Your search keyword '"xylem transport"' showing total 184 results

1. Exploring optimal stomatal control under alternative hypotheses for the regulation of plant sources and sinks.

Author

Dewar, Roderick, Hölttä, Teemu, and Salmon, Yann

Subjects

*STOMATA, *EUROPEAN aspen, *EUROPEAN white birch, *NORWAY spruce, *TURGOR

Abstract

Summary: Experimental evidence that nonstomatal limitations to photosynthesis (NSLs) correlate with leaf sugar and/or leaf water status suggests the possibility that stomata adjust to maximise photosynthesis through a trade‐off between leaf CO2 supply and NSLs, potentially involving source–sink interactions. However, the mechanisms regulating NSLs and sink strength, as well as their implications for stomatal control, remain uncertain.We used an analytically solvable model to explore optimal stomatal control under alternative hypotheses for source and sink regulation. We assumed that either leaf sugar concentration or leaf water potential regulates NSLs, and that either phloem turgor pressure or phloem sugar concentration regulates sink phloem unloading.All hypotheses led to realistic stomatal responses to light, CO2 and air humidity, including conservative behaviour for the intercellular‐to‐atmospheric CO2 concentration ratio. Sugar‐regulated and water‐regulated NSLs are distinguished by the presence/absence of a stomatal closure response to changing sink strength. Turgor‐regulated and sugar‐regulated phloem unloading are distinguished by the presence/absence of stomatal closure under drought and avoidance/occurrence of negative phloem turgor. Results from girdling and drought experiments on Pinus sylvestris, Betula pendula, Populus tremula and Picea abies saplings are consistent with optimal stomatal control under sugar‐regulated NSLs and turgor‐regulated unloading.Our analytical results provide a simple representation of stomatal responses to above‐ground and below‐ground environmental factors and sink activity. [ABSTRACT FROM AUTHOR]

Published

2022

2. Drought-Induced Root Pressure in Sorghum bicolor

Author

Sarah Tepler Drobnitch, Louise H. Comas, Nora Flynn, Jorge Ibarra Caballero, Ryan W. Barton, Joshua Wenz, Taylor Person, Julie Bushey, Courtney E. Jahn, and Sean M. Gleason

Subjects

water relations, xylem transport, root pressure, RNA-Seq, agriculture, transporter, Plant culture, SB1-1110

Abstract

Root pressure, also manifested as profusive sap flowing from cut stems, is a phenomenon in some species that has perplexed biologists for much of the last century. It is associated with increased crop production under drought, but its function and regulation remain largely unknown. In this study, we investigated the initiation, mechanisms, and possible adaptive function of root pressure in six genotypes of Sorghum bicolor during a drought experiment in the greenhouse. We observed that root pressure was induced in plants exposed to drought followed by re-watering but possibly inhibited by 100% re-watering in some genotypes. We found that root pressure in drought stressed and re-watered plants was associated with greater ratio of fine: coarse root length and shoot biomass production, indicating a possible role of root allocation in creating root pressure and adaptive benefit of root pressure for shoot biomass production. Using RNA-Seq, we identified gene transcripts that were up- and down-regulated in plants with root pressure expression, focusing on genes for aquaporins, membrane transporters, and ATPases that could regulate inter- and intra-cellular transport of water and ions to generate positive xylem pressure in root tissue.

Published

2021

3. Drought-Induced Root Pressure in Sorghum bicolor.

Author

Drobnitch, Sarah Tepler, Comas, Louise H., Flynn, Nora, Ibarra Caballero, Jorge, Barton, Ryan W., Wenz, Joshua, Person, Taylor, Bushey, Julie, Jahn, Courtney E., and Gleason, Sean M.

Subjects

MEMBRANE transport proteins, BIOMASS production, PRESSURE, SORGHUM, GENES, AGRICULTURAL productivity

Abstract

Root pressure, also manifested as profusive sap flowing from cut stems, is a phenomenon in some species that has perplexed biologists for much of the last century. It is associated with increased crop production under drought, but its function and regulation remain largely unknown. In this study, we investigated the initiation, mechanisms, and possible adaptive function of root pressure in six genotypes of Sorghum bicolor during a drought experiment in the greenhouse. We observed that root pressure was induced in plants exposed to drought followed by re-watering but possibly inhibited by 100% re-watering in some genotypes. We found that root pressure in drought stressed and re-watered plants was associated with greater ratio of fine: coarse root length and shoot biomass production, indicating a possible role of root allocation in creating root pressure and adaptive benefit of root pressure for shoot biomass production. Using RNA-Seq, we identified gene transcripts that were up- and down-regulated in plants with root pressure expression, focusing on genes for aquaporins, membrane transporters, and ATPases that could regulate inter- and intra-cellular transport of water and ions to generate positive xylem pressure in root tissue. [ABSTRACT FROM AUTHOR]

Published

2021

4. Stem hydraulic architecture and xylem vulnerability to cavitation for miombo woodlands canopy tree species

Author

Vinya, Royd, Yadvinder, Malhi, and Nick, Brown

Subjects

634.9, Botanical sciences (see Plant sciences), cavitation, miombo woodlands, hydraulic architecture, xylem transport, specific leaf area, leaf dry matter content, hydraulic conductivity

Abstract

Africa's miombo woodlands constitute one of the most important dry tropical forests on earth, yet the hydraulic function of these woodlands remains poorly researched. Given the current predictions of increased aridity by the end of this century in the miombo ecoregion, understanding the likely response of miombo woodlands tree species to water stress is crucial in planning adaptation strategies. Predicting the response of miombo woodlands to future climate trends is hampered by a lack of knowledge on the physiology of the common miombo woodlands tree species. In particular, plant-water relations for this woodlands type are not well understood. An understanding of plant-water relations for this woodlands type will provide insights into how water limits tree species distribution in this ecosystem. This will also improve our prediction model on the likely response of this ecosystem to predicted climate change. For this reason, the overall objective of this research was to evaluate the hydraulic architecture and xylem vulnerability to cavitation for nine principal miombo woodlands tree species differing in drought tolerance ability and habitat preference. This was achieved by; examining the hydraulic properties and evaluating the extent to which each hydraulic design was vulnerable to water stress-induced xylem cavitation; investigating how seasonal changes in plant-water relations influences seasonal patterns of leaf display and; analyzing the relationship between stem hydraulic supply and leaf functional traits related to drought tolerance ability. This research has found that drought-intolerant tree species with mesic specialization have more efficient stem hydraulic systems than co-occurring habitat broad ranging species. Broad ranging tree species attain wider habitat distribution by adjusting their hydraulic supply in response to changing ecosystem water availability. The finding that hydraulic properties differ significantly between tree species with contrasting habitat preference suggests that tree hydraulic design may have some adaptive ecological role in influencing species habitat preferences in miombo woodlands. The evaluation of xylem vulnerability to cavitation revealed that mesic specialized tree species were more vulnerable to water stress-induced cavitation than habitat broad ranging tree species. Vulnerability to cavitation in individuals from the same broad-ranging species growing in contrasting habitats showed only marginal and statistically insignificant (P > 0.05) differences between wet and dry sites. In the investigation of the influence of seasonal changes in stem water relations on seasonal leaf display, seasonal rhythms in stem water status were found to exert significant controls on leaf phenology. Mesic specialists had strong stem water controls throughout the year in comparison to broad ranging tree species. An analysis of the relationship between stem hydraulic supply and leaf functional traits suggests that stem hydraulic supply constrains leaf biomass allocation patterns among miombo tree species. Mesic specialists tend to invest more in leaf longevity than broad ranging tree species. This thesis has uncovered some interesting relationships between plant-water-relations and the distribution of miombo woodlands tree species. These results lead to the conclusion that in an event of increased ecosystem drying under future climate trends, tree species with mesic specialisation are at a greater risk of experiencing cavitation related species mortality than broad ranging ones.

Published

2010

5. Seasonal coordination of leaf hydraulics and gas exchange in a wintergreen fern.

Author

Prats, Kyra A and Brodersen, Craig R

Subjects

HYDRAULICS, LEAF temperature, CHLOROPHYLL spectra, FREEZE-thaw cycles, ATMOSPHERIC temperature, FERNS

Abstract

Wintergreen fern Polystichum acrostichoides has fronds that are photosynthetically active year-round, despite diurnal and seasonal changes in soil moisture, air temperature and light availability. This species can fix much of its annual carbon during periods when the deciduous canopy is open. Yet, remaining photosynthetically active year-round requires the maintenance of photosynthetic and hydraulic systems that are vulnerable to freeze–thaw cycles. We aimed to determine the anatomical and physiological strategies P. acrostichoides uses to maintain positive carbon gain, and the coordination between the hydraulic and photosynthetic systems. We found that the first night below 0 °C led to 25 % loss of conductivity (PLC) in stipes, suggesting that winter-induced embolism occurred. Maximum photosynthetic rate and chlorophyll fluorescence declined during winter but recovered by spring, despite PLC remaining high; the remaining hydraulic capacity was sufficient to supply the leaves with water. The onset of colder temperatures coincided with the development of a necrotic hinge zone at the stipe base, allowing fronds to overwinter lying prostrate and maintain a favourable leaf temperature. Our conductivity data show that the hinge zone did not affect leaf hydraulics because of the flexibility of the vasculature. Collectively, these strategies help P. acrostichoides to survive in northeastern forests. [ABSTRACT FROM AUTHOR]

Published

2020

6. Is Decreased Xylem Sap Surface Tension Associated With Embolism and Loss of Xylem Hydraulic Conductivity in Pathogen-Infected Norway Spruce Saplings?

