Genomic and functional analysis of phage-mediated horizontal gene transfer in Pseudomonas syringae on the plant surface

Michelle T. Hulin; Mojgan Rabiey; Ziyue Zeng; Andrea Vadillo Dieguez; Sophia Bellamy; Phoebe Swift; John W. Mansfield; Robert W. Jackson; Richard J. Harrison

doi:10.1111/nph.18573

Genomic and functional analysis of phage-mediated horizontal gene transfer in Pseudomonas syringae on the plant surface

Michelle T. Hulin, Mojgan Rabiey, Ziyue Zeng, Andrea Vadillo Dieguez, Sophia Bellamy, Phoebe Swift, John W. Mansfield, Robert W. Jackson^*, Richard J. Harrison^*

^*Corresponding author for this work

Biosciences

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Abstract

Many strains of Pseudomonas colonise plant surfaces, including the cherry canker pathogens, Pseudomonas syringae pathovars syringae and morsprunorum. We have examined the genomic diversity of P. syringae in the cherry phyllosphere and focused on the role of prophages in transfer of genes encoding Type 3 secreted effector (T3SE) proteins contributing to the evolution of virulence.

Phylogenomic analysis was carried out on epiphytic pseudomonads in the UK orchards. Significant differences in epiphytic populations occurred between regions. Nonpathogenic strains were found to contain reservoirs of T3SE genes. Members of P. syringae phylogroups 4 and 10 were identified for the first time from Prunus.

Using bioinformatics, we explored the presence of the gene encoding T3SE HopAR1 within related prophage sequences in diverse P. syringae strains including cherry epiphytes and pathogens. Results indicated that horizontal gene transfer (HGT) of this effector between phylogroups may have involved phage. Prophages containing hopAR1 were demonstrated to excise, circularise and transfer the gene on the leaf surface.

The phyllosphere provides a dynamic environment for prophage‐mediated gene exchange and the potential for the emergence of new more virulent pathotypes. Our results suggest that genome‐based epidemiological surveillance of environmental populations will allow the timely application of control measures to prevent damaging diseases.

Original language	English
Pages (from-to)	959-973
Number of pages	25
Journal	New Phytologist
Volume	237
Issue number	3
Early online date	2 Dec 2022
DOIs	https://doi.org/10.1111/nph.18573
Publication status	Published - 5 Jan 2023

Keywords

Bacterial evolution
genomic diversity
horizontal gene transfer
phyllosphere
prophage
Pseudomonas syringae

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10.1111/nph.18573Licence: Creative Commons: Attribution (CC BY)

HulinM2022GenomicFinal published version, 4.52 MBLicence: Creative Commons: Attribution (CC BY)

Predicting the emergence of host-adapted bacterial phytopathogens
Jackson, R.
Biotechnology & Biological Sciences Research Council
1/09/20 → 31/03/24
Project: Research Councils

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title = "Genomic and functional analysis of phage-mediated horizontal gene transfer in Pseudomonas syringae on the plant surface",

abstract = "Many strains of Pseudomonas colonise plant surfaces, including the cherry canker pathogens, Pseudomonas syringae pathovars syringae and morsprunorum. We have examined the genomic diversity of P. syringae in the cherry phyllosphere and focused on the role of prophages in transfer of genes encoding Type 3 secreted effector (T3SE) proteins contributing to the evolution of virulence. Phylogenomic analysis was carried out on epiphytic pseudomonads in the UK orchards. Significant differences in epiphytic populations occurred between regions. Nonpathogenic strains were found to contain reservoirs of T3SE genes. Members of P. syringae phylogroups 4 and 10 were identified for the first time from Prunus. Using bioinformatics, we explored the presence of the gene encoding T3SE HopAR1 within related prophage sequences in diverse P. syringae strains including cherry epiphytes and pathogens. Results indicated that horizontal gene transfer (HGT) of this effector between phylogroups may have involved phage. Prophages containing hopAR1 were demonstrated to excise, circularise and transfer the gene on the leaf surface. The phyllosphere provides a dynamic environment for prophage‐mediated gene exchange and the potential for the emergence of new more virulent pathotypes. Our results suggest that genome‐based epidemiological surveillance of environmental populations will allow the timely application of control measures to prevent damaging diseases.",

