Model and Image based Investigation into Xylella fastidiosa Within-Host Dynamics
Model and Image based Investigation into Xylella fastidiosa Within-Host Dynamics
Photosynthesis relies on the transport of water and sugars from roots to leaves facilitated by two key tissues: xylem and phloem. Blockages in the xylem/phloem, either by structures formed by the pathogen itself or those formed by the plant as a defence mechanism, disrupt the soil-plant-atmosphere continuum and cause many vascular plant disease symptoms. Xylella fastidiosa (X. fastidiosa) is a bacterium that colonises internal plant vascular networks causing pathogenic effects on several commercially important crops, including those associated with the olive quick decline syndrome causing devastating olive decline in Apulia, Southern Italy. 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. We are developing a mathematical model describing within-host biofilm development that predicts water-stresses that ultimately inhibit plant functionality. Our approach is centred on the assumption that the biofilm structure is determined by the arrangement of extracellular polysaccharide (EPS) molecules, and as such, our model contains a polymer-physical description of X. fastidiosa biofilm formation dynamics. We used our model, requiring minimal empirical assumptions, to replicate biofilm aggregation observed by microfluidics. We have also produced X-ray Computed Tomography (XCT) images of vascular networks in both resistant and susceptible olive cultivars. We are using these images to test whether susceptibility is correlated with morphological differences that might influence fluid flow through the plant. This work improves the understanding of possible cultivar resistance mechanisms to aid informed breeding and orchard management, and model simulations will provide insights for understanding xylem blockages and their relation to observed symptom severity.
https://zenodo.org/record/4679488#.YtAtCGDMLIW
Walker, Nancy, Catherine
0b539663-b1db-4e93-a513-2580c3229df4
Rankin, Kathryn E.
d9516566-0ad8-473d-b99b-4683c663a2b7
Ruiz, Siul Aljadi
d79b3b82-7c0d-47cc-9616-11d29e6a41bd
McKay Fletcher, Daniel
60e9adeb-182b-4dfd-846a-b684f8e2358e
Williams, Katherine
bf87a040-9a95-4c4e-a078-d289404b7523
Petroselli, Chiara
19266726-2dc0-4790-af77-7ccdc45865eb
Saponari, M
89d2e04b-1e6d-4c87-a73e-29f8d3138d56
White, S
4d0d9e26-8766-44f9-88e6-05ab9c343ed9
Roose, Tiina
3581ab5b-71e1-4897-8d88-59f13f3bccfe
26 April 2021
Walker, Nancy, Catherine
0b539663-b1db-4e93-a513-2580c3229df4
Rankin, Kathryn E.
d9516566-0ad8-473d-b99b-4683c663a2b7
Ruiz, Siul Aljadi
d79b3b82-7c0d-47cc-9616-11d29e6a41bd
McKay Fletcher, Daniel
60e9adeb-182b-4dfd-846a-b684f8e2358e
Williams, Katherine
bf87a040-9a95-4c4e-a078-d289404b7523
Petroselli, Chiara
19266726-2dc0-4790-af77-7ccdc45865eb
Saponari, M
89d2e04b-1e6d-4c87-a73e-29f8d3138d56
White, S
4d0d9e26-8766-44f9-88e6-05ab9c343ed9
Roose, Tiina
3581ab5b-71e1-4897-8d88-59f13f3bccfe
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 into Xylella fastidiosa Within-Host Dynamics.
3rd European Conference on Xylella fastidosa and XF-ACTORS final meeting (xylella21).
26 - 30 Apr 2021.
5 pp
.
(https://zenodo.org/record/4679488#.YtAtCGDMLIW).
Record type:
Conference or Workshop Item
(Poster)
Abstract
Photosynthesis relies on the transport of water and sugars from roots to leaves facilitated by two key tissues: xylem and phloem. Blockages in the xylem/phloem, either by structures formed by the pathogen itself or those formed by the plant as a defence mechanism, disrupt the soil-plant-atmosphere continuum and cause many vascular plant disease symptoms. Xylella fastidiosa (X. fastidiosa) is a bacterium that colonises internal plant vascular networks causing pathogenic effects on several commercially important crops, including those associated with the olive quick decline syndrome causing devastating olive decline in Apulia, Southern Italy. 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. We are developing a mathematical model describing within-host biofilm development that predicts water-stresses that ultimately inhibit plant functionality. Our approach is centred on the assumption that the biofilm structure is determined by the arrangement of extracellular polysaccharide (EPS) molecules, and as such, our model contains a polymer-physical description of X. fastidiosa biofilm formation dynamics. We used our model, requiring minimal empirical assumptions, to replicate biofilm aggregation observed by microfluidics. We have also produced X-ray Computed Tomography (XCT) images of vascular networks in both resistant and susceptible olive cultivars. We are using these images to test whether susceptibility is correlated with morphological differences that might influence fluid flow through the plant. This work improves the understanding of possible cultivar resistance mechanisms to aid informed breeding and orchard management, and model simulations will provide insights for understanding xylem blockages and their relation to observed symptom severity.
Text
4679488_walker_xylella21
- Version of Record
More information
Published date: 26 April 2021
Additional Information:
ISMC (18/05/21 – 22/05/21), e-poster. Copernicus Meetings (No. ISMC2021-14).
Venue - Dates:
3rd European Conference on Xylella fastidosa and XF-ACTORS final meeting (xylella21), 2021-04-26 - 2021-04-30
Identifiers
Local EPrints ID: 467599
URI: http://eprints.soton.ac.uk/id/eprint/467599
DOI: https://zenodo.org/record/4679488#.YtAtCGDMLIW
PURE UUID: 315fcdf5-37ea-49d0-8cef-e4ee66eae5aa
Catalogue record
Date deposited: 14 Jul 2022 17:19
Last modified: 04 Jun 2024 01:57
Export record
Altmetrics
Contributors
Author:
Kathryn E. Rankin
Author:
Katherine Williams
Author:
Chiara Petroselli
Author:
M Saponari
Author:
S White
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics