Aspergillus flavus

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Category: fungi
Primary role: pathogen fungal
Class: Eurotiomycetes
Order: Eurotiales
Family: Aspergillaceae
Genus: Aspergillus

External: GBIF #5259820

4 AI-consensus-verified claims across 1 interaction category.

Related entities

Top entities sharing the most verified claims with Aspergillus flavus.

pathogen pressure 4 claims

This entity is the subject of pathogen pressure on Zea mays (Corn) · effect: harmful

“aflatoxins produced primarily by Aspergillus flavus and other fungi”

pathogenOf ✓ 2/2 AI critics agreed

Ristaino J.B., Anderson P.K., Bebber D.P., Brauman K.A., Cunniffe N.J., Fedoroff N.V., Finegold C., Garrett K.A., Gilligan C.A., Jones C.M., Martin M.D., MacDonald G.K., Neenan P., Records A., Schmale D.G., Tateosian L., Wei Q. (2021) · The persistent threat of emerging plant disease pandemics to global food security · p. 3 #6495315
This entity is the subject of pathogen pressure on Arachis hypogaea ((jordnøtt)) · effect: harmful

“utilization of corn and groundnuts (peanut) as sources of nutrition”

pathogenOf ✓ 2/2 AI critics agreed

Ristaino J.B., Anderson P.K., Bebber D.P., Brauman K.A., Cunniffe N.J., Fedoroff N.V., Finegold C., Garrett K.A., Gilligan C.A., Jones C.M., Martin M.D., MacDonald G.K., Neenan P., Records A., Schmale D.G., Tateosian L., Wei Q. (2021) · The persistent threat of emerging plant disease pandemics to global food security · p. 2 #6495316
This entity is the subject of pathogen pressure on Zea mays (Corn) · effect: harmful

“aflatoxins produced primarily by Aspergillus flavus and other fungi”

pathogenOf ✓ 2/2 AI critics agreed

Ristaino J.B., Anderson P.K., Bebber D.P., Brauman K.A., Cunniffe N.J., Fedoroff N.V., Finegold C., Garrett K.A., Gilligan C.A., Jones C.M., Martin M.D., MacDonald G.K., Neenan P., Records A., Schmale D.G., Tateosian L., Wei Q. (2021) · The persistent threat of emerging plant disease pandemics to global food security · p. 3 #6495954
This entity is the subject of pathogen pressure on Arachis hypogaea ((jordnøtt)) · effect: harmful

“utilization of corn and groundnuts (peanut)... compromised by aflatoxins”

pathogenOf ✓ 2/2 AI critics agreed

Ristaino J.B., Anderson P.K., Bebber D.P., Brauman K.A., Cunniffe N.J., Fedoroff N.V., Finegold C., Garrett K.A., Gilligan C.A., Jones C.M., Martin M.D., MacDonald G.K., Neenan P., Records A., Schmale D.G., Tateosian L., Wei Q. (2021) · The persistent threat of emerging plant disease pandemics to global food security · p. 3 #6495955

Genus-level evidence

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

pathogen pressure · Aspergillus spp. → Lens culinaris · effect: harmful

“wheat, lentil and mung bean seeds”

Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies · p. 131 #6493021
pathogen pressure · Aspergillus spp. → Vigna radiata · effect: harmful

“wheat, lentil and mung bean seeds”

Fiebrig I.N. (ed.), Tornaghi C., McAllister G., Moeller N., Pedersen M., Sucholas J., Greinwald A., Ukhanova M., Luick R., Fiebrig I.N., van de Vijver M., van Kan C.J., Tilzey M., Stobart A., Prieto Garcia J., Vieweger A., Westaway S., Whistance L., Kümmritz S., Klocke B., Krähmer A., Johnson M., Sarabia L., Solorio F., Galindo F., González P., Sandoval Castro C.A., Torres F., Ku J., Păcurar F., Reif A., Ruşdea E., Nair M.N.B., Punniamurthy N., Venkatasubramanian P., Balasubramani S.P., Kukkupuni S.K., Weins C., Bombardi L., Peralta M.C.C., Bach A.E. (2023) · Medicinal Agroecology: Reviews, Case Studies, and Research Methodologies · p. 131 #6493022
pathogen pressure · Aspergillus spp. → Zea mays · effect: harmful

