Your search keyword '"Kathy Steppe"' showing total 335 results

1. Leaf morphology, optical characteristics and phytochemical traits of butterhead lettuce affected by increasing the far-red photon flux

Author

Ellen Van de Velde, Kathy Steppe, and Marie-Christine Van Labeke

Subjects

lettuce, far-red photon flux, light-emitting diodes, leaf morphology, leaf reflectance, light use efficiency, Plant culture, SB1-1110

Abstract

Light and its spectral characteristics are crucial for plant growth and development. The far-red photon flux mediates many plant processes through the action of phytochrome and also accelerates the photosynthetic electron transfer rate. In this study, we assessed the effects of far-red addition on butterhead lettuce morphology, light use efficiency, optical properties, and phytochemical characteristics. Three-week-old lettuce plants (Lactuca sativa L. cv. Alyssa) were grown for up to 28 days under a 10% blue and 90% red light spectrum (200 µmol m-2 s-1, 16 h photoperiod) to which five different intensities of far-red light (peak at 735 nm) were added (0-9-18-36-72 µmol m-2 s-1). White light-emitting diodes were included as a proxy for sunlight. Increasing supplemental far-red photon flux from zero to 21% increased the light use efficiency (g per mol) by 37% on day 14; 43% on day 21; and 39% on day 28. Measurements of projected head area suggest that this was associated with an increase in leaf expansion and photon capture and not necessarily a direct effect on photosynthesis. Moreover, vegetation indices based on leaf reflectance showed a decrease in chlorophyll-related indices under a high far-red photon flux. This decrease in pigment content was confirmed by chemical analyses, suggesting that the plants may not reach their full potential in terms of photon capture, limiting the overall photosynthetic performance. Furthermore, the stress-related Carter 1 index increased in plants grown under a high far-red photon flux, indicating early plant stress. Far-red tended to decrease the content of total phenolics and increase soluble sugars. The higher sugar levels can be attributed to an improved photochemical efficiency due to photosystem I excitation by far-red wavelengths, also known as the Emerson Enhancement effect. Despite these higher sugar levels, no effect on foliar nitrate content was observed. Our results show that far-red supplementation has the potential to enhance light interception at the early growth stages, although higher intensities of far-red may cause plant stress.

Published

2023

2. The Impact of a Six-Hour Light–Dark Cycle on Wheat Ear Emergence, Grain Yield, and Flour Quality in Future Plant-Growing Systems

Author

Helena Clauw, Hans Van de Put, Abderahman Sghaier, Trui Kerkaert, Els Debonne, Mia Eeckhout, and Kathy Steppe

Subjects

spring wheat, Triticum aestivum, photoperiod, space, closed environment, vertical farming, Chemical technology, TP1-1185

Abstract

Cultivating wheat (Triticum aestivum) in a closed environment offers applications in both indoor farming and in outer-space farming. Tailoring the photoperiod holds potential to shorten the growth cycle, thereby increasing the annual number of cycles. As wheat is a long-day plant, a night shorter than a critical length is required to induce flowering. In growth chambers, experiments were conducted to examine the impact of a 6 h light–dark cycle on the timing of wheat ear emergence, grain yield, and flour quality. Under equal daily light-integral conditions, the 6 h light–dark cycle promoted growth and development, resulting in accelerated ear emergence when compared to a 12 h cycle, additionally indicating that 12 h of darkness was excessive. To further stimulate heading and increase yield, the 6 h cycle was changed at the onset of stem elongation to a 14 h–10 h, mimicking spring conditions, and maintained until maturity. This successful transition was then combined with two levels of light intensity and nutrient solution, which did not significantly impact yield, while tillering and grain ripening did increase under higher light intensities. Moreover, it enabled manipulation of the baking quality, although lower-end falling numbers were observed. In conclusion, combining a 6 h light–dark cycle until stem elongation with a 14 h–10 h cycle presents a promising strategy for increasing future wheat production in closed environments. The observation of low falling numbers underscores the importance of factoring in flour quality when designing the wheat-growing systems of the future.

Published

2024

3. The 2018 European heatwave led to stem dehydration but not to consistent growth reductions in forests

Author

Roberto L. Salomón, Richard L. Peters, Roman Zweifel, Ute G. W. Sass-Klaassen, Annemiek I. Stegehuis, Marko Smiljanic, Rafael Poyatos, Flurin Babst, Emil Cienciala, Patrick Fonti, Bas J. W. Lerink, Marcus Lindner, Jordi Martinez-Vilalta, Maurizio Mencuccini, Gert-Jan Nabuurs, Ernst van der Maaten, Georg von Arx, Andreas Bär, Linar Akhmetzyanov, Daniel Balanzategui, Michal Bellan, Jörg Bendix, Daniel Berveiller, Miroslav Blaženec, Vojtěch Čada, Vinicio Carraro, Sébastien Cecchini, Tommy Chan, Marco Conedera, Nicolas Delpierre, Sylvain Delzon, Ľubica Ditmarová, Jiri Dolezal, Eric Dufrêne, Johannes Edvardsson, Stefan Ehekircher, Alicia Forner, Jan Frouz, Andrea Ganthaler, Vladimír Gryc, Aylin Güney, Ingo Heinrich, Rainer Hentschel, Pavel Janda, Marek Ježík, Hans-Peter Kahle, Simon Knüsel, Jan Krejza, Łukasz Kuberski, Jiří Kučera, François Lebourgeois, Martin Mikoláš, Radim Matula, Stefan Mayr, Walter Oberhuber, Nikolaus Obojes, Bruce Osborne, Teemu Paljakka, Roman Plichta, Inken Rabbel, Cyrille B. K. Rathgeber, Yann Salmon, Matthew Saunders, Tobias Scharnweber, Zuzana Sitková, Dominik Florian Stangler, Krzysztof Stereńczak, Marko Stojanović, Katarína Střelcová, Jan Světlík, Miroslav Svoboda, Brian Tobin, Volodymyr Trotsiuk, Josef Urban, Fernando Valladares, Hanuš Vavrčík, Monika Vejpustková, Lorenz Walthert, Martin Wilmking, Ewa Zin, Junliang Zou, and Kathy Steppe

Subjects

Science

Abstract

Forest dynamics are monitored at large scales with remote sensing, but individual tree data are necessary for ground-truthing and mechanistic insights. This study on high temporal resolution dendrometer data across Europe reveals that the 2018 heatwave affected tree physiology and growth in unexpected way.

Published

2022

4. Editorial: Digital imaging of plants

Author

Michele Pisante, Angelica Galieni, Fabio Stagnari, Kathy Steppe, Qingguo Xie, and Nicola D'Ascenzo

Subjects

digital plant imaging, plant positron emission tomography, plant RGB imaging, plant functional imaging, early stress detection, Plant culture, SB1-1110

Published

2022

5. Effect of Seaweed-Based Biostimulants on Growth and Development of Hydrangea paniculata under Continuous or Periodic Drought Stress

Author

Paulien De Clercq, Els Pauwels, Seppe Top, Kathy Steppe, and Marie-Christine Van Labeke

Subjects

woody ornamentals, biostimulants, seaweed extracts, drought stress, pigments, stress metabolites, Plant culture, SB1-1110

Abstract

To adapt to climate change and water scarcity during dry, hot summers, more sustainable, or even deficit, irrigation is required in the ornamental sector, as it uses large amounts of water to sustain high-value crop production. Biostimulants, especially seaweed extracts, could offer a sustainable solution against drought stress as they are known to increase plant tolerance to abiotic stress. The effect of four seaweed extracts based on Ascophyllum nodosum, Soliera chordalis, Ecklonia maxima, and Saccharina latissima and one microbial biostimulant were tested on container-grown Hydrangea paniculata under drought stress conditions for two years. During the first trial year, in 2019, overall irrigation was reduced by 20%. In 2021, plants were subjected to repeated drying and wetting cycles. In general, less irrigation, and thus a lower substrate moisture content, reduced stomatal conductance, biomass production, and root development, but increased plant compactness. The biostimulants showed minor effects, but these were not observed in both experiments. Treatment with the A. nodosum extract resulted in longer branches and more biomass under deficit irrigation but tended to accelerate flowering when repeated drying and wetting cycles were applied. The E. maxima extract negatively affected the branching of Hydrangea under repeated drying and wetting cycles.

Published

2023

6. Two Co-occurring Liana Species Strongly Differ in Their Hydraulic Traits in a Water-Limited Neotropical Forest

Author

Kasper Coppieters, Hans Verbeeck, Simon Dequeker, Jennifer S. Powers, German Vargas G., Chris M. Smith-Martin, Kathy Steppe, and Félicien Meunier

Subjects

drought tolerance, lianas, tropical dry forest, vulnerability to embolism, optical vulnerability, acoustic vulnerability, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

Lianas are a key growth form in tropical forests. They are believed to be strong competitors for water, thanks to their presumed efficient vascular systems. However, despite being a large polyphyletic group, they are currently often considered as a functionally homogeneous entity. In this study, we challenged this assumption by estimating the variability in hydraulic traits of two common, co-occurring liana species in a water-limited environment, namely, a seasonally dry tropical forest in Costa Rica. We measured vulnerability to embolism at the leaf and branch levels using two different methods (optical and acoustic vulnerability) and found that both species had very different hydraulic properties. Compared to reported P50 values in literature, we found two extreme P50 values: a low value for Bignonia diversifolia (−4.30 ± 0.54 MPa at the leaf level; −7.42 ± 0.54 MPa at the branch level) and a high value for Cissus microcarpa (−1.07 ± 0.14 at the leaf level; −1.20 ± 0.05 MPa at the branch level). Furthermore, B. diversifolia had a higher apparent modulus of elasticity in the radial direction (556.6 ± 401.0 MPa) and a variable midday water potential. On the other hand, C. microcarpa had a low apparent modulus of elasticity in the radial direction (37.8 ± 26.3 MPa) and a high branch water content, which enabled the species to keep its water potential stable during the dehydration experiments and during a drought period in the field. This mechanism may enable this species to coexist with species that are more resistant to drought-induced embolisms such as B. diversifolia. Although only two species were studied, considerable overlap was found between the range of hydraulic properties of trees growing in the same location and trees and lianas growing in two forests in Panama. These findings demonstrate that lianas cannot be considered as a homogeneous group and call for further research into the intra-growth form diversity of liana properties.

