Your search keyword '"leaf dark respiration"' showing total 9 results

1. Hyperspectral reflectance integrates key traits for predicting leaf metabolism.

Author

Magney TS

Published

2024

2. Limited thermal acclimation of photosynthesis in tropical montane tree species.

Author

Dusenge ME, Wittemann M, Mujawamariya M, Ntawuhiganayo EB, Zibera E, Ntirugulirwa B, Way DA, Nsabimana D, Uddling J, and Wallin G

Subjects

Acclimatization, Carbon Dioxide, Forests, Plant Leaves metabolism, Ribulose-Bisphosphate Carboxylase metabolism, Temperature, Photosynthesis, Trees metabolism

Abstract

The temperature sensitivity of physiological processes and growth of tropical trees remains a key uncertainty in predicting how tropical forests will adjust to future climates. In particular, our knowledge regarding warming responses of photosynthesis, and its underlying biochemical mechanisms, is very limited. We grew seedlings of two tropical montane rainforest tree species, the early-successional species Harungana montana and the late-successional species Syzygium guineense, at three different sites along an elevation gradient, differing by 6.8℃ in daytime ambient air temperature. Their physiological and growth performance was investigated at each site. The optimum temperature of net photosynthesis (T optA ) did not significantly increase in warm-grown trees in either species. Similarly, the thermal optima (T optV and T optJ ) and activation energies (E aV and E aJ ) of maximum Rubisco carboxylation capacity (V cmax ) and maximum electron transport rate (J max ) were largely unaffected by warming. However, V cmax , J max and foliar dark respiration (R d ) at 25℃ were significantly reduced by warming in both species, and this decline was partly associated with concomitant reduction in total leaf nitrogen content. The ratio of J max /V cmax decreased with increasing leaf temperature for both species, but the ratio at 25℃ was constant across sites. Furthermore, in H. montana, stomatal conductance at 25℃ remained constant across the different temperature treatments, while in S. guineense it increased with warming. Total dry biomass increased with warming in H. montana but remained constant in S. guineense. The biomass allocated to roots, stem and leaves was not affected by warming in H. montana, whereas the biomass allocated to roots significantly increased in S. guineense. Overall, our findings show that in these two tropical montane rainforest tree species, the capacity to acclimate the thermal optimum of photosynthesis is limited while warming-induced reductions in respiration and photosynthetic capacity rates are tightly coupled and linked to responses of leaf nitrogen., (© 2021 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2021

3. What happens at night? Physiological mechanisms related to maintaining grain yield under high night temperature in rice.

Author

Xu J, Misra G, Sreenivasulu N, and Henry A

Subjects

Carbohydrate Metabolism, Darkness, Genome-Wide Association Study, Hot Temperature, Philippines, Plant Leaves physiology, Plant Stems genetics, Plant Stems metabolism, Polymorphism, Single Nucleotide, Spectroscopy, Fourier Transform Infrared, Oryza physiology, Seeds growth & development, Thermotolerance physiology

Abstract

High night temperature (HNT) causes substantial yield loss in rice (Oryza sativa L.). In this study, the physiological processes related to flag leaf dark respiration (Rn) and grain filling under HNT were explored in a multi-parent advanced generation intercross population developed for heat tolerance (MAGIC heat ) along with selected high temperature tolerant breeding lines developed with heat-tolerant parents. Within a subset of lines, flag leaf Rn under HNT treatment was related to lower spikelet number per panicle and thus reduced yield. HNT enhanced the nighttime reduction of non-structural carbohydrates (NSC) in stem tissue, but not in leaves, and stem nighttime NSC reduction was negatively correlated with yield. Between heading and harvest, the major difference in NSC concentration was found for starch, but not for soluble sugar. HNT weakened the relationship between NSC remobilization and harvest index at both the phenotypic and genetic level. By using genome-wide association studies, an invertase inhibitor, MADS box transcription factors and a UDP-glycosyltransferase that were identified as candidate genes orchestrating stem NSC remobilization in the control treatment were lost under HNT. With the identification of physiological and genetic components related to rice HNT response, this study offers promising prebreeding materials and trait targets to sustain yield stability under climate change., (© 2021 John Wiley & Sons Ltd.)

