Your search keyword '"*LEAF temperature"' showing total 24 results

1. Rapid leaf xylem acclimation diminishes the chances of embolism in grapevines.

Author

Sorek, Yonatan, Netzer, Yishai, Cohen, Shabtai, and Hochberg, Uri

Subjects

*EMBOLISMS, *XYLEM, *ACCLIMATIZATION, *GRAPES, *LEAF temperature, *DROUGHTS, *VITIS vinifera, *HEAT waves (Meteorology), *PLANT-water relationships

Abstract

Under most conditions tight stomatal regulation in grapevines (Vitis vinifera) avoids xylem embolism. The current study evaluated grapevine responses to challenging scenarios that might lead to leaf embolism and consequential leaf damage. We hypothesized that embolism would occur if the vines experienced low xylem water potential (Ψx) shortly after bud break or later in the season under a combination of extreme drought and heat. We subjected vines to two potentially dangerous environments: (i) withholding irrigation from a vineyard grown in a heatwave-prone environment, and (ii) subjecting potted vines to terminal drought 1 month after bud break. In the field experiment, a heatwave at the beginning of August resulted in leaf temperatures over 45 °C. However, effective stomatal response maintained the xylem water potential (Ψx) well above the embolism threshold, and no leaf desiccation was observed. In the pot experiment, leaves of well-watered vines in May were relatively vulnerable to embolism with 50% embolism (P50) at –1.8 MPa. However, when exposed to drought, these leaves acclimated their leaf P50 by 0.65 MPa in less than a week and before reaching embolism values. When dried to embolizing Ψx, the leaf damage proportion matched (percentage-wise) the leaf embolism level. Our findings indicate that embolism and leaf damage are usually avoided by the grapevines' efficient stomatal regulation and rapid acclimation of their xylem vulnerability. [ABSTRACT FROM AUTHOR]

Published

2023

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

Author

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

Subjects

*MANGROVE plants, *THERMAL tolerance (Physiology), *ACCLIMATIZATION, *LEAF temperature, *BODY temperature regulation, *LEAF physiology, *RESPIRATION

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 (Q 10) 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. [ABSTRACT FROM AUTHOR]

Published

2023

3. Elevated [CO2] negatively impacts C4 photosynthesis under heat and water stress without penalizing biomass.

Author

Al-Salman, Yazen, Ghannoum, Oula, and Cano, Francisco Javier

Subjects

*BIOMASS, *PHOTOSYNTHESIS, *EVAPORATIVE cooling, *STOMATA, *DROUGHT tolerance, *LEAF temperature, *HEAT waves (Meteorology)

Abstract

Elevated [CO2] (eCO2) and water stress reduce leaf stomatal conductance (g s), which may affect leaf thermoregulation during heat waves (heat stress). Two sorghum lines, with different leaf width were grown in a glasshouse at a mean day temperature of 30 °C, under different [CO2] and watering levels, and subjected to heat stress (43 °C) for 6 d at the start of the reproductive stage. We measured leaf photosynthetic and stomatal responses to light transients before harvesting the plants. Photosynthesis at growth conditions (A growth) and biomass accumulation were enhanced by eCO2 under control conditions. Heat stress increased g s, especially in wider leaves, and reduced the time constant of stomatal opening (k open) at ambient [CO2] but not eCO2. However, heat stress reduced photosynthesis under water stress and eCO2 due to increased leaf temperature and reduced evaporative cooling. eCO2 prevented the reduction of biomass under both water and heat stress, possibly due to improved plant and soil water status as a result of reduced g s. Our results suggest that the response of the C4 crop sorghum to future climate conditions depends on the trade-off between low g s needed for high water use efficiency and drought tolerance, and the high g s needed for improved thermoregulation and heat tolerance under an eCO2 future. [ABSTRACT FROM AUTHOR]

Published

2023

4. Bioclimatic controls of CO2 assimilation near range limits of the CAM succulent tree Aloidendron dichotomum.

Author

Grey, Kerry-Anne, Foden, Wendy B, and Midgley, Guy F

Subjects

*CRASSULACEAN acid metabolism, *EFFECT of human beings on climate change, *SUCCULENT plants, *LEAF temperature, *PYRUVATE carboxylase