Published

2022

7. Osmotic Adjustment in Wheat (Triticum aestivum L.) During Pre- and Post-anthesis Drought

Author

Sarah Verbeke, Carmen María Padilla-Díaz, Geert Haesaert, and Kathy Steppe

Subjects

plant stress, leaf water potential, source-sink, turgor, Van't Hoff equation, osmotic adjustment, Plant culture, SB1-1110

Abstract

Pre-anthesis drought is expected to greatly increase yield losses in wheat (Triticum aestivum L.), one of the most important crops worldwide. Most studies investigate the effects of pre-anthesis drought only at maturity. The physiology of the plant before anthesis and how it is affected during drought is less studied. Our study focused on physiological patterns in wheat plants during pre- and post-anthesis drought. To this end, we measured leaf xylem water potential, osmotic potential and water content in different plant parts at a high temporal frequency: every 3 days, three times a day. The experiment started just before booting until 2 weeks after flowering. Drought stress was induced by withholding irrigation with rewatering upon turgor loss, which occurred once before and once after anthesis. The goal was to investigate the patterns of osmotic adjustment, when it is used for protection against drought, and if the strategy changes during the phenological development of the plant. Our data gave no indication of daily osmotic adjustment, but did show a delicate control of the osmotic potential during drought in both leaves and stem. Under high drought stress, osmotic potential decreased to avoid further water loss. Before anthesis, rewatering restored leaf water potential and osmotic potential quickly. After anthesis, rewatering restored water potential in the flag leaves, but the osmotic potential in the stem and flag leaf remained low longer. Osmotic adjustment was thus maintained longer after anthesis, showing that the plants invest more energy in the osmotic adjustment after anthesis than before anthesis. We hypothesize that this is because the plants consider the developing ear after anthesis a more important carbohydrate sink than the stem, which is a carbohydrate sink before anthesis, to be used later as a reserve. Low osmotic potential in the stem allowed turgor maintenance, while the low osmotic potential in the flag leaf led to an increase in leaf turgor beyond the level of the control plants. This allowed leaf functioning under drought and assured that water was redirected to the flag leaf and not used to refill the stem storage.

Published

2022

8. X-ray microtomography and linear discriminant analysis enable detection of embolism-related acoustic emissions

Author

Niels J. F. De Baerdemaeker, Michiel Stock, Jan Van den Bulcke, Bernard De Baets, Luc Van Hoorebeke, and Kathy Steppe

Subjects

Drought-induced embolism formation, Acoustic emissions, Machine learning, Linear discriminant analysis, X-ray computed microtomography, Fraxinus excelsior L., Plant culture, SB1-1110, Biology (General), QH301-705.5

Abstract

Abstract Background Acoustic emission (AE) sensing is in use since the late 1960s in drought-induced embolism research as a non-invasive and continuous method. It is very well suited to assess a plant’s vulnerability to dehydration. Over the last couple of years, AE sensing has further improved due to progress in AE sensors, data acquisition methods and analysis systems. Despite these recent advances, it is still challenging to detect drought-induced embolism events in the AE sources registered by the sensors during dehydration, which sometimes questions the quantitative potential of AE sensing. Results In quest of a method to separate embolism-related AE signals from other dehydration-related signals, a 2-year-old potted Fraxinus excelsior L. tree was subjected to a drought experiment. Embolism formation was acoustically measured with two broadband point-contact AE sensors while simultaneously being visualized by X-ray computed microtomography (µCT). A machine learning method was used to link visually detected embolism formation by µCT with corresponding AE signals. Specifically, applying linear discriminant analysis (LDA) on the six AE waveform parameters amplitude, counts, duration, signal strength, absolute energy and partial power in the range 100–200 kHz resulted in an embolism-related acoustic vulnerability curve (VCAE-E) better resembling the standard µCT VC (VCCT), both in time and in absolute number of embolized vessels. Interestingly, the unfiltered acoustic vulnerability curve (VCAE) also closely resembled VCCT, indicating that VCs constructed from all registered AE signals did not compromise the quantitative interpretation of the species’ vulnerability to drought-induced embolism formation. Conclusion Although machine learning could detect similar numbers of embolism-related AE as µCT, there still is insufficient model-based evidence to conclusively attribute these signals to embolism events. Future research should therefore focus on similar experiments with more in-depth analysis of acoustic waveforms, as well as explore the possibility of Fast Fourier transformation (FFT) to remove non-embolism-related AE signals.

Published

2019

9. Guide to Plant-PET Imaging Using 11CO2

Author

Jens Mincke, Jan Courtyn, Christian Vanhove, Stefaan Vandenberghe, and Kathy Steppe

Subjects

11CO2, carbon-11 (11C), positron emission tomography (PET), plant-PET, guide, image analysis, Plant culture, SB1-1110

Abstract

Due to its high sensitivity and specificity for tumor detection, positron emission tomography (PET) has become a standard and widely used molecular imaging technique. Given the popularity of PET, both clinically and preclinically, its use has been extended to study plants. However, only a limited number of research groups worldwide report PET-based studies, while we believe that this technique has much more potential and could contribute extensively to plant science. The limited application of PET may be related to the complexity of putting together methodological developments from multiple disciplines, such as radio-pharmacology, physics, mathematics and engineering, which may form an obstacle for some research groups. By means of this manuscript, we want to encourage researchers to study plants using PET. The main goal is to provide a clear description on how to design and execute PET scans, process the resulting data and fully explore its potential by quantification via compartmental modeling. The different steps that need to be taken will be discussed as well as the related challenges. Hereby, the main focus will be on, although not limited to, tracing 11CO2 to study plant carbon dynamics.

Published

2021

10. Foliar Water Uptake Capacity in Six Mangrove Species

Author

Katrien H. D. Schaepdryver, Willem Goossens, Abdulla Naseef, Sreejith Kalpuzha Ashtamoorthy, and Kathy Steppe

Subjects

foliar water uptake, mangrove, plant–water relations, trichomes, leaf anatomy, water absorption, Plant ecology, QK900-989

Abstract

Foliar water uptake (FWU) is a mechanism that enables plants to acquire water from the atmosphere through their leaves. As mangroves live in a saline sediment water environment, the mechanism of FWU might be of vital importance to acquire freshwater and grow. The goal of this study was to assess the FWU capacity of six different mangrove species belonging to four genera using a series of submersion experiments in which the leaf mass increase was measured and expressed per unit leaf area. The foliar water uptake capacity differed between species with the highest and lowest average water uptake in Avicennia marina (Forssk.) Vierh. (1.52 ± 0.48 mg H2O cm−2) and Bruguiera gymnorhiza (L.) Lam. (0.13 ± 0.06 mg H2O cm−2), respectively. Salt-excreting species showed a higher FWU capacity than non-excreting species. Moreover, A. marina, a salt-excreting species, showed a distinct leaf anatomical trait, i.e., trichomes, which were not observed in the other species and might be involved in the water absorption process. The storage of leaves in moist Ziplock bags prior to measurement caused leaf water uptake to already occur during transport to the field station, which proportionately increased the leaf water potential (A. marina: −0.31 ± 0.13 MPa and B. gymnorhiza: −2.70 ± 0.27 MPa). This increase should be considered when performing best practice leaf water potential measurements but did not affect the quantification of FWU capacity because of the water potential gradient between a leaf and the surrounding water during submersion. Our results highlight the differences that exist in FWU capacity between species residing in the same area and growing under the same environmental conditions. This comparative study therefore enhances our understanding of mangrove species’ functioning.

Published

2022

11. Acoustic Vulnerability, Hydraulic Capacitance, and Xylem Anatomy Determine Drought Response of Small Grain Cereals

Author

Szanne Degraeve, Niels J. F. De Baerdemaeker, Maarten Ameye, Olivier Leroux, Geert Jozej Willem Haesaert, and Kathy Steppe

Subjects

acoustic emission, drought stress, hydraulic capacitance, small grain cereals, vulnerability curve, xylem anatomy, Plant culture, SB1-1110

Abstract

Selection of high-yielding traits in cereal plants led to a continuous increase in productivity. However, less effort was made to select on adaptive traits, favorable in adverse and harsh environments. Under current climate change conditions and the knowledge that cereals are staple foods for people worldwide, it is highly important to shift focus to the selection of traits related to drought tolerance, and to evaluate new tools for efficient selection. Here, we explore the possibility to use vulnerability to drought-induced xylem embolism of wheat cultivars Excalibur and Hartog (Triticum aestivum L.), rye cultivar Duiker Max (Secale cereale L.), and triticale cultivars Dublet and US2014 (x Triticosecale Wittmack) as a proxy for their drought tolerance. Multiple techniques were combined to underpin this hypothesis. During bench-top dehydration experiments, acoustic emissions (AEs) produced by formation of air emboli were detected, and hydraulic capacitances quantified. By only looking at the AE50 values, one would classify wheat cultivar Excalibur as most tolerant and triticale cultivar Dublet as most vulnerable to drought-induced xylem embolism, though Dublet had significantly higher hydraulic capacitances, which are essential in terms of internal water storage to temporarily buffer or delay water shortage. In addition, xylem anatomical traits revealed that both cultivars have a contrasting trade-off between hydraulic safety and efficiency. This paper emphasizes the importance of including a cultivar’s hydraulic capacitance when evaluating its drought response and vulnerability to drought-induced xylem embolism, instead of relying on the AE50 as the one parameter.