Author

Paljakka, Teemu, Rissanen, Kaisa, Vanhatalo, Anni, Salmon, Yann, Jyske, Tuula, Prisle, Nønne L., Linnakoski, Riikka, Lin, Jack J., Laakso, Tapio, Kasanen, Risto, Bäck, Jaana, and Hölttä, Teemu

Subjects

NORWAY spruce, XYLEM, EMBOLISMS, QUINIC acid, BARK beetles, ELECTRIC conduits, SURFACE tension, HYDRAULIC conductivity

Abstract

Increased abiotic stress along with increasing temperatures, dry periods and forest disturbances may favor biotic stressors such as simultaneous invasion of bark beetle and ophiostomatoid fungi. It is not fully understood how tree desiccation is associated with colonization of sapwood by fungi. A decrease in xylem sap surface tension (σxylem) as a result of infection has been hypothesized to cause xylem embolism by lowering the threshold for air-seeding at the pits between conduits and disruptions in tree water transport. However, this hypothesis has not yet been tested. We investigated tree water relations by measuring the stem xylem hydraulic conductivity (Kstem), σxylem, stem relative water content (RWCstem), and water potential (Ψstem), and canopy conductance (gcanopy), as well as the compound composition in xylem sap in Norway spruce (Picea abies) saplings. We conducted our measurements at the later stage of Endoconidiophora polonica infection when visible symptoms had occurred in xylem. Saplings of two clones (44 trees altogether) were allocated to treatments of inoculated, wounded control and intact control trees in a greenhouse. The saplings were destructively sampled every second week during summer 2016. σxylem, Kstem and RWCstem decreased following the inoculation, which may indicate that decreased σxylem resulted in increased embolism. gcanopy did not differ between treatments indicating that stomata responded to Ψstem rather than to embolism formation. Concentrations of quinic acid, myo-inositol, sucrose and alkylphenol increased in the xylem sap of inoculated trees. Myo-inositol concentrations also correlated negatively with σxylem and Kstem. Our study is a preliminary investigation of the role of σxylem in E. polonica infected trees based on previous hypotheses. The results suggest that E. polonica infection can lead to a simultaneous decrease in xylem sap surface tension and a decline in tree hydraulic conductivity, thus hampering tree water transport. [ABSTRACT FROM AUTHOR]

Published

2020

7. Systemic Long-Distance Signaling and Communication Between Rootstock and Scion in Grafted Vegetables.

Author

Lu, Xiaohong, Liu, Wenqian, Wang, Tao, Zhang, Jiali, Li, Xiaojun, and Zhang, Wenna

Subjects

ROOTSTOCKS, VEGETABLES, NICOTIANA benthamiana, ARABIDOPSIS thaliana, ABIOTIC stress

Abstract

Grafting is widely used in fruit, vegetable, and flower propagation to improve biotic and abiotic stress resistance, yield, and quality. At present, the systemic changes caused by grafting, as well as the mechanisms and effects of long-distance signal transport between rootstock and scion have mainly been investigated in model plants (Arabidopsis thaliana and Nicotiana benthamiana). However, these aspects of grafting vary when different plant materials are grafted, so the study of model plants provides only a theoretical basis and reference for the related research of grafted vegetables. The dearth of knowledge about the transport of signaling molecules in grafted vegetables is inconsistent with the rapid development of large-scale vegetable production, highlighting the need to study the mechanisms regulating the rootstock-scion interaction and long-distance transport. The rapid development of molecular biotechnology and "omics" approaches will allow researchers to unravel the physiological and molecular mechanisms involved in the rootstock–scion interaction in vegetables. We summarize recent progress in the study of the physiological aspects (e.g., hormones and nutrients) of the response in grafted vegetables and focus in particular on long-distance molecular signaling (e.g., RNA and proteins). This review provides a theoretical basis for studies of the rootstock–scion interaction in grafted vegetables, as well as provide guidance for rootstock breeding and selection to meet specific demands for efficient vegetable production. [ABSTRACT FROM AUTHOR]

Published

2020

8. Leaf carbon and water status control stomatal and nonstomatal limitations of photosynthesis in trees.

Author

Salmon, Yann, Lintunen, Anna, Dayet, Alexia, Chan, Tommy, Dewar, Roderick, Vesala, Timo, and Hölttä, Teemu

Subjects

*EUROPEAN aspen, *GAS exchange in plants, *PHOTOSYNTHESIS, *EUROPEAN white birch, *PHOTOSYNTHETIC rates, *SCOTS pine

Abstract

Summary: Photosynthetic rate is concurrently limited by stomatal limitations and nonstomatal limitations (NSLs). However, the controls on NSLs to photosynthesis and their coordination with stomatal control on different timescales remain poorly understood. According to a recent optimization hypothesis, NSLs depend on leaf osmotic or water status and are coordinated with stomatal control so as to maximize leaf photosynthesis.Drought and notching experiments were conducted on Pinus sylvestris, Picea abies, Betula Pendula and Populus tremula seedlings in glasshouse conditions to study the dependence of NSLs on leaf osmotic and water status, and their coordination with stomatal control, on timescales of minutes and weeks, to test the assumptions and predictions of the optimization hypothesis.Both NSLs and stomatal conductance followed power‐law functions of leaf osmotic concentration and leaf water potential. Moreover, stomatal conductance was proportional to the square root of soil‐to‐leaf hydraulic conductance, as predicted by the optimization hypothesis.Though the detailed mechanisms underlying the dependence of NSLs on leaf osmotic or water status lie outside the scope of this study, our results support the hypothesis that NSLs and stomatal control are coordinated to maximize leaf photosynthesis and allow the effect of NSLs to be included in models of tree gas‐exchange. [ABSTRACT FROM AUTHOR]

Published

2020

9. Development of a highly sensitive, quick, and easy LC-ESI-TOF-MS method to quantify nicotianamine and 2'-deoxymugineic acid in plants

Author

Kakei, Yusuke, Yamaguchi, Isomaro, Takahashi, Michiko, Nakanishi, Hiromi, Mori, Satoshi, and Nishizawa, Naoko K

Subjects

Nutrient Acquisition, Homeostasis and Sink/Source Relations, 2’-dexymugineic acid, Fe-deficiency, nicotianamine, xylem transport, LC-ESI-TOF-MS, quantification method

Abstract

A highly sensitive quantitative method for assaying nicotianamine (NA) and 2'-deoxymugineic acid (DMA) using liquid chromatography electrospray ionization time-of-flight mass spectrometry (LC-ESI-TOF-MS) was developed. This method requires fewer sample preparation steps than high-performance liquid chromatography (HPLC). The amino and hydroxyl groups of NA and DMA were derivatized using 9-fluorenylmethoxycarbonyl chloride, which improved their retention on a C18 reversed-phase column and facilitated separation. The amounts of NA and DMA in 10 μl of xylem sap from rice cultivated under Fe-sufficient and Fe-deficient conditions were quantified without concentration. In Fe-sufficient plants, the concentrations of NA and DMA were almost equal to that of Fe. In Fe-deficient plants, the concentration of NA did not change significantly, whereas that of DMA increased markedly.

Published

2009

10. Cargo‐dependent and cell wall‐associated xylem transport in Arabidopsis.

Author

Endo, Satoshi, Iwai, Yumi, and Fukuda, Hiroo

Subjects

*XYLEM, *PLANT cells & tissues, *ARABIDOPSIS, *FLUOROPHORES, *FLUORESCEIN

Abstract

Summary: Sap molecules are transported by xylem flow throughout the whole plant body. Factors regulating the xylem transport of different molecules remain to be identified.We used fluorophores to visualize xylem transport from roots to leaves in Arabidopsis thaliana. Several previously established Arabidopsis lines with modified xylem cell walls were used to determine the contribution of xylem cell walls to xylem transport.Fluorophores underwent xylem flow‐dependent transport from roots to leaves within 20 min. A comparison of rhodamine, fluorescein and three fluorescently labeled CLV3/ESR‐related (CLE) peptides revealed cargo‐dependent xylem transport patterns in terms of leaf position and vein order. Only minor changes in amino acid sequence were sufficient to alter the xylem transport patterns of the labeled CLE peptides. We found that the xylem transport pattern of fluorescein was affected in Arabidopsis lines with modified AtXYN1,LAC4 or CCoAOMT1 expression. In these lines, application of a defense inducer, pipecolic acid, to roots resulted in altered defense response patterns in leaves, whereas all the lines showed wild‐type‐like responses when pipecolic acid was sprayed onto leaves.The combined results reveal a finely controlled cargo‐dependent xylem transport and suggest that the xylem cell wall structure is crucial for this transport system. [ABSTRACT FROM AUTHOR]

Published

2019

11. Functional xylem anatomy of aspen exhibits greater change due to insect defoliation than to drought.

Author

Hillabrand, R M, Lieffers, V J, Hogg, E H, Martínez-Sancho, E, Menzel, A, and Hacke, U G

Subjects

*TREE-rings, *XYLEM, *POPULUS tremuloides, *DEFOLIATION, *CAVITATION, *DROUGHTS

Abstract

The study of tree rings can reveal long-term records of a tree's response to the environment. This dendroecological approach, when supplemented with finer-scale observations of the xylem anatomy, can provide novel information about a tree's year-to-year anatomical and hydraulic adjustments. Here we use this method in aspen (Populus tremuloides Michx.) to identify xylem response to drought and insect defoliation. Surprisingly, we found that precipitation influenced vessel diameter mostly in the trees' youth, while this correlation was less pronounced at maturity. This is likely due to a reduction in stress the stand experiences as it ages, and reflects an ability to mediate drought stress as trees mature. Defoliation events caused consistent and profound changes in fiber anatomy likely leading to reduced structural support to vessels. We therefore expect that in years of defoliation trees may be vulnerable to drought-induced cavitation when leaf area recovers. This study highlights how the inclusion of cellular level measurements in tree ring studies provides additional information on how stress events may alter tree functioning through alterations in structure. [ABSTRACT FROM AUTHOR]

Published

2019

12. Mechanistic modelling of coupled phloem/xylem transport for L-systems: combining analytical and computational methods.

Author

Seleznyova, Alla N and Hanan, Jim

Subjects

*XYLEM, *PHLOEM, *CARBOHYDRATES, *PLANT growth, *PLANT physiology

Abstract

Background and Aims Transport of carbohydrates and water are essential aspects of plant function. The aim of this study was to develop and test the methods for mechanistic modelling of quasi-stationary coupled phloem/ xylem transport in the context of functional--structural plant modelling. Methods The novelty of this approach is in combining analytical and computational methods. The plant structure is modelled at a metamer level with the internodes represented by conduit elements and the lateral organs represented by sources and sinks. Transport equations are solved analytically for each internode and then the solutions are adjusted and 'sewn' together using an iterative computational procedure taking into account concentration-dependent sinks and sources. The model is implemented in L-studio and uses the aspect-oriented modelling approach for phloem/xylem coupling. Key Results To our knowledge, this is the first transport model that provides continuous distributions of the system variables in a complex developing structure. The model takes into account non-linear dependence of phloem resistance and osmotic potential on the local carbohydrate concentration. The model solutions show excellent agreement with the existing results of other analytical and numerical models. These comparisons confirm the validity of the approximations made in the model. Combining analytical and computational methods made it possible to take into account continuous sink/source distribution within internodes without much increase in the complexity of the computational procedure, because the necessary changes in the model were mostly in the analytical part. The results emphasize sensitivity of phloem flux and lateral xylem flux to the presence of distributed sinks and sources along the transport system. Conclusions The presented approach provides a new insight into mechanistic modelling of phloem/xylem transport in growing plants. It will be useful for both fine-scale modelling of carbohydrate dynamics and for creating simpler models at a growth unit level. [ABSTRACT FROM AUTHOR]

Published

2018

13. A steady-state stomatal model of balanced leaf gas exchange, hydraulics and maximal source-sink flux.

Author

Hölttä, Teemu, Lintunen, Anna, Chan, Tommy, Mäkelä, Annikki, and Nikinmaa, Eero

Subjects

*STOMATA, *TREE physiology, *PLANT physiology, *XYLEM, *PHLOEM

Abstract

Trees must simultaneously balance their CO2 uptake rate via stomata, photosynthesis, the transport rate of sugars and rate of sugar utilization in sinks while maintaining a favourable water and carbon balance. We demonstrate using a numerical model that it is possible to understand stomatal functioning from the viewpoint of maximizing the simultaneous photosynthetic production, phloem transport and sink sugar utilization rate under the limitation that the transpiration-driven hydrostatic pressure gradient sets for those processes. A key feature in our model is that non-stomatal limitations to photosynthesis increase with decreasing leaf water potential and/or increasing leaf sugar concentration and are thus coupled to stomatal conductance. Maximizing the photosynthetic production rate using a numerical steady-state model leads to stomatal behaviour that is able to reproduce the well-known trends of stomatal behaviour in response to, e.g., light, vapour concentration difference, ambient CO2 concentration, soil water status, sink strength and xylem and phloem hydraulic conductance. We show that our results for stomatal behaviour are very similar to the solutions given by the earlier models of stomatal conductance derived solely from gas exchange considerations. Our modelling results also demonstrate how the 'marginal cost of water' in the unified stomatal conductance model and the optimal stomatal model could be related to plant structural and physiological traits, most importantly, the soil-to-leaf hydraulic conductance and soil moisture. [ABSTRACT FROM AUTHOR]

Published

2017

14. NITROGEN USED STRATEGIES OF NODULATED AMAZONIAN LEGUME: INGA EDULIS.

Author

Justino, G. C., Omena-Garcia, R. P., dos Santos, A. M. S., de Camargos, L. S, Sodek, L., and Gonçalves, J. F. C.