Abstract

Aloidendron dichotomum appears to be undergoing the early stages of a range shift in response to anthropogenic climate change in south-western Africa. High mortality has been recorded in warmer populations, while population expansions have been recorded in cooler poleward parts of its range. This study aimed to determine the key environmental controls on A. dichotomum photosynthesis in areas of population expansion, to inform the potential attribution of directional population expansion to anthropogenic warming. Nocturnal acid accumulation and CO2 assimilation were measured in individuals growing under a range of temperature and watering treatments in a greenhouse experiment. In addition, nocturnal acid accumulation and phospho enol pyruvate carboxylase activity were quantified in two wild populations at the most southerly and south-easterly range extents. Multiple lines of evidence confirmed that A. dichotomum performs Crassulacean acid metabolism. Total nocturnal acid accumulation was highest at night-time temperatures of ~21.5 °C, regardless of soil water availability, and night-time CO2 assimilation rates increased with leaf temperature, suggesting a causal link to the cool southern range limit. Leaf acidity at the start of the dark period was highly predictive of nocturnal acid accumulation in all individuals, implicating light availability during the day as an important determinant of nocturnal acid accumulation. [ABSTRACT FROM AUTHOR]

Published

2022

5. Maize PHYTOMELATONIN RECEPTOR1 functions in plant tolerance to osmotic and drought stress.

Author

Wang, Lin-Feng, Lu, Kai-Kai, Li, Ting-Ting, Zhang, Yu, Guo, Jia-Xing, Song, Ru-Feng, and Liu, Wen-Cheng

Subjects

*DROUGHT tolerance, *CORN, *LEAF temperature, *BLOOD proteins, *PLANT growth

Abstract

Phytomelatonin is a universal signal molecule that regulates plant growth and stress responses; however, only one receptor that can directly bind with and perceive melatonin signaling has been identified so far, namely AtPMTR1/CAND2 in Arabidopsis. Whether other plants contain a similar receptor and, if so, how it functions is still unknown. In this study, we identified a new phytomelatonin receptor in the monocot maize (Zea mays), and investigated its role in plant responses to osmotic and drought stress. Using homology searching, we identified a plasma membrane-localized protein, Zm00001eb214610/ZmPMTR1, with strong binding activity to melatonin as a potential phytomelatonin receptor in maize. Overexpressing ZmPMTR1 in Arabidopsis Col-0 promoted osmotic stress tolerance, and rescued osmotic stress sensitivity of the Arabidopsis cand2-1 mutant. Furthermore, ZmPMTR1 also largely rescued defects in melatonin-induced stomatal closure in the cand2-1 mutant, thereby reducing water loss rate and increasing tolerance to drought stress. In addition, we identified a maize mutant of ZmPMTR1 , EMS4-06e2fl , with a point-mutation causing premature termination of protein translation, and found that this mutant had lower leaf temperatures, increased rate of water loss, and enhanced drought stress sensitivity. Thus, we present ZmPMTR1 as the first phytomelatonin receptor to be identified and examined in a monocot plant, and our results indicate that it plays an important function in the response of maize to drought stress. [ABSTRACT FROM AUTHOR]

Published

2022

6. Updating the steady-state model of C4 photosynthesis.

Author

Caemmerer, Susanne von

Subjects

*SWITCHGRASS, *ELECTRON transport, *PHOTOSYNTHESIS, *SORGHUM, *GAS analysis, *LEAF temperature, *SETARIA

Abstract

C4 plants play a key role in world agriculture. For example, C4 crops such as maize and sorghum are major contributors to food production in both developed and developing countries, and the C4 grasses sugarcane, miscanthus, and switchgrass are major plant sources of bioenergy. In the challenge to manipulate and enhance C4 photosynthesis, steady-state models of leaf photosynthesis provide an important tool for gas exchange analysis and thought experiments that can explore photosynthetic pathway changes. Here a previous C4 photosynthetic model developed by von Caemmerer and Furbank has been updated with new kinetic parameterization and temperature dependencies added. The parameterization was derived from experiments on the C4 monocot, Setaria viridis , which for the first time provides a cohesive parameterization. Mesophyll conductance and its temperature dependence have also been included, as this is an important step in the quantitative correlation between the initial slope of the CO2 response curve of CO2 assimilation and in vitro phosphoenolpyruvate carboxylase activity. Furthermore, the equations for chloroplast electron transport have been updated to include cyclic electron transport flow, and equations have been added to calculate the electron transport rate from measured CO2 assimilation rates. [ABSTRACT FROM AUTHOR]

Published

2021

7. Effect of leaf temperature on the estimation of photosynthetic and other traits of wheat leaves from hyperspectral reflectance.