Published

2021

12. Respiratory CO2 Combined With a Blend of Volatiles Emitted by Endophytic Serendipita Strains Strongly Stimulate Growth of Arabidopsis Implicating Auxin and Cytokinin Signaling

Author

Jolien Venneman, Lore Vandermeersch, Christophe Walgraeve, Kris Audenaert, Maarten Ameye, Jan Verwaeren, Kathy Steppe, Herman Van Langenhove, Geert Haesaert, and Danny Vereecke

Subjects

endophytic Sebacinales, fungal volatiles, phytohormone signaling, Piriformospora, plant growth and development, plant-microbe interactions, Plant culture, SB1-1110

Abstract

Rhizospheric microorganisms can alter plant physiology and morphology in many different ways including through the emission of volatile organic compounds (VOCs). Here we demonstrate that VOCs from beneficial root endophytic Serendipita spp. are able to improve the performance of in vitro grown Arabidopsis seedlings, with an up to 9.3-fold increase in plant biomass. Additional changes in VOC-exposed plants comprised petiole elongation, epidermal cell and leaf area expansion, extension of the lateral root system, enhanced maximum quantum efficiency of photosystem II (Fv/Fm), and accumulation of high levels of anthocyanin. Notwithstanding that the magnitude of the effects was highly dependent on the test system and cultivation medium, the volatile blends of each of the examined strains, including the references S. indica and S. williamsii, exhibited comparable plant growth-promoting activities. By combining different approaches, we provide strong evidence that not only fungal respiratory CO2 accumulating in the headspace, but also other volatile compounds contribute to the observed plant responses. Volatile profiling identified methyl benzoate as the most abundant fungal VOC, released especially by Serendipita cultures that elicit plant growth promotion. However, under our experimental conditions, application of methyl benzoate as a sole volatile did not affect plant performance, suggesting that other compounds are involved or that the mixture of VOCs, rather than single molecules, accounts for the strong plant responses. Using Arabidopsis mutant and reporter lines in some of the major plant hormone signal transduction pathways further revealed the involvement of auxin and cytokinin signaling in Serendipita VOC-induced plant growth modulation. Although we are still far from translating the current knowledge into the implementation of Serendipita VOCs as biofertilizers and phytostimulants, volatile production is a novel mechanism by which sebacinoid fungi can trigger and control biological processes in plants, which might offer opportunities to address agricultural and environmental problems in the future.

Published

2020

13. Salt Stress Induced Changes in Photosynthesis and Metabolic Profiles of One Tolerant (‘Bonica’) and One Sensitive (‘Black Beauty’) Eggplant Cultivars (Solanum melongena L.)

Author

Sami Hannachi, Kathy Steppe, Mabrouka Eloudi, Lassaad Mechi, Insaf Bahrini, and Marie-Christine Van Labeke

Subjects

antioxidant response, electrolyte leakage, mineral content, photosynthesis, photorespiration, total phenols, Botany, QK1-989

Abstract

The impact of salinity on the physiological and biochemical parameters of tolerant (‘Bonica’) and susceptible (‘Black Beauty’) eggplant varieties (Solanum melongena L.) was determined. The results revealed that the increase in salinity contributes to a significant decline in net photosynthesis (An) in both varieties; however, at the highest salt concentration (160 mM NaCl), the decrease in photorespiration (Rl) was less pronounced in the tolerant cultivar ‘Bonica’. Stomatal conductance (gs) was significantly reduced in ‘Black Beauty’ following exposure to 40 mM NaCl. However, gs of ‘Bonica’ was only substantially reduced at the highest level of NaCl (160 mM). In addition, a significant decrease in Chla, Chlb, total Chl, Chla/b and carotenoids (p > 0.05) was found in ‘Black Beauty’, and soluble carbohydrates accumulation and electrolyte leakage (EL) were more pronounced in ‘Black Beauty’ than in ‘Bonica’. The total phenols increase in ‘Bonica’ was 65% higher than in ‘Black Beauty’. In ‘Bonica’, the roots displayed the highest enzyme scavenging activity compared to the leaves. Salt stress contributes to a significant augmentation of root catalase and guaiacol peroxidase activities. In ‘Bonica’, the Na concentration was higher in roots than in leaves, whereas in ‘Black Beauty‘, the leaves accumulated more Na. Salt stress significantly boosted the Na/K ratio in ‘Black Beauty’, while no significant change occurred in ‘Bonica’. ACC deaminase activity was significantly higher in ‘Bonica’ than in ‘Black Beauty’.

Published

2022

14. High-Resolution in vivo Imaging of Xylem-Transported CO2 in Leaves Based on Real-Time 11C-Tracing

Author

Michiel Hubeau, Michael R. Thorpe, Jens Mincke, Jasper Bloemen, Ingvar Bauweraerts, Peter E. H. Minchin, Veerle De Schepper, Filip De Vos, Christian Vanhove, Stefaan Vandenberghe, and Kathy Steppe

Subjects

Populus canadensis, 11C (carbon-11), isotope, radiotracer, positron emission tomography (PET), positron autoradiography, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

Plant studies using the short-lived isotope 11C to label photosynthate via atmospheric carbon dioxide (CO2), have greatly advanced our knowledge about the allocation of recent photosynthate from leaves to sinks. However, a second source for photosynthesis is CO2 in the transpiration stream, coming from respiration in plant tissues. Here, we use in vivo tracing of xylem-transported 11CO2 to increase our knowledge on whole plant carbon cycling. We developed a new method for in vivo tracing of xylem-transported CO2 in excised poplar leaves using 11C in combination with positron emission tomography (PET) and autoradiography. To show the applicability of both measurement techniques in visualizing and quantifying CO2 transport dynamics, we administered the tracer via the cut petiole and manipulated the transport by excluding light or preventing transpiration. Irrespective of manipulation, some tracer was found in main and secondary veins, little of it was fixed in minor veins or mesophyll, while most of it diffused out the leaf. Transpiration, phloem loading and CO2 recycling were identified as mechanisms that could be responsible for the transport of internal CO2. Both 11C-PET and autoradiography can be successfully applied to study xylem-transported CO2, toward better understanding of leaf and plant carbon cycling, and its importance in different growing conditions.

Published

2019

15. 11C-Autoradiographs to Image Phloem Loading

Author

Michiel Hubeau, Jens Mincke, Christian Vanhove, Anaïs Pasiphaé Gorel, Adeline Fayolle, Jackie Epila, Olivier Leroux, Stefaan Vandenberghe, and Kathy Steppe

Subjects

autoradiography, carbon-11 (11C), phloem loading, carbon distribution, Populus tremula L., Erythrophleum spp., Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

Generally, tree species load photoassimilates passively into the phloem, while herbaceous species load actively. These phloem loading strategies have implications for phloem sugar concentration and growth potential. Whereas, in previous research, phloem loading identification was performed with 14C-autoradiography, we suggest 11C-autoradiography, because of its compatibility with plant-PET (positron emission tomography) scans. Because 11C-autoradiography has been hardly used in plant sciences so far, it was tested in contrasting plant species: one temperate tree species, Populus tremula L., three tropical tree species, Erythrophleum suaveolens (Guill. & Perr.) Brenan, E. ivorense A. Chev., and Maesopsis eminii Engl., and two herbaceous crop species Solanum lycopersicum L. and S. tuberosum L. Our results confirmed that P. tremula is a passive loader, and Solanum spp. are active loaders. Erythrophleum spp. and young leaves of M. eminii showed the expected passive loading strategy, but the mature leaves of M. eminii showed an uncommon pattern. Images corrected for leaf tissue thickness supported that mature leaves of M. eminii used active phloem loading, which is linked to continuous investment in growth and new leaves, supporting the lower carbon storage levels often observed in tropical tree species. With this study, we demonstrate that 11C-autoradiography is a powerful tool to acquire detailed tracer distribution in leaves to typify phloem loading strategies in plant species.

Published

2019

16. Tree Circumference Changes and Species-Specific Growth Recovery After Extreme Dry Events in a Montane Rainforest in Southern Ecuador

Author

Volker Raffelsbauer, Susanne Spannl, Kelly Peña, Darwin Pucha-Cofrep, Kathy Steppe, and Achim Bräuning

Subjects

stem diameter variations, dendrometer, tropical mountain rainforest, drought recovery, tree life form, Plant culture, SB1-1110

Abstract

Under drought conditions, even tropical rainforests might turn from carbon sinks to sources, and tree species composition might be altered by increased mortality. We monitored stem diameter variations of 40 tree individuals with stem diameters above 10 cm belonging to eleven different tree genera and three tree life forms with high-resolution dendrometers from July 2007 to November 2010 and additionally March 2015 to December 2017 in a tropical mountain rainforest in South Ecuador, a biodiversity hotspot with more than 300 different tree species belonging to different functional types. Although our study area receives around 2200 mm of annual rainfall, dry spells occur regularly during so-called “Veranillo del Niño” (VdN) periods in October-November. In climate change scenarios, droughts are expected with higher frequency and intensity as today. We selected dry intervals with a minimum of four consecutive days to examine how different tree species respond to drought stress, raising the question if some species are better adapted to a possible higher frequency and increasing duration of dry periods. We analyzed the averaged species-specific stem shrinkage rates and recovery times during and after dry periods. The two deciduous broadleaved species Cedrela montana and Handroanthus chrysanthus showed the biggest stem shrinkage of up to 2 mm after 10 consecutive dry days. A comparison of daily circumference changes over 600 consecutive days revealed different drought responses between the families concerning the percentage of days with stem shrinkage/increment, ranging from 27.5 to 72.5% for Graffenrieda emarginata to 45–55% for Podocarpus oleifolius under same climate conditions. Moreover, we found great difference of recovery times after longer-lasting (i.e., eight to ten days) VdN drought events between the two evergreen broadleaved species Vismia cavanillesiana and Tapirira guianensis. While Vismia replenished to pre-VdN stem circumference after only 5 days, Tapirira needed 52 days on average to restore its circumference. Hence, a higher frequency of droughts might increase inter-species competition and species-specific mortality and might finally alter the species composition of the ecosystem.

