response of A and R were dependent upon population and growth temperature. Under cooler growth temperatures, the population from the coolest, wettest environment had the lowest A (at 25 °C) among all four populations, but exhibited the highest A (at 25 °C) under warmer growth temperatures. Populations varied in R (at 20 °C) and the temperature sensitivity of R (i.e., Q10 or activation energy) under cool, but not warm growth temperatures. However, populations showed similar yet lower R (at 20 °C) and no differences in the temperature sensitivity of R under warmer growth temperatures. We conclude that C. calophylla populations from contrasting climates vary in physiological acclimation to temperature, which might influence how this ecologically important tree species and the forests of southwestern Australia respond to climate change.

Published

2017

41. Rhizosphere-driven increase in nitrogen and phosphorus availability under elevated atmospheric CO2 in a mature Eucalyptus woodland

Author

Raúl Ochoa-Hueso, John E. Drake, Sally A. Power, Mark G. Tjoelker, John Hughes, Juan Piñeiro, and Manuel Delgado-Baquerizo

Subjects

0106 biological sciences, chemistry.chemical_classification, Rhizosphere, Chemistry, Phosphorus, Soil organic matter, Soil Science, chemistry.chemical_element, Plant Science, Woodland, 010603 evolutionary biology, 01 natural sciences, Nutrient, Agronomy, Terrestrial ecosystem, Organic matter, Ecosystem, 010606 plant biology & botany

Abstract

Rhizosphere processes are integral to carbon sequestration by terrestrial ecosystems in response to rising concentrations of atmospheric CO2. Yet, the nature and magnitude of rhizosphere responses to elevated CO2, particularly in nutrient and water-limited forest ecosystems, remain poorly understood. We investigated rhizosphere responses (enzyme activities and nutrient availability) to atmospheric CO2 enrichment (ambient +150 μmol CO2 mol−1) in a phosphorus-limited mature eucalypt woodland in south-eastern Australia (the EucFACE experiment). Following 17 months of treatment, the activity of rhizosphere soil exoenzymes related to starch and cellulose degradation decreased between 0 and 10 cm and increased from 10 to 30 cm depth under elevated CO2. This response was concurrent with increases in nitrogen and phosphorus availability and smaller C:P nutrient ratios in rhizosphere soil under elevated CO2. This nutrient-poor eucalypt woodland exhibited rhizosphere responses to atmospheric CO2 enrichment that increased nutrient availability in rhizosphere soil and suggest accelerated rates of soil organic matter decomposition, both of which may, in turn, promote plant growth under elevated CO2 concentrations.

Published

2017

42. Supplementary material to 'Temperature response measurements from eucalypts give insight into the impact of Australian isoprene emissions on air quality in 2050'

Author

Kathryn M. Emmerson, Malcolm Possell, Michael J. Aspinwall, Sebastian Pfautsch, and Mark G. Tjoelker

Published

2020

43. No evidence of homeostatic regulation of leaf temperature in Eucalyptus parramattensis trees: integration of CO

Author

John E, Drake, Richard, Harwood, Angelica, Vårhammar, Margaret M, Barbour, Peter B, Reich, Craig V M, Barton, and Mark G, Tjoelker

Subjects

Plant Leaves, Eucalyptus, Temperature, Homeostasis, Carbon Dioxide, Oxygen Isotopes, Photosynthesis, Trees

Abstract

Thermoregulation of leaf temperature (T

Published

2019

44. An extreme heatwave enhanced the xanthophyll de-epoxidation state in leaves of

Author

Namraj, Dhami, John E, Drake, Mark G, Tjoelker, David T, Tissue, and Christopher I, Cazzonelli

