Daniel McKay Fletcher scite author profile

Xylella fastidiosa is a xylem-limited plant pathogen infecting many crops globally and is the cause of the recent olive disease epidemic in Italy. One strategy proposed to mitigate losses is to replant susceptible crops with resistant varieties. Several genetic, biochemical and biophysical traits are associated to X. fastidiosa disease resistance.However, mechanisms underpinning resistance are poorly understood. We hypothesize that the susceptibility of olive cultivars to infection will correlate to xylem vessel diameters, with narrower vessels being resistant to air embolisms and having slower flow rates limiting pathogen spread. To test this, we scanned stems from four olive cultivars of varying susceptibility to X. fastidiosa using X-ray computed tomography.Scans were processed by a bespoke methodology that segmented vessels, facilitating diameter measurements. Though significant differences were not found comparing stem-average vessel section diameters among cultivars, they were found when comparing diameter distributions. Moreover, the measurements indicated that although vessel diameter distributions may play a role regarding the resistance of Leccino, it is unlikely they do for FS17. Considering Young-Laplace and Hagen-Poiseuille equations, we inferred differences in embolism susceptibility and hydraulic conductivity of the vasculature. Our results suggest susceptible cultivars, having a greater proportion of larger vessels, are more vulnerable to air embolisms. In addition, results suggest that under certain pressure conditions, functional vasculature in susceptible cultivars could be subject to greater stresses than in resistant cultivars. These results support investigation into xylem morphological screening to help inform olive replanting. Furthermore, our framework could test the relevance of xylem geometry to disease resistance in other crops.

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Linking root structure to functionality: the impact of root system architecture on citrate‐enhanced phosphate uptake

Fletcher

Ruiz

Dias

et al. 2020

New Phytologist

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Summary Root citrate exudation is thought to be important for phosphate solubilization. Previous research has concluded that cluster‐like roots benefit most from this exudation in terms of increased phosphate uptake, suggesting that root structure plays an important role in citrate‐enhanced uptake (additional phosphate uptake due to citrate exudation). Time‐resolved computed tomography images of wheat root systems were used as the geometry for 3D citrate‐phosphate solubilization models. Citrate‐enhanced uptake was correlated with morphological measures of the root systems to determine which had the most benefit. A large variation of citrate‐enhanced uptake over 11 root structures was observed. Root surface area dominated absolute phosphate uptake, but did not explain citrate‐enhanced uptake. Number of exuding root tips correlated well with citrate‐enhanced uptake. Root tips in close proximity could collectively exude high amounts of citrate, resulting in a delayed spike in citrate‐enhanced uptake. Root system architecture plays an important role in citrate‐enhanced uptake. Singular morphological measurements of the root systems cannot entirely explain variations in citrate‐enhanced uptake. Root systems with many tips would benefit greatly from citrate exudation. Quantifying citrate‐enhanced uptake experimentally is difficult as variations in root surface area would overwhelm citrate benefits.

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Quantifying citrate-enhanced phosphate root uptake using microdialysis

et al. 2019

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Aims Organic acid exudation by plant roots is thought to promote phosphate (P) solubilisation and bioavailability in soils with poorly available nutrients. Here we describe a new combined experimental (microdialysis) and modelling approach to quantify citrate-enhanced P desorption and its importance for root P uptake. Methods To mimic the rhizosphere, microdialysis probes were placed in soil and perfused with citrate solutions (0.1, 1.0 and 10 mM) and the amount of P recovered from soil used to quantify rhizosphere P availability. Parameters in a mathematical model describing probe P uptake, citrate exudation, P movement and citrate-enhanced desorption were fit to the experimental data. These parameters were Plant Soil

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Measurement of micro-scale soil deformation around roots using four-dimensional synchrotron tomography and image correlation

Keyes

Cooper

Duncan

et al. 2017

J. R. Soc. Interface.

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This study applied time lapse (four-dimensional) synchrotron X-ray computed tomography to observe micro-scale interactions between plant roots and soil. Functionally contrasting maize root tips were repeatedly imaged during ingress into soil columns of varying water content and compaction. This yielded sequences of three-dimensional densiometric data, representing time-resolved geometric soil and root configurations at the micronmetre scale. These data were used as inputs for two full-field kinematic quantification methods, which enabled the analysis of three-dimensional soil deformation around elongating roots. Discrete object tracking was used to track rigid mineral grains, while continuum digital volume correlation was used to track grey-level patterns within local sub-volumes. These techniques both allowed full-field soil displacements to be quantified at an intra-rhizosphere spatial sampling scale of less than 300 µm. Significant differences in deformation mechanisms were identified around different phenotypes under different soil conditions. A uniquely strong contrast was observed between intact and de-capped roots grown in dry, compacted soil. This provides evidence that functional traits of the root cap significantly reduce the amount of soil disturbance per unit of root elongation, with this effect being particularly significant in drier soil.

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Precipitation-optimised targeting of nitrogen fertilisers in a model maize cropping system

Fletcher

Ruiz

Dias

et al. 2021

Science of The Total Environment

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