Published

2019

17. Applying RGB- and Thermal-Based Vegetation Indices from UAVs for High-Throughput Field Phenotyping of Drought Tolerance in Forage Grasses

Author

Tom De Swaef, Wouter H. Maes, Jonas Aper, Joost Baert, Mathias Cougnon, Dirk Reheul, Kathy Steppe, Isabel Roldán-Ruiz, and Peter Lootens

Subjects

UAV, RGB camera, thermal camera, drought tolerance, forage grass, HSV, Science

Abstract

The persistence and productivity of forage grasses, important sources for feed production, are threatened by climate change-induced drought. Breeding programs are in search of new drought tolerant forage grass varieties, but those programs still rely on time-consuming and less consistent visual scoring by breeders. In this study, we evaluate whether Unmanned Aerial Vehicle (UAV) based remote sensing can complement or replace this visual breeder score. A field experiment was set up to test the drought tolerance of genotypes from three common forage types of two different species: Festuca arundinacea, diploid Lolium perenne and tetraploid Lolium perenne. Drought stress was imposed by using mobile rainout shelters. UAV flights with RGB and thermal sensors were conducted at five time points during the experiment. Visual-based indices from different colour spaces were selected that were closely correlated to the breeder score. Furthermore, several indices, in particular H and NDLab, from the HSV (Hue Saturation Value) and CIELab (Commission Internationale de l’éclairage) colour space, respectively, displayed a broad-sense heritability that was as high or higher than the visual breeder score, making these indices highly suited for high-throughput field phenotyping applications that can complement or even replace the breeder score. The thermal-based Crop Water Stress Index CWSI provided complementary information to visual-based indices, enabling the analysis of differences in ecophysiological mechanisms for coping with reduced water availability between species and ploidy levels. All species/types displayed variation in drought stress tolerance, which confirms that there is sufficient variation for selection within these groups of grasses. Our results confirmed the better drought tolerance potential of Festuca arundinacea, but also showed which Lolium perenne genotypes are more tolerant.

Published

2021

18. Counter-Intuitive Response to Water Limitation in a Southern European Provenance of Frangula alnus Mill. in a Common Garden Experiment

Author

Kristine Vander Mijnsbrugge, Lise De Clerck, Nele Van der Schueren, Stefaan Moreels, Amy Lauwers, Kathy Steppe, Liselotte De Ligne, Matteo Campioli, and Jan Van den Bulcke

Subjects

drought, common garden, post-drought recovery, general linear mixed models, bud burst, leaf senescence, Plant ecology, QK900-989

Abstract

Climate change will intensify drought periods during the growing season in Western Europe. We mimicked this prediction by withholding water in summer from young rooted cuttings of Frangula alnus Mill., a common shrub species, originating from different latitudes in Europe (Italy, Belgium and Sweden) and growing in a common garden environment in Belgium. We followed the responses to the drought up to two years after the treatment. Counter-intuitively, the Italian provenance displayed earlier symptoms and stronger effects of water limitation than the other two provenances. A putative higher transpiration in this provenance could be suggested based on a relative larger shoot growth, larger leaves and a higher stomatal density. After the post-drought re-watering, the droughted plants of the Italian provenance entered leaf senescence later than the control plants, likely as a compensation mechanism for the lost growing time. Bud burst in the first year after the drought treatment and leaf senescence in the next autumn were both advanced in the drought treated group when compared with the control plants. Bud burst in the second year after the drought treatment did not display any differentiation anymore between control and drought treated plants. Growth traits also displayed legacies of the water limitation. For example, the drought treated plants showed a lower number of reshoots upon pruning in the year after the drought treatment. Our results suggest that assisted migration from southern Europe to western Europe as a climate change adaptation strategy might not always follow the expected patterns.

Published

2020

19. Influence of Drought on Foliar Water Uptake Capacity of Temperate Tree Species

Author

Jeroen D.M. Schreel, Jonas S. von der Crone, Ott Kangur, and Kathy Steppe

Subjects

aridity, climate change, drought, foliar absorption, foliar water uptake, plant ecophysiology, plant-water relations, temperate forests, trees, water potential, Plant ecology, QK900-989

Abstract

Foliar water uptake (FWU) has been investigated in an increasing number of species from a variety of areas but has remained largely understudied in deciduous, temperate tree species from non-foggy regions. As leaf wetting events frequently occur in temperate regions, FWU might be more important than previously thought and should be investigated. As climate change progresses, the number of drought events is expected to increase, basically resulting in a decreasing number of leaf wetting events, which might make FWU a seemingly less important mechanism. However, the impact of drought on FWU might not be that unidirectional because drought will also cause a more negative tree water potential, which is expected to result in more FWU. It yet remains unclear whether drought results in a general increase or decrease in the amount of water absorbed by leaves. The main objectives of this study are, therefore: (i) to assess FWU-capacity in nine widely distributed key tree species from temperate regions, and (ii) to investigate the effect of drought on FWU in these species. Based on measurements of leaf and soil water potential and FWU-capacity, the effect of drought on FWU in temperate tree species was assessed. Eight out of nine temperate tree species were able to absorb water via their leaves. The amount of water absorbed by leaves and the response of this plant trait to drought were species-dependent, with a general increase in the amount of water absorbed as leaf water potential decreased. This relationship was less pronounced when using soil water potential as an independent variable. We were able to classify species according to their response in FWU to drought at the leaf level, but this classification changed when using drought at the soil level, and was driven by iso- and anisohydric behavior. FWU hence occurred in several key tree species from temperate regions, be it with some variability, which potentially allows these species to partly reduce the effects of drought stress. We recommend including this mechanism in future research regarding plant−water relations and to investigate the impact of different pathways used for FWU.

Published

2019

20. Can UAV-Based Infrared Thermography Be Used to Study Plant-Parasite Interactions between Mistletoe and Eucalypt Trees?

Author

Wouter H. Maes, Alfredo R. Huete, Michele Avino, Matthias M. Boer, Remy Dehaan, Elise Pendall, Anne Griebel, and Kathy Steppe

Subjects

infrared thermography, transpiration, plant hemiparasite, UAV, Science

Abstract

Some of the remnants of the Cumberland Plain woodland, an endangered dry sclerophyllous forest type of New South Wales, Australia, host large populations of mistletoe. In this study, the extent of mistletoe infection was investigated based on a forest inventory. We found that the mistletoe infection rate was relatively high, with 69% of the Eucalyptus fibrosa and 75% of the E. moluccana trees being infected. Next, to study the potential consequences of the infection for the trees, canopy temperatures of mistletoe plants and of infected and uninfected trees were analyzed using thermal imagery acquired during 10 flights with an unmanned aerial vehicle (UAV) in two consecutive summer seasons. Throughout all flight campaigns, mistletoe canopy temperature was 0.3⁻2 K lower than the temperature of the eucalypt canopy it was growing in, suggesting higher transpiration rates. Differences in canopy temperature between infected eucalypt foliage and mistletoe were particularly large when incoming radiation peaked. In these conditions, eucalypt foliage from infected trees also had significantly higher canopy temperatures (and likely lower transpiration rates) compared to that of uninfected trees of the same species. The study demonstrates the potential of using UAV-based infrared thermography for studying plant-water relations of mistletoe and its hosts.

Published

2018

21. A tree-centered approach to assess impacts of extreme climatic events on forests

Author

Ute Sass-Klaassen, Patrick Fonti, Paolo Cherubini, Jozica Gricar, Elisabeth M. R. Robert, Kathy Steppe, and Achim Braeuning

Subjects

Climate Change, structure-function relationships, Tree, long-term monitoring, Resilience., Mechanistic understanding, Plant culture, SB1-1110

Published

2016

22. Taxon-Independent and Taxon-Dependent Responses to Drought in Seedlings from Quercus robur L., Q. petraea (Matt.) Liebl. and Their Morphological Intermediates

Author

Kristine Vander Mijnsbrugge, Arion Turcsán, Jorne Maes, Nils Duchêne, Steven Meeus, Beatrijs Van der Aa, Kathy Steppe, and Marijke Steenackers

Subjects

sessile oak, pedunculate oak, hybridization, survival, leaf senescence, growth, Plant ecology, QK900-989

Abstract

The increasing severity and frequency of summer droughts at mid-latitudes in Europe may impact forest regeneration. We investigated whether the sympatric species Quercus robur L., Q. petraea (Matt.) Liebl., and their morphological intermediates respond differentially to water deficit. Acorns were sourced from a naturally mixed population. Half of the potted seedlings were subjected to two successive drought periods during the first growing season, each followed by a plentiful re-watering. The surviving drought-exposed seedlings subsisted independent of the taxon of the mother tree. The phenological responses were also taxon-independent. However, drought-exposed plants showed a retarded height growth in the year following the treatment which was taxon-dependent. Offspring from Q. robur and from trees with leaves resembling Q. robur leaves and infructescences resembling Q. petraea infructescences showed a stronger decrease in height growth compared to the offspring from Q. petraea and from trees with leaves resembling Q. petraea leaves and infructescences resembling Q. robur infructescences. Diameter growth in the year following the drought treatment showed a weak taxon-dependent response. Together, our results may suggest that the composition of oak species and their hybrids in natural oak forests could be altered upon prolonged periods of precipitation deficit.

