In vivo Observation of Tree Drought Response with Low-Field NMR and Neutron Imaging

Malone, Michael W.; Yoder, Jacob; Hunter, James F.; Espy, Michelle A.; Dickman, L. Turin; Nelson, R. O.; Vogel, Sven C.; Sandin, Henrik; Sevanto, Sanna

doi:10.3389/fpls.2016.00564

Cited by 17 publications

(18 citation statements)

References 33 publications

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“…Desiccation‐avoiding plants, on the other hand, could have high hydraulic conductivity between the xylem and the phloem, because they control the declining xylem water potential by early stomatal closure. These hypotheses are supported by our observation of large storage tissue surrounding the phloem in piñon pine (Figure S2) and the branch‐scale observations of Malone et al (), which suggested higher hydraulic conductivity in the radial direction in pine than in juniper. These hypotheses and all our findings, however, could still fit together if the turgor loss in pine phloem (Sevanto et al, ) was facilitated by turgor loss in the storage tissue rather than in phloem conduits, and the highest resistance to radial water flux in juniper was at the cambial zone rather than between phloem conduits.…”

Section: Discussionsupporting

confidence: 89%

Is desiccation tolerance and avoidance reflected in xylem and phloem anatomy of two coexisting arid‐zone coniferous trees?

Sevanto

Ryan

Dickman

et al. 2018

Plant Cell & Environment

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Plants close their stomata during drought to avoid excessive water loss, but species differ in respect to the drought severity at which stomata close. The stomatal closure point is related to xylem anatomy and vulnerability to embolism, but it also has implications for phloem transport and possibly phloem anatomy to allow sugar transport at low water potentials. Desiccation-tolerant plants that close their stomata at severe drought should have smaller xylem conduits and/or fewer and smaller interconduit pits to reduce vulnerability to embolism but more phloem tissue and larger phloem conduits compared with plants that avoid desiccation. These anatomical differences could be expected to increase in response to long-term reduction in precipitation. To test these hypotheses, we used tridimensional synchroton X-ray microtomograph and light microscope imaging of combined xylem and phloem tissues of 2 coniferous species: one-seed juniper (Juniperus monosperma) and piñon pine (Pinus edulis) subjected to precipitation manipulation treatments. These species show different xylem vulnerability to embolism, contrasting desiccation tolerance, and stomatal closure points. Our results support the hypothesis that desiccation tolerant plants require higher phloem transport capacity than desiccation avoiding plants, but this can be gained through various anatomical adaptations in addition to changing conduit or tissue size.

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Section: Discussionsupporting

confidence: 89%

Is desiccation tolerance and avoidance reflected in xylem and phloem anatomy of two coexisting arid‐zone coniferous trees?

Sevanto

Ryan

Dickman

et al. 2018

Plant Cell & Environment

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“…While low field NMRs suffer from reduced resolution and sensitivity, their low cost and portability make them ideal for field deployment with often nothing more than a power supply required for monitoring. Some examples, include a mobile NMR lab for leaf phenotyping in the field [ 180 ], a portable sensor for monitoring water and sap flow [ 181 ], a device to detect water content in trees [ 182 , 183 ], fast field cycling NMR in plant leaves [ 184 ], as-well as lipid and metabolites profiling in seeds [ 185 ]. Advancement in technologies such as dynamic nuclear polarization in combination with low field NMR [ 186 ], and zero/ultra-low field NMR with optical detection [ 187 ] offer potential for huge increases in sensitivity that would advance low field NMR into a powerful tool for in-vivo analysis and monitoring.…”

Section: Resultsmentioning

confidence: 99%

In-Vivo NMR Spectroscopy: A Powerful and Complimentary Tool for Understanding Environmental Toxicity

et al. 2018

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Part review, part perspective, this article examines the applications and potential of in-vivo Nuclear Magnetic Resonance (NMR) for understanding environmental toxicity. In-vivo NMR can be applied in high field NMR spectrometers using either magic angle spinning based approaches, or flow systems. Solution-state NMR in combination with a flow system provides a low stress approach to monitor dissolved metabolites, while magic angle spinning NMR allows the detection of all components (solutions, gels and solids), albeit with additional stress caused by the rapid sample spinning. With in-vivo NMR it is possible to use the same organisms for control and exposure studies (controls are the same organisms prior to exposure inside the NMR). As such individual variability can be reduced while continual data collection over time provides the temporal resolution required to discern complex interconnected response pathways. When multidimensional NMR is combined with isotopic labelling, a wide range of metabolites can be identified in-vivo providing a unique window into the living metabolome that is highly complementary to more traditional metabolomics studies employing extracts, tissues, or biofluids.

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“…For trees, the model used might vary between the 'semi-permeable phloem' and models in which conduit walls are non-permeable with loading and unloading zones where material exchange occurs, as well as the degree to which the model can be modified (Sevanto et al 2018). However most of the conclusions about trees seem to be speculative or hypothetical because of a lack of empirical evidence (Sevanto 2014;Malone et al 2016;Sevanto et al 2018). Furthermore, there are many open questions concerning the conduit wall permeability, conduit location in relation to other cell types in the phloem, as well as the relevance of these anatomical features for phloem function under environmental stress (De Schepper et al 2013;.…”

Section: Is the Phloem Involved In Drought-induced Mortality?mentioning

confidence: 99%

Drought impacts on tree phloem: from cell-level responses to ecological significance

et al. 2019

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On-going climate change is increasing the risk of drought stress across large areas worldwide. Such drought events decrease ecosystem productivity and have been increasingly linked to tree mortality. Understanding how trees respond to water shortage is key to predicting the future of ecosystem functions. Phloem is at the core of the tree functions, moving resources such as non-structural carbohydrates, nutrients, and defence and information molecules across the whole plant. Phloem function and ability to transport resources is tightly controlled by the balance of carbon and water fluxes within the tree. As such, drought is expected to impact phloem function by decreasing the amount of available water and new photoassimilates. Yet, the effect of drought on the phloem has received surprisingly little attention in the last decades. Here we review existing knowledge on drought impacts on phloem transport from loading and unloading processes at cellular level to possible effects on long-distance transport and consequences to ecosystems via ecophysiological feedbacks. We also point to new research frontiers that need to be explored to improve our understanding of phloem function under drought. In particular, we show how phloem transport is affected differently by increasing drought intensity, from no response to a slowdown, and explore how severe drought might actually disrupt the phloem transport enough to threaten tree survival. Because transport of resources affects other organisms interacting with the tree, we also review the ecological consequences of phloem response to drought and especially predatory, mutualistic and competitive relations. Finally, as phloem is the main path for carbon from sources to sink, we show how drought can affect biogeochemical cycles through changes in phloem transport. Overall, existing knowledge is consistent with the hypotheses that phloem response to drought matters for understanding tree and ecosystem function. However, future research on a large range of species and ecosystems is urgently needed to gain a comprehensive understanding of the question.

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In vivo Observation of Tree Drought Response with Low-Field NMR and Neutron Imaging

Cited by 17 publications

References 33 publications

Is desiccation tolerance and avoidance reflected in xylem and phloem anatomy of two coexisting arid‐zone coniferous trees?

Is desiccation tolerance and avoidance reflected in xylem and phloem anatomy of two coexisting arid‐zone coniferous trees?

In-Vivo NMR Spectroscopy: A Powerful and Complimentary Tool for Understanding Environmental Toxicity

Drought impacts on tree phloem: from cell-level responses to ecological significance

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