Subjects

*LEGUMES, *NITROGEN content of plants, *NITROGEN fixation, *PLANT roots, *PLANT shoots

Abstract

Symbiotic nitrogen fixation in legumes is strongly diminished by mineral nitrogen. Nevertheless, recent work with some tropical legumes revealed low sensitivity to mineral nitrogen or even enhancement of nodulation by ammonium. Thus, in this study, we investigated plant growth and nodulation of Inga edulis over a period of 128 days using different sources of nitrogen, i.e. ammonium (15 mM), nitrate (15 mM) and symbiotic nitrogen fixation. Plant growth was evaluated through dry mass, height, stem diameter and root/shoot ratio as well as nodulation by nodule number and dry mass. Nitrate, ureides and total amino acids were determined in roots, shoots and xylem sap. All three nitrogen sources were found to stimulate growth relative to the noninoculated N-free control, however ammonium was the most effective. Nodulation, both nodule number and mass, was strongly reduced by nitrate but not ammonium. The transport of total amino acids in the xylem sap was stimulated by ammonium without change in the composition with asparagine predominating in all treatments. Inga edulis can benefit from fertilisation with ammonium since even at high concentrations growth was improved without impairing nodulation, a condition appropriate for restoration of soil conditions. [ABSTRACT FROM AUTHOR]

Published

2017

15. Fruit Calcium: Transport and Physiology

Author

Bradleigh eHocking, Stephen Donald Tyerman, Rachel eBurton, and Matthew eGilliham

Subjects

Calcium, pectin, Fruit ripening, water transport, xylem transport, Plant culture, SB1-1110

Abstract

Calcium has well-documented roles in plant signaling, water relations and cell wall interactions. Significant research into how calcium impacts these individual processes in various tissues has been carried out; however, the influence of calcium on fruit ripening has not been thoroughly explored. Here, we review the current state of knowledge on how calcium may impact fruit development, physical traits and disease susceptibility through facilitating developmental and stress response signaling, stabilizing membranes, influencing water relations and modifying cell wall properties through cross-linking of de-esterified pectins. We explore the involvement of calcium in hormone signaling integral to ripening and the physiological mechanisms behind common disorders that have been associated with fruit calcium deficiency (e.g. blossom end rot in tomatoes or bitter pit in apples). This review works towards an improved understanding of how the many roles of calcium interact to influence fruit ripening, and proposes future research directions to fill knowledge gaps. Specifically, we focus mostly on grapes and present a model that integrates existing knowledge around these various functions of calcium in fruit, which provides a basis for understanding the physiological impacts of sub-optimal calcium nutrition in grapes. Calcium accumulation and distribution in fruit is shown to be highly dependent on water delivery and cell wall interactions in the apoplasm. Localized calcium deficiencies observed in particular species or varieties can result from differences in xylem morphology, fruit water relations and pectin composition, and can cause leaky membranes, irregular cell wall softening, impaired hormonal signaling and aberrant fruit development. We propose that the role of apoplasmic calcium-pectin crosslinking, particularly in the xylem, is an understudied area that may have a key influence on fruit water relations. Furthermore, we believe that improved knowledge of the calcium-regulated signaling pathways that control ripening would assist in addressing calcium deficiency disorders and improving fruit pathogen resistance.

Published

2016

16. Leaf carbon and water status control stomatal and nonstomatal limitations of photosynthesis in trees

Author

Alexia Dayet, Yann Salmon, Roderick C. Dewar, Timo Vesala, Teemu Hölttä, Anna Lintunen, Tommy Chan, Micrometeorology and biogeochemical cycles, INAR Physics, Ecosystem processes (INAR Forest Sciences), Institute for Atmospheric and Earth System Research (INAR), Forest Ecology and Management, Viikki Plant Science Centre (ViPS), University Management, and Department of Forest Sciences

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, Physiology, chemistry.chemical_element, drought, Plant Science, Leaf water, Photosynthesis, 114 Physical sciences, stomatalconductance, 01 natural sciences, leaf water potential, Trees, 03 medical and health sciences, xylem transport, biology, fungi, Water, food and beverages, Picea abies, 15. Life on land, biology.organism_classification, Hydraulic conductance, Carbon, leaf osmoticconcentration, notching, Plant Leaves, %22">Pinus , Horticulture, 030104 developmental biology, chemistry, Plant Stomata, Environmental science, non-stomatal limitation, 010606 plant biology & botany

Abstract

Photosynthetic rate is concurrently limited by stomatal limitations and nonstomatal limitations (NSLs). However, the controls on NSLs to photosynthesis and their coordination with stomatal control on different timescales remain poorly understood. According to a recent optimization hypothesis, NSLs depend on leaf osmotic or water status and are coordinated with stomatal control so as to maximize leaf photosynthesis. Drought and notching experiments were conducted on Pinus sylvestris, Picea abies, Betula Pendula and Populus tremula seedlings in glasshouse conditions to study the dependence of NSLs on leaf osmotic and water status, and their coordination with stomatal control, on timescales of minutes and weeks, to test the assumptions and predictions of the optimization hypothesis. Both NSLs and stomatal conductance followed power-law functions of leaf osmotic concentration and leaf water potential. Moreover, stomatal conductance was proportional to the square root of soil-to-leaf hydraulic conductance, as predicted by the optimization hypothesis. Though the detailed mechanisms underlying the dependence of NSLs on leaf osmotic or water status lie outside the scope of this study, our results support the hypothesis that NSLs and stomatal control are coordinated to maximize leaf photosynthesis and allow the effect of NSLs to be included in models of tree gas-exchange.

Published

2020

17. Exploring optimal stomatal control under alternative hypotheses for the regulation of plant sources and sinks

Author

Yann Salmon, Roderick C. Dewar, Teemu Hölttä, Institute for Atmospheric and Earth System Research (INAR), Department of Forest Sciences, Viikki Plant Science Centre (ViPS), Ecosystem processes (INAR Forest Sciences), Forest Ecology and Management, and Micrometeorology and biogeochemical cycles

Subjects

0106 biological sciences, Stomatal conductance, DOWN-REGULATION, Physiology, MESOPHYLL CONDUCTANCE, Turgor pressure, LEAF GAS-EXCHANGE, SUGAR-TRANSPORT, Plant Science, Phloem, Biology, CO2 CONCENTRATION, Photosynthesis, 01 natural sciences, 03 medical and health sciences, NONSTOMATAL LIMITATIONS, Girdling, Botany, Phloem transport, optimisation model, sink activity, WATER-STRESS, 030304 developmental biology, xylem transport, 0303 health sciences, photosynthesis, nonstomatal limitation, fungi, phloem transport, food and beverages, Picea abies, 15. Life on land, biology.organism_classification, 11831 Plant biology, Droughts, Plant Leaves, stomatal conductance, Plant Stomata, SOIL-TEMPERATURE, Sink (computing), non-stomatal limitation, 010606 plant biology & botany

Abstract

Summary Experimental evidence that nonstomatal limitations to photosynthesis (NSLs) correlate with leaf sugar and/or leaf water status suggests the possibility that stomata adjust to maximise photosynthesis through a trade-off between leaf CO2 supply and NSLs, potentially involving source-sink interactions. However, the mechanisms regulating NSLs and sink strength, as well as their implications for stomatal control, remain uncertain. We used an analytically solvable model to explore optimal stomatal control under alternative hypotheses for source and sink regulation. We assumed that either leaf sugar concentration or leaf water potential regulates NSLs, and that either phloem turgor pressure or phloem sugar concentration regulates sink phloem unloading. All hypotheses lead to realistic stomatal responses to light, CO2 and air humidity, including conservative behaviour for the intercellular-to-atmospheric CO2 concentration ratio. Sugar- and water-regulated NSLs are distinguished by the presence/absence of a stomatal closure response to changing sink strength. Turgor- and sugar-regulated phloem unloading are distinguished by the presence/absence of stomatal closure under drought and avoidance/occurrence of negative phloem turgor. Results from girdling and drought experiments on Pinus sylvestris, Betula pendula, Populus tremula and Picea abies saplings are consistent with optimal stomatal control under sugar-regulated NSLs and turgor-regulated unloading. Our analytical results provide a simple representation of stomatal responses to above- and below-ground environmental factors and sink activity. Experimental evidence that nonstomatal limitations to photosynthesis (NSLs) correlate with leaf sugar and/or leaf water status suggests the possibility that stomata adjust to maximise photosynthesis through a trade-off between leaf CO2 supply and NSLs, potentially involving source-sink interactions. However, the mechanisms regulating NSLs and sink strength, as well as their implications for stomatal control, remain uncertain. We used an analytically solvable model to explore optimal stomatal control under alternative hypotheses for source and sink regulation. We assumed that either leaf sugar concentration or leaf water potential regulates NSLs, and that either phloem turgor pressure or phloem sugar concentration regulates sink phloem unloading. All hypotheses led to realistic stomatal responses to light, CO2 and air humidity, including conservative behaviour for the intercellular-to-atmospheric CO2 concentration ratio. Sugar-regulated and water-regulated NSLs are distinguished by the presence/absence of a stomatal closure response to changing sink strength. Turgor-regulated and sugar-regulated phloem unloading are distinguished by the presence/absence of stomatal closure under drought and avoidance/occurrence of negative phloem turgor. Results from girdling and drought experiments on Pinus sylvestris, Betula pendula, Populus tremula and Picea abies saplings are consistent with optimal stomatal control under sugar-regulated NSLs and turgor-regulated unloading. Our analytical results provide a simple representation of stomatal responses to above-ground and below-ground environmental factors and sink activity.