Published

2017

23. Metabolic Fingerprinting to Assess the Impact of Salinity on Carotenoid Content in Developing Tomato Fruits

Author

Lieven Van Meulebroek, Jochen Hanssens, Kathy Steppe, and Lynn Vanhaecke

Subjects

tomato (Solanum lycopersicum L.), metabolic fingerprinting, mass spectrometry, salinity, carotenoids, phytohormones, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

As the presence of health-promoting substances has become a significant aspect of tomato fruit appreciation, this study investigated nutrient solution salinity as a tool to enhance carotenoid accumulation in cherry tomato fruit (Solanum lycopersicum L. cv. Juanita). Hereby, a key objective was to uncover the underlying mechanisms of carotenoid metabolism, moving away from typical black box research strategies. To this end, a greenhouse experiment with five salinity treatments (ranging from 2.0 to 5.0 decisiemens (dS) m−1) was carried out and a metabolomic fingerprinting approach was applied to obtain valuable insights on the complicated interactions between salinity treatments, environmental conditions, and the plant’s genetic background. Hereby, several hundreds of metabolites were attributed a role in the plant’s salinity response (at the fruit level), whereby the overall impact turned out to be highly depending on the developmental stage. In addition, 46 of these metabolites embraced a dual significance as they were ascribed a prominent role in carotenoid metabolism as well. Based on the specific mediating actions of the retained metabolites, it could be determined that altered salinity had only marginal potential to enhance carotenoid accumulation in the concerned tomato fruit cultivar. This study invigorates the usefulness of metabolomics in modern agriculture, for instance in modeling tomato fruit quality. Moreover, the metabolome changes that were caused by the different salinity levels may enclose valuable information towards other salinity-related plant processes as well.

Published

2016

24. Acoustic Emissions to Measure Drought-Induced Cavitation in Plants

Author

Linus De Roo, Lidewei L. Vergeynst, Niels J.F. De Baerdemaeker, and Kathy Steppe

Subjects

cavitation, embolism, acoustic emission detection, vulnerability curve, drought, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Acoustic emissions are frequently used in material sciences and engineering applications for structural health monitoring. It is known that plants also emit acoustic emissions, and their application in plant sciences is rapidly increasing, especially to investigate drought-induced plant stress. Vulnerability to drought-induced cavitation is a key trait of plant water relations, and contains valuable information about how plants may cope with drought stress. There is, however, no consensus in literature about how this is best measured. Here, we discuss detection of acoustic emissions as a measure for drought-induced cavitation. Past research and the current state of the art are reviewed. We also discuss how the acoustic emission technique can help solve some of the main issues regarding quantification of the degree of cavitation, and how it can contribute to our knowledge about plant behavior during drought stress. So far, crossbreeding in the field of material sciences proved very successful, and we therefore recommend continuing in this direction in future research.

Published

2016

25. Mechanistic modeling reveals the importance of turgor-driven apoplastic water transport in wheat stem parenchyma during carbohydrate mobilization

Author

Sarah Verbeke, Carmen María Padilla‐Díaz, Clara Martínez‐Arias, Willem Goossens, Geert Haesaert, Kathy Steppe, Future of Farming Institute, and RS: FSE BFFI Future of Farming Institute

Subjects

Agriculture and Food Sciences, Physiology, DRY-MATTER, Triticum aestivum, Carbohydrates, Plant Science, CHEMICAL-COMPOSITION, POSTANTHESIS CHANGES, SAP FLOW, GENOTYPIC VARIATION, mobilization, water-soluble carbohydrates (WSC), DROUGHT, Triticum, drought stress, Water, hydrostatic gradient, osmotic adjustment, Biological Transport, GRAIN-YIELD, composite transport model, CELL-WALLS, Droughts, remobilization, DURUM-WHEAT, Edible Grain

Abstract

During stem elongation, wheat (Triticum aestivum) increases its stem carbohydrate content before anthesis as a reserve for grain filling. Hydraulic functioning during this mobilization process is not well understood and contradictory results exist on the direct effect of drought on carbohydrate mobilization. In a dedicated experiment, wheat plants were subjected to drought stress during carbohydrate mobilization. Measurements, important to better understand stem physiology, showed some unexpected patterns that could not be explained by our current knowledge on water transport. Traditional water flow and storage models failed to properly describe the drought response in wheat stems during carbohydrate mobilization. To explain the measured patterns, hypotheses were formulated and integrated in a dedicated model for wheat. The new mechanistic model simulates two hypothetical water storage compartments: one where water is quickly exchanged with the xylem and one that contains the carbohydrate storage. Water exchange between these compartments is turgor-driven. The model was able to simulate the measured increase in stored carbohydrate concentrations with a decrease in water content and stem diameter. Calibration of the model showed the importance of turgor-driven apoplastic water flow during carbohydrate mobilization. This resulted in an increase in stem hydraulic capacitance, which became more important under drought stress.

Published

2023

26. Daytime stomatal regulation in mature temperate trees prioritizes stem rehydration at night

Author

Richard L. Peters, Kathy Steppe, Christoforos Pappas, Roman Zweifel, Flurin Babst, Lars Dietrich, Georg von Arx, Rafael Poyatos, Marina Fonti, Patrick Fonti, Charlotte Grossiord, Mana Gharun, Nina Buchmann, David N. Steger, and Ansgar Kahmen

Subjects

Physiology, Plant Science, canopy conductance, dendrometer, European forests, hydraulictraits, leaf water potential, sap flow, stomatalcontrol, wood anatomy

Abstract

Trees remain sufficiently hydrated during drought by closing stomata and reducing canopy conductance (Gc) in response to variations in atmospheric water demand and soil water availability. Thresholds that control the reduction of Gc are proposed to optimize hydraulic safety against carbon assimilation efficiency. However, the link between Gc and the ability of stem tissues to rehydrate at night remains unclear. We investigated whether species-specific Gc responses aim to prevent branch embolisms, or enable night-time stem rehydration, which is critical for turgor-dependent growth. For this, we used a unique combination of concurrent dendrometer, sap flow and leaf water potential measurements and collected branch-vulnerability curves of six common European tree species. Species-specific Gc reduction was weakly related to the water potentials at which 50% of branch xylem conductivity is lost (P50). Instead, we found a stronger relationship with stem rehydration. Species with a stronger Gc control were less effective at refilling stem-water storage as the soil dries, which appeared related to their xylem architecture. Our findings highlight the importance of stem rehydration for water-use regulation in mature trees, which likely relates to the maintenance of adequate stem turgor. We thus conclude that stem rehydration must complement the widely accepted safety–efficiency stomatal control paradigm. ISSN:0028-646X ISSN:1469-8137

Published

2023

27. Differences between tree stem CO 2 efflux and O 2 influx rates cannot be explained by internal CO 2 transport or storage in large beech trees

Author

Juliane Helm, Roberto L. Salomón, Boaz Hilman, Jan Muhr, Alexander Knohl, Kathy Steppe, Yves Gibon, Cédric Cassan, Henrik Hartmann, Max Planck Institute for Biogeochemistry (MPI-BGC), Max-Planck-Gesellschaft, University of Basel (Unibas), Universidad Politécnica de Madrid (UPM), Universiteit Gent = Ghent University (UGENT), Georg-August-University = Georg-August-Universität Göttingen, Biologie du fruit et pathologie (BFP), Université de Bordeaux (UB)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), European Research Council under the European Union's Horizon 2020 research and innovation programme (grant agreement no.682512-OXYFLUX), Research Foundation Flanders (FWO) and the Marie Sklodowska-Curie research programme (665501), and European Project

Subjects

CO2/O2 ratio, carbon dioxide transport, Physiology, [SDV]Life Sciences [q-bio], temperate forest, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Plant Science, vertical stem gradient, mature trees, oxygen consumption

Abstract

International audience; Tree stem respiration (R S) is a substantial component of the forest carbon balance. The mass balance approach uses stem CO 2 efflux and internal xylem fluxes to sum up R S , while the oxygen-based method assumes O 2 influx as a proxy of R S. So far, both approaches have yielded inconsistent results regarding the fate of respired CO 2 in tree stems, a major challenge for quantifying forest carbon dynamics. We collected a data set of CO 2 efflux, O 2 influx, xylem CO 2 concentration, sap flow, sap pH, stem temperature, nonstructural carbohydrates concentration and potential phosphoenolpyruvate carboxylase (PEPC) capacity on mature beech trees to identify the sources of differences between approaches. The ratio of CO 2 efflux to O 2 influx was consistently below unity (0.7) along a 3-m vertical gradient, but internal fluxes did not bridge the gap between influx and efflux, nor did we find evidence for changes in respiratory substrate use. PEPC capacity was comparable with that previously reported in green current-year twigs. Although we could not reconcile differences between approaches, results shed light on the uncertain fate of CO 2 respired by parenchyma cells across the sapwood. Unexpected high values of PEPC

Published

2023

28. Comparing dual heat pulse methods with Péclet's number as universal switch to measure sap flow across a wide range

Author

Yuchen Ma, Ruiqi Ren, Han Fu, Bingcheng Si, Nicholas J Kinar, Gang Liu, and Kathy Steppe

Subjects

Physiology, Plant Science

Abstract

Accurate determination of sap flow over a wide measurement range is important for assessing tree transpiration. However, this is difficult to achieve by using a single heat pulse method. Recent attempts have been made to combine multiple heat pulse methods and have successfully increased the sap flow measurement range. However, relative performance of different dual methods has not yet been addressed, and selection of the numerical threshold used to switch between methods has not been verified among different dual methods. This paper evaluates three different dual methods with respect to measurement range, precision, and sources of uncertainty: (1) the heat ratio (HR) and compensation heat pulse (CHP) method; (2) the HR and T-max method, and (3) the HR and double ratio (DR) method. Field experiments showed that methods #1, #2 with three needles, and #3 compare well with the benchmark Sapflow+ method, having root mean square deviations (RMSD) of 4.7 cm h−1, 3.0 cm h−1 and 2.4 cm h−1, respectively. The three dual methods are equivalent in accuracy (p > 0.05). Moreover, all dual methods can satisfactorily measure reverse, low and medium heat pulse velocities. However, for high velocities (> 100 cm h−1), the HR + T-max (method #2) performed better than the other methods. Another advantage is that this method has a three- instead of four-needle probe configuration, making it less error-prone to probe misalignment and plant wounding. All dual methods in this study use the HR method for calculating low to medium flow and a different method for calculating high flow. The optimal threshold for switching from HR to another method is HR’s maximum flow, which can be accurately determined from the Péclet number. This study therefore provides guidance for an optimal selection of methods for quantification of sap flow over a wide measurement range.

