Diaporthe pseudophoenicicola
- Category
- fungi
- Primary role
- pathogen fungal
- Class
- Sordariomycetes
- Order
- Diaporthales
- Family
- Diaporthaceae
- Genus
- Diaporthe
Fungi | Ascomycota | Sordariomycetes | Diaporthales | Diaporthaceae | Diaporthe
External: GBIF #8109236
0 AI-consensus-verified claims .
No verified claims involving this entity yet.
Genus-level evidence
4 claims where the source named the organism only at the genus or collective level (e.g. Diaporthe sp.) and did not determine the species. Listed separately because they apply to the genus, not specifically to Diaporthe pseudophoenicicola.
- pathogen pressure · Diaporthe sp. → Citrus x paradisi · effect: harmful
“Grapefruit ... Melanose”
University of Guam Cooperative Extension & Outreach (2024) · Guam Fruit and Vegetable Pesticide Guide, 6th Edition · p. 155 #6735157 - pathogen pressure · Diaporthe sp. → Citrus x limon · effect: harmful
“Lemon ... Melanose”
University of Guam Cooperative Extension & Outreach (2024) · Guam Fruit and Vegetable Pesticide Guide, 6th Edition · p. 164 #6735235 - pathogen pressure · Diaporthe sp. → Citrus x aurantiifolia · effect: harmful
“Lime ... Melanose”
University of Guam Cooperative Extension & Outreach (2024) · Guam Fruit and Vegetable Pesticide Guide, 6th Edition · p. 170 #6735290 - pathogen pressure · Diaporthe sp. → Citrus X sinensis · effect: harmful
“Orange ... Melanose”
University of Guam Cooperative Extension & Outreach (2024) · Guam Fruit and Vegetable Pesticide Guide, 6th Edition · p. 180 #6735371
Aggregated via GloBI — not independently verified by AgroEco.
mutualism 7
- GloBI symbiontOf Diaporthe pseudophoenicicola 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 Diaporthe pseudophoenicicola Oono, R., Rasmussen, A. and Lefevre, E., 2017. Distance decay relationships in foliar fungal endophytes are driven by rare taxa.. Environmental Microbiology. doi:10.1111/1462-2920.1379 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola 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 Diaporthe pseudophoenicicola Ruan, R., Jiang, Z., Wu, Y., Xu, M. and Ni, J., 2019. High-throughput sequence analysis reveals variation in the relative abundance of components of the bacterial and fungal microbiota in the rhizosphere of Ginkgo biloba.. PeerJ. doi:10.7717/peerj.8051 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Griffin, E. A., Harrison, J. G., McCormick, M. K., Burghardt, K. T. and Parker, J. D., 2019. Tree Diversity Reduces Fungal Endophyte Richness and Diversity in a Large-Scale Temperate Forest Experiment.. Diversity. doi:10.3390/d11120234 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Sun, X., Li, J.L., He, C., Li, X.C. and Guo, L.D., 2021. Specific network and phylosymbiosis pattern in endophyte community of coastal halophytes. Fungal Ecology. doi:10.1016/j.funeco.2021.101088 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Fukasawa, Y., Matsukura, K., Stephan, J.G., Makoto, K., Suzuki, S.N., Kominami, Y., Takagi, M., Tanaka, N., Takemoto, S., Kinuura, H. and Okano, K., 2021. Patterns of community composition and diversity in latent fungi of living Quercus serrata trunks across a range of oak wilt prevalence and climate variables in Japan. Fungal Ecology. doi:10.1016/j.funeco.2021.101095 DOI
crop interaction 7
- GloBI symbiontOf Diaporthe pseudophoenicicola 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 Diaporthe pseudophoenicicola Oono, R., Rasmussen, A. and Lefevre, E., 2017. Distance decay relationships in foliar fungal endophytes are driven by rare taxa.. Environmental Microbiology. doi:10.1111/1462-2920.1379 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola 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 Diaporthe pseudophoenicicola Ruan, R., Jiang, Z., Wu, Y., Xu, M. and Ni, J., 2019. High-throughput sequence analysis reveals variation in the relative abundance of components of the bacterial and fungal microbiota in the rhizosphere of Ginkgo biloba.. PeerJ. doi:10.7717/peerj.8051 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Griffin, E. A., Harrison, J. G., McCormick, M. K., Burghardt, K. T. and Parker, J. D., 2019. Tree Diversity Reduces Fungal Endophyte Richness and Diversity in a Large-Scale Temperate Forest Experiment.. Diversity. doi:10.3390/d11120234 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Sun, X., Li, J.L., He, C., Li, X.C. and Guo, L.D., 2021. Specific network and phylosymbiosis pattern in endophyte community of coastal halophytes. Fungal Ecology. doi:10.1016/j.funeco.2021.101088 DOI
- GloBI symbiontOf Diaporthe pseudophoenicicola Fukasawa, Y., Matsukura, K., Stephan, J.G., Makoto, K., Suzuki, S.N., Kominami, Y., Takagi, M., Tanaka, N., Takemoto, S., Kinuura, H. and Okano, K., 2021. Patterns of community composition and diversity in latent fungi of living Quercus serrata trunks across a range of oak wilt prevalence and climate variables in Japan. Fungal Ecology. doi:10.1016/j.funeco.2021.101095 DOI