keywords = "Bacterial evolution, genomic diversity, horizontal gene transfer, phyllosphere, prophage, Pseudomonas syringae",

author = "Hulin, {Michelle T.} and Mojgan Rabiey and Ziyue Zeng and Dieguez, {Andrea Vadillo} and Sophia Bellamy and Phoebe Swift and Mansfield, {John W.} and Jackson, {Robert W.} and Harrison, {Richard J.}",

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AU - Hulin, Michelle T.

AU - Rabiey, Mojgan

AU - Zeng, Ziyue

AU - Dieguez, Andrea Vadillo

AU - Bellamy, Sophia

AU - Swift, Phoebe

AU - Mansfield, John W.

AU - Jackson, Robert W.

AU - Harrison, Richard J.

PY - 2023/1/5

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N2 - Many strains of Pseudomonas colonise plant surfaces, including the cherry canker pathogens, Pseudomonas syringae pathovars syringae and morsprunorum. We have examined the genomic diversity of P. syringae in the cherry phyllosphere and focused on the role of prophages in transfer of genes encoding Type 3 secreted effector (T3SE) proteins contributing to the evolution of virulence. Phylogenomic analysis was carried out on epiphytic pseudomonads in the UK orchards. Significant differences in epiphytic populations occurred between regions. Nonpathogenic strains were found to contain reservoirs of T3SE genes. Members of P. syringae phylogroups 4 and 10 were identified for the first time from Prunus. Using bioinformatics, we explored the presence of the gene encoding T3SE HopAR1 within related prophage sequences in diverse P. syringae strains including cherry epiphytes and pathogens. Results indicated that horizontal gene transfer (HGT) of this effector between phylogroups may have involved phage. Prophages containing hopAR1 were demonstrated to excise, circularise and transfer the gene on the leaf surface. The phyllosphere provides a dynamic environment for prophage‐mediated gene exchange and the potential for the emergence of new more virulent pathotypes. Our results suggest that genome‐based epidemiological surveillance of environmental populations will allow the timely application of control measures to prevent damaging diseases.

AB - Many strains of Pseudomonas colonise plant surfaces, including the cherry canker pathogens, Pseudomonas syringae pathovars syringae and morsprunorum. We have examined the genomic diversity of P. syringae in the cherry phyllosphere and focused on the role of prophages in transfer of genes encoding Type 3 secreted effector (T3SE) proteins contributing to the evolution of virulence. Phylogenomic analysis was carried out on epiphytic pseudomonads in the UK orchards. Significant differences in epiphytic populations occurred between regions. Nonpathogenic strains were found to contain reservoirs of T3SE genes. Members of P. syringae phylogroups 4 and 10 were identified for the first time from Prunus. Using bioinformatics, we explored the presence of the gene encoding T3SE HopAR1 within related prophage sequences in diverse P. syringae strains including cherry epiphytes and pathogens. Results indicated that horizontal gene transfer (HGT) of this effector between phylogroups may have involved phage. Prophages containing hopAR1 were demonstrated to excise, circularise and transfer the gene on the leaf surface. The phyllosphere provides a dynamic environment for prophage‐mediated gene exchange and the potential for the emergence of new more virulent pathotypes. Our results suggest that genome‐based epidemiological surveillance of environmental populations will allow the timely application of control measures to prevent damaging diseases.

KW - Bacterial evolution

KW - genomic diversity

KW - horizontal gene transfer

KW - phyllosphere

KW - prophage

KW - Pseudomonas syringae

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DO - 10.1111/nph.18573

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JO - New Phytologist

JF - New Phytologist

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ER -

Genomic and functional analysis of phage-mediated horizontal gene transfer in Pseudomonas syringae on the plant surface

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Keywords

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Predicting the emergence of host-adapted bacterial phytopathogens

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