Subjects

Research Article

Abstract

Heatwaves are becoming more frequent with climate warming and can impact tree growth and reproduction. Eucalyptus parramattensis can cope with an extreme heatwave in the field via transpiratory cooling and enhanced leaf thermal tolerance that protected foliar tissues from photo-inhibition and photo-oxidation during natural midday irradiance. Here, we explored whether changes in foliar carotenoids and/or the xanthophyll cycle state can facilitate leaf acclimation to long-term warming and/or an extreme heatwave event. We found that leaves had similar carotenoid levels when grown for one year under ambient and experimental long-term warming (+ 3 °C) conditions in whole tree chambers. Exposure to a 4-day heatwave (> 43 °C) significantly altered the xanthophyll de-epoxidation state of carotenoids revealing one mechanism by which trees could minimise foliar photo-oxidative damage. The levels of zeaxanthin were significantly higher in both young and old leaves during the heatwave, revealing that violaxanthin de-epoxidation and perhaps de novo zeaxanthin synthesis contributed to enhancement of the xanthophyll cycle state. In a future climate of long-term warming and increased heatwave events, leaves of E. parramattensis will be able to utilise biochemical strategies to alter the xanthophyll cycle state and cope with extreme temperatures under natural solar irradiation.

Published

2019

45. Elevated CO2 alters the temperature sensitivity of stem CO2 efflux in a mature eucalypt woodland

Author

David S. Ellsworth, Nam Jin Noh, Kristine Y. Crous, Jinquan Li, Mark G. Tjoelker, Craig V. M. Barton, Elise Pendall, and Roberto L. Salomón

Subjects

Maintenance respiration, Carbon dioxide in Earth's atmosphere, Q10, Growing season, Plant Science, Seasonality, Biology, medicine.disease, Eucalyptus, Animal science, Respiration, medicine, Agronomy and Crop Science, Water content, Ecology, Evolution, Behavior and Systematics

Abstract

The CO2 efflux from tree stem surfaces to atmosphere (RS) is an important component in the carbon (C) balance of forest ecosystems. Rising atmospheric carbon dioxide concentrations [CO2] are expected to stimulate RS, because of greater C assimilation and carbohydrate supply to stems under rising [CO2]. Growth respiration (Rg) and maintenance respiration (Rm) during the warm growing season may respond differently to rising [CO2] due to different metabolic demands. To test the effect of elevated [CO2] (eCO2, ambient +150 ppm) on RS, we examined RS in mature Eucalyptus trees on a monthly basis for an entire year during the seventh year of exposure to eCO2. RS varied seasonally and mirrored seasonal variation in temperature. While RS was not significantly increased under eCO2 compared to ambient CO2 (aCO2), its temperature sensitivity was significantly decreased (Q10 of 1.92 for aCO2 and 1.56 for eCO2). The estimated annual Rg accounted for approximately 7–8% of annual total RS, 419 ± 103 g C m−2 yr-1, indicating that Rm contributes substantially to total RS in this mature woodland. Monthly mean RS was correlated with monthly mean soil temperature, soil moisture and monthly stem growth rate in this dry year, but soil moisture levels may have been insufficient to observe the impacts of eCO2 on stem growth in this droughted and phosphorous limited site. Our results highlight that eCO2 tends to increase Rm at low temperatures during the non-growing season, thus decreasing the temperature sensitivity of RS, despite a neutral effect of eCO2 on RS rates on a yearly basis.

Published

2021

46. Coupled response of stomatal and mesophyll conductance to light enhances photosynthesis of shade leaves under sunflecks

Author

Susanne von Caemmerer, Remko A. Duursma, Mark G. Tjoelker, and Courtney E. Campany

Subjects

0106 biological sciences, 0301 basic medicine, Canopy, Stomatal conductance, Physiology, AMAX, Conductance, Plant Science, Biology, Photosynthesis, 01 natural sciences, Photosynthetic capacity, 03 medical and health sciences, Light intensity, 030104 developmental biology, Isotopes of carbon, Botany, 010606 plant biology & botany