Published

2021

4. Diel- and temperature-driven variation of leaf dark respiration rates and metabolite levels in rice.

Author

Rashid FAA, Scafaro AP, Asao S, Fenske R, Dewar RC, Masle J, Taylor NL, and Atkin OK

Subjects

Carbon Dioxide, Cell Respiration, Photosynthesis, Plant Leaves, Respiratory Rate, Temperature, Oryza

Abstract

Leaf respiration in the dark (R dark ) is often measured at a single time during the day, with hot-acclimation lowering R dark at a common measuring temperature. However, it is unclear whether the diel cycle influences the extent of thermal acclimation of R dark , or how temperature and time of day interact to influence respiratory metabolites. To examine these issues, we grew rice under 25°C : 20°C, 30°C : 25°C and 40°C : 35°C day : night cycles, measuring R dark and changes in metabolites at five time points spanning a single 24-h period. R dark differed among the treatments and with time of day. However, there was no significant interaction between time and growth temperature, indicating that the diel cycle does not alter thermal acclimation of R dark . Amino acids were highly responsive to the diel cycle and growth temperature, and many were negatively correlated with carbohydrates and with organic acids of the tricarboxylic acid (TCA) cycle. Organic TCA intermediates were significantly altered by the diel cycle irrespective of growth temperature, which we attributed to light-dependent regulatory control of TCA enzyme activities. Collectively, our study shows that environmental disruption of the balance between respiratory substrate supply and demand is corrected for by shifts in TCA-dependent metabolites., (© 2020 The Authors. New Phytologist © 2020 New Phytologist Trust.)

Published

2020

5. Transgenic maize phosphoenolpyruvate carboxylase alters leaf-atmosphere CO 2 and 13 CO 2 exchanges in Oryza sativa.

Author

Giuliani R, Karki S, Covshoff S, Lin HC, Coe RA, Koteyeva NK, Evans MA, Quick WP, von Caemmerer S, Furbank RT, Hibberd JM, Edwards GE, and Cousins AB

Subjects

Cell Respiration, Malates metabolism, Mesophyll Cells metabolism, Photosynthesis, Plant Leaves physiology, Plant Proteins metabolism, Plants, Genetically Modified, Atmosphere chemistry, Carbon Dioxide metabolism, Carbon Isotopes chemistry, Oryza metabolism, Phosphoenolpyruvate Carboxylase metabolism, Plant Leaves metabolism, Zea mays enzymology, Zea mays genetics

Abstract

The engineering process of C 4 photosynthesis into C 3 plants requires an increased activity of phosphoenolpyruvate carboxylase (PEPC) in the cytosol of leaf mesophyll cells. The literature varies on the physiological effect of transgenic maize (Zea mays) PEPC (ZmPEPC) leaf expression in Oryza sativa (rice). Therefore, to address this issue, leaf-atmosphere CO 2 and 13 CO 2 exchanges were measured, both in the light (at atmospheric O 2 partial pressure of 1.84 kPa and at different CO 2 levels) and in the dark, in transgenic rice expressing ZmPEPC and wild-type (WT) plants. The in vitro PEPC activity was 25 times higher in the PEPC overexpressing (PEPC-OE) plants (~20% of maize) compared to the negligible activity in WT. In the PEPC-OE plants, the estimated fraction of carboxylation by PEPC (β) was ~6% and leaf net biochemical discrimination against 13 CO 2 [Formula: see text] was ~ 2‰ lower than in WT. However, there were no differences in leaf net CO 2 assimilation rates (A) between genotypes, while the leaf dark respiration rates (R d ) over three hours after light-dark transition were enhanced (~ 30%) and with a higher 13 C composition [Formula: see text] in the PEPC-OE plants compared to WT. These data indicate that ZmPEPC in the PEPC-OE rice plants contributes to leaf carbon metabolism in both the light and in the dark. However, there are some factors, potentially posttranslational regulation and PEP availability, which reduce ZmPEPC activity in vivo.

Published

2019

6. Knockdown of glycine decarboxylase complex alters photorespiratory carbon isotope fractionation in Oryza sativa leaves.

Author

Giuliani R, Karki S, Covshoff S, Lin HC, Coe RA, Koteyeva NK, Quick WP, Von Caemmerer S, Furbank RT, Hibberd JM, Edwards GE, and Cousins AB

Subjects

Cell Respiration, Glycine Decarboxylase Complex metabolism, Oryza enzymology, Oryza metabolism, Plant Leaves enzymology, Plant Leaves metabolism, Plant Proteins metabolism, Carbon Isotopes analysis, Glycine Decarboxylase Complex genetics, Oryza genetics, Photosynthesis, Plant Proteins genetics