Published

2023

29. Insights into the daily emissions and consumptions of methane and nitrous oxide from tropical tree stem surfaces

Author

Laëtitia M. Bréchet, Roberto L. Salomόn, Warren Daniel, Clément Stahl, Benoît Burban, Jean-Yves Goret, Kathy Steppe, Joost van Haren, Scott Saleska, and Ivan A. Janssens

Abstract

Methane (CH4) and nitrous oxide (N2O), critical climate-forcing trace gases, are rising sharply in the atmosphere. The estimate for their natural emissions remains uncertain because of mismatches between bottom-up (from flux measurements to process-based models) and top-down (from satellites to inversion models) approaches. Besides soils, trees can exchange CH4 and N2O with the atmosphere (either emitting or taking up), potentially acting as conduits for transporting large amounts of soil-produced CH4 and N2O. However, tree CH4 and N2O fluxes are not included yet in models, mainly because of a lack of detailed understanding of the sources and drivers of their temporal variation. This holds particularly true in tropical forests where high-frequency measurements are rare.We first hypothesized that, although on well-aerated upland forest soils, trees contribute to ecosystem CH4 and N2O fluxes, with seasonal CH4 and N2O flux dynamics being reversed between the stems and soil. Second, we postulated that, at the daily scale, circadian rhythms of tree physiology affect stem CH4 and N2O fluxes. We investigated these hypotheses by examining the high-temporal-resolution fluxes of CH4 and N2O of three tropical trees. We measured fluxes from their stems (and adjacent soils) with an automated chamber system and tree and environmental variables (i.e. tree growth, sap flux density, tree water deficit, stem and soil temperature, stem and soil water content) over 20 months in a tropical forest, in French Guiana.Long-term series of stem CH4 and N2O fluxes not only revealed that stems emitted CH4 and consumed N2O but also that flux variability was greater between tree individuals than seasons. We also found that stem CH4 and N2O fluxes were not linked to soil fluxes and exhibited diurnal patterns, with stems being greater emitters of CH4 and lower consumers of N2O in the early morning than at midday. CH4 and N2O peaks at sunrise suggest that gases accumulated in the stem at night when there was no gas flow and were vented out as soon as the pressurized flow started, following daily tree water dynamics. These preliminary results showed clear evidence of the need for continuous CH4 and N2O flux measurements in tropical forests to disentangle tree-mediated CH4 and N2O transport; more study is required to determine the relative importance of wood microbial organisms and tree traits for regulating gas transport through their aboveground parts.

Published

2023

30. Plant Sensors Untangle the Water-Use and Growth Effects of Selected Seaweed-Derived Biostimulants on Drought-Stressed Tomato Plants (Solanum lycopersicum)

Author

Seppe Top, Bertrand Vandoorne, Els Pauwels, Maaike Perneel, Marie-Christine Van Labeke, and Kathy Steppe

Subjects

Plant Science, Agronomy and Crop Science

Published

2023

31. Supplementary material to 'Does back-flow of leaf water introduce a discrepancy in plant water source tracing through stable isotopes?'

Author

Jeroen D. M. Schreel, Kathy Steppe, Adam B. Roddy, and María Poca

Published

2023

32. Using a Full Plant Model to Simulate Different Ventilation Strategies in a Vertical Farm Using Cfd

Author

Wito Plas, Toon Demeester, Jonas R. Coussement, Kathy Steppe, and Michel De Paepe

Published

2023

33. Automated detection of atmospheric and soil drought stress in Ficus benjamina using stem diameter measurements and modelling

Author

Hans Van de Put and Kathy Steppe

Subjects

Agriculture and Food Sciences, INDICATORS, Irrigation, Vapour Pressure Deficit, Turgor pressure, Microclimate, Soil Science, Soil science, Ficus benjamina, IRRIGATION, SAP FLOW, PLANT, WATER-STRESS, Water Science and Technology, Shrinkage, biology, Irrigation scheduling, FLUCTUATIONS, biology.organism_classification, REFERENCE VALUES, DAILY TRUNK SHRINKAGE, Soil water, GROWTH, TREES, Environmental science, Agronomy and Crop Science

Abstract

Plant stems show reversible diurnal fluctuation and irreversible growth, both related to plant water status. The reversible stem diameter shrinkage and swelling are caused by a depletion and refilling of the plant's internal water storage pools, while irreversible growth occurs when turgor pressure exceeds a certain threshold value. For this reason, stem diameter measurements provide a useful tool to assess plant water status. In this study, the use of continuous stem diameter measurements to detect atmospheric and soil drought stress in Ficus benjamina L. was explored by assessing the deviation between measured and simulated stem diameter variations using a mechanistic stem diameter model with moving window calibration. Sap flow, either directly measured or simulated with measurements of the microclimate, was used as input to the model. Both atmospheric stress by a high vapor pressure deficit and drought stress by a reduced soil water content were detected, with the latter 2 to 3 days earlier than detection based on maximum daily shrinkage and daily growth. Therefore, comparing stem diameter measurements with model simulations shows great potential for irrigation scheduling in horticulture.

Published

2021

34. The nematode effector Mj-NEROSs interacts with ISP influencing plastid ROS production to suppress plant immunity

Author

Boris Stojilković, Hui Xiang, Yujin Chen, Lander Bauters, Hans Van de Put, Kathy Steppe, Jinling Liao, Janice de Almeida Engler, and Godelieve Gheysen

Abstract

Root-knot nematodes are an important group of plant pathogens that mainly infect plant roots. They establish a feeding site in the host upon infection while secreting hundreds of effectors. These effector proteins are crucial for successful pathogen propagation. Although many effectors have been described, their targets and molecular mode of action are still unknown. Here we report the analysis of the RKN effector, Mj-NEROSs (MeloidogynejavanicanematodeeffectorROS suppressor), which emerges to have an essential role in suppressing host immunity by inhibiting INF1-induced cell death and reducing callose deposition. Secreted from the subventral esophageal glands to giant cells, Mj-NEROSs localizes in plastids where it interacts withISP, interfering with the electron transport rate and ROS production. Moreover, our transcriptome analysis shows the downregulation of ROS-related genes upon Mj-NEROSs expression. We propose that Mj-NEROSs manipulates root plastids leading to transcriptional changes, lowering ROS production, and suppressing host immunity.

Published

2022

35. Translocation of 11C-labelled photosynthates to strawberry fruits depends on leaf transpiration during twilight

Author

Yuta Miyoshi, Jens Mincke, Jonathan Vermeiren, Jan Courtyn, Christian Vanhove, Stefaan Vandenberghe, Naoki Kawachi, and Kathy Steppe

Subjects

Light intensity, DYNAMICS, Positron emission tomography, Technology and Engineering, QUALITY ATTRIBUTES, XYLEM, Relative humidity, Plant Science, PHOTOASSIMILATE TRANSLOCATION, TRANSPORT, SUGARS, GROWTH, Radioisotope tracer, PHLOEM, Photosynthate translocation, TEMPERATURE, Agronomy and Crop Science, SYSTEM, Ecology, Evolution, Behavior and Systematics, Visualization

Abstract

Photosynthate translocation from leaves to fruits is an important determinant of crop yield and quality. In protected cultivation, environmental control based on photosynthate translocation is indicative for realising high-yield and high-quality production. There are, however, few studies on the environmental response of photosynthate translocation, especially during twilight. In greenhouses, these transition periods are charac-terised by a drastic change in relative humidity (RH). In this study, we focused on light intensity as a key environmental factor to steer translocation under high RH prevailing under twilight conditions. We fed (CO2)-C-11 to a leaf of strawberry plants (Fragaria x ananassa Duch.) and analysed real-time dynamics of C-11-labeled photo-synthate translocation to individual fruits on an inflorescence of intact plants by using positron emission to-mography (PET) under different light intensities (i.e., 50, 200 and 400 mu mol m(-2) s(-1)). No clear relationship was obtained between 11C-photosynthate translocation and light intensity since the results revealed that trans-location rates into the fruits were highest under the light intensity of 200 mu mol m(-2) s(-1) followed by those of 400 and 50 mu mol m(-2) s(-1). However, there was a strong negative correlation between transpiration rate of the C-11-fed leaf and C-11-photosynthate translocation rate. These novel findings indicate that transpiration, which controls leaf moisture status, is one of the drivers for photosynthate translocation towards fruits during twilight conditions.

Published

2023

36. Efflux and assimilation of xylem‐transported <scp> CO 2 </scp> in stems and leaves of tree species with different wood anatomy

Author

Roberto L. Salomón, Kathy Steppe, Pascal Boeckx, Linus De Roo, and Samuel Bodé

Subjects

0106 biological sciences, 0301 basic medicine, FLUXES, Physiology, FATE, Plant Science, engineering.material, 01 natural sciences, CARBON-DIOXIDE, 03 medical and health sciences, RESPIRED CO2, Respiration, stem CO2 efflux, plant respiration, Leafy, Transpiration, CO2 recycling, Maple, C-13-LABELED CO2, Chemistry, fungi, Biology and Life Sciences, TRANSPIRATION, food and beverages, Xylem, Anatomy, 15. Life on land, DIFFUSION, 030104 developmental biology, TISSUE PHOTOSYNTHESIS, RESPIRATION, carbon allocation, visual_art, woody tissue photosynthesis, Shoot, Tracheid, visual_art.visual_art_medium, engineering, CO2 diffusion, Bark, xylem CO2 transport, C-CO2 labelling, SAP, 010606 plant biology & botany

Abstract

Determining the fate of CO2 respired in woody tissues is necessary to understand plant respiratory physiology and to evaluate CO2 recycling mechanisms. An aqueous 13 C-enriched CO2 solution was infused into the stem of 3-4 m tall trees to estimate efflux and assimilation of xylem-transported CO2 via cavity ring down laser spectroscopy and isotope ratio mass spectrometry, respectively. Different tree locations (lower stem, upper stem and leafy shoots) and tissues (xylem, bark and leaves) were monitored in species with tracheid, diffuse- and ring- porous wood anatomy (cedar, maple and oak, respectively). Radial xylem CO2 diffusivity and xylem [CO2 ] were lower in cedar relative to maple and oak trees, thereby limiting label diffusion. Part of the labeled 13 CO2 was assimilated in cedar (8.7 %) and oak (20.6 %) trees, mostly in xylem and bark tissues of the stem, while limited solution uptake in maple trees hindered detection of label assimilation. Little label reached foliar tissues, suggesting substantial label loss along the stem-branch transition following reductions in the radial diffusive pathway. Differences in respiration rates and radial xylem CO2 diffusivity (lower in conifer relative to angiosperm species) might reconcile discrepancies in efflux and assimilation of xylem-transported CO2 so far observed between taxonomic clades. This article is protected by copyright. All rights reserved.