Abstract

Light gradients within tree canopies play a major role in the distribution of plant resources that define the photosynthetic capacity of sun and shade leaves. However, the biochemical and diffusional constraints on gas exchange in sun and shade leaves in response to light remain poorly quantified, but critical for predicting canopy carbon and water exchange. To investigate the CO2 diffusion pathway of sun and shade leaves, leaf gas exchange was coupled with concurrent measurements of carbon isotope discrimination to measure net leaf photosynthesis (An), stomatal conductance (gs) and mesophyll conductance (gm) in Eucalyptus tereticornis trees grown in climate controlled whole-tree chambers. Compared to sun leaves, shade leaves had lower An, gm, leaf nitrogen and photosynthetic capacity (Amax) but gs was similar. When light intensity was temporarily increased for shade leaves to match that of sun leaves, both gs and gm increased, and An increased to values greater than sun leaves. We show that dynamic physiological responses of shade leaves to altered light environments have implications for up-scaling leaf level measurements and predicting whole canopy carbon gain. Despite exhibiting reduced photosynthetic capacity, the rapid up-regulation of gm with increased light enables shade leaves to respond quickly to sunflecks.

Published

2016

47. Functional adaptations and trait plasticity of urban trees along a climatic gradient

Author

Sally A. Power, Renée M. Marchin, Mark G. Tjoelker, Anthea Challis, Manuel Esperón-Rodríguez, and Paul D. Rymer

Subjects

0106 biological sciences, Phenotypic plasticity, Ecology, Specific leaf area, biology, Resistance (ecology), Drought tolerance, Tristaniopsis laurina, Soil Science, Forestry, 010501 environmental sciences, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Temperate climate, Transect, 0105 earth and related environmental sciences, Celtis australis

Abstract

In urban environments, long-term tree survival and performance requires physiological tolerance or phenotypic plasticity in plant functional traits. Knowledge of these traits can inform the likely persistence of urban forests under future, more severe climates. We assessed the plasticity of morphological and physiological traits of tree species planted along an urban climatic gradient in the Greater Sydney region during a severe, multi-year drought in eastern Australia. We selected four sites along a ∼55 km east-west transect, ranging from the cool/wet coast to the warm/dry inland. We assessed five tree species (four natives, one exotic) with different predicted climatic vulnerability based on climate-origins, estimating functional traits indicative of drought tolerance: carbon isotope composition (δ13C), Huber value (HV), specific leaf area (SLA), wood density (WD), and leaf turgor loss point (πtlp). Broadly, trees planted in warm/dry sites had more negative πtlp, higher WD, δ13C and HV, and lower SLA than cool/wet sites, indicating phenotypic plasticity to drought. The leaf-level traits πtlp, δ13C and SLA were more strongly correlated with temperature and precipitation, compared to HV and WD. Species differed in the extent of their trait shifts along the transect, with greater plasticity evident in the exotic Celtis australis and the more temperate cool-climate Tristaniopsis laurina, compared to the more tropical, warm-climate Cupaniopsis anacardioides, which showed limited plasticity and lower drought tolerance. Our findings reveal adaptive capacity of urban trees to climate via plasticity in drought tolerance traits, which can direct species selection to improve urban forests resistance to climate change.

Published

2020

48. No evidence for triose phosphate limitation of light-saturated leaf photosynthesis under current atmospheric CO

Author

Dushan P, Kumarathunge, Belinda E, Medlyn, John E, Drake, Alistair, Rogers, and Mark G, Tjoelker

Subjects

Plant Leaves, Light, Atmosphere, Trioses, Temperature, Carbon Dioxide, Photosynthesis, Phosphates

Abstract

The triose phosphate utilization (TPU) rate has been identified as one of the processes that can limit terrestrial plant photosynthesis. However, we lack a robust quantitative assessment of TPU limitation of photosynthesis at the global scale. As a result, TPU, and its potential limitation of photosynthesis, is poorly represented in terrestrial biosphere models (TBMs). In this study, we utilized a global data set of photosynthetic CO

Published

2019

49. Range size and growth temperature influence Eucalyptus species responses to an experimental heatwave

Author

Malcolm Possell, Steven C. Van Sluyter, Siobhan Dennison, Owen K. Atkin, John E. Drake, Angelica Vårhammar, Mark G. Tjoelker, David T. Tissue, Peter B. Reich, Michael J. Aspinwall, Paul D. Rymer, and Sebastian Pfautsch