“Portion of ear of corn infected with Aspergillus”

Unknown (Unknown) · History of Plant Pathology and Early Significant Plant Diseases (Chapter 1 Introduction) #6493157

Aggregated via GloBI — not independently verified by AgroEco.

mutualism 39

GloBI symbiontOf Aspergillus flavus Li, R., Yang, S., Lin, M., Guo, S., Han, X., Ren, M., Du, L., Song, Y., You, Y., Zhan, J. and Huang, W.,, 2021. The biogeography of fungal communities across different chinese wine-producing regions associated with environmental factors and spontaneous fermentation performance. Frontiers in microbiology. doi:10.3389/fmicb.2021.636639 DOI
GloBI symbiontOf Aspergillus flavus Wu, C., Wang, F., Ge, A., Zhang, H., Chen, G., Deng, Y., Yang, J., Chen, J. and Ge, T., 2021. Enrichment of microbial taxa after the onset of wheat yellow mosaic disease. Agriculture, Ecosystems & Environment. doi:10.1016/j.agee.2021.107651 DOI
GloBI symbiontOf Aspergillus flavus Veloso, T.G.R., da Silva, M.D.C.S., Cardoso, W.S., Guarçoni, R.C., Kasuya, M.C.M. and Pereira, L.L., 2020. Effects of environmental factors on microbiota of fruits and soil of Coffea arabica in Brazil.. Scientific Reports. doi:10.1038/s41598-020-71309-y DOI
GloBI symbiontOf Aspergillus flavus Ma, J., Ma, K., Liu, J. and Chen, N, 2022. Rhizosphere Soil Microbial Community Under Ice in a High-Latitude Wetland: Different Community Assembly Processes Shape Patterns of Rare and Abundant Microbes. Frontiers in microbiology. doi:10.3389/fmicb.2022.783371 DOI
GloBI symbiontOf Aspergillus flavus 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
GloBI symbiontOf Aspergillus flavus Longa, C.M.O., Antonielli, L., Bozza, E., Sicher, C., Pertot, I. and Perazzolli, M., 2022. Plant organ and sampling time point determine the taxonomic structure of microbial communities associated to apple plants in the orchard environment.. Microbiological Research. doi:10.1016/j.micres.2022.126991 DOI
GloBI symbiontOf Aspergillus flavus Cregger, M.A., Veach, A.M., Yang, Z.K., Crouch, M.J., Vilgalys, R., Tuskan, G.A. and Schadt, C.W., 2018. The Populus holobiont: dissecting the effects of plant niches and genotype on the microbiome.. Microbiome. doi:10.1186/s40168-018-0413-8 DOI
GloBI symbiontOf Aspergillus flavus Ettinger, C.L., Vann, L.E. and Eisen, J.A., 2020. Global diversity and biogeography of the Zostera marina mycobiome.. bioRxiv. doi:10.1101/2020.10.29.361022 DOI
GloBI symbiontOf Aspergillus flavus Wang, W., Zhai, Y., Cao, L., Tan, H. and Zhang, R., 2016. Endophytic bacterial and fungal microbiota in sprouts, roots and stems of rice (Oryza sativa L.).. Microbiological Research. doi:10.1016/j.micres.2016.04.009 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus LI, X.D., Ming, S.H.I., Hong, P.A.N., LU, X.J., WEI, X.Y., Ping, L.U., LIAN, Q.X. and FU, Y.H., 2020. Diversity in metagenomic sequences reveals new pathogenic fungus associated with smut in Job�s tears. JOURNAL OF INTEGRATIVE AGRICULTURE. doi:10.1016/S2095-3119(20)63164-1 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Zhu, S., Wang, Y., Xu, X., Liu, T., Wu, D., Zheng, X., Tang, S. and Dai, Q., 2018. Potential use of high-throughput sequencing of soil microbial communities for estimating the adverse effects of continuous cropping on ramie (Boehmeria nivea L. Gaud).. PloS One. doi:10.1371/journal.pone.0197095 DOI