Published

2022

18. Significance of Sulphur nutrition against metal induced oxidative stress in plants

Author

Mohd Mazid, Khan Zeba H., Saima Quddusi, Taqi Ahmed Khan, and Firoz Mohammad

Subjects

Xylem transport, phloem transport, oxidative stress, translocation, antioxidant, chelation, Biochemistry, QD415-436

Abstract

Sulphur (S) is available to plants as sulphate (SO42-) in the soil to the roots and as gaseous SO2 in the atmosphere to the shoots. Of all the macronutrient, S is perhaps the nutrient which has attracted the most attention in soil science and plant nutrition due to its potential defensive characteristics to pests, good nutritive potentiality to crops and its relative immobility in the soil-plant system. This review highlights the mechanisms of uptake and translocation of S from soil and its transport in xylem and phloem tissues of plants. Moreover, it also throws new insights, have led us to revisit the hypothesis of S chelation in reference to oxidative stress induced by heavy metals sequestration.

Published

2011

19. Dynamics of Long-distance Signaling via Plant Vascular Tissues

Author

Michitaka eNotaguchi and Satoru eOkamoto

Subjects

Protein Transport, RNA Transport, Phloem transport, xylem transport, Long-distance signaling, Peptide transport, Plant culture, SB1-1110

Abstract

Plant vascular systems are constructed by specific cell wall modifications through which cells are highly specialized to make conduits for water and nutrients. Xylem vessels are formed by thickened cell walls that remain after programmed cell death, and serve as water conduits from the root to the shoot. In contrast, phloem tissues consist of a complex of living cells, including sieve tube elements and their neighboring companion cells, and translocate photosynthetic assimilates from mature leaves to developing young tissues. Intensive studies on the content of vascular flow fluids have unveiled that plant vascular tissues transport various types of gene product, and the transport of some provides the molecular basis for the long-distance communications. Analysis of xylem sap has demonstrated the presence of proteins in the xylem transpiration stream. Recent studies have revealed that CLE and CEP peptides secreted in the roots are transported to above ground via the xylem in response to plant-microbe interaction and soil nitrogen starvation, respectively. Their leucine-rich repeat transmembrane receptors localized in the shoot phloem are required for relaying the signal from the shoot to the root. These findings well fit to the current scenario of root-to-shoot-to-root feedback signaling, where peptide transport achieves the root-to-shoot signaling, the first half of the signaling process. Meanwhile, it is now well evidenced that proteins and a range of RNAs are transported via the phloem translocation system, and some of those can exert their physiological functions at their destinations, including roots. Thus, plant vascular systems may serve not only as conduits for the translocation of essential substances but also as long-distance communication pathways that allow plants to adapt to changes in internal and external environments at the whole plant level.

Published

2015

20. Pragmatic hydraulic theory predicts stomatal responses to climatic water deficits.

Author

Sperry, John S., Wang, Yujie, Wolfe, Brett T., Mackay, D. Scott, Anderegg, William R. L., McDowell, Nate G., and Pockman, William T.

Subjects

*ECOSYSTEM dynamics, *PRAGMATICS, *PLANT anatomy, *EFFECT of drought on plants, *CLIMATE change, *DROUGHT tolerance

Abstract

Ecosystem models have difficulty predicting plant drought responses, partially from uncertainty in the stomatal response to water deficits in soil and atmosphere. We evaluate a 'supply-demand' theory for water-limited stomatal behavior that avoids the typical scaffold of empirical response functions. The premise is that canopy water demand is regulated in proportion to threat to supply posed by xylem cavitation and soil drying., The theory was implemented in a trait-based soil-plant-atmosphere model. The model predicted canopy transpiration ( E), canopy diffusive conductance ( G), and canopy xylem pressure ( Pcanopy) from soil water potential ( Psoil) and vapor pressure deficit ( D)., Modeled responses to D and Psoil were consistent with empirical response functions, but controlling parameters were hydraulic traits rather than coefficients. Maximum hydraulic and diffusive conductances and vulnerability to loss in hydraulic conductance dictated stomatal sensitivity and hence the iso- to anisohydric spectrum of regulation. The model matched wide fluctuations in G and Pcanopy across nine data sets from seasonally dry tropical forest and piñon-juniper woodland with < 26% mean error., Promising initial performance suggests the theory could be useful in improving ecosystem models. Better understanding of the variation in hydraulic properties along the root-stem-leaf continuum will simplify parameterization. [ABSTRACT FROM AUTHOR]

Published

2016

21. ABA flow modelling in Ricinus communis exposed to salt stress and variable nutrition.

Author

Peuke, Andreas D.

Subjects

*RICINUS, *ABSCISIC acid, *PLANT metabolism, *GENE expression, *XYLEM

Abstract

In a series of experiments with Ricinus communis, abscisic acid (ABA) concentrations in tissues and transport saps, its de novo biosynthesis, long-distance transport, and metabolism (degradation) were affected by nutritional conditions, nitrogen (N) source, and nutrient limitation, or salt stress. In the present study these data were statistically reevaluated, and new correlations presented that underpin the importance of this universal phytohormone. The biggest differences in ABA concentration were observed in xylem sap. N source had the strongest effect; however, nutrient limitation (particularly phosphorus limitation) and salt also had significant effects. ABA was found in greater concentration in phloem sap compared with xylem sap; however, the effect of treatment on ABA concentration in phloem was lower. In the leaves, ABA concentration was most variable compared with the other tissues. This variation was only affected by the N source. In roots, ABA was significantly decreased by nutrient limitation. Of the compartments in which ABA was quantified, xylem sap ABA concentration was most significantly correlated with leaf stomatal conductance and leaf growth. Additionally, ABA concentration in xylem was significantly correlated to that in phloem, indicating a 6-fold concentration increase from xylem to phloem. The ABA flow model showed that biosynthesis of ABA in roots affected the xylem flow of ABA. Moreover, ABA concentration in xylem affected the degradation of the phytohormone in shoots and also its export from shoots via phloem. The role of phloem transport is discussed since it stimulates ABA metabolism in roots. [ABSTRACT FROM AUTHOR]

Published

2016

22. Vulnerability of Protoxylem and Metaxylem Vessels to Embolisms and Radial Refilling in a Vascular Bundle of Maize Leaves.

Author

Bae Geun Hwang, Jeongeun Ryu, and Sang Joon Lee

Subjects

EMBOLISMS, CORN

Abstract

Regulation of water flow in an interconnected xylem vessel network enables plants to survive despite challenging environment changes that can cause xylem embolism. In this study, vulnerability to embolisms of xylem vessels and their water-refilling patterns in vascular bundles of maize leaves were experimentally investigated by employing synchrotron X-ray micro-imaging technique. A vascular bundle in maize consisted of a protoxylem vessel with helical thickenings between two metaxylem vessels with single perforation plates and nonuniformly distributed pits. When embolism was artificially induced in excised maize leaves by exposing them to air, protoxylem vessels became less vulnerable to dehydration compared tometaxylemvessels. After supplying water into the embolized vascular bundles, when water-refilling process stopped at the perforation plates in metaxylem vessels, discontinuous radial water influx occurred surprisingly in the adjacent protoxylem vessels. Alternating water refilling pattern in protoxylem and metaxylem vessels exhibited probable correlation between the incidence location and time of water refilling and the structural properties of xylem vessels. These results imply that the maintenance of water transport and modulation of water refilling are affected by hydrodynamic roles of perforation plates and radial connectivity in a xylem vascular bundle network. [ABSTRACT FROM AUTHOR]

Published

2016

23. Limited vertical CO2 transport in stems of mature boreal Pinus sylvestris trees

Author

Tarvainen, Lasse, Wallin, Göran, Linder, Sune, Näsholm, Torgny, Oren, Ram, Löfvenius, Mikaell Ottosson, Räntfors, Mats, Tor-Ngern, Pantana, Marshall, John D., Tarvainen, Lasse, Wallin, Göran, Linder, Sune, Näsholm, Torgny, Oren, Ram, Löfvenius, Mikaell Ottosson, Räntfors, Mats, Tor-Ngern, Pantana, and Marshall, John D.

Abstract

Several studies have suggested that CO2 transport in the transpiration stream can considerably bias estimates of root and stem respiration in ring-porous and diffuse-porous tree species. Whether this also happens in species with tracheid xylem anatomy and lower sap flow rates, such as conifers, is currently unclear. We infused C-13-labelled solution into the xylem near the base of two 90-year-old Pinus sylvestris L. trees. A custom-built gas exchange system and an online isotopic analyser were used to sample the CO2 efflux and its isotopic composition continuously from four positions along the bole and one upper canopy shoot in each tree. Phloem and needle tissue C-13 enrichment was also evaluated at these positions. Most of the C-13 label was lost by diffusion within a few metres of the infusion point indicating rapid CO2 loss during vertical xylem transport. No C-13 enrichment was detected in the upper bole needle tissues. Furthermore, mass balance calculations showed that c. 97% of the locally respired CO2 diffused radially to the atmosphere. Our results support the notion that xylem CO2 transport is of limited magnitude in conifers. This implies that the concerns that stem transport of CO2 derived from root respiration biases chamber-based estimates of forest carbon cycling may be unwarranted for mature conifer stands.

Published

2021

24. Anatomical changes with needle length are correlated with leaf structural and physiological traits across five <scp> Pinus </scp> species

Author

Sari Palmroth, Ram Oren, Jean-Christophe Domec, Chris A. Maier, Na Wang, Northeast Forestry University, Nicholas School of the Environment, Duke University [Durham], Southern Research Station, United States Department of Agriculture Forest Services, Interactions Sol Plante Atmosphère (UMR ISPA), Institut National de la Recherche Agronomique (INRA)-Ecole Nationale Supérieure des Sciences Agronomiques de Bordeaux-Aquitaine (Bordeaux Sciences Agro), Department of Forest Sciences, and University of Alaska [Fairbanks] (UAF)

Subjects

leaf traits, 0106 biological sciences, 0301 basic medicine, Stomatal conductance, Physiology, Range (biology), [SDV]Life Sciences [q-bio], stomata, Plant Science, Biology, 01 natural sciences, nitrogen, 03 medical and health sciences, Xylem, Leaf size, Pinus echinata, xylem transport, photosynthesis, fungi, Water, Biological Transport, Plant Transpiration, plant hydraulics, 15. Life on land, Pinus, biology.organism_classification, Photosynthetic capacity, film.actor, Plant Leaves, Horticulture, 030104 developmental biology, leaf structure, Pinus virginiana, film, Plant morphology, Plant Stomata, [SDE]Environmental Sciences, water relations, conductance, pine, 010606 plant biology & botany

Abstract

International audience; The genus Pinus has wide geographical range and includes species that are the most economically valued among forest trees worldwide. Pine needle length varies greatly among species, but the effects of needle length on anatomy, function, and coordination and trade-offs among traits are poorly understood. We examined variation in leaf morphological, anatomical, mechanical, chemical, and physiological characteristics among five southern pine species: Pinus echinata, Pinus elliottii, Pinus palustris, Pinus taeda, and Pinus virginiana. We found that increasing needle length contributed to a trade-off between the relative fractions of support versus photosynthetic tissue (mesophyll) across species. From the shortest (7 cm) to the longest (36 cm) needles, mechanical tissue fraction increased by 50%, whereas needle dry density decreased by 21%, revealing multiple adjustments to a greater need for mechanical support in longer needles. We also found a fourfold increase in leaf hydraulic conductance over the range of needle length across species, associated with weaker upward trends in stomatal conductance and photosynthetic capacity. Our results suggest that the leaf size strongly influences their anatomical traits, which, in turn, are reflected in leaf mechanical support and physiological capacity.