Published

2021

37. Temporal variability in tree responses to elevated atmospheric <scp> CO 2 </scp>

Author

Roberto L. Salomón, Fran Lauriks, and Kathy Steppe

Subjects

0106 biological sciences, 0301 basic medicine, Canopy, Stomatal conductance, biology, Physiology, Scots pine, Carbon sink, Plant Science, Seasonality, biology.organism_classification, medicine.disease, Atmospheric sciences, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Photosynthetic acclimation, medicine, Environmental science, Water-use efficiency, 010606 plant biology & botany, Transpiration

Abstract

At leaf level, elevated atmospheric CO2 concentration (eCO(2)) results in stimulation of carbon net assimilation and reduction of stomatal conductance. However, a comprehensive understanding of the impact of eCO(2) at larger temporal (seasonal and annual) and spatial (from leaf to whole-tree) scales is still lacking. Here, we review overall trends, magnitude and drivers of dynamic tree responses to eCO(2), including carbon and water relations at the leaf and the whole-tree level. Spring and early season leaf responses are most susceptible to eCO(2) and are followed by a down-regulation towards the onset of autumn. At the whole-tree level, CO2 fertilization causes consistent biomass increments in young seedlings only, whereas mature trees show a variable response. Elevated CO2-induced reductions in leaf stomatal conductance do not systematically translate into limitation of whole-tree transpiration due to the unpredictable response of canopy area. Reduction in the end-of-season carbon sink demand and water-limiting strategies are considered the main drivers of seasonal tree responses to eCO(2). These large temporal and spatial variabilities in tree responses to eCO(2) highlight the risk of predicting tree behavior to eCO(2) based on single leaf-level point measurements as they only reveal snapshots of the dynamic responses to eCO(2).

Published

2021

38. In situ measurement of plant hydraulic conductance

Author

Kerri Mocko, M. Catalan, A. Downey, Joseph M. Michaud, A. Hunt, G. Roldan, H. J. Schenk, and Kathy Steppe

Subjects

In situ, geography, geography.geographical_feature_category, Materials science, Soil science, Horticulture, Chaparral, Hydraulic conductance

Published

2020

39. Using the SAPFLUXNET database to understand transpiration regulation of trees and forests

Author

Víctor Granda, Maurizio Mencuccini, Rafael Poyatos, Kathy Steppe, Victor Flo, and Jordi Martínez-Vilalta

Subjects

Environmental science, Forestry, Horticulture, Transpiration

Published

2020

40. Observed and modelled stem respiration CO2 and O2 fluxes in mature beech trees

Author

Juliane Helm, Roberto Salomón, Jan Muhr, Kathy Steppe, Boaz Hilman, and Henrik Hartmann

Abstract

We lack a detailed understanding of tree carbon flux dynamics to quantify stem respiration correctly. Stem CO2 radial diffusivity and vertical CO2 transport with the xylem sap produce uncertainties in respiration estimates based on stem CO2 efflux measurements. Two independent approaches have been applied for comparison to assess such uncertainties: (1) the mass balance approach accounts for CO2 efflux from the stem to the atmosphere, CO2 transport through the xylem and CO2 stored within the stem to estimate total respiration rates, and (2) measurements of stem O2 consumption as a more robust proxy for stem respiration than stem CO2 efflux, because O2 is less soluble than CO2 in the sap solution and hence less affected by vertical transport.In this study, we compare these two approaches and study CO2 and O2 flux dynamics along the stem height to capture CO2 transport. During summer 2019, we measured vertical CO2 and radial CO2 and O2 fluxes, sap flow, stem temperature and xylem sap pH from twigs. Stem CO2 and O2 fluxes were calculated along 4-m stem segments on mature beech trees in a managed forest in Germany.We found that xylem [CO2] and CO2 and O2 fluxes did not vary with stem height. Interestingly, stem CO2 efflux was a poor predictor of stem respiration in the monitored mature trees. O2 influx was always higher than CO2 efflux (on average CO2-to-O2 ratios was 0.72), resulting in an underestimation of stem respiration when using CO2 measurements only, which is standard practice.Preliminary results of the implementation of this dataset into a biophysical stem respiration model (TReSpire) suggest that CO2 respired in the xylem of mature trees encounter a relatively long diffusive pathway to reach the bark tissues, so that a significant fraction of CO2 dissolves in the sap and is transported upwards before being detected by traditional approaches. Our study provides insights into stem carbon flux dynamics in large trees, and thus helps to improve estimation of ecosystem carbon cycling.

Published

2022

41. Woody tissue photosynthesis increases radial stem growth of young poplar trees under ambient atmospheric CO2 but its contribution ceases under elevated CO2

Author

Linus De Roo, Kathy Steppe, Roberto L. Salomón, Jacek Oleksyn, and Fran Lauriks

Subjects

Drought stress, Stomatal conductance, Physiology, Phenology, Growing season, Plant Science, Poplar trees, Carbon Dioxide, Biology, Photosynthesis, Wood, Canopy conductance, Trees, Plant Leaves, Horticulture, Populus, Co2 concentration

Abstract

Woody tissue photosynthesis (Pwt) contributes to the tree carbon (C) budget and generally stimulates radial stem growth under ambient atmospheric CO2 concentration (aCO2). Moreover, Pwt has potential to enhance tree survival under changing climates by delaying negative effects of drought stress on tree hydraulic functioning. However, the relevance of Pwt on tree performance under elevated atmospheric CO2 concentration (eCO2) remains unexplored. To fill this knowledge gap, 1-year-old Populus tremula L. seedlings were grown in two treatment chambers at aCO2 and eCO2 (400 and 660 ppm, respectively), and woody tissues of half of the seedlings in each treatment chamber were light-excluded to prevent Pwt. Radial stem growth, sap flow, leaf photosynthesis and stomatal and canopy conductance were measured throughout the growing season, and the concentration of non-structural carbohydrates (NSC) in stem tissues was determined at the end of the experiment. Fuelled by eCO2, an increase in stem growth of 18 and 50% was observed in control and light-excluded trees, respectively. Woody tissue photosynthesis increased radial stem growth by 39% under aCO2, while, surprisingly, no impact of Pwt on stem growth was observed under eCO2. By the end of the growing season, eCO2 and Pwt had little effect on stem growth, leaf photosynthesis acclimated to eCO2, but stomatal conductance did not, and homeostatic stem NSC pools were observed among combined treatments. Our results highlight that eCO2 potentially fulfils plant C requirements, limiting the contribution of Pwt to stem growth as atmospheric [CO2] rises, and that radial stem growth in young developing trees was C (source) limited during early phenological stages but transitioned towards sink-driven control at the end of the growing season.

Published

2020

42. Identifying the pathways for foliar water uptake in beech ( Fagus sylvatica L.): a major role for trichomes

Author

Kathy Steppe, Olivier Leroux, Adriana Rubinstein, Jeroen D. M. Schreel, Willem Goossens, and Craig R. Brodersen

Subjects

0106 biological sciences, 0301 basic medicine, Ecophysiology, Cuticle, Plant Science, 01 natural sciences, Cell wall, 03 medical and health sciences, Fagus sylvatica, Water uptake, Botany, Fagus, Genetics, Temperate climate, Beech, biology, Cryoelectron Microscopy, Water, food and beverages, Trichomes, Cell Biology, biology.organism_classification, Trichome, Plant Leaves, 030104 developmental biology, 010606 plant biology & botany

Abstract

Foliar water uptake (FWU), the direct uptake of water into leaves, is a global phenomenon, having been observed in an increasing number of plant species. Despite the growing recognition of its functional relevance, our understanding of how FWU occurs and which foliar surface structures are implicated, is limited. In the present study, fluorescent and ionic tracers, as well as microcomputed tomography, were used to assess potential pathways for water entry in leaves of beech, a widely distributed tree species from European temperate regions. Although none of the tracers entered the leaf through the stomatal pores, small amounts of silver precipitation were observed in some epidermal cells, indicating moderate cuticular uptake. Trichomes, however, were shown to absorb and redistribute considerable amounts of ionic and fluorescent tracers. Moreover, microcomputed tomography indicated that 72% of empty trichomes refilled during leaf surface wetting and microscopic investigations revealed that trichomes do not have a cuticle but are covered with a pectin-rich cell wall layer. Taken together, our findings demonstrate that foliar trichomes, which exhibit strong hygroscopic properties as a result of their structural and chemical design, constitute a major FWU pathway in beech.