Author

Khan, Hammad A, Nakamura, Yukiko, Furbank, Robert T, and Evans, John R

Subjects

*LEAF temperature, *TEMPERATURE effect, *REFLECTANCE, *WHEAT, *LEAF area, *HYPERACCUMULATOR plants

Abstract

A growing number of leaf traits can be estimated from hyperspectral reflectance data. These include structural and compositional traits, such as leaf mass per area (LMA) and nitrogen and chlorophyll content, but also physiological traits such a Rubisco carboxylation activity, electron transport rate, and respiration rate. Since physiological traits vary with leaf temperature, how does this impact on predictions made from reflectance measurements? We investigated this with two wheat varieties, by repeatedly measuring each leaf through a sequence of temperatures imposed by varying the air temperature in a growth room. Leaf temperatures ranging from 20 °C to 35 °C did not alter the estimated Rubisco capacity normalized to 25 °C (V cmax25), or chlorophyll or nitrogen contents per unit leaf area. Models estimating LMA and V cmax25/N were both slightly influenced by leaf temperature: estimated LMA increased by 0.27% °C–1 and V cmax25/N increased by 0.46% °C–1. A model estimating Rubisco activity closely followed variation associated with leaf temperature. Reflectance spectra change with leaf temperature and therefore contain a temperature signal. [ABSTRACT FROM AUTHOR]

Published

2021

8. Elevated [CO2] negatively impacts C4 photosynthesis under heat and water stress without penalizing biomass

Author

Oula Ghannoum, Francisco Javier Cano, Yazen Al-Salman, Al-Salman, Yazen, Ghannoum, Oula, and Cano, F. J.

Subjects

Heat tolerance, C4 photosynthesis, Physiology, CO2 response, Plant Science, Stomatal kinetics, Drought response, Sorghum, Leaf temperature

Abstract

Elevated [CO2] (eCO2) and water stress reduce leaf stomatal conductance (gs), which may affect leaf thermoregulation during heat waves (heat stress). Two sorghum lines, with different leaf width were grown in a glasshouse at a mean day temperature of 30 °C, under different [CO2] and watering levels, and subjected to heat stress (43 °C) for 6 d at the start of the reproductive stage. We measured leaf photosynthetic and stomatal responses to light transients before harvesting the plants. Photosynthesis at growth conditions (Agrowth) and biomass accumulation were enhanced by eCO2 under control conditions. Heat stress increased gs, especially in wider leaves, and reduced the time constant of stomatal opening (kopen) at ambient [CO2] but not eCO2. However, heat stress reduced photosynthesis under water stress and eCO2 due to increased leaf temperature and reduced evaporative cooling. eCO2 prevented the reduction of biomass under both water and heat stress, possibly due to improved plant and soil water status as a result of reduced gs. Our results suggest that the response of the C4 crop sorghum to future climate conditions depends on the trade-off between low gs needed for high water use efficiency and drought tolerance, and the high gs needed for improved thermoregulation and heat tolerance under an eCO2 future.

Published

2023

9. Thermography methods to assess stomatal behaviour in a dynamic environment.

Author

Vialet-Chabrand, Silvere and Lawson, Tracy

Subjects

*THERMOGRAPHY, *WATER efficiency, *LEAF temperature, *PLANT-water relationships, *DYNAMIC balance (Mechanics), *REFERENCE sources

Abstract

Although thermography allows rapid, non-invasive measurements of large numbers of plants, it has not been used extensively due to the difficulty in deriving biologically relevant information such as leaf transpiration (E) and stomatal conductance (g sw) from thermograms. Methods normalizing leaf temperature using temperatures from reference materials (e.g. with and without evaporative flux) to generate stress indices are generally preferred due to their ease of use to assess plant water status. Here, a simplified method to solve dynamic energy balance equations is presented, which enables the calculation of 'wet' and 'dry' leaf temperatures in order to derive stress indices, whilst providing accurate estimates of E and g sw. Comparing stress indices and gas exchange parameters highlights the limitation of stress indices in a dynamic environment and how this problem can be overcome using artificial leaf references with known conductance. Additionally, applying the equations for each pixel of a thermogram to derive the rapidity of stomatal response over the leaf lamina in wheat revealed the spatial heterogeneity of stomatal behaviour. Rapidity of stomatal movements is an important determinant of water use efficiency, and our results showed 'patchy' responses that were linked to both the spatial and temporal response of g sw. [ABSTRACT FROM AUTHOR]

Published

2020

10. Updating the steady-state model of C4 photosynthesis

Author

Susanne von Caemmerer

Subjects

C4 photosynthesis, Physiology, Setaria Plant, Phosphoenolpyruvate carboxylase activity, Plant Science, Photosynthesis, chloroplast electron transport, PEP carboxylase, Carbon Cycle, Bioenergy, Review Papers, biology, A–Ci curves, Setaria viridis, AcademicSubjects/SCI01210, Miscanthus, leaf temperature, Carbon Dioxide, biology.organism_classification, Electron transport chain, Plant Leaves, Environmental science, CO2 diffusion, Biological system, Plant Sources