Published

2019

25. Effects of prolonged drought on the anatomy of sun and shade needles in young Norway spruce trees.

Author

Gebauer, Roman, Volařík, Daniel, Urban, Josef, Børja, Isabella, Nagy, Nina Elisabeth, Eldhuset, Toril Drabløs, and Krokene, Paal

Subjects

*SPRUCE, *DROUGHTS, *XYLEM, *PHLOEM, *CLIMATE change, *PHOTOSYNTHETICALLY active radiation (PAR)

Abstract

Predicted increases in the frequency and duration of drought are expected to negatively affect tree vitality, but we know little about how water shortage will influence needle anatomy and thereby the trees' photosynthetic and hydraulic capacity. In this study, we evaluated anatomical changes in sun and shade needles of 20-year-old Norway spruce trees exposed to artificial drought stress. Canopy position was found to be important for needle structure, as sun needles had significantly higher values than shade needles for all anatomical traits (i.e., cross-sectional needle area, number of tracheids in needle, needle hydraulic conductivity, and tracheid lumen area), except proportion of xylem area per cross-sectional needle area. In sun needles, drought reduced all trait values by 10-40%, whereas in shade needles, only tracheid maximum diameter was reduced by drought. Due to the relatively weaker response of shade needles than sun needles in drought-stressed trees, the difference between the two needle types was reduced by 25% in the drought-stressed trees compared to the control trees. The observed changes in needle anatomy provide new understanding of how Norway spruce adapts to drought stress and may improve predictions of how forests will respond to global climate change. [ABSTRACT FROM AUTHOR]

Published

2015

26. What plant hydraulics can tell us about responses to climate-change droughts.

Author

Sperry, John S. and Love, David M.

Subjects

*CLIMATOLOGY, *DROUGHTS, *RAINFALL, *METEOROLOGICAL precipitation, *HYDRAULIC accumulators

Abstract

Climate change exposes vegetation to unusual drought, causing declines in productivity and increased mortality. Drought responses are hard to anticipate because canopy transpiration and diffusive conductance (G) respond to drying soil and vapor pressure deficit (D) in complex ways. A growing database of hydraulic traits, combined with a parsimonious theory of tree water transport and its regulation, may improve predictions of at-risk vegetation. The theory uses the physics of flow through soil and xylem to quantify how canopy water supply declines with drought and ceases by hydraulic failure. This transpiration 'supply function' is used to predict a water 'loss function' by assuming that stomatal regulation exploits transport capacity while avoiding failure. Supply-loss theory incorporates root distribution, hydraulic redistribution, cavitation vulnerability, and cavitation reversal. The theory efficiently defines stomatal responses to D, drying soil, and hydraulic vulnerability. Driving the theory with climate predicts droughtinduced loss of plant hydraulic conductance (k), canopyG, carbon assimilation, and productivity. Data lead to the 'chronic stress hypothesis' wherein > 60% loss of k increases mortality by multiple mechanisms. Supply-loss theory predicts the climatic conditions that push vegetation over this risk threshold. The theory's simplicity and predictive power encourage testing and application in large-scale modeling. [ABSTRACT FROM AUTHOR]

Published

2015

27. Contrasting effects of nicotianamine synthase knockdown on zinc and nickel tolerance and accumulation in the zinc/cadmium hyperaccumulator Arabidopsis halleri.

Author

Cornu, Jean‐Yves, Deinlein, Ulrich, Höreth, Stephan, Braun, Manuel, Schmidt, Holger, Weber, Michael, Persson, Daniel P., Husted, Søren, Schjoerring, Jan K., and Clemens, Stephan

Subjects

*NICOTIANAMINE, *HYPERACCUMULATOR plants, *ARABIDOPSIS halleri, *BIOACCUMULATION in plants, *ZINC, *NICKEL, *CADMIUM, *PLANT roots

Abstract

Elevated nicotianamine synthesis in roots of Arabidopsis halleri has been established as a zinc (Zn) hyperaccumulation factor. The main objective of this study was to elucidate the mechanism of nicotianamine-dependent root-to-shoot translocation of metals., Metal tolerance and accumulation in wild-type ( WT) and Ah NAS2- RNA interference ( RNAi) plants were analysed. Xylem exudates were subjected to speciation analysis and metabolite profiling., Suppression of root nicotianamine synthesis had no effect on Zn and cadmium (Cd) tolerance but rendered plants nickel (Ni)-hypersensitive. It also led to a reduction of Zn root-to-shoot translocation, yet had the opposite effect on Ni mobility, even though both metals form coordination complexes of similar stability with nicotianamine. Xylem Zn concentrations were positively, yet nonstoichiometrically, correlated with nicotianamine concentrations. Two fractions containing Zn coordination complexes were detected in WT xylem. One of them was strongly reduced in Ah NAS2-suppressed plants and coeluted with 67Zn-labelled organic acid complexes. Organic acid concentrations were not responsive to nicotianamine concentrations and sufficiently high to account for complexing the coordinated Zn., We propose a key role for nicotianamine in controlling the efficiency of Zn xylem loading and thereby the formation of Zn coordination complexes with organic acids, which are the main Zn ligands in the xylem but are not rate-limiting for Zn translocation. [ABSTRACT FROM AUTHOR]

Published

2015

28. Is decreased xylem sap surface tension associated with embolism and loss of xylem hydraulic conductivity in pathogen-infected Norway spruce saplings?

Author

Paljakka, T. (Teemu), Rissanen, K. (Kaisa), Vanhatalo, A. (Anni), Salmon, Y. (Yann), Jyske, T. (Tuula), Prisle, N. L. (Nønne L.), Linnakoski, R. (Riikka), Lin, J. J. (Jack J.), Laakso, T. (Tapio), Kasanen, R. (Risto), Bäck, J. (Jaana), Hölttä, T. (Teemu), Paljakka, T. (Teemu), Rissanen, K. (Kaisa), Vanhatalo, A. (Anni), Salmon, Y. (Yann), Jyske, T. (Tuula), Prisle, N. L. (Nønne L.), Linnakoski, R. (Riikka), Lin, J. J. (Jack J.), Laakso, T. (Tapio), Kasanen, R. (Risto), Bäck, J. (Jaana), and Hölttä, T. (Teemu)

Abstract

Increased abiotic stress along with increasing temperatures, dry periods and forest disturbances may favor biotic stressors such as simultaneous invasion of bark beetle and ophiostomatoid fungi. It is not fully understood how tree desiccation is associated with colonization of sapwood by fungi. A decrease in xylem sap surface tension (σxylem) as a result of infection has been hypothesized to cause xylem embolism by lowering the threshold for air-seeding at the pits between conduits and disruptions in tree water transport. However, this hypothesis has not yet been tested. We investigated tree water relations by measuring the stem xylem hydraulic conductivity (Kstem), σxylem, stem relative water content (RWCstem), and water potential (Ψstem), and canopy conductance (gcanopy), as well as the compound composition in xylem sap in Norway spruce (Picea abies) saplings. We conducted our measurements at the later stage of Endoconidiophora polonica infection when visible symptoms had occurred in xylem. Saplings of two clones (44 trees altogether) were allocated to treatments of inoculated, wounded control and intact control trees in a greenhouse. The saplings were destructively sampled every second week during summer 2016. σxylem, Kstem and RWCstem decreased following the inoculation, which may indicate that decreased σxylem resulted in increased embolism. gcanopy did not differ between treatments indicating that stomata responded to Ψstem rather than to embolism formation. Concentrations of quinic acid, myo-inositol, sucrose and alkylphenol increased in the xylem sap of inoculated trees. Myo-inositol concentrations also correlated negatively with σxylem and Kstem. Our study is a preliminary investigation of the role of σxylem in E. polonica infected trees based on previous hypotheses. The results suggest that E. polonica infection can lead to a simultaneous decrease in xylem sap surface tension and a decline in tree hydraulic conductivity, thus hampering tree water

Published

2020

29. Drought-Induced Root Pressure in Sorghum bicolor

Author

Jorge Ibarra Caballero, Sean M. Gleason, Courtney E. Jahn, Joshua Wenz, Ryan W. Barton, Nora Flynn, Sarah Tepler Drobnitch, Julie Bushey, Taylor Person, and Louise H. Comas

Subjects

fungi, Greenhouse, Sorghum bicolor, Xylem, Aquaporin, food and beverages, Plant Science, Biology, lcsh:Plant culture, Adaptive functioning, Shoot biomass, aquaporin, root pressure, Horticulture, Root length, Root pressure, transporter, lcsh:SB1-1110, RNA-Seq, water relations, Original Research, xylem transport, agriculture

Abstract

Root pressure, also manifested as profusive sap flowing from cut stems, is a phenomenon in some species that has perplexed biologists for much of the last century. It is associated with increased crop production under drought, but its function and regulation remain largely unknown. In this study, we investigated the initiation, mechanisms, and possible adaptive function of root pressure in six genotypes of Sorghum bicolor during a drought experiment in the greenhouse. We observed that root pressure was induced in plants exposed to drought followed by re-watering but possibly inhibited by 100% re-watering in some genotypes. We found that root pressure in drought stressed and re-watered plants was associated with greater ratio of fine: coarse root length and shoot biomass production, indicating a possible role of root allocation in creating root pressure and adaptive benefit of root pressure for shoot biomass production. Using RNA-Seq, we identified gene transcripts that were up- and down-regulated in plants with root pressure expression, focusing on genes for aquaporins, membrane transporters, and ATPases that could regulate inter- and intra-cellular transport of water and ions to generate positive xylem pressure in root tissue.

