Identification of native endophytic Trichoderma spp. for investigation of in vitro antagonism towards Armillaria mellea using synthetic‐ and plant‐based substrates

Aims To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. Methods and Results In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence....

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Published inJournal of applied microbiology Vol. 131; no. 1; pp. 392 - 403
Main Authors Rees, H.J., Bashir, N., Drakulic, J., Cromey, M.G., Bailey, A.M., Foster, G.D.
Format Journal Article
LanguageEnglish
Published England Oxford University Press 01.07.2021
Subjects
Antagonism
Armillaria mellea
Armillaria root rot
biocontrol
Biological control
Chemical treatment
Colonies
cost effectiveness
Disks
endophyte
Endophytes
Fungi
Host plants
pathogens
Root rot
Substrates
Trichoderma
Trichoderma virens
Trichoderma
endophyte
antagonism
Armillaria mellea
fungi
biocontrol
Online AccessGet full text
ISSN1364-5072
1365-2672
1365-2672
DOI10.1111/jam.14938

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Abstract Aims To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. Methods and Results In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co‐cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre‐colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate‐based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea. Conclusions Of the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre‐colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material. Significance and Impact of the Study Controlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost‐effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
AbstractList To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea.AIMSTo isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea.In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co-cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre-colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate-based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea.METHODS AND RESULTSIn all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co-cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre-colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate-based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea.Of the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre-colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material.CONCLUSIONSOf the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre-colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material.Controlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost-effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.SIGNIFICANCE AND IMPACT OF THE STUDYControlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost-effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
AIMS: To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. METHODS AND RESULTS: In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co‐cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre‐colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate‐based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea. CONCLUSIONS: Of the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre‐colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material. SIGNIFICANCE AND IMPACT OF THE STUDY: Controlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost‐effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
Aims To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. Methods and Results In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co‐cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre‐colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate‐based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea. Conclusions Of the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre‐colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material. Significance and Impact of the Study Controlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost‐effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. In all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co-cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre-colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate-based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea. Of the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre-colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material. Controlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost-effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
AimsTo isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea.Methods and ResultsIn all, 40 Trichoderma isolates were obtained from a range of host plants and identities were confirmed by ITS, rpb2 and tef1 sequence. When tested in dual culture assays for antagonism against A. mellea, Trichoderma isolates overgrew the A. mellea colonies within four days and by eight days 38 Trichoderma isolates significantly reduced A. mellea colony size. Armillaria mellea was unable to be recovered from five of eight co‐cultivations tested, suggesting Trichoderma had killed the A. mellea in these cases. Pre‐colonized hazel disks were used to determine what happens in a more heterogeneous situation with A. mellea and a refined set of eight Trichoderma isolates. Similar to plate‐based assays, Trichoderma quickly covered A. mellea stopping any further growth and two Trichoderma isolates were able to eradicate A. mellea.ConclusionsOf the Trichoderma spp. tested, endophytic isolates of Trichoderma virens and T. hamatum offered the greatest antagonism towards A. mellea. Using pre‐colonized hazel disks was of great importance for this work to demonstrate the fungal interactions in plant material.Significance and Impact of the StudyControlling Armillaria root rot is difficult with chemical treatments, thus an environmentally benign and cost‐effective alternative is required. This study highlights the prospect of biological control as an effective, environmentally friendly alternative to chemicals.
Author Cromey, M.G.
Bailey, A.M.
Bashir, N.
Drakulic, J.
Rees, H.J.
Foster, G.D.
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Issue 1
Keywords Trichoderma
endophyte
antagonism
Armillaria mellea
fungi
biocontrol
Language English
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Snippet Aims To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. Methods and...
To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. In all, 40...
AimsTo isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea.Methods and...
To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea.AIMSTo isolate...
AIMS: To isolate endophytic Trichoderma species and investigate the potential for biological control of the root rot pathogen Armillaria mellea. METHODS AND...
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SubjectTerms Antagonism
Armillaria mellea
Armillaria root rot
biocontrol
Biological control
Chemical treatment
Colonies
cost effectiveness
Disks
endophyte
Endophytes
Fungi
Host plants
pathogens
Root rot
Substrates
Trichoderma
Trichoderma virens
Title Identification of native endophytic Trichoderma spp. for investigation of in vitro antagonism towards Armillaria mellea using synthetic‐ and plant‐based substrates
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fjam.14938
https://www.ncbi.nlm.nih.gov/pubmed/33219581
https://www.proquest.com/docview/2543760668
https://www.proquest.com/docview/2463104243
https://www.proquest.com/docview/2636421977
Volume 131
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