GloBI symbiontOf Aspergillus flavus Liu, Y., Lu, M., Zhang, X., Sun, Q., Liu, R. and Lian, B., 2019. Shift of the microbial communities from exposed sandstone rocks to forest soils during pedogenesis.. International Biodeterioration & Biodegradation. doi:10.1016/j.ibiod.2019.03.006 DOI
GloBI symbiontOf Aspergillus flavus Zhang, L., Yin, X., Zhang, J., Wei, Y., Huo, D., Ma, C., Chang, H., Cai, K. and Shi, H., 2021. Comprehensive microbiome and metabolome analyses reveal the physiological mechanism of chlorotic Areca leaves. TREE PHYSIOLOGY. doi:10.1093/treephys/tpaa112 DOI
GloBI symbiontOf Aspergillus flavus Kirkman, E.R., Hilton, S., Sethuraman, G., Elias, D.M., Taylor, A., Clarkson, J., Soh, A.C., Bass, D., Ooi, G.T., McNamara, N.P. and Bending, G.D., 2022. Diversity and Ecological Guild Analysis of the Oil Palm Fungal Microbiome Across Root, Rhizosphere, and Soil Compartments.. Frontiers in microbiology. doi:10.3389/fmicb.2022.792928 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus 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 Aspergillus flavus Tan, L., Zeng, W.A., Xiao, Y., Li, P., Gu, S., Wu, S., Zhai, Z., Feng, K., Deng, Y. and Hu, Q., 2021. Fungi-bacteria associations in wilt diseased rhizosphere and endosphere by interdomain ecological network analysis. Frontiers in Microbiology. doi:10.3389/fmicb.2021.722626 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus 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 Aspergillus flavus Zhang, Y., Gao, C., Masum, M., Islam, M., Cheng, Y., Wei, C., Guan, Y. and Guan, J., 2021. Dynamic Microbiome Changes Reveal the Effect of 1-Methylcyclopropene Treatment on Reducing Post-harvest Fruit Decay in “Doyenne du Comice” Pear. Frontiers in Microbiology. doi:10.3389/fmicb.2021.729014 DOI
GloBI symbiontOf Aspergillus flavus Cordier, T., Robin, C., Capdevielle, X., Desprez-Loustau, M.L. and Vacher, C., 2012. Spatial variability of phyllosphere fungal assemblages: genetic distance predominates over geographic distance in a European beech stand (Fagus syluatica).. Fungal Ecology. doi:10.1016/j.funeco.2011.12.004 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Cruz, A.F., Barka, G.D., Blum, L.E.B., Tanaka, T., Ono, N., Kanaya, S. and Reineke, A., 2019. Evaluation of microbial communities in peels of Brazilian tropical fruits by amplicon sequence analysis.. Brazilian Journal of Microbiology. doi:10.1007/s42770-019-00088-0 DOI
GloBI symbiontOf Aspergillus flavus Chen, J., Zang, Y., Yang, Z., Qu, T., Sun, T., Liang, S., Zhu, M., Wang, Y. and Tang, X., 2022. Composition and Functional Diversity of Epiphytic Bacterial and Fungal Communities on Marine Macrophytes in an Intertidal Zone. Frontiers in Microbiology. doi:10.3389/fmicb.2022.839465 DOI