Published

2021

30. Scaling of xylem and phloem transport capacity and resource usage with tree size

Author

Teemu eHölttä, Miika eKurppa, and Eero eNikinmaa

Subjects

Phloem transport, xylem transport, carbon allocation, nitrogen allocation, pipe model, Metabolic scaling, Plant culture, SB1-1110

Abstract

Xylem and phloem need to maintain steady transport rates of water and carbohydrates to match the exchange rates of these compounds at the leaves. A major proportion of the carbon and nitrogen assimilated by a tree is allocated to the construction and maintenance of the xylem and phloem long distance transport tissues. This proportion can be expected to increase with increasing tree size due to the growing transport distances between the assimilating tissues, i.e. leaves and fine roots, at the expense of their growth. We formulated whole tree level scaling relations to estimate how xylem and phloem volume, nitrogen content and hydraulic conductance scale with tree size, and how these properties are distributed along a tree height. Xylem and phloem thicknesses and nitrogen contents were measured within varying positions in four tree species from Southern Finland. Phloem volume, nitrogen amount and hydraulic conductance were found to be concentrated towards the branch and stem apices, in contrast to the xylem where these properties were more concentrated towards the tree base. All of the species under study demonstrated very similar trends. Total nitrogen amount allocated to xylem and phloem was predicted to be comparable to the nitrogen amount allocated to the leaves in small and medium size trees, and to increase significantly above the nitrogen content of the leaves in larger trees. Total volume, hydraulic conductance and nitrogen content of the xylem were predicted to increase faster than that of the phloem with increasing tree height in small trees (

Published

2013

31. The physiological resilience of fern sporophytes and gametophytes: advances in water relations offer new insights into an old lineage

Author

Jarmila ePittermann, Craig eBrodersen, and James eWatkins

Subjects

Ferns, cavitation, desiccation tolerance, xylem transport, gametophytes, Plant culture, SB1-1110

Abstract

Ferns are some of the oldest vascular plants in existence and they are the second most diverse lineage of tracheophytes next to angiosperms. Recent efforts to understand fern success have fo-cused on the physiological capacity and stress tolerance of both the sporophyte and the gameto-phyte generations. In this review, we examine these insights through the lens of plant water rela-tions, focusing primarily on the form and function of xylem tissue in the sporophyte, as well as the tolerance to and recovery from drought and desiccation stress in both stages of the fern life cycle. The absence of secondary xylem in ferns is compensated by selection for efficient primary xylem composed of large, closely arranged tracheids with permeable pit membranes. Protection from drought-induced hydraulic failure appears to arise from a combination of pit membrane traits and the arrangement of vascular bundles. Features such as tracheid-based xylem and vari-ously sized megaphylls are shared between ferns and more derived lineages, and offer an oppor-tunity to compare convergent and divergent hydraulic strategies critical to the success of xylem-bearing plants. Fern gametophytes show a high degree of desiccation tolerance but new evidence shows that morphological attributes in the gametophytes may facilitate water retention, though little work has addressed the ecological significance of this variation. We conclude with an emergent hypothesis that selection acted on the physiology of both the sporophyte and gameto-phyte generations in a synchronous manner that is consistent with selection for drought tolerance in the epiphytic niche, and the increasingly diverse habitats of the mid to late Cenozoic.

Published

2013

32. Maintenance of xylem network transport capacity: a review of embolism repair in vascular plants

Author

Craig eBrodersen and Andrew eMcElrone

Subjects

Biophysics, Embolism, Ecophysiology of plants, drought tolerance, xylem transport, Plant culture, SB1-1110

Abstract

Maintenance of long distance water transport in xylem is essential to plant health and productivity. Both biotic and abiotic environmental conditions lead to embolism formation within the xylem resulting in lost transport capacity and ultimately death. Plants exhibit a variety of strategies to either prevent or restore hydraulic capacity through cavitation resistance with specialized anatomy, replacement of compromised conduits with new growth, and a metabolically active embolism repair mechanism. In recent years, mounting evidence suggests that metabolically active cells surrounding the xylem conduits in some, but not all, species are capable of restoring hydraulic conductivity. This review summarizes our current understanding of the osmotically driven embolism repair mechanism, the known genetic and anatomical components related to embolism repair, rehydration pathways through the xylem, and the role of capacitance. Anatomical differences between functional plant groups may be one of the limiting factors that allow some plants to refill while others do not, but further investigations are necessary to fully understand this dynamic process. Finally, xylem networks should no longer be considered an assemblage of dead, empty conduits, but instead a metabolically active tissue finely tuned to respond to ever changing environmental cues.

Published

2013

33. Accumulation of cytokinins in roots and their export to the shoots of durum wheat plants treated with the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP).

Author

Kudoyarova, Guzel R., Korobova, Alla V., Akhiyarova, Guzel R., Arkhipova, Tatiana N., Zaytsev, Denis Yu., Prinsen, Els, Egutkin, Naum L., Medvedev, Sergey S., and Veselov, Stanislav Yu.

Subjects

*CYTOKININS, *GENE expression in plants, *PLANT roots, *PLANT cell culture, *PLANT shoots, *PLANT development, *ZEATIN, WHEAT genetics

Abstract

Cytokinin low from roots to shoots can serve as a long-distance signal important for root-to-shoot communication. In the past, changes in cytokinin low from roots to shoots have been mainly attributed to changes in the rate of synthesis or breakdown in the roots. The present research tested the possibility that active uptake of cytokinin by root cells may also influence its export to shoots. To this end, we collapsed the proton gradient across root membranes using the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) to inhibit secondary active uptake of exogenous and endogenous cytokinins. We report the impact of CCCP on cytokinin concentrations and delivery in xylem sap and on accumulation in shoots of 7-day-old wheat plants in the presence and absence of exogenous cytokinin applied as zeatin. Zeatin treatment increased the total accumulation of cytokinin in roots and shoots but the effect was smaller for the shoots. Immunohistochemical localization of cytokinins using zeatin-specific antibodies showed an increase in immunostaining of the cells adjacent to xylem in the roots of zeatin-treated plants. Inhibition of secondary active cytokinin uptake by CCCP application decreased cytokinin accumulation in root cells but increased both low from the roots and accumulation in the shoots. The possible importance of secondary active uptake of cytokinins by root cells for the control of their export to the shoot is discussed.. [ABSTRACT FROM AUTHOR]

Published

2014

34. Seasonal coordination of leaf hydraulics and gas exchange in a wintergreen fern

Author

Kyra A Prats and Craig R. Brodersen

Subjects

Canopy, Polystichum acrostichoides, Frond, photosynthesis, high light, biology, AcademicSubjects/SCI01210, wintergreen, Plant Science, Photosynthesis, biology.organism_classification, Aobpla/1028, Aobpla/1048, Deciduous, Agronomy, Studies, Fern, freeze–thaw, Aobpla/1030, water relations, Water content, Chlorophyll fluorescence, xylem transport

Abstract

Wintergreen fern Polystichum acrostichoides has fronds that are photosynthetically active year-round, despite diurnal and seasonal changes in soil moisture, air temperature and light availability. This species can fix much of its annual carbon during periods when the deciduous canopy is open. Yet, remaining photosynthetically active year-round requires the maintenance of photosynthetic and hydraulic systems that are vulnerable to freeze–thaw cycles. We aimed to determine the anatomical and physiological strategies P. acrostichoides uses to maintain positive carbon gain, and the coordination between the hydraulic and photosynthetic systems. We found that the first night below 0 °C led to 25 % loss of conductivity (PLC) in stipes, suggesting that winter-induced embolism occurred. Maximum photosynthetic rate and chlorophyll fluorescence declined during winter but recovered by spring, despite PLC remaining high; the remaining hydraulic capacity was sufficient to supply the leaves with water. The onset of colder temperatures coincided with the development of a necrotic hinge zone at the stipe base, allowing fronds to overwinter lying prostrate and maintain a favourable leaf temperature. Our conductivity data show that the hinge zone did not affect leaf hydraulics because of the flexibility of the vasculature. Collectively, these strategies help P. acrostichoides to survive in northeastern forests., Wintergreen ferns, such as Polystichum acrostichoides, retain their fronds throughout the year despite freezing temperatures and drastic seasonal changes in soil moisture and light intensity. We monitored photosynthetic capacity and the functional status of the vascular system for over a year and found that despite losing over 60 % of their water transport capacity from freeze–thaw induced cavitation, photosynthesis recovered in the spring. We found that localized, frost-triggered frond flexibility allows this species to lay flat on the ground and maintain warmer leaf temperatures, a process facilitated by highly flexible vascular bundles that bend without disrupting the water conducting pathway.

Published

2020

35. Systemic Long-Distance Signaling and Communication Between Rootstock and Scion in Grafted Vegetables

Author

Xiaohong Lu, Xiaojun Li, Wenna Zhang, Tao Wang, Wenqian Liu, and Jiali Zhang

Subjects

vegetable grafting, long-distance signaling, Plant Science, Review, Biology, lcsh:Plant culture, Phloem transport, Arabidopsis thaliana, lcsh:SB1-1110, Hormone transport, xylem transport, hormone transport, Molecular signaling, Abiotic stress, business.industry, phloem transport, food and beverages, biology.organism_classification, Grafting, systemic signaling, Biotechnology, Related research, protein transport, Rootstock, business, RNA transport

Abstract

Grafting is widely used in fruit, vegetable, and flower propagation to improve biotic and abiotic stress resistance, yield, and quality. At present, the systemic changes caused by grafting, as well as the mechanisms and effects of long-distance signal transport between rootstock and scion have mainly been investigated in model plants (Arabidopsis thaliana and Nicotiana benthamiana). However, these aspects of grafting vary when different plant materials are grafted, so the study of model plants provides only a theoretical basis and reference for the related research of grafted vegetables. The dearth of knowledge about the transport of signaling molecules in grafted vegetables is inconsistent with the rapid development of large-scale vegetable production, highlighting the need to study the mechanisms regulating the rootstock-scion interaction and long-distance transport. The rapid development of molecular biotechnology and "omics" approaches will allow researchers to unravel the physiological and molecular mechanisms involved in the rootstock-scion interaction in vegetables. We summarize recent progress in the study of the physiological aspects (e.g., hormones and nutrients) of the response in grafted vegetables and focus in particular on long-distance molecular signaling (e.g., RNA and proteins). This review provides a theoretical basis for studies of the rootstock-scion interaction in grafted vegetables, as well as provide guidance for rootstock breeding and selection to meet specific demands for efficient vegetable production.

Published

2020

36. Limited vertical CO2 transport in stems of mature boreal Pinus sylvestris trees

Author

Lasse Tarvainen, Pantana Tor-ngern, Sune Linder, Göran Wallin, Mats Räntfors, John D. Marshall, Mikaell Ottosson Löfvenius, Torgny Näsholm, Ram Oren, and Department of Forest Sciences

Subjects

0106 biological sciences, Canopy, EFFLUX, C-13, Physiology, STOMATAL CONDUCTANCE, Plant Science, Phloem, 01 natural sciences, Trees, CARBON-DIOXIDE, 03 medical and health sciences, Xylem, RESPIRED CO2, Respiration, Botany, stable isotope, stem CO2 efflux, DAYTIME DEPRESSION, xylem transport, 030304 developmental biology, 4112 Forestry, 0303 health sciences, biology, Plant Stems, pH, fungi, Scots pine, food and beverages, NORWAY SPRUCE, FLUX COMPONENTS, Pinus sylvestris, XYLEM SAP, 15. Life on land, Carbon Dioxide, SEASONAL-VARIATIONS, biology.organism_classification, Pinus, carbon allocation, Shoot, Tracheid, Transpiration stream, Environmental science, respiration, EXTERNAL FLUXES, 010606 plant biology & botany

Abstract

Several studies have suggested that CO2 transport in the transpiration stream can considerably bias estimates of root and stem respiration in ring-porous and diffuse-porous tree species. Whether this also happens in species with tracheid xylem anatomy and lower sap flow rates, such as conifers, is currently unclear. We infused 13C-labelled solution into the xylem near the base of two 90-year-old Pinus sylvestris L. trees. A custom-built gas exchange system and an online isotopic analyser were used to sample the CO2 efflux and its isotopic composition continuously from four positions along the bole and one upper canopy shoot in each tree. Phloem and needle tissue 13C enrichment was also evaluated at these positions. Most of the 13C label was lost by diffusion within a few metres of the infusion point indicating rapid CO2 loss during vertical xylem transport. No 13C enrichment was detected in the upper bole needle tissues. Furthermore, mass balance calculations showed that c. 97% of the locally respired CO2 diffused radially to the atmosphere. Our results support the notion that xylem CO2 transport is of limited magnitude in conifers. This implies that the concerns that stem transport of CO2 derived from root respiration biases chamber-based estimates of forest carbon cycling may be unwarranted for mature conifer stands.