Abstract

C4 plants play a key role in world agriculture. For example, C4 crops such as maize and sorghum are major contributors to food production in both developed and developing countries, and the C4 grasses sugarcane, miscanthus, and switchgrass are major plant sources of bioenergy. In the challenge to manipulate and enhance C4 photosynthesis, steady-state models of leaf photosynthesis provide an important tool for gas exchange analysis and thought experiments that can explore photosynthetic pathway changes. Here a previous C4 photosynthetic model developed by von Caemmerer and Furbank has been updated with new kinetic parameterization and temperature dependencies added. The parameterization was derived from experiments on the C4 monocot, Setaria viridis, which for the first time provides a cohesive parameterization. Mesophyll conductance and its temperature dependence have also been included, as this is an important step in the quantitative correlation between the initial slope of the CO2 response curve of CO2 assimilation and in vitro phosphoenolpyruvate carboxylase activity. Furthermore, the equations for chloroplast electron transport have been updated to include cyclic electron transport flow, and equations have been added to calculate the electron transport rate from measured CO2 assimilation rates., Update of a C4 photosynthesis model developed by von Caemmerer and Furbank to include temperature dependencies and equations to calculate the electron transport rate from measured CO2 assimilation rates.

Published

2021

11. Increase in leaf temperature opens stomata and decouples net photosynthesis from stomatal conductance in Pinus taeda and Populus deltoides x nigra.

Author

Urban, Josef, Ingwers, Miles W., McGuire, Mary Anne, and Teskey, Robert O.

Subjects

*GAS exchange in plants, *LEAF temperature, *STOMATA, *LOBLOLLY pine, *COTTONWOOD

Abstract

The effect of temperature on stomatal conductance (gs) and corresponding gas exchange parameters was studied in two tree species with contrasting leaf anatomy and ecophysiology--a broadleaf angiosperm, Populus deltoides x nigra (poplar), and a needle-leaf gymnosperm, Pinus taeda (loblolly pine). Experiments were conducted in growth chambers across a leaf temperature range of 19-48°C. Manipulations of temperature were done in well-watered and drought soil conditions and under ambient (400 ppm) and elevated (800 ppm) air CO2 concentrations. Increases in leaf temperature caused stomatal opening at both ambient and elevated [CO2]. The gs increased by 42% in poplar and by 40% in loblolly pine when leaf temperature increased from 30°C to 40°C at a vapour pressure difference of 1 kPa. Stomatal limitation to photosynthesis decreased in elevated temperature in loblolly pine but not in poplar. The ratio of net photosynthesis to gs depended on leaf temperature, especially at high temperatures. Evaporative cooling of transpiring leaves resulted in reductions in leaf temperature up to 9°C in well-watered poplar but only 1°C in drought-stressed poplar and in loblolly pine. As global mean temperatures rise and temperature extremes become more frequent and severe, understanding the effect of temperature on gs, and modelling that relationship, will become increasingly important. [ABSTRACT FROM AUTHOR]

Published

2017

12. Elevated [CO2] negatively impacts C4 photosynthesis under heat and water stress without penalizing biomass.

Author

Al-Salman Y, Ghannoum O, and Cano FJ

Subjects

Biomass, Photosynthesis physiology, Plant Leaves physiology, Edible Grain, Carbon Dioxide, Dehydration

Abstract

Elevated [CO2] (eCO2) and water stress reduce leaf stomatal conductance (gs), which may affect leaf thermoregulation during heat waves (heat stress). Two sorghum lines, with different leaf width were grown in a glasshouse at a mean day temperature of 30 °C, under different [CO2] and watering levels, and subjected to heat stress (43 °C) for 6 d at the start of the reproductive stage. We measured leaf photosynthetic and stomatal responses to light transients before harvesting the plants. Photosynthesis at growth conditions (Agrowth) and biomass accumulation were enhanced by eCO2 under control conditions. Heat stress increased gs, especially in wider leaves, and reduced the time constant of stomatal opening (kopen) at ambient [CO2] but not eCO2. However, heat stress reduced photosynthesis under water stress and eCO2 due to increased leaf temperature and reduced evaporative cooling. eCO2 prevented the reduction of biomass under both water and heat stress, possibly due to improved plant and soil water status as a result of reduced gs. Our results suggest that the response of the C4 crop sorghum to future climate conditions depends on the trade-off between low gs needed for high water use efficiency and drought tolerance, and the high gs needed for improved thermoregulation and heat tolerance under an eCO2 future., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2023

13. The α-subunit of the rice heterotrimeric G protein, RGA1, regulates drought tolerance during the vegetative phase in the dwarf rice mutant d1.

Author

Ferrero-Serrano, Ángel and Assmann, Sarah M.