Abstract

The influence of reduced glycine decarboxylase complex (GDC) activity on leaf atmosphere CO2 and 13CO2 exchange was tested in transgenic Oryza sativa with the GDC H-subunit knocked down in leaf mesophyll cells. Leaf measurements on transgenic gdch knockdown and wild-type plants were carried out in the light under photorespiratory and low photorespiratory conditions (i.e. 18.4 kPa and 1.84 kPa atmospheric O2 partial pressure, respectively), and in the dark. Under approximately current ambient O2 partial pressure (18.4 kPa pO2), the gdch knockdown plants showed an expected photorespiratory-deficient phenotype, with lower leaf net CO2 assimilation rates (A) than the wild-type. Additionally, under these conditions, the gdch knockdown plants had greater leaf net discrimination against 13CO2 (Δo) than the wild-type. This difference in Δo was in part due to lower 13C photorespiratory fractionation (f) ascribed to alternative decarboxylation of photorespiratory intermediates. Furthermore, the leaf dark respiration rate (Rd) was enhanced and the 13CO2 composition of respired CO2 (δ13CRd) showed a tendency to be more depleted in the gdch knockdown plants. These changes in Rd and δ13CRd were due to the amount and carbon isotopic composition of substrates available for dark respiration. These results demonstrate that impairment of the photorespiratory pathway affects leaf 13CO2 exchange, particularly the 13C decarboxylation fractionation associated with photorespiration., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2019

7. [Differences of leaf dark respiration and light inhibition between saplings and mature trees of Pinus koraiensis and Tilia amurensis.]

Author

Sun JW, Yao FQ, and Zhang ZH

Subjects

Ecosystem, Forests, Pinus physiology, Sunlight, Tilia physiology, Trees

Abstract

Leaf dark respiration is an important component of carbon cycle. Understanding the differences of leaf dark respiration and light inhibition between saplings and mature trees is important for accurate estimation of ecosystem gross primary productivity (GPP). We meansured leaf dark respiration of saplings and mature trees of two dominant species (Pinus koraiensis and Tilia amurensis) in light and in darkness in the broadleaved-Korean pine mixed forest on Changbai Mountain. Differences of leaf dark respiration, light inhibition and leaf physiological and ecological parameters between saplings and mature trees were analyzed. The reason of differences on leaf dark respiration and the light inhibition were explored. The results showed that leaf dark respiration of saplings of two species under light was 6.8%-39.6% higher than that of mature trees in growing season. Light inhibition of leaf dark respiration in saplings was 2.5%-14.1% lower than in mature trees. The difference of light inhibition of leaf dark respiration between saplings and mature trees of P. koraiensis was higher than that of T. amurensis, with a maximum difference of 18.6%. The higher leaf dark respiration and lower light inhibition degree in saplings might result from the changes of max net photosynthesis rate, specific leaf area, and stomatal conductance, instead of leaf nitrogen content.

Published

2019

8. Early and late adjustments of the photosynthetic traits and stomatal density in Quercus ilex L. grown in an ozone-enriched environment.

Author

Fusaro L, Gerosa G, Salvatori E, Marzuoli R, Monga R, Kuzminsky E, Angelaccio C, Quarato D, and Fares S

Subjects

Environment, Oxidative Stress, Plant Leaves drug effects, Plant Leaves physiology, Plant Stomata drug effects, Plant Stomata physiology, Quercus drug effects, Reproducibility of Results, Seasons, Seedlings drug effects, Seedlings physiology, Ozone adverse effects, Photosynthesis drug effects, Plant Transpiration drug effects, Quercus physiology

Abstract

Quercus ilex L. seedlings were exposed in open-top chambers for one growing season to three levels of ozone (O3 ): charcoal filtered air, non-filtered air supplemented with +30% or +74% ambient air O3 . Key functional parameters related to photosynthetic performance and stomatal density were measured to evaluate the response mechanisms of Q. ilex to chronic O3 exposure, clarifying how ecophysiological traits are modulated during the season in an ozone-enriched environment. Dark respiration showed an early response to O3 exposure, increasing approximately 45% relative to charcoal-filtered air in both O3 enriched treatments. However, at the end of the growing season, maximum rate of assimilation (Amax ) and stomatal conductance (gs ) showed a decline (-13% and -36%, for Amax and gs , respectively) only in plants under higher O3 levels. Photosystem I functionality supported the capacity of Q. ilex to cope with oxidative stress by adjusting the energy flow partitioning inside the photosystems. The response to O3 was also characterised by increased stomatal density in both O3 enriched treatments relative to controls. Our results suggest that in order to improve the reliability of metrics for O3 risk assessment, the seasonal changes in the response of gs and photosynthetic machinery to O3 stress should be considered., (© 2015 German Botanical Society and The Royal Botanical Society of the Netherlands.)

Published

2016

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

Author

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

Subjects

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

Abstract

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

Published

2015