Published

2020

37. Scaling of xylem and phloem transport capacity and resource usage with tree size.

Author

Hölttä, Teemu, Kurppa, Miika, and Nikinmaa, Eero

Subjects

PHYSIOLOGICAL control systems, GENETIC research, PLANT genetics, PLANT nutrition & genetics, PHLOEM, VASCULAR system of plants, XYLEM

Abstract

Xylem and phloem need to maintain steady transport rates of water and carbohydrates to match the exchange rates of these compounds at the leaves. A major proportion of the carbon and nitrogen assimilated by a tree is allocated to the construction and maintenance of the xylem and phloem long distance transport tissues. This proportion can be expected to increase with increasing tree size due to the growing transport distances between the assimilating tissues, i.e., leaves and fine roots, at the expense of their growth. We formulated whole tree level scaling relations to estimate how xylem and phloem volume, nitrogen content and hydraulic conductance scale with tree size, and how these properties are distributed along a tree height. Xylem and phloem thicknesses and nitrogen contents were measured within varying positions in four tree species from Southern Finland. Phloem volume, nitrogen amount and hydraulic conductance were found to be concentrated toward the branch and stem apices, in contrast to the xylem where these properties were more concentrated toward the tree base. All of the species under study demonstrated very similar trends. Total nitrogen amount allocated to xylem and phloem was predicted to be comparable to the nitrogen amount allocated to the leaves in small and medium size trees, and to increase significantly above the nitrogen content of the leaves in larger trees. Total volume, hydraulic conductance and nitrogen content of the xylem were predicted to increase faster than that of the phloem with increasing tree height in small trees (<∼10 m in height). In larger trees, xylem sapwood turnover to heartwood, if present, would maintain phloem conductance at the same level with xylem conductance with further increases in tree height. Further simulations with a previously published xylem-phloem transport model demonstrated that the Münch pressure flow hypothesis could explain phloem transport with increasing tree height even for the tallest trees. [ABSTRACT FROM AUTHOR]

Published

2013

38. The physiological resilience of fern sporophytes and gametophytes: advances in water relations offer new insights into an old lineage.

Author

Pittermann, Jarmila, Brodersen, Craig, and Watkins Jr, James E.

Subjects

FERN gametophytes, ANGIOSPERMS, XYLEM, TRACHEARY cells, PLANT water requirements, CENOZOIC Era, PHYSIOLOGY

Abstract

Ferns are some of the oldest vascular plants in existence and they are the second most diverse lineage of tracheophytes next to angiosperms. Recent efforts to understand fern success have focused on the physiological capacity and stress tolerance of both the sporophyte and the gametophyte generations. In this review, we examine these insights through the lens of plant water relations, focusing primarily on the form and function of xylem tissue in the sporophyte, as well as the tolerance to and recovery from drought and desiccation stress in both stages of the fern life cycle. The absence of secondary xylem in ferns is compensated by selection for efficient primary xylem composed of large, closely arranged tracheids with permeable pit membranes. Protection from drought-induced hydraulic failure appears to arise from a combination of pit membrane traits and the arrangement of vascular bundles. Features such as tracheid-based xylem and variously sized megaphylls are shared between ferns and more derived lineages, and offer an opportunity to compare convergent and divergent hydraulic strategies critical to the success of xylem-bearing plants. Fern gametophytes show a high degree of desiccation tolerance but new evidence shows that morphological attributes in the gametophytes may facilitate water retention, though little work has addressed the ecological significance of this variation. We conclude with an emergent hypothesis that selection acted on the physiology of both the sporophyte and gametophyte generations in a synchronous manner that is consistent with selection for drought tolerance in the epiphytic niche, and the increasingly diverse habitats of the mid to late Cenozoic. [ABSTRACT FROM AUTHOR]

Published

2013

39. Maintenance of xylem network transport capacity: a review of embolism repair in vascular plants.

Author

Brodersen, Craig R. and McElrone, Andrew J.

Subjects

VASCULAR plants, PLANT health, EMBOLISM (Botany), PLANT ecology, XYLEM, HYDRAULIC conductivity

Abstract

Maintenance of long distance water transport in xylem is essential to plant health and productivity. Both biotic and abiotic environmental conditions lead to embolism formation within the xylem resulting in lost transport capacity and ultimately death. Plants exhibit a variety of strategies to either prevent or restore hydraulic capacity through cavitation resistance with specialized anatomy, replacement of compromised conduits with new growth, and a metabolically active embolism repair mechanism. In recent years, mounting evidence suggests that metabolically active cells surrounding the xylem conduits in some, but not all, species are capable of restoring hydraulic conductivity. This review summarizes our current understanding of the osmotically driven embolism repair mechanism, the known genetic and anatomical components related to embolism repair, rehydration pathways through the xylem, and the role of capacitance. Anatomical differences between functional plant groups may be one of the limiting factors that allow some plants to refill while others do not, but further investigations are necessary to fully understand this dynamic process. Finally, xylem networks should no longer be considered an assemblage of dead, empty conduits, but instead a metabolically active tissue finely tuned to respond to ever changing environmental cues. [ABSTRACT FROM AUTHOR]

Published

2013

40. Transport of root-respired CO2 via the transpiration stream affects aboveground carbon assimilation and CO2 efflux in trees.

Author

Bloemen, Jasper, McGuire, Mary Anne, Aubrey, Doug P., Teskey, Robert O., and Steppe, Kathy

Subjects

*TREES, *CARBON dioxide, *PLANT transpiration, *PLANT stems, *COTTONWOOD

Abstract

Upward transport of CO2 via the transpiration stream from belowground to aboveground tissues occurs in tree stems. Despite potentially important implications for our understanding of plant physiology, the fate of internally transported CO2 derived from autotrophic respiratory processes remains unclear., We infused a 13 CO2-labeled aqueous solution into the base of 7-yr-old field-grown eastern cottonwood ( Populus deltoides) trees to investigate the effect of xylem-transported CO2 derived from the root system on aboveground carbon assimilation and CO2 efflux., The 13C label was transported internally and detected throughout the tree. Up to 17% of the infused label was assimilated, while the remainder diffused to the atmosphere via stem and branch efflux. The largest amount of assimilated 13C was found in branch woody tissues, while only a small quantity was assimilated in the foliage. Petioles were more highly enriched in 13C than other leaf tissues., Our results confirm a recycling pathway for respired CO2 and indicate that internal transport of CO2 from the root system may confound the interpretation of efflux-based estimates of woody tissue respiration and patterns of carbohydrate allocation. [ABSTRACT FROM AUTHOR]

Published

2013

41. The tomato CAROTENOID CLEAVAGE DIOXYGENASE8 ( Sl CCD8) regulates rhizosphere signaling, plant architecture and affects reproductive development through strigolactone biosynthesis.

Author

Kohlen, Wouter, Charnikhova, Tatsiana, Lammers, Michiel, Pollina, Tobia, Tóth, Peter, Haider, Imran, Pozo, María J., Maagd, Ruud A., Ruyter-Spira, Carolien, Bouwmeester, Harro J., and López-Ráez, Juan A.

Subjects

*CAROTENOIDS, *DIOXYGENASES, *RHIZOSPHERE, *BIOSYNTHESIS, *PLANT physiology, *RNA, *PLANT morphology

Abstract

Strigolactones are plant hormones that regulate both above- and belowground plant architecture. Strigolactones were initially identified as rhizosphere signaling molecules. In the present work, the tomato ( Solanum lycopersicum) CAROTENOID CLEAVAGE DIOXYGENASE 8 ( Sl CCD8) was cloned and its role in rhizosphere signaling and plant physiology assessed by generating knock-down lines., Transgenic Sl CCD8 plants were generated by RNAi-mediated silencing. Lines with different levels of strigolactone reduction - confirmed by UPLC- MS/ MS - were selected and their phenotypes investigated., Lines exhibiting reduced Sl CCD8 levels displayed increased shoot branching, reduced plant height, increased number of nodes and excessive adventitious root development. In addition, these lines exhibited reproductive phenotypes such as smaller flowers, fruits, as well as fewer and smaller seeds per fruit. Furthermore, we show that strigolactone loading to the xylem sap is possibly restricted to orobanchol., Infestation by Phelipanche ramosa was reduced by 90% in lines with a relatively mild reduction in strigolactone biosynthesis and secretion while arbuscular mycorrhizal symbiosis, apical dominance and fruit yield were only mildly affected. This demonstrates that reduction of strigolactone biosynthesis could be a suitable tool in parasitic weed management. Furthermore, our results suggest that strigolactones are involved in even more physiological processes than so far assumed. [ABSTRACT FROM AUTHOR]

Published

2012

42. Transpiration alters the contribution of autotrophic and heterotrophic components of soil CO2 efflux.

Author

Grossiord, Charlotte, Mareschal, Louis, and Epron, Daniel

Subjects

*PLANT transpiration, *HETEROTROPHIC bacteria, *AUTOTROPHIC bacteria, *EFFECT of carbon dioxide on plants, *CARBON in soils, *EUCALYPTUS, *SOIL respiration, *CARBON isotopes

Abstract

An unbiased partitioning of autotrophic and heterotrophic components of soil CO2 efflux is important to estimate forest carbon budgets and soil carbon sequestration. The contribution of autotrophic sources to soil CO2 efflux ( FA) may be underestimated during the daytime as a result of internal transport of CO2 produced by root respiration through the transpiration stream. [ABSTRACT FROM AUTHOR]

Published

2012

43. Cavitation induced by a surfactant leads to a transient release of water stress and subsequent ‘run away’ embolism in Scots pine (Pinus sylvestris) seedlings.