Subjects

0106 biological sciences, Thermotolerance, Stomatal conductance, 010504 meteorology & atmospheric sciences, Range (biology), Climate Change, Large range, Biology, Forests, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, chemistry.chemical_compound, Species Specificity, Environmental Chemistry, Isoprene, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, Eucalyptus, Ecology, Plant Dispersal, Global warming, Temperature, 15. Life on land, Plant Leaves, Horticulture, chemistry, 13. Climate action, Tree species, Heat-Shock Response

Abstract

Understanding forest tree responses to climate warming and heatwaves is important for predicting changes in tree species diversity, forest C uptake, and vegetation-climate interactions. Yet, tree species differences in heatwave tolerance and their plasticity to growth temperature remain poorly understood. In this study, populations of four Eucalyptus species, two with large range sizes and two with comparatively small range sizes, were grown under two temperature treatments (cool and warm) before being exposed to an equivalent experimental heatwave. We tested whether the species with large and small range sizes differed in heatwave tolerance, and whether trees grown under warmer temperatures were more tolerant of heatwave conditions than trees grown under cooler temperatures. Visible heatwave damage was more common and severe in the species with small rather than large range sizes. In general, species that showed less tissue damage maintained higher stomatal conductance, lower leaf temperatures, larger increases in isoprene emissions, and less photosynthetic inhibition than species that showed more damage. Species exhibiting more severe visible damage had larger increases in heat shock proteins (HSPs) and respiratory thermotolerance (Tmax ). Thus, across species, increases in HSPs and Tmax were positively correlated, but inversely related to increases in isoprene emissions. Integration of leaf gas-exchange, isoprene emissions, proteomics, and respiratory thermotolerance measurements provided new insight into mechanisms underlying variability in tree species heatwave tolerance. Importantly, warm-grown seedlings were, surprisingly, more susceptible to heatwave damage than cool-grown seedlings, which could be associated with reduced enzyme concentrations in leaves. We conclude that species with restricted range sizes, along with trees growing under climate warming, may be more vulnerable to heatwaves of the future.

Published

2018

50. Responses of respiration in the light to warming in field-grown trees: a comparison of the thermal sensitivity of the Kok and Laisk methods

Author

Danielle A. Way, Michael J. Aspinwall, Kristine Y. Crous, Courtney E. Campany, Oula Ghannoum, John E. Drake, David T. Tissue, and Mark G. Tjoelker

Subjects

0106 biological sciences, 0301 basic medicine, Light, Physiology, Chemistry, Cell Respiration, Phosphoenolpyruvate carboxylase activity, Temperature, Plant Science, 15. Life on land, Carbon Dioxide, Darkness, 01 natural sciences, Acclimatization, Degree (temperature), Mitochondria, Trees, 03 medical and health sciences, Horticulture, 030104 developmental biology, 13. Climate action, Respiration, Plant Stomata, Mesophyll Cells, 010606 plant biology & botany

Abstract

The Kok and Laisk techniques can both be used to estimate light respiration Rlight . We investigated whether responses of Rlight to short- and long-term changes in leaf temperature depend on the technique used to estimate Rlight . We grew Eucalyptus tereticornis in whole-tree chambers under ambient temperature (AT) or AT + 3°C (elevated temperature, ET). We assessed dark respiration Rdark and light respiration with the Kok (RKok ) and Laisk (RLaisk ) methods at four temperatures to determine the degree of light suppression of respiration using both methods in AT and ET trees. The ET treatment had little impact on Rdark , RKok or RLaisk . Although the thermal sensitivities of RKok or RLaisk were similar, RKok was higher than RLaisk . We found negative values of RLaisk at the lowest measurement temperatures, indicating positive net CO2 uptake, which we propose may be related to phosphoenolpyruvate carboxylase activity. Light suppression of Rdark decreased with increasing leaf temperature, but the degree of suppression depended on the method used. The Kok and Laisk methods do not generate the same estimates of Rlight or light suppression of Rdark between 20 and 35°C. Negative rates of RLaisk imply that this method may become less reliable at low temperatures.

Published

2018