Published

2020

43. Spectral quality of monochromatic LED affects photosynthetic acclimation to high‐intensity sunlight of Chrysanthemum and Spathiphyllum

Author

Kathy Steppe, Marie-Christine Van Labeke, and Liang Zheng

Subjects

0106 biological sciences, 0301 basic medicine, Light, Chrysanthemum, Physiology, Spathiphyllum, Acclimatization, Plant Science, Photosynthetic efficiency, Photosynthesis, 01 natural sciences, 03 medical and health sciences, Dry weight, Ornamental plant, Genetics, Araceae, Chlorophyll fluorescence, biology, Chemistry, Cell Biology, General Medicine, biology.organism_classification, Plant Leaves, Horticulture, 030104 developmental biology, Photosynthetic acclimation, Sunlight, 010606 plant biology & botany

Abstract

Vertical farming using light-emitting diode offers potential for the early production phase (few weeks) of young ornamental plants. However, once transferred to the greenhouse, the photosynthetic acclimation of these young plants might depend on this initial light regime. To obtain insight about this acclimatization, Chrysanthemum (sun species) and Spathiphyllum (shade species) were preconditioned in growth chambers for 4 weeks under four light qualities: blue (B), red (R), red/blue (RB, 60% R) and white (W) at 100 mu mol m(-2) s(-1). Monochromatic light (R and B) limited leaf development of both species, which resulted in a lower leaf mass per area when compared to multispectral light (RB for Chrysanthemum, RB and W for Spathiphyllum). R-developed leaves had a lower photosynthetic efficiency in both species. After the light quality pretreatment, plants were transferred to the greenhouse with high-intensity natural light conditions. On the first day of transfer, R and B preconditioned leaves of both species had an inhibited photosynthesis. After 1 week in natural light condition, rapid light curve parameters of Chrysanthemum leaves that developed under B acclimated to sunlight had a similar level than RB-developed leaves unlike R-leaves. Spathiphyllum leaves showed a decrease in maximum electron transport rate and this was most pronounced for the R pretreatment. After 1 month, R-preconditioned Chrysanthemum had the lowest dry mass, while no effects on the dry weight of Spathiphyllum with respect to the pretreatments were observed. Light quality during preconditioning affected the leaf ability to acclimate to natural high light intensities in greenhouse environment.

Published

2020

44. Woody tissue photosynthesis reduces stem CO 2 efflux by half and remains unaffected by drought stress in young <scp> Populus tremula </scp> trees

Author

Linus De Roo, Roberto L. Salomón, and Kathy Steppe

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Cellular respiration, Chemistry, fungi, food and beverages, Xylem, Plant Science, Photosynthesis, 01 natural sciences, 03 medical and health sciences, Horticulture, chemistry.chemical_compound, 030104 developmental biology, Respiration, Carbon dioxide, Phloem transport, Phloem, 010606 plant biology & botany, Transpiration

Abstract

A substantial portion of locally respired CO2 in stems can be assimilated by chloroplast-containing tissues. Woody tissue photosynthesis (Pwt ) therefore plays a major role in the stem carbon balance. To study the impact of Pwt on stem carbon cycling along a gradient of water availability, stem CO2 efflux (EA ), xylem CO2 concentration ([CO2 ]), and xylem water potential (Ψxylem ) were measured in 4-year-old Populus tremula L. trees exposed to drought stress and different regimes of light exclusion of woody tissues. Under well-watered conditions, local Pwt decreased EA up to 30%. Axial CO2 diffusion (Dax ) induced by distant Pwt caused an additional decrease in EA of up to 25% and limited xylem [CO2 ] build-up. Under drought stress, absolute decreases in EA driven by Pwt remained stable, denoting that Pwt was not affected by drought. At the end of the dry period, when transpiration was low, local Pwt and Dax offset 20% and 10% of stem respiration on a daily basis, respectively. These results highlight (a) the importance of Pwt for an adequate interpretation of EA measurements and (b) homeostatic Pwt along a drought stress gradient, which might play a crucial role to fuel stem metabolism when leaf carbon uptake and phloem transport are limited.

Published

2020

45. Salt Stress Induced Changes in Photosynthesis and Metabolic Profiles of One Tolerant (‘Bonica’) and One Sensitive (‘Black Beauty’) Eggplant Cultivars (Solanum melongena L.)

Author

Labeke, Sami Hannachi, Kathy Steppe, Mabrouka Eloudi, Lassaad Mechi, Insaf Bahrini, and Marie-Christine Van

Subjects

antioxidant response, electrolyte leakage, mineral content, photosynthesis, photorespiration, total phenols, salt, Solanum melongena L

Abstract

The impact of salinity on the physiological and biochemical parameters of tolerant (‘Bonica’) and susceptible (‘Black Beauty’) eggplant varieties (Solanum melongena L.) was determined. The results revealed that the increase in salinity contributes to a significant decline in net photosynthesis (An) in both varieties; however, at the highest salt concentration (160 mM NaCl), the decrease in photorespiration (Rl) was less pronounced in the tolerant cultivar ‘Bonica’. Stomatal conductance (gs) was significantly reduced in ‘Black Beauty’ following exposure to 40 mM NaCl. However, gs of ‘Bonica’ was only substantially reduced at the highest level of NaCl (160 mM). In addition, a significant decrease in Chla, Chlb, total Chl, Chla/b and carotenoids (p > 0.05) was found in ‘Black Beauty’, and soluble carbohydrates accumulation and electrolyte leakage (EL) were more pronounced in ‘Black Beauty’ than in ‘Bonica’. The total phenols increase in ‘Bonica’ was 65% higher than in ‘Black Beauty’. In ‘Bonica’, the roots displayed the highest enzyme scavenging activity compared to the leaves. Salt stress contributes to a significant augmentation of root catalase and guaiacol peroxidase activities. In ‘Bonica’, the Na concentration was higher in roots than in leaves, whereas in ‘Black Beauty‘, the leaves accumulated more Na. Salt stress significantly boosted the Na/K ratio in ‘Black Beauty’, while no significant change occurred in ‘Bonica’. ACC deaminase activity was significantly higher in ‘Bonica’ than in ‘Black Beauty’.

Published

2022

46. Foliar water uptake does not contribute to embolism repair in beech (Fagus sylvatica L.)

Author

Jeroen D M Schreel, Craig Brodersen, Thomas De Schryver, Manuel Dierick, Adriana Rubinstein, Koen Dewettinck, Matthieu N Boone, Luc Van Hoorebeke, and Kathy Steppe

Subjects

Plant Leaves, Xylem, fungi, Embolism, Fagus, food and beverages, Water, Plant Science, Original Articles, X-Ray Microtomography, Droughts

Abstract

Background and Aims Foliar water uptake has recently been suggested as a possible mechanism for the restoration of hydraulically dysfunctional xylem vessels. In this paper we used a combination of ecophysiological measurements, X-ray microcomputed tomography and cryo-scanning electron microscopy during a drought treatment to fully evaluate this hypothesis. Key Results Based on an assessment of these methods in beech (Fagus sylvatica L.) seedlings we were able to (1) confirm an increase in the amount of hydraulically redistributed water absorbed by leaves when the soil water potential decreased, and (2) locate this redistributed water in hydraulically active vessels in the stem. However, (3) no embolism repair was observed irrespective of the organ under investigation (i.e. stem, petiole or leaf) or the intensity of drought. Conclusions Our data provide evidence for a hydraulic pathway from the leaf surface to the stem xylem following a water potential gradient, but this pathway exists only in functional vessels and does not play a role in embolism repair for beech.

Published

2022

47. A Temperature Ratio Heat Pulse (Trhp) Method for Measuring Sap Flow

Author

yuchen ma, Ruiqi Ren, han fu, Bingcheng Si, Nicholas J. Kinar, Tamir Kamai, and Kathy Steppe

Published

2022

48. Prospects and Limitations of Nitrogen Fertigation and Summer Application in ‘Conference’ Pear Trees

Author

Ben Colpaert, Kathy Steppe, Sofie Reynaert, Pieter Janssens, Ann Gomand, Bart Vanhoutte, Serge Remy, and Pascal Boeckx

Published

2022

49. Limited plasticity of anatomical and hydraulic traits in aspen trees under elevated CO(2) and seasonal drought

Author

Roberto L. Salomón, Linus De Roo, Willem Goossens, Fran Lauriks, Kathy Steppe, and Olivier Leroux

Subjects

Early season, Stomatal conductance, Water release, Dehydration, Physiology, Abiotic stress, fungi, Cell Plasticity, food and beverages, Growing season, Xylem, Plant Development, Plant Science, Biology, Plasticity, Carbon Dioxide, Droughts, Populus, Agronomy, Genetics, Late season, Seasons, Research Articles

Abstract

The timing of abiotic stress elicitors on wood formation largely affects xylem traits that determine xylem efficiency and vulnerability. Nonetheless, seasonal variability of elevated CO2 (eCO2) effects on tree functioning under drought remains largely unknown. To address this knowledge gap, 1-year-old aspen (Populus tremula L.) trees were grown under ambient (±445 ppm) and elevated (±700 ppm) CO2 and exposed to an early (spring/summer 2019) or late (summer/autumn 2018) season drought event. Stomatal conductance and stem shrinkage were monitored in vivo as xylem water potential decreased. Additional trees were harvested for characterization of wood anatomical traits and to determine vulnerability and desorption curves via bench dehydration. The abundance of narrow vessels decreased under eCO2 only during the early season. At this time, xylem vulnerability to embolism formation and hydraulic capacitance during severe drought increased under eCO2. Contrastingly, stomatal closure was delayed during the late season, while hydraulic vulnerability and capacitance remained unaffected under eCO2. Independently of the CO2 treatment, elastic, and inelastic water pools depleted simultaneously after 50% of complete stomatal closure. Our results suggest that the effect of eCO2 on drought physiology and wood traits are small and variable during the growing season and question a sequential capacitive water release from elastic and inelastic pools as drought proceeds.

Published

2021

50. Salt Stress Induced Changes in Photosynthesis and Metabolic Profiles of One Tolerant ('Bonica') and One Sensitive ('Black Beauty') Eggplant Cultivars (

Author

Sami, Hannachi, Kathy, Steppe, Mabrouka, Eloudi, Lassaad, Mechi, Insaf, Bahrini, and Marie-Christine, Van Labeke

Abstract

The impact of salinity on the physiological and biochemical parameters of tolerant ('Bonica') and susceptible ('Black Beauty') eggplant varieties (

Published

2021