Author

Hölttä, Teemu, Juurola, Eija, Lindfors, Lauri, and Porcar-Castell, Albert

Subjects

*PHYSIOLOGICAL stress, *EMBOLISMS, *SCOTS pine, *SEEDLINGS, *XYLEM

Abstract

Cavitation decreases the hydraulic conductance of the xylem and has, therefore, detrimental effects on plant water balance. However, cavitation is also hypothesized to relieve water stress temporarily by releasing water from embolizing conduits to the transpiration stream. Stomatal closure in response to decreasing water potentials in order to avoid excessive cavitation has been well documented in numerous previous studies. However, it has remained unclear whether the stomata sense cavitation events themselves or whether they act in response to a decrease in leaf water potential to a level at which cavitation is initiated. The effects of massive cavitation on leaf water potential, transpiration, and stomatal behaviour were studied by feeding a surfactant into the transpiration stream of Scots pine (Pinus sylvestris) seedlings. The stomatal response to cavitation in connection with the capacitive effect was also studied. A major transient increase in leaf water potential was found due to cavitation in the seedlings. As cavitation was induced by lowering the surface tension, the two mechanisms could be uncoupled, as the usual relation between xylem water potential and the onset of cavitation did not hold. Our results indicate that the seedlings responded more to leaf water potential and less to cavitation itself, as stomatal closure was insufficient to prevent the seedlings from being driven to ‘run-away’ cavitation in a manner of hours. [ABSTRACT FROM PUBLISHER]

Published

2012

44. A physiological model of softwood cambial growth.

Author

HÖLTTÄ, TEEMU, MÄKINEN, HARRI, NÖJD, PEKKA, MÄKELÄ, ANNIKKI, and NIKINMAA, EERO

Subjects

*SOFTWOOD, *PHLOEM, *XYLEM, *BIOLOGICAL transport, *TREE physiology

Abstract

Cambial growth was modelled as a function of detailed levelled physiological processes for cell enlargement and water and sugar transport to the cambium. Cambial growth was described at the cell level where local sugar concentration and turgor pressure induce irreversible cell expansion and cell wall synthesis. It was demonstrated how transpiration and photosynthesis rates, metabolic and physiological processes and structural features of a tree mediate their effects directly on the local water and sugar status and influence cambial growth. Large trees were predicted to be less sensitive to changes in the transient water and sugar status, compared with smaller ones, as they have more water and sugar storage and were, therefore, less coupled to short-term changes in the environment. Modelling the cambial dynamics at the individual cell level turned out to be a complex task as the radial short-distance transport of water and sugars and control signals determining cell division and cessation of cell enlargement and cell wall synthesis had to be described simultaneously. [ABSTRACT FROM PUBLISHER]

Published

2010

45. Correlations in concentrations, xylem and phloem flows, and partitioning of elements and ions in intact plants. A summary and statistical re-evaluation of modelling experiments in Ricinus communis.

Author

Peuke, Andreas D.

Subjects

*XYLEM, *PHLOEM, *PLANT nutrients, *IONS, *CASTOR oil plant

Abstract

Within the last two decades, a series of papers have dealt with the effects of nutrition and nutrient deficiency, as well as salt stress, on the long-distance transport and partitioning of nutrients in castor bean. Flows in xylem and phloem were modelled according to an empirically-based modelling technique that permits additional quantification of the uptake and incorporation into plant organs. In the present paper these data were statistically re-evaluated, and new correlations are presented. Numerous relationships between different compartments and transport processes for single elements, but also between elements, were detected. These correlations revealed different selectivities for ions in bulk net transport. Generally, increasing chemical concentration gradients for mineral nutrients from the rhizosphere to the root and from the xylem to leaf tissue were observed, while such gradients decreased from root tissue to the xylem and from leaves to the phloem. These studies showed that, for the partitioning of nutrients within a plant, the correlated interactions of uptake, xylem and phloem flow, as well as loading and unloading of solutes from transport systems, are of central importance. For essential nutrients, tight correlations between uptake, xylem and phloem flow, and the resulting partitioning of elements, were observed, which allows the stating of general models. For non-essential ions like Na+ or Cl–, a statistically significant dependence of xylem transport on uptake was not detected. The central role of the phloem for adjusting, but also signalling, of nutrition status is discussed, since strong correlations between leaf nutrient concentrations and those in phloem saps were observed. In addition, negative correlations between phloem sap sugar concentration and net-photosynthesis, growth, and uptake of nutrients were demonstrated. The question remains whether this is only a consequence of an insufficient use of carbohydrates in plants or a ubiquitous signal for stress in plants. In general, high sugar concentrations in phloem saps indicate (nutritional) stress, and high nutrient concentrations in phloem saps indicate nutritional sufficiency of leaf tissues. [ABSTRACT FROM PUBLISHER]

Published

2010

46. Neoformation of clay in lateral root catchments of mallee eucalypts: a chemical perspective.

Author

Verboom, William H., Pate, John S., and Aspandiar, Mehrooz

Subjects

*CLAY soils, *PAVEMENTS, *EUCALYPTUS, *PLANT colonization, *SAND dunes

Abstract

Background and Aims: A previous paper (Annals of Botany 103: 673–685) described formation of clayey pavements in lateral root catchments of eucalypts colonizing a recently formed sand dune in south-west Western Australia. Here chemical and morphological aspects of their formation at the site are studied. [ABSTRACT FROM PUBLISHER]

Published

2010

47. A Highly Sensitive, Quick and Simple Quantification Method for Nicotianamine and 2′-Deoxymugineic Acid from Minimum Samples Using LC/ESI-TOF-MS Achieves Functional Analysis of These Components in Plants.

Author

Kakei, Yusuke, Yamaguchi, Isomaro, Kobayashi, Takanori, Takahashi, Michiko, Nakanishi, Hiromi, Yamakawa, Takashi, and Nishizawa, Naoko K.

Subjects

*ELECTROSPRAY ionization mass spectrometry, *HYDROXYL group, *RICE, *IRON deficiency diseases, *XYLEM, *PLANTS

Abstract

A highly sensitive quantitative method for assaying nicotianamine (NA) and 2′-deoxymugineic acid (DMA) using liquid chromatography/electrospray ionization time-of-flight mass spectrometry (LC/ESI-TOF-MS) was developed. The amino and hydroxyl groups of NA and DMA were derivatized using 9-fluorenylmethoxycarbonyl chloride. The amounts of NA and DMA in 10 μl of xylem sap from rice cultivated under iron (Fe)-sufficient and Fe-deficient conditions were quantified without concentration. In Fe-sufficient plants, the concentrations of NA and DMA were almost equal to that of Fe. In Fe-deficient plants, the concentration of NA did not change significantly, whereas that of DMA increased markedly. [ABSTRACT FROM PUBLISHER]

Published

2009

48. Root-derived CO2 efflux via xylem stream rivals soil CO2 efflux.

Author

Aubrey, Doug P. and Teskey, Robert O.

Subjects

*PLANT roots, *PRIMARY productivity (Biology), *FOREST productivity, *RESPIRATION in plants, *RESPIRATORY quotient, *BIOLOGICAL productivity, *COTTONWOOD, *PLANT photorespiration, *CARBON dioxide sinks, *CARBON dioxide adsorption

Abstract

• Respiration consumes a large portion of annual gross primary productivity in forest ecosystems and is dominated by belowground metabolism. Here, we present evidence of a previously unaccounted for internal CO2 flux of large magnitude from tree roots through stems. If this pattern is shown to persist over time and in other forests, it suggests that belowground respiration has been grossly underestimated. • Using an experimental Populus deltoides plantation as a model system, we tested the hypothesis that a substantial portion of the CO2 released from belowground autotrophic respiration remains within tree root systems and is transported aboveground through the xylem stream rather than diffusing into the soil atmosphere. • On a daily basis, the amount of CO2 that moved upward from the root system into the stem via the xylem stream (0.26 mol CO2 m−2 d−1) rivalled that which diffused from the soil surface to the atmosphere (0.27 mol CO2 m−2 d−1). We estimated that twice the amount of CO2 derived from belowground autotrophic respiration entered the xylem stream as diffused into the soil environment. • Our observations indicate that belowground autotrophic respiration consumes substantially more carbohydrates than previously recognized and challenge the paradigm that all root-respired CO2 diffuses into the soil atmosphere. [ABSTRACT FROM AUTHOR]

Published

2009

49. Selenium uptake, translocation and speciation in wheat supplied with selenate or selenite.

Author

Hua-Fen Li, McGrath, Steve P., and Fang-Jie Zhao

Subjects

*SELENIUM, *SELENITES, *WHEAT, *XYLEM, *PLANT-water relationships, *PLANT cells & tissues, *PHOSPHATES

Abstract

• Selenite can be a dominant form of selenium (Se) in aerobic soils; however, unlike selenate, the mechanism of selenite uptake by plants remains unclear. • Uptake, translocation and Se speciation in wheat ( Triticum aestivum) supplied with selenate or selenite, or both, were investigated in hydroponic experiments. The kinetics of selenite influx was determined in short-term (30 min) experiments. Selenium speciation in the water-extractable fraction of roots and shoots was determined by HPLC-ICPMS. • Plants absorbed similar amounts of Se within 1 d when supplied with selenite or selenate. Selenate and selenite uptake were enhanced in sulphur-starved and phosphorus-starved plants, respectively. Phosphate markedly increased Km of the selenite influx. Selenate and selenite uptake were both metabolically dependent. Selenite was rapidly converted to organic forms in roots, with limited translocation to shoots. Selenomethionine, selenomethionine Se-oxide, Se-methyl-selenocysteine and several other unidentified Se species were detected in the root extracts and xylem sap from selenite-treated plants. Selenate was highly mobile in xylem transport, but little was assimilated to organic forms in 1 d. The presence of selenite decreased selenate uptake and xylem transport. • Selenite uptake is an active process likely mediated, at least partly, by phosphate transporters. Selenite and selenate differ greatly in the ease of assimilation and xylem transport. [ABSTRACT FROM AUTHOR]

Published

2008

50. Oxygen isotope enrichment of organic matter in Ricinus communis during the diel course and as affected by assimilate transport.

Author

Gessler, Arthur, Peuke, Andreas D., Keitel, Claudia, and Farquhar, Graham D.

Subjects

*OXYGEN, *ISOTOPES, *LEAVES, *ORGANIC compounds, *PLANT cells & tissues, *PLANT-water relationships

Abstract

• The oxygen isotope composition in leaf water and organic compounds in different plant tissues is useful for assessing the physiological performance of plants in their environment, but more information is needed on Δ18O variation during a diel course. • Here, we assessed Δ18O of the organic matter in leaves, phloem and xylem in stem segments, and fine roots of Ricinus communis during a full diel cycle. Enrichment of newly assimilated organic matter in equilibrium with leaf water was calculated by applying a nonsteady-state evaporative enrichment model. • During the light period, Δ18O of the water soluble organic matter pool in leaves and phloem could be explained by a 27‰ enrichment compared with leaf water enrichment. Leaf water enrichment influenced Δ18O of phloem organic matter during the night via daytime starch synthesis and night-time starch remobilization. Phloem transport did not affect Δ18O of phloem organic matter. • Diel variation in Δ18O in organic matter pools can be modeled, and oxygen isotopic information is not biased during transport through the plant. These findings will aid field studies that characterize environmental influences on plant water balance using Δ18O in phloem organic matter or tree rings. [ABSTRACT FROM AUTHOR]

Published

2007