Subjects

*RICE, *G proteins, *DROUGHT tolerance, *PLANT mutation, *RICE varieties, *PHOTOSYNTHESIS

Abstract

Essential in the Green Revolution was the development of high-yielding dwarf varieties of rice (Oryza sativa L.), but their selection was not based on responses to water limitation. We studied physiological responses to progressive drought of the dwarf rice mutant, d1, in which the RGA1 gene, which encodes the GTP-binding a-subunit of the heterotrimeric G protein, is non-functional. Wild-type (WT) plants cease net carbon fixation 11 days after water is withheld, while d1 plants maintain net photosynthesis for an additional week. During drought, d1 plants exhibit greater stomatal conductance than the WT, but both genotypes exhibit the same transpirational water loss per unit leaf area. This is explained by a smaller driving force for water loss in d1 owing to its lower leaf temperatures, consistent with its more erect architecture. As drought becomes more severe, WT plants show an accelerated decline in photosynthesis, which may be exacerbated by the higher leaf temperatures in the WT. We thus show how a rice mutant with dwarf and erect leaves has a decreased susceptibility to water stress. Accordingly, it may be useful to incorporate RGA1 mutation in breeding or biotechnological strategies for development of drought-resistant rice. [ABSTRACT FROM AUTHOR]

Published

2016

14. Estimating evapotranspiration and drought stress with ground-based thermal remote sensing in agriculture: a review.

Author

Maes, W. H. and Steppe, K.

Subjects

*EVAPOTRANSPIRATION, *DROUGHT tolerance, *REMOTE sensing, *AGRICULTURE, *EFFECT of temperature on plants, *GRAPES, *PLANT canopies

Abstract

As evaporation of water is an energy-demanding process, increasing evapotranspiration rates decrease the surface temperature (Ts) of leaves and plants. Based on this principle, ground-based thermal remote sensing has become one of the most important methods for estimating evapotranspiration and drought stress and for irrigation. This paper reviews its application in agriculture. The review consists of four parts. First, the basics of thermal remote sensing are briefly reviewed. Second, the theoretical relation between Ts and the sensible and latent heat flux is elaborated. A modelling approach was used to evaluate the effect of weather conditions and leaf or vegetation properties on leaf and canopy temperature. Ts increases with increasing air temperature and incoming radiation and with decreasing wind speed and relative humidity. At the leaf level, the leaf angle and leaf dimension have a large influence on Ts; at the vegetation level, Ts is strongly impacted by the roughness length; hence, by canopy height and structure. In the third part, an overview of the different ground-based thermal remote sensing techniques and approaches used to estimate drought stress or evapotranspiration in agriculture is provided. Among other methods, stress time, stress degree day, crop water stress index (CWSI), and stomatal conductance index are discussed. The theoretical models are used to evaluate the performance and sensitivity of the most important methods, corroborating the literature data. In the fourth and final part, a critical view on the future and remaining challenges of ground-based thermal remote sensing is presented. [ABSTRACT FROM PUBLISHER]

Published

2012

15. Visible foliar injury and infrared imaging show that daylength affects short-term recovery after ozone stress in Trifolium subterraneum.

Author

Vollsnes, Ane V., Eriksen, Aud Berglen, Otterholt, Eli, Kvaal, Knut, Oxaal, Unni, and Futsaether, Cecilia M.

Subjects

*SUBTERRANEAN clover, *EFFECT of ozone on plants, *OZONE, *INFRARED imaging, *LEAVES

Abstract

Tropospheric ozone is a major air pollutant affecting plants worldwide. Plants in northern regions can display more ozone injury than plants at lower latitudes despite lower ozone levels. Larger ozone influx and shorter nights have been suggested as possible causes. However, the effects of the dim light present during northern summer nights have not been investigated. Young Trifolium subterraneum plants kept in environmentally controlled growth rooms under long day (10 h bright light, 14 h dim light) or short day (10 h bright light, 14 h darkness) conditions were exposed to 6 h of 70 ppb ozone during daytime for three consecutive days. Leaves were visually inspected and imaged in vivo using thermal imaging before and after the daily exposure. In long-day-treated plants, visible foliar injury within 1 week after exposure was more severe. Multivariate statistical analyses showed that the leaves of ozone-exposed long-day-treated plants were also warmer with more homogeneous temperature distributions than exposed short day and control plants, suggesting reduced transpiration. Temperature disruptions were not restricted to areas displaying visible damage and occurred even in leaves with only slight visible injury. Ozone did not affect the leaf temperature of short-day-treated plants. As all factors influencing ozone influx were the same for long- and short-day-treated plants, only the dim nocturnal light could account for the different ozone sensitivities. Thus, the twilight summer nights at high latitudes may have a negative effect on repair and defence processes activated after ozone exposure, thereby enhancing sensitivity. [ABSTRACT FROM PUBLISHER]

Published

2009

16. Exploring thermal imaging variables for the detection of stress responses in grapevine under different irrigation regimes.