GloBI symbiontOf Aspergillus flavus Katsoula, A., Vasileiadis, S., Karamanoli, K., Vokou, D. and Karpouzas, D.G., 2021. Factors Structuring the Epiphytic Archaeal and Fungal Communities in a Semi-arid Mediterranean Ecosystem. Microbial ecology. doi:10.1007/s00248-021-01712-z DOI
GloBI symbiontOf Aspergillus flavus Fu, L., Ou, Y., Shen, Z., Wang, B., Li, R. and Shen, Q., 2019. Stable Microbial Community and Specific Beneficial Taxa Associated with Natural Healthy Banana Rhizosphere.. Journal of Microbiology and Biotechnology. doi:10.4014/jmb.1904.04061 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Kamutando, C.N., Vikram, S., Kamgan-Nkuekam, G., Makhalanyane, T.P., Greve, M., Le Roux, J.J., Richardson, D.M., Cowan, D. and Valverde, A., 2017. Soil nutritional status and biogeography influence rhizosphere microbial communities associated with the invasive tree Acacia dealbata.. Scientific Reports. doi:10.1038/s41598-017-07018-w DOI
GloBI symbiontOf Aspergillus flavus Vanegas, J., Munoz-García, A., Pérez-Parra, K.A., Figueroa-Galvis, I., Mestanza, O. and Polanía, J., 2019. Effect of salinity on fungal diversity in the rhizosphere of the halophyte Avicennia germinans from a semi-arid mangrove.. Fungal Ecology. doi:10.1016/j.funeco.2019.07.009 DOI
GloBI symbiontOf Aspergillus flavus Li, Y., Li, Z., Arafat, Y. and Lin, W., 2020. Studies on fungal communities and functional guilds shift in tea continuous cropping soils by high-throughput sequencing.. Annals of Microbiology. doi:10.1186/s13213-020-01555-y DOI
GloBI symbiontOf Aspergillus flavus Zhang, Z., Luo, L., Tan, X., Kong, X., Yang, J., Wang, D., Zhang, D., Jin, D. and Liu, Y., 2018. Pumpkin powdery mildew disease severity influences the fungal diversity of the phyllosphere.. PeerJ. doi:10.7717/peerj.4559 DOI
GloBI symbiontOf Aspergillus flavus Kemler, M., Garnas, J., Wingfield, M.J., Gryzenhout, M., Pillay, K.A. and Slippers, B., 2013. Ion Torrent PGM as tool for fungal community analysis: a case study of endophytes in Eucalyptus grandis reveals high taxonomic diversity.. PLoS One. doi:10.1371/journal.pone.0081718 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Franić, I., Prospero, S., Adamson, K., Allan, E., Attorre, F., Auger-Rozenberg, M.A., Augustin, S., Avtzis, D., Baert, W., Barta, M. and Bauters, K., 2022. Worldwide diversity of endophytic fungi and insects associated with dormant tree twigs.. Scientific Data. doi:10.1038/s41597-022-01162-3 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Barnes, C.J., Maldonado, C., Froslev, T.G., Antonelli, A. and Ronsted, N., 2016. Unexpectedly High Beta-Diversity of Root-Associated Fungal Communities in the Bolivian Andes.. Frontiers in Microbiology. doi:10.3389/fmicb.2016.01377 DOI
GloBI symbiontOf Aspergillus flavus Michael, P. J., Jones, D., White, N., Hane, J. K., Bunce, M., and Gibberd, M., 2020. Crop-Zone Weed Mycobiomes of the South-Western Australian Grain Belt. Frontiers in Microbiology. doi:10.3389/fmicb.2020.581592 DOI

