Trichoderma aerugineum

Category: fungi
Primary role: biocontrol
Class: Sordariomycetes
Order: Hypocreales
Family: Hypocreaceae
Genus: Trichoderma

External: GBIF #8131975

0 AI-consensus-verified claims .

No verified claims involving this entity yet.

Genus-level evidence

7 claims where the source named the organism only at the genus or collective level (e.g. Trichoderma sp.) and did not determine the species. Listed separately because they apply to the genus, not specifically to Trichoderma aerugineum.

biocontrol · Trichoderma spp. → plant pathogens (general) · effect: beneficial

“fungus Trichoderma and bacteria Pseudomonas fluorescens colonize plant roots and protect them”

Magdoff F., Van Es H. (2021) · Building Soils for Better Crops: Ecological Management for Healthy Soils (Fourth Edition) · p. 59 #6492069
biocontrol · Trichoderma spp. → Plant pathogenic fungi · effect: beneficial

“Mechanisms employed by Trichoderma species in the biological control of plant diseases”

Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) · p. 354 #6493960
biocontrol · Trichoderma spp. → Plantae pathogens (fungal) · effect: beneficial

“Trichoderma and Gliocladium, which are used as biocontrol agents against several plant pathogenic fungi”

Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) · p. 394 #6494263
biocontrol · Trichoderma spp. → plant-parasitic nematodes · effect: beneficial

“Hirsutella rhossiliensis, Dactylella oviparasitica and Trichoderma spp.”

Perry R.N., Moens M., Jones J.T. (2024) · Plant Nematology, 3rd Edition · p. 455 #6494725
biocontrol · Trichoderma spp. → Fusarium oxysporum · effect: beneficial

“significantly higher levels of the beneficial fungus Trichoderma were found in OMVs”

Dufour R. (2000) · Farmscaping to Enhance Biological Control · p. 35 #6495804
biocontrol · Trichoderma (genus) → Fungi (kingdom) · effect: beneficial

“Trichoderma species have received considerable attention for the production of antimicrobial compounds”

Mendes R., Garbeva P., Raaijmakers J.M. (2013) · The rhizosphere microbiome: significance of plant-beneficial, plant-pathogenic and human-pathogenic microorganisms · p. 7 #6495883
biocontrol · Trichoderma spp. → bacterial pathogens · effect: beneficial

“Bacillus spp., Pseudomonas spp., Trichoderma spp., etc., and is conferred through plant hormone-mediated signalling”

· sundin_bacterial_disease_management_2016.pdf · p. 1510 #6496459

Aggregated via GloBI — not independently verified by AgroEco.

mutualism 12

GloBI symbiontOf Trichoderma aerugineum Schlatter, D.C., Hansen, J.C., Schillinger, W.F., Sullivan, T.S. and Paulitz, T.C., 2019. Common and unique rhizosphere microbial communities of wheat and canola in a semiarid Mediterranean environment.. Applied Soil Ecology. doi:10.1016/j.apsoil.2019.07.010 DOI
GloBI symbiontOf Trichoderma aerugineum Tong, A.Z., Liu, W., Liu, Q., Xia, G.Q., 2021. Diversity and composition of the Panax ginseng rhizosphere microbiome in various cultivation modesand ages. BMC microbiology. doi:10.1186/s12866-020-02081-2 DOI
GloBI symbiontOf Trichoderma aerugineum Benitez, M. S., Ewing, P. M., Osborne, S. L. and Lehman, R. M., 2021. Rhizosphere microbial communities explain positive effects of diverse crop rotations on maize and soybean performance. Soil Biology and Biochemistry. doi:10.1016/j.soilbio.2021.108309 DOI
GloBI symbiontOf Trichoderma aerugineum Benitez, M. S., Ewing, P. M., Osborne, S. L. and Lehman, R. M., 2021. Rhizosphere microbial communities explain positive effects of diverse crop rotations on maize and soybean performance. Soil Biology and Biochemistry. doi:10.1016/j.soilbio.2021.108309 DOI
GloBI symbiontOf Trichoderma aerugineum Schlatter, D.C., Hansen, J.C., Schillinger, W.F., Sullivan, T.S. and Paulitz, T.C., 2019. Common and unique rhizosphere microbial communities of wheat and canola in a semiarid Mediterranean environment.. Applied Soil Ecology. doi:10.1016/j.apsoil.2019.07.010 DOI
GloBI symbiontOf Trichoderma aerugineum Mardanova, A., Lutfullin, M., Hadieva, G., Akosah, Y., Pudova, D., Kabanov, D., Shagimardanova, E., Vankov, P., Vologin, S., Gogoleva, N., Stasevski, Z. and Sharipova, M., 2019. Structure and variation of root-associated microbiomes of potato grown in alfisol.. World Journal of Microbiology and Biotechnology.
GloBI symbiontOf Trichoderma aerugineum Tian, L., Yu, S., Zhang, L., Dong, K. and Feng, B., 2022. Mulching practices manipulate the microbial community diversity and network of root‑associated compartments in the Loess Plateau. Soil and Tillage Research. doi:10.1016/j.still.2022.105476 DOI
GloBI symbiontOf Trichoderma aerugineum Xu, L., Ravnskov, S., Larsen, J. and Nicolaisen, M., 2012. Linking fungal communities in roots, rhizosphere, and soil to the health status of Pisum sativum.. FEMS Microbiology Ecology. doi:10.1111/j.1574-6941.2012.01445.x DOI
GloBI symbiontOf Trichoderma aerugineum Si, P., Shao, W., Yu, H., Yang, X., Gao, D., Qiao, X., Wang, Z. and Wu, G., 2018. Rhizosphere Microenvironments of Eight Common Deciduous Fruit Trees Were Shaped by Microbes in Northern China.. Frontiers in Microbiology. doi:10.3389/fmicb.2018.03147 DOI
GloBI symbiontOf Trichoderma aerugineum Sternhagen, E.C., Black, K.L., Hartmann, E.D., Shivega, W.G., Johnson, P.G., McGlynn, R.D., Schmaltz, L.C., Asheim Keller, R.J., Vink, S.N. and Aldrich-Wolfe, L., 2020. Contrasting Patterns of Functional Diversity in Coffee Root Fungal Communities Associated with Organic and Conventionally Managed Fields. Applied and Environmental Microbiology. doi:10.1128/AEM.00052-20 DOI
GloBI symbiontOf Trichoderma aerugineum Lee, M. R. and Hawkes, C. V., 2020. Plant and soil drivers of whole-plant microbiomes: variation in switchgrass fungi from coastal to mountain sites. Phytobiomes Journal. doi:10.1094/PBIOMES-07-20-0056-FI DOI
GloBI symbiontOf Trichoderma aerugineum Liu, Y., Zhang, X., Yang, M.L. and Wang, S.M., 2020. Study on the correlation between soil microbial diversity and ambient environmental factors influencing the safflower distribution in Xinjiang. Journal of basic microbiology. doi:10.1002/jobm.201900626 DOI