Author

Grant, Olga M., Tronina, Ł ukasz, Jones, Hamlyn G., and Chaves, M. Manuela

Subjects

*CHEMIGATION, *GRAPES, *WATER in agriculture, *SOIL moisture, *AGRICULTURAL experimentation

Abstract

Temperatures of leaves or canopies can be used as indicators of stomatal closure in response to soil water deficit. In 2 years of field experiments with grapevines (Vitis vinifera L., cvs Castelão and Aragonês), it was found that thermal imaging can distinguish between irrigated and non-irrigated canopies, and even between deficit irrigation treatments. Average canopy temperature was inversely correlated with stomatal conductance measured with a porometer. Variation of the distribution of temperatures within canopies was not found to be a reliable indicator of stress. A large degree of variation between images was found in reference ‘wet’ and ‘dry’ leaves used in the first year for the calculation of an index proportional to stomatal conductance. In the second year, fully irrigated (FI) (100% Etc) and non-irrigated (NI) canopies were used as alternatives to wet and dry leaves. A crop water stress index utilizing these FI and NI ‘references’, where stressed canopies have the highest values and non-stressed canopies have the lowest values, was found to be a suitable measure for detecting stress. It is suggested that the average temperatures of areas of canopies containing several leaves may be more useful for distinguishing between irrigation treatments than the temperatures of individual leaves. Average temperatures over several leaves per canopy may be expected to reduce the impact of variation in leaf angles. The results are discussed in relation to the application of thermal imaging to irrigation scheduling and monitoring crop performance. [ABSTRACT FROM PUBLISHER]

Published

2007

17. 3D lidar imaging for detecting and understanding plant responses and canopy structure.

Author

Omasa, Kenji, Hosoi, Fumiki, and Konishi, Atsumi

Subjects

*REJUVENESCENCE (Botany), *CHLOROPLAST pigments, *LEAF temperature, *GASES from plants, *PLANT photorespiration

Abstract

Understanding and diagnosing plant responses to stress will benefit greatly from three-dimensional (3D) measurement and analysis of plant properties because plant responses are strongly related to their 3D structures. Light detection and ranging (lidar) has recently emerged as a powerful tool for direct 3D measurement of plant structure. Here the use of 3D lidar imaging to estimate plant properties such as canopy height, canopy structure, carbon stock, and species is demonstrated, and plant growth and shape responses are assessed by reviewing the development of lidar systems and their applications from the leaf level to canopy remote sensing. In addition, the recent creation of accurate 3D lidar images combined with natural colour, chlorophyll fluorescence, photochemical reflectance index, and leaf temperature images is demonstrated, thereby providing information on responses of pigments, photosynthesis, transpiration, stomatal opening, and shape to environmental stresses; these data can be integrated with 3D images of the plants using computer graphics techniques. Future lidar applications that provide more accurate dynamic estimation of various plant properties should improve our understanding of plant responses to stress and of interactions between plants and their environment. Moreover, combining 3D lidar with other passive and active imaging techniques will potentially improve the accuracy of airborne and satellite remote sensing, and make it possible to analyse 3D information on ecophysiological responses and levels of various substances in agricultural and ecological applications and in observations of the global biosphere. [ABSTRACT FROM PUBLISHER]

Published

2007

18. Thermal imaging of cucumber leaves affected by downy mildew and environmental conditions.

Author

Oerke, E-C., Steiner, U., Dehne, H-W., and Lindenthal, M.

Subjects

*PSEUDOPERONOSPORA, *CUCUMBER diseases & pests, *DOWNY mildew diseases, *LEAVES, *PLANT diseases

Abstract

Pathogenesis of Pseudoperonospora cubensis causing downy mildew of cucumber resulted in changes in the metabolic processes within cucumber leaves including the transpiration rate. Due to the negative correlation between transpiration rate and leaf temperature, digital infrared thermography permitted a noninvasive monitoring and an indirect visualization of downy mildew development. Depending on the stage of pathogenesis and the topology of chloroses and necroses, infection resulted in a typical temperature pattern. Spatial heterogeneity of the leaf temperature could be quantified by the maximum temperature difference (MTD) within a leaf. The MTD increased during pathogenesis with the formation of necrotic tissue and was related to disease severity as described by linear and quadratic regression curves. Under controlled conditions, changes in temperature of infected leaves allowed the discrimination between healthy and infected areas in thermograms, even before visible symptoms of downy mildew appeared. Environmental conditions during thermographic measurement, in particular air temperature and humidity, as well as water content and age of the leaf influenced the temperature of its surface. Conditions enhancing the transpiration rate facilitated the detection of changes in leaf temperature of infected leaves at early stages of infection. As modified by environmental conditions, MTD alone is not suitable for the quantification of downy mildew severity in the field. [ABSTRACT FROM AUTHOR]