pathogen pressure 6

GloBI pathogenOf Zea mays Gary P. Munkvold, collator (last update: 8/27/17). Diseases of Corn (syn. Maize) (Zea mays L.). The American Phytopathological Society. Accessed on 2019-10-24 at https://www.apsnet.org/edcenter/resources/commonnames/Pages/Corn.aspx
GloBI pathogenOf Arachis hypogaea D. Morris Porter, primary collator (last update 3/8/93). Diseases of Peanut (Arachis hypogaea L.). The American Phytopathological Society. Accessed on 2019-10-24 at https://www.apsnet.org/edcenter/resources/commonnames/Pages/Peanut.aspx
GloBI hasHost Zea mays https://mycoportal.org/portal/collections/individual/index.php?occid=1313848
GloBI hasHost Arachis hypogaea https://mycoportal.org/portal/collections/individual/index.php?occid=3565533
GloBI hasHost Saccharum officinarum https://mycoportal.org/portal/collections/individual/index.php?occid=1313985
GloBI hasHost Triticum aestivum https://mycoportal.org/portal/collections/individual/index.php?occid=3280112

crop interaction 45

GloBI pathogenOf Zea mays Gary P. Munkvold, collator (last update: 8/27/17). Diseases of Corn (syn. Maize) (Zea mays L.). The American Phytopathological Society. Accessed on 2019-10-24 at https://www.apsnet.org/edcenter/resources/commonnames/Pages/Corn.aspx
GloBI pathogenOf Arachis hypogaea D. Morris Porter, primary collator (last update 3/8/93). Diseases of Peanut (Arachis hypogaea L.). The American Phytopathological Society. Accessed on 2019-10-24 at https://www.apsnet.org/edcenter/resources/commonnames/Pages/Peanut.aspx
GloBI symbiontOf Aspergillus flavus Li, R., Yang, S., Lin, M., Guo, S., Han, X., Ren, M., Du, L., Song, Y., You, Y., Zhan, J. and Huang, W.,, 2021. The biogeography of fungal communities across different chinese wine-producing regions associated with environmental factors and spontaneous fermentation performance. Frontiers in microbiology. doi:10.3389/fmicb.2021.636639 DOI
GloBI symbiontOf Aspergillus flavus Wu, C., Wang, F., Ge, A., Zhang, H., Chen, G., Deng, Y., Yang, J., Chen, J. and Ge, T., 2021. Enrichment of microbial taxa after the onset of wheat yellow mosaic disease. Agriculture, Ecosystems & Environment. doi:10.1016/j.agee.2021.107651 DOI
GloBI hasHost Zea mays https://mycoportal.org/portal/collections/individual/index.php?occid=1313848
GloBI hasHost Arachis hypogaea https://mycoportal.org/portal/collections/individual/index.php?occid=3565533
GloBI symbiontOf Aspergillus flavus Veloso, T.G.R., da Silva, M.D.C.S., Cardoso, W.S., Guarçoni, R.C., Kasuya, M.C.M. and Pereira, L.L., 2020. Effects of environmental factors on microbiota of fruits and soil of Coffea arabica in Brazil.. Scientific Reports. doi:10.1038/s41598-020-71309-y DOI
GloBI symbiontOf Aspergillus flavus Ma, J., Ma, K., Liu, J. and Chen, N, 2022. Rhizosphere Soil Microbial Community Under Ice in a High-Latitude Wetland: Different Community Assembly Processes Shape Patterns of Rare and Abundant Microbes. Frontiers in microbiology. doi:10.3389/fmicb.2022.783371 DOI
GloBI symbiontOf Aspergillus flavus 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
GloBI symbiontOf Aspergillus flavus Longa, C.M.O., Antonielli, L., Bozza, E., Sicher, C., Pertot, I. and Perazzolli, M., 2022. Plant organ and sampling time point determine the taxonomic structure of microbial communities associated to apple plants in the orchard environment.. Microbiological Research. doi:10.1016/j.micres.2022.126991 DOI
GloBI symbiontOf Aspergillus flavus Cregger, M.A., Veach, A.M., Yang, Z.K., Crouch, M.J., Vilgalys, R., Tuskan, G.A. and Schadt, C.W., 2018. The Populus holobiont: dissecting the effects of plant niches and genotype on the microbiome.. Microbiome. doi:10.1186/s40168-018-0413-8 DOI
