Model and image based investigation of Xylella Fastidiosa Dynamics
Model and image based investigation of Xylella Fastidiosa Dynamics
Xylella fastidiosa (X. fastidiosa) is a bacterium that colonises internal plant vascular networks causing pathogenic effects on several commercially important crops (e.g. olives, grapes, coffee, etc.). Despite a growing research effort since the recent detection of X. fastidiosa in Europe, the exact processes leading to X. fastidiosa disease symptoms are not fully understood due to difficulties in observing internal plant structures. Our goal is to utilise models to elucidate fundamental processes that lead to olive quick decline syndrome, the disease responsible for the devastating olive decline in Apulia, Southern Italy. We endeavour to do this by developing a fundamental mathematical modelling framework describing within-host biofilm development, and the resulting water-stresses that ultimately inhibit plant functionality and development.
We have begun work on developing a fluid mechanics model that invokes a polymer-physical description of X.fastidiosa biofilm formation dynamics. Our approach is centred on the assumption that the biofilm structure is determined by the arrangement of extracellular polysaccharide (EPS) molecules. We have also produced X-ray Computed Tomography (XCT) images of both resistant and susceptible olive cultivars to determine possible morphological differences between the vascular networks of the cultivars. Additionally, these images provide detailed geometries for our models, with which we will investigate the effect of xylem geometry on resistance. Preliminary modelling results of EPS dominant biofilm formation characterise biofilm coalescence in a consistent manner with early microfluidic controlled experiments and require fewer empirical assumptions. We hope our work will improve the understanding of possible cultivar resistance mechanisms to enable informed breeding and effective replanting in Apulia, and that model simulations will provide insights for improving the efficiency of current sampling techniques.
Walker, Nancy, Catherine
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Rankin, Kathryn E.
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Ruiz, Siul Aljadi
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McKay Fletcher, Daniel
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Williams, Katherine
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Petroselli, Chiara
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Saponari, M
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White, S
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Roose, Tiina
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26 April 2021
Walker, Nancy, Catherine
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Rankin, Kathryn E.
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Ruiz, Siul Aljadi
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McKay Fletcher, Daniel
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Williams, Katherine
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Petroselli, Chiara
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Saponari, M
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White, S
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Roose, Tiina
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Walker, Nancy, Catherine, Rankin, Kathryn E., Ruiz, Siul Aljadi, McKay Fletcher, Daniel, Williams, Katherine, Petroselli, Chiara, Saponari, M, White, S and Roose, Tiina
(2021)
Model and image based investigation of Xylella Fastidiosa Dynamics.
3rd European conference on Xylella Fastidosa, IFOAM Organics Europe, Brussels, Belgium.
26 - 30 Apr 2021.
9 pp
.
Record type:
Conference or Workshop Item
(Other)
Abstract
Xylella fastidiosa (X. fastidiosa) is a bacterium that colonises internal plant vascular networks causing pathogenic effects on several commercially important crops (e.g. olives, grapes, coffee, etc.). Despite a growing research effort since the recent detection of X. fastidiosa in Europe, the exact processes leading to X. fastidiosa disease symptoms are not fully understood due to difficulties in observing internal plant structures. Our goal is to utilise models to elucidate fundamental processes that lead to olive quick decline syndrome, the disease responsible for the devastating olive decline in Apulia, Southern Italy. We endeavour to do this by developing a fundamental mathematical modelling framework describing within-host biofilm development, and the resulting water-stresses that ultimately inhibit plant functionality and development.
We have begun work on developing a fluid mechanics model that invokes a polymer-physical description of X.fastidiosa biofilm formation dynamics. Our approach is centred on the assumption that the biofilm structure is determined by the arrangement of extracellular polysaccharide (EPS) molecules. We have also produced X-ray Computed Tomography (XCT) images of both resistant and susceptible olive cultivars to determine possible morphological differences between the vascular networks of the cultivars. Additionally, these images provide detailed geometries for our models, with which we will investigate the effect of xylem geometry on resistance. Preliminary modelling results of EPS dominant biofilm formation characterise biofilm coalescence in a consistent manner with early microfluidic controlled experiments and require fewer empirical assumptions. We hope our work will improve the understanding of possible cultivar resistance mechanisms to enable informed breeding and effective replanting in Apulia, and that model simulations will provide insights for improving the efficiency of current sampling techniques.
Text
Nancy-Walker
- Version of Record
More information
Published date: 26 April 2021
Additional Information:
3rd European Conference of Xylella fastidiosa (29/04/21 – 30/04/21), e-poster and Young researchers’ initiative short oral presentation.
Venue - Dates:
3rd European conference on Xylella Fastidosa, IFOAM Organics Europe, Brussels, Belgium, 2021-04-26 - 2021-04-30
Identifiers
Local EPrints ID: 467647
URI: http://eprints.soton.ac.uk/id/eprint/467647
PURE UUID: c96f3dd5-1274-434a-87bb-d124d7c5f24b
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Date deposited: 18 Jul 2022 17:57
Last modified: 04 Jun 2024 01:57
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Contributors
Author:
Kathryn E. Rankin
Author:
Katherine Williams
Author:
Chiara Petroselli
Author:
M Saponari
Author:
S White
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