Published

2006

19. Leaf movements and photoinhibition in relation to water stress in field-grown beans.

Author

Pastenes, Claudio, Pimentel, Paula, and Lillo, Jacob

Subjects

*PLANT photoinhibition, *PLANT-water relationships, *LEAF temperature, *STOMATA, *LEAF anatomy

Abstract

Photoinhibition in plants depends on the extent of light energy being absorbed in excess of what can be used in photochemistry and is expected to increase as environmental constraints limit CO2 assimilation. Water stress induces the closure of stomata, limiting carbon availability at the carboxylation sites in the chloroplasts and, therefore, resulting in an excessive excitation of the photosynthetic apparatus, particularly photosystem II (PSII). Mechanisms have evolved in plants in order to protect against photoinhibition, such as non-photochemical energy dissipation, chlorophyll concentration changes, chloroplast movements, increases in the capacity for scavenging the active oxygen species, and leaf movement or paraheliotropism, avoiding direct exposure to sun. In beans (Phaseolus vulgaris L.), paraheliotropism seems to be an important feature of the plant to avoid photoinhibition. The extent of the leaf movement is increased as the water potential drops, reducing light interception and maintaining a high proportion of open PSII reaction centres. Photoinhibition in water-stressed beans, measured as the capacity to recover Fv/Fm, is not higher than in well-watered plants and leaf temperature is maintained below the ambient, despite the closure of stomata. Bean leaves restrained from moving, increase leaf temperature and reduce qP, the content of D1 protein and the capacity to recover Fv/Fm after dark adaptation, the extent of such changes being higher in water-stressed plants. Data are presented suggesting that even though protective under water stress, paraheliotropism, by reducing light interception, affects the capacity to maintain high CO2 assimilation rates throughout the day in well-watered plants. [ABSTRACT FROM PUBLISHER]

Published

2005

20. Use of infrared thermography for monitoring stomatal closure in the field: application to grapevine.

Author

Jones, Hamlyn G., Stoll, Manfred, Santos, Tiago, De Sousa, Claudia, Chaves, M. Manuela, and Grant, Olga M.

Subjects

*INFRARED imaging, *THERMOGRAPHY, *GRAPES, *STOMATA, *PLANT-water relationships

Abstract

This paper reviews and discusses strategies for the use of thermal imaging for studies of stomatal conductance in the field and compares techniques for image collection and analysis. Measurements were taken under a range of environmental conditions and on sunlit and shaded canopies to illustrate the variability of temperatures and derived stress indices. A simple procedure is presented for correcting for calibration drift within the images from the low-cost thermal imager used (SnapShot 225, Infrared Solutions, Inc.). The use of wet and dry reference surfaces as thresholds to eliminate the inclusion of non-leaf material in the analysis of canopy temperature is discussed. An index that is proportional to stomatal conductance was compared with stomatal measurements with a porometer. The advantages and disadvantages of a possible new approach to the use of thermal imagery for the detection of stomatal closure in grapevine canopies, based on an analysis of the temperature of shaded leaves, rather than sunlit leaves, are discussed. Evidence is presented that the temperature of reference surfaces exposed within the canopy can be affected by the canopy water status. [ABSTRACT FROM AUTHOR]

Published

2002

21. The α-subunit of the rice heterotrimeric G protein, RGA1, regulates drought tolerance during the vegetative phase in the dwarf rice mutant d1

Author

Sarah M. Assmann and Ángel Ferrero-Serrano

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, heterotrimeric G protein, Physiology, Mutant, Drought tolerance, Oryza sativa, Plant Science, drought, Biology, Photosynthesis, 01 natural sciences, 03 medical and health sciences, d1, Heterotrimeric G protein, Cultivar, Plant Proteins, musculoskeletal, neural, and ocular physiology, fungi, Plant physiology, food and beverages, rice, Oryza, leaf temperature, GTP-Binding Protein alpha Subunits, Droughts, 030104 developmental biology, Agronomy, RGA1, Mutation, 010606 plant biology & botany, circulatory and respiratory physiology, Research Paper

Abstract

Highlight The rice d1 Gα mutant with dwarf and erect leaves exhibits a lower leaf temperature and reduced susceptibility to water stress., Essential in the Green Revolution was the development of high-yielding dwarf varieties of rice (Oryza sativa L.), but their selection was not based on responses to water limitation. We studied physiological responses to progressive drought of the dwarf rice mutant, d1, in which the RGA1 gene, which encodes the GTP-binding α-subunit of the heterotrimeric G protein, is non-functional. Wild-type (WT) plants cease net carbon fixation 11 days after water is withheld, while d1 plants maintain net photosynthesis for an additional week. During drought, d1 plants exhibit greater stomatal conductance than the WT, but both genotypes exhibit the same transpirational water loss per unit leaf area. This is explained by a smaller driving force for water loss in d1 owing to its lower leaf temperatures, consistent with its more erect architecture. As drought becomes more severe, WT plants show an accelerated decline in photosynthesis, which may be exacerbated by the higher leaf temperatures in the WT. We thus show how a rice mutant with dwarf and erect leaves has a decreased susceptibility to water stress. Accordingly, it may be useful to incorporate RGA1 mutation in breeding or biotechnological strategies for development of drought-resistant rice.