GloBI hasHost Saccharum officinarum https://mycoportal.org/portal/collections/individual/index.php?occid=1313985
GloBI symbiontOf Aspergillus flavus Ettinger, C.L., Vann, L.E. and Eisen, J.A., 2020. Global diversity and biogeography of the Zostera marina mycobiome.. bioRxiv. doi:10.1101/2020.10.29.361022 DOI
GloBI symbiontOf Aspergillus flavus Wang, W., Zhai, Y., Cao, L., Tan, H. and Zhang, R., 2016. Endophytic bacterial and fungal microbiota in sprouts, roots and stems of rice (Oryza sativa L.).. Microbiological Research. doi:10.1016/j.micres.2016.04.009 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus LI, X.D., Ming, S.H.I., Hong, P.A.N., LU, X.J., WEI, X.Y., Ping, L.U., LIAN, Q.X. and FU, Y.H., 2020. Diversity in metagenomic sequences reveals new pathogenic fungus associated with smut in Job�s tears. JOURNAL OF INTEGRATIVE AGRICULTURE. doi:10.1016/S2095-3119(20)63164-1 DOI
GloBI symbiontOf Aspergillus flavus 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 hasHost Triticum aestivum https://mycoportal.org/portal/collections/individual/index.php?occid=3280112
GloBI symbiontOf Aspergillus flavus Zhu, S., Wang, Y., Xu, X., Liu, T., Wu, D., Zheng, X., Tang, S. and Dai, Q., 2018. Potential use of high-throughput sequencing of soil microbial communities for estimating the adverse effects of continuous cropping on ramie (Boehmeria nivea L. Gaud).. PloS One. doi:10.1371/journal.pone.0197095 DOI
GloBI symbiontOf Aspergillus flavus Liu, Y., Lu, M., Zhang, X., Sun, Q., Liu, R. and Lian, B., 2019. Shift of the microbial communities from exposed sandstone rocks to forest soils during pedogenesis.. International Biodeterioration & Biodegradation. doi:10.1016/j.ibiod.2019.03.006 DOI
GloBI symbiontOf Aspergillus flavus Zhang, L., Yin, X., Zhang, J., Wei, Y., Huo, D., Ma, C., Chang, H., Cai, K. and Shi, H., 2021. Comprehensive microbiome and metabolome analyses reveal the physiological mechanism of chlorotic Areca leaves. TREE PHYSIOLOGY. doi:10.1093/treephys/tpaa112 DOI
GloBI symbiontOf Aspergillus flavus Kirkman, E.R., Hilton, S., Sethuraman, G., Elias, D.M., Taylor, A., Clarkson, J., Soh, A.C., Bass, D., Ooi, G.T., McNamara, N.P. and Bending, G.D., 2022. Diversity and Ecological Guild Analysis of the Oil Palm Fungal Microbiome Across Root, Rhizosphere, and Soil Compartments.. Frontiers in microbiology. doi:10.3389/fmicb.2022.792928 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus 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 Aspergillus flavus Tan, L., Zeng, W.A., Xiao, Y., Li, P., Gu, S., Wu, S., Zhai, Z., Feng, K., Deng, Y. and Hu, Q., 2021. Fungi-bacteria associations in wilt diseased rhizosphere and endosphere by interdomain ecological network analysis. Frontiers in Microbiology. doi:10.3389/fmicb.2021.722626 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus 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 Aspergillus flavus Zhang, Y., Gao, C., Masum, M., Islam, M., Cheng, Y., Wei, C., Guan, Y. and Guan, J., 2021. Dynamic Microbiome Changes Reveal the Effect of 1-Methylcyclopropene Treatment on Reducing Post-harvest Fruit Decay in “Doyenne du Comice” Pear. Frontiers in Microbiology. doi:10.3389/fmicb.2021.729014 DOI
GloBI symbiontOf Aspergillus flavus Cordier, T., Robin, C., Capdevielle, X., Desprez-Loustau, M.L. and Vacher, C., 2012. Spatial variability of phyllosphere fungal assemblages: genetic distance predominates over geographic distance in a European beech stand (Fagus syluatica).. Fungal Ecology. doi:10.1016/j.funeco.2011.12.004 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Cruz, A.F., Barka, G.D., Blum, L.E.B., Tanaka, T., Ono, N., Kanaya, S. and Reineke, A., 2019. Evaluation of microbial communities in peels of Brazilian tropical fruits by amplicon sequence analysis.. Brazilian Journal of Microbiology. doi:10.1007/s42770-019-00088-0 DOI