crop interaction 12

GloBI symbiontOf Trichoderma aerugineum Schlatter, D.C., Hansen, J.C., Schillinger, W.F., Sullivan, T.S. and Paulitz, T.C., 2019. Common and unique rhizosphere microbial communities of wheat and canola in a semiarid Mediterranean environment.. Applied Soil Ecology. doi:10.1016/j.apsoil.2019.07.010 DOI
GloBI symbiontOf Trichoderma aerugineum Tong, A.Z., Liu, W., Liu, Q., Xia, G.Q., 2021. Diversity and composition of the Panax ginseng rhizosphere microbiome in various cultivation modesand ages. BMC microbiology. doi:10.1186/s12866-020-02081-2 DOI
GloBI symbiontOf Trichoderma aerugineum Benitez, M. S., Ewing, P. M., Osborne, S. L. and Lehman, R. M., 2021. Rhizosphere microbial communities explain positive effects of diverse crop rotations on maize and soybean performance. Soil Biology and Biochemistry. doi:10.1016/j.soilbio.2021.108309 DOI
GloBI symbiontOf Trichoderma aerugineum Benitez, M. S., Ewing, P. M., Osborne, S. L. and Lehman, R. M., 2021. Rhizosphere microbial communities explain positive effects of diverse crop rotations on maize and soybean performance. Soil Biology and Biochemistry. doi:10.1016/j.soilbio.2021.108309 DOI
GloBI symbiontOf Trichoderma aerugineum Schlatter, D.C., Hansen, J.C., Schillinger, W.F., Sullivan, T.S. and Paulitz, T.C., 2019. Common and unique rhizosphere microbial communities of wheat and canola in a semiarid Mediterranean environment.. Applied Soil Ecology. doi:10.1016/j.apsoil.2019.07.010 DOI
GloBI symbiontOf Trichoderma aerugineum Mardanova, A., Lutfullin, M., Hadieva, G., Akosah, Y., Pudova, D., Kabanov, D., Shagimardanova, E., Vankov, P., Vologin, S., Gogoleva, N., Stasevski, Z. and Sharipova, M., 2019. Structure and variation of root-associated microbiomes of potato grown in alfisol.. World Journal of Microbiology and Biotechnology.
GloBI symbiontOf Trichoderma aerugineum Tian, L., Yu, S., Zhang, L., Dong, K. and Feng, B., 2022. Mulching practices manipulate the microbial community diversity and network of root‑associated compartments in the Loess Plateau. Soil and Tillage Research. doi:10.1016/j.still.2022.105476 DOI
GloBI symbiontOf Trichoderma aerugineum Xu, L., Ravnskov, S., Larsen, J. and Nicolaisen, M., 2012. Linking fungal communities in roots, rhizosphere, and soil to the health status of Pisum sativum.. FEMS Microbiology Ecology. doi:10.1111/j.1574-6941.2012.01445.x DOI
GloBI symbiontOf Trichoderma aerugineum Si, P., Shao, W., Yu, H., Yang, X., Gao, D., Qiao, X., Wang, Z. and Wu, G., 2018. Rhizosphere Microenvironments of Eight Common Deciduous Fruit Trees Were Shaped by Microbes in Northern China.. Frontiers in Microbiology. doi:10.3389/fmicb.2018.03147 DOI
GloBI symbiontOf Trichoderma aerugineum Sternhagen, E.C., Black, K.L., Hartmann, E.D., Shivega, W.G., Johnson, P.G., McGlynn, R.D., Schmaltz, L.C., Asheim Keller, R.J., Vink, S.N. and Aldrich-Wolfe, L., 2020. Contrasting Patterns of Functional Diversity in Coffee Root Fungal Communities Associated with Organic and Conventionally Managed Fields. Applied and Environmental Microbiology. doi:10.1128/AEM.00052-20 DOI
GloBI symbiontOf Trichoderma aerugineum Lee, M. R. and Hawkes, C. V., 2020. Plant and soil drivers of whole-plant microbiomes: variation in switchgrass fungi from coastal to mountain sites. Phytobiomes Journal. doi:10.1094/PBIOMES-07-20-0056-FI DOI
GloBI symbiontOf Trichoderma aerugineum Liu, Y., Zhang, X., Yang, M.L. and Wang, S.M., 2020. Study on the correlation between soil microbial diversity and ambient environmental factors influencing the safflower distribution in Xinjiang. Journal of basic microbiology. doi:10.1002/jobm.201900626 DOI

Genus-level evidence

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