Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline

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Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline. / Denman, Sandra; Plummer, Sarah; Peace, Andrew et al.
In: Systematic and Applied Microbiology, Vol. 39, No. 7, 01.10.2016, p. 484-490.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Denman, S, Plummer, S, Peace, A & McDonald, J 2016, 'Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline', Systematic and Applied Microbiology, vol. 39, no. 7, pp. 484-490.

APA

Denman, S., Plummer, S., Peace, A., & McDonald, J. (2016). Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline. Systematic and Applied Microbiology, 39(7), 484-490.

CBE

Denman S, Plummer S, Peace A, McDonald J. 2016. Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline. Systematic and Applied Microbiology. 39(7):484-490.

MLA

Denman, Sandra et al. "Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline". Systematic and Applied Microbiology. 2016, 39(7). 484-490.

VancouverVancouver

Denman S, Plummer S, Peace A, McDonald J. Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline. Systematic and Applied Microbiology. 2016 Oct 1;39(7):484-490. Epub 2016 Aug 6.

Author

Denman, Sandra ; Plummer, Sarah ; Peace, Andrew et al. / Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline. In: Systematic and Applied Microbiology. 2016 ; Vol. 39, No. 7. pp. 484-490.

RIS

TY - JOUR

T1 - Isolation studies reveal a shift in the cultivable microbiome of oak affected with Acute Oak Decline

AU - Denman, Sandra

AU - Plummer, Sarah

AU - Peace, Andrew

AU - McDonald, James

PY - 2016/10/1

Y1 - 2016/10/1

N2 - Acute Oak Decline is a syndrome within the Oak Decline complex in Britain. Profuse stem bleeding and larval galleries of the native buprestid, Agrilus biguttatus characterize the disease. A systematic study comparing healthy with diseased trees was undertaken. This work reports the result of isolations from healthy trees, diseased and non-symptomatic tissue within AOD affected trees, at five sites in England. Bacteria and fungi were identified using the DNA gyrase B gene, or ITS 1 sequencing. A significantly higher proportion of diseased tissues (82%) yielded more bacteria than either healthy (18%) or non-symptomatic tissue in diseased trees (33%). Overall bacterial community compositions varied at each site, but significant similarities were evident in diseased tissues at all sites. Enterobacteriaceae dominated in diseased trees whereas Pseudomonadaceae dominated healthy trees. Significant associations between diseased tissues and certain bacterial species occurred, implying that the cause of tissue necrosis was not due to random microbiota. Brenneria goodwinii and Gibbsiella quercinecans were key species consistently isolated from diseased tissue; Rahnella victoriana and an un-named Pseudomonas taxon were also frequently isolated from both healthy and diseased trees. Most fungi isolated were from the outer bark and had no significant association with tree health status. It was concluded that there was a shift in the cultivatable bacterial microbiome of diseased trees, with Enterobacteriaceae strongly represented in symptomatic but not healthy tissues. No single species dominated the isolations from diseased tissues and the tissue degradation in AOD is therefore likely to have a polymicrobial cause.

AB - Acute Oak Decline is a syndrome within the Oak Decline complex in Britain. Profuse stem bleeding and larval galleries of the native buprestid, Agrilus biguttatus characterize the disease. A systematic study comparing healthy with diseased trees was undertaken. This work reports the result of isolations from healthy trees, diseased and non-symptomatic tissue within AOD affected trees, at five sites in England. Bacteria and fungi were identified using the DNA gyrase B gene, or ITS 1 sequencing. A significantly higher proportion of diseased tissues (82%) yielded more bacteria than either healthy (18%) or non-symptomatic tissue in diseased trees (33%). Overall bacterial community compositions varied at each site, but significant similarities were evident in diseased tissues at all sites. Enterobacteriaceae dominated in diseased trees whereas Pseudomonadaceae dominated healthy trees. Significant associations between diseased tissues and certain bacterial species occurred, implying that the cause of tissue necrosis was not due to random microbiota. Brenneria goodwinii and Gibbsiella quercinecans were key species consistently isolated from diseased tissue; Rahnella victoriana and an un-named Pseudomonas taxon were also frequently isolated from both healthy and diseased trees. Most fungi isolated were from the outer bark and had no significant association with tree health status. It was concluded that there was a shift in the cultivatable bacterial microbiome of diseased trees, with Enterobacteriaceae strongly represented in symptomatic but not healthy tissues. No single species dominated the isolations from diseased tissues and the tissue degradation in AOD is therefore likely to have a polymicrobial cause.

M3 - Article

VL - 39

SP - 484

EP - 490

JO - Systematic and Applied Microbiology

JF - Systematic and Applied Microbiology

SN - 0723-2020

IS - 7

ER -