Published

2016

22. Updating the steady-state model of C4 photosynthesis.

Author

von Caemmerer S

Subjects

Carbon Cycle, Photosynthesis, Plant Leaves, Carbon Dioxide, Setaria Plant

Abstract

C4 plants play a key role in world agriculture. For example, C4 crops such as maize and sorghum are major contributors to food production in both developed and developing countries, and the C4 grasses sugarcane, miscanthus, and switchgrass are major plant sources of bioenergy. In the challenge to manipulate and enhance C4 photosynthesis, steady-state models of leaf photosynthesis provide an important tool for gas exchange analysis and thought experiments that can explore photosynthetic pathway changes. Here a previous C4 photosynthetic model developed by von Caemmerer and Furbank has been updated with new kinetic parameterization and temperature dependencies added. The parameterization was derived from experiments on the C4 monocot, Setaria viridis, which for the first time provides a cohesive parameterization. Mesophyll conductance and its temperature dependence have also been included, as this is an important step in the quantitative correlation between the initial slope of the CO2 response curve of CO2 assimilation and in vitro phosphoenolpyruvate carboxylase activity. Furthermore, the equations for chloroplast electron transport have been updated to include cyclic electron transport flow, and equations have been added to calculate the electron transport rate from measured CO2 assimilation rates., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2021

23. Visible foliar injury and infrared imaging show that daylength affects short-term recovery after ozone stress in Trifolium subterraneum

Author

Eli Otterholt, Knut Kvaal, Unni Oxaal, Ane V. Vollsnes, Aud Berglen Eriksen, and Cecilia M. Futsaether

Subjects

Trifolium subterraneum, Ozone, Light, Physiology, principal component analysis, Photoperiod, Plant Science, Nocturnal, transpiration, chemistry.chemical_compound, Stress, Physiological, Botany, thermal imaging, Tropospheric ozone, Ecosystem, Transpiration, photoperiodism, Pollutant, biology, Temperature, food and beverages, visible foliar injury, Daylength, leaf temperature, biology.organism_classification, Research Papers, thermography, Plant Leaves, Horticulture, ozone, chemistry, Darkness, Environmental science, Trifolium

Abstract

Tropospheric ozone is a major air pollutant affecting plants worldwide. Plants in northern regions can display more ozone injury than plants at lower latitudes despite lower ozone levels. Larger ozone influx and shorter nights have been suggested as possible causes. However, the effects of the dim light present during northern summer nights have not been investigated. Young Trifolium subterraneum plants kept in environmentally controlled growth rooms under long day (10 h bright light, 14 h dim light) or short day (10 h bright light, 14 h darkness) conditions were exposed to 6 h of 70 ppb ozone during daytime for three consecutive days. Leaves were visually inspected and imaged in vivo using thermal imaging before and after the daily exposure. In long-day-treated plants, visible foliar injury within 1 week after exposure was more severe. Multivariate statistical analyses showed that the leaves of ozone-exposed long-day-treated plants were also warmer with more homogeneous temperature distributions than exposed short day and control plants, suggesting reduced transpiration. Temperature disruptions were not restricted to areas displaying visible damage and occurred even in leaves with only slight visible injury. Ozone did not affect the leaf temperature of short-day-treated plants. As all factors influencing ozone influx were the same for long- and short-day-treated plants, only the dim nocturnal light could account for the different ozone sensitivities. Thus, the twilight summer nights at high latitudes may have a negative effect on repair and defence processes activated after ozone exposure, thereby enhancing sensitivity.

Published

2009

24. How do changes in temperature during growth affect leaf pigment composition and photosynthesis in genotypes differing in sensitivity to low temperature?

Author

Haldimann, P

Subjects

*EFFECT of temperature on corn, *PLANT pigments, *PHOTOSYNTHESIS, *LEAF temperature, *EFFECT of temperature on plants

Abstract

Examines the changes in photosynthetic activity and composition of pigments induced by changes in temperature in the leaf of chilling-tolerant and chilling-sensitive genotypes of maize Zea mays. Conversion of zeaxanthin to violaxanthin in the xanthophyll cycle; Formation of a competent photosynthetic apparatus at low temperature; Components of the carotenoid pool.

Published

1999