GloBI symbiontOf Aspergillus flavus Chen, J., Zang, Y., Yang, Z., Qu, T., Sun, T., Liang, S., Zhu, M., Wang, Y. and Tang, X., 2022. Composition and Functional Diversity of Epiphytic Bacterial and Fungal Communities on Marine Macrophytes in an Intertidal Zone. Frontiers in Microbiology. doi:10.3389/fmicb.2022.839465 DOI
GloBI symbiontOf Aspergillus flavus Katsoula, A., Vasileiadis, S., Karamanoli, K., Vokou, D. and Karpouzas, D.G., 2021. Factors Structuring the Epiphytic Archaeal and Fungal Communities in a Semi-arid Mediterranean Ecosystem. Microbial ecology. doi:10.1007/s00248-021-01712-z DOI
GloBI symbiontOf Aspergillus flavus Fu, L., Ou, Y., Shen, Z., Wang, B., Li, R. and Shen, Q., 2019. Stable Microbial Community and Specific Beneficial Taxa Associated with Natural Healthy Banana Rhizosphere.. Journal of Microbiology and Biotechnology. doi:10.4014/jmb.1904.04061 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Kamutando, C.N., Vikram, S., Kamgan-Nkuekam, G., Makhalanyane, T.P., Greve, M., Le Roux, J.J., Richardson, D.M., Cowan, D. and Valverde, A., 2017. Soil nutritional status and biogeography influence rhizosphere microbial communities associated with the invasive tree Acacia dealbata.. Scientific Reports. doi:10.1038/s41598-017-07018-w DOI
GloBI symbiontOf Aspergillus flavus Vanegas, J., Munoz-García, A., Pérez-Parra, K.A., Figueroa-Galvis, I., Mestanza, O. and Polanía, J., 2019. Effect of salinity on fungal diversity in the rhizosphere of the halophyte Avicennia germinans from a semi-arid mangrove.. Fungal Ecology. doi:10.1016/j.funeco.2019.07.009 DOI
GloBI symbiontOf Aspergillus flavus Li, Y., Li, Z., Arafat, Y. and Lin, W., 2020. Studies on fungal communities and functional guilds shift in tea continuous cropping soils by high-throughput sequencing.. Annals of Microbiology. doi:10.1186/s13213-020-01555-y DOI
GloBI symbiontOf Aspergillus flavus Zhang, Z., Luo, L., Tan, X., Kong, X., Yang, J., Wang, D., Zhang, D., Jin, D. and Liu, Y., 2018. Pumpkin powdery mildew disease severity influences the fungal diversity of the phyllosphere.. PeerJ. doi:10.7717/peerj.4559 DOI
GloBI symbiontOf Aspergillus flavus Kemler, M., Garnas, J., Wingfield, M.J., Gryzenhout, M., Pillay, K.A. and Slippers, B., 2013. Ion Torrent PGM as tool for fungal community analysis: a case study of endophytes in Eucalyptus grandis reveals high taxonomic diversity.. PLoS One. doi:10.1371/journal.pone.0081718 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Franić, I., Prospero, S., Adamson, K., Allan, E., Attorre, F., Auger-Rozenberg, M.A., Augustin, S., Avtzis, D., Baert, W., Barta, M. and Bauters, K., 2022. Worldwide diversity of endophytic fungi and insects associated with dormant tree twigs.. Scientific Data. doi:10.1038/s41597-022-01162-3 DOI
GloBI symbiontOf Aspergillus flavus 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 Aspergillus flavus Barnes, C.J., Maldonado, C., Froslev, T.G., Antonelli, A. and Ronsted, N., 2016. Unexpectedly High Beta-Diversity of Root-Associated Fungal Communities in the Bolivian Andes.. Frontiers in Microbiology. doi:10.3389/fmicb.2016.01377 DOI
GloBI symbiontOf Aspergillus flavus Michael, P. J., Jones, D., White, N., Hane, J. K., Bunce, M., and Gibberd, M., 2020. Crop-Zone Weed Mycobiomes of the South-Western Australian Grain Belt. Frontiers in Microbiology. doi:10.3389/fmicb.2020.581592 DOI

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