taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
9AB1A9EB35075922B58C74699725C4C0.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217442	https://doi.org/10.3897/mycokeys.112.139831.figure3	Figure 3. Aquilariomyces maomingensis (MHZU 23-0022, holotype) A – C appearance of ascomata on the host (the arrows indicate ascomata) D, E vertical sections through the ascomata (the arrows indicate ostioles) F ostiole with periphyses G short fluffs around the periphery of the ascomata H peridium I, J trabeculae pseudoparaphyses (J the arrows indicate septate pseudoparaphyses) K – N asci O a club-shaped pedicel P – U ascospores (S stained with Indian ink) V germinated ascospore W, X colonies on PDA obverse and reverse views. Scale bars: 200 µm (D – F); 30 µm (G, H); 10 µm (I); 50 µm (K – N); 20 µm (P – V).	Figure 3. Aquilariomyces maomingensis (MHZU 23-0022, holotype) A – C appearance of ascomata on the host (the arrows indicate ascomata) D, E vertical sections through the ascomata (the arrows indicate ostioles) F ostiole with periphyses G short fluffs around the periphery of the ascomata H peridium I, J trabeculae pseudoparaphyses (J the arrows indicate septate pseudoparaphyses) K – N asci O a club-shaped pedicel P – U ascospores (S stained with Indian ink) V germinated ascospore W, X colonies on PDA obverse and reverse views. Scale bars: 200 µm (D – F); 30 µm (G, H); 10 µm (I); 50 µm (K – N); 20 µm (P – V).	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
9AB1A9EB35075922B58C74699725C4C0.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217441	https://doi.org/10.3897/mycokeys.112.139831.figure2	Figure 2. Phylogram generated from maximum likelihood (ML) analysis based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 52 taxa, which comprised 4387 base pairs of LSU = 967, ITS = 516, SSU = 872, rpb 2 = 1024, tef 1 - α = 1008. The best-scoring RAxML tree with a final likelihood value of - 31596.745436 is presented. The matrix had 2090 distinct alignment patterns, with 47.13 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.249245, C = 0.257277, G = 0.271627, T = 0.221851; substitution rates: AC = 1.210949, AG = 2.948777, AT = 1.318881, CG = 0.897105, CT = 6.444599, GT = 1.0; gamma distribution shape parameter α = 0.441696. Bootstrap support values for ML equal to or greater than 70 % and clade credibility values equal to or greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Trematosphaeria pertusa (CBS 122368). The new isolates are indicated in red, and the ex-type strains are in bold.	Figure 2. Phylogram generated from maximum likelihood (ML) analysis based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 52 taxa, which comprised 4387 base pairs of LSU = 967, ITS = 516, SSU = 872, rpb 2 = 1024, tef 1 - α = 1008. The best-scoring RAxML tree with a final likelihood value of - 31596.745436 is presented. The matrix had 2090 distinct alignment patterns, with 47.13 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.249245, C = 0.257277, G = 0.271627, T = 0.221851; substitution rates: AC = 1.210949, AG = 2.948777, AT = 1.318881, CG = 0.897105, CT = 6.444599, GT = 1.0; gamma distribution shape parameter α = 0.441696. Bootstrap support values for ML equal to or greater than 70 % and clade credibility values equal to or greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Trematosphaeria pertusa (CBS 122368). The new isolates are indicated in red, and the ex-type strains are in bold.	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
9AB1A9EB35075922B58C74699725C4C0.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217443	https://doi.org/10.3897/mycokeys.112.139831.figure4	Figure 4. Comparison of morphological structure between Aquilariomyces maomingensis and Aq. aquilariae. Aquilariomyces maomingensis (MHZU 23-0022 holotype) A ascomata wrapped in short fluffs B micrograph of fluffs C brown ascospores. Aquilariomyces aquilariae (MHZU 23-0036, holotype) (Du et al. 2024 b) D ascomata wrapped in long fluffs E micrograph of fluffs F hyaline ascospores. Scale bars: 20 µm (B, C, E, F).	Figure 4. Comparison of morphological structure between Aquilariomyces maomingensis and Aq. aquilariae. Aquilariomyces maomingensis (MHZU 23-0022 holotype) A ascomata wrapped in short fluffs B micrograph of fluffs C brown ascospores. Aquilariomyces aquilariae (MHZU 23-0036, holotype) (Du et al. 2024 b) D ascomata wrapped in long fluffs E micrograph of fluffs F hyaline ascospores. Scale bars: 20 µm (B, C, E, F).	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
0354648CCFF0581C973EC0C8FA855A58.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217441	https://doi.org/10.3897/mycokeys.112.139831.figure2	Figure 2. Phylogram generated from maximum likelihood (ML) analysis based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 52 taxa, which comprised 4387 base pairs of LSU = 967, ITS = 516, SSU = 872, rpb 2 = 1024, tef 1 - α = 1008. The best-scoring RAxML tree with a final likelihood value of - 31596.745436 is presented. The matrix had 2090 distinct alignment patterns, with 47.13 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.249245, C = 0.257277, G = 0.271627, T = 0.221851; substitution rates: AC = 1.210949, AG = 2.948777, AT = 1.318881, CG = 0.897105, CT = 6.444599, GT = 1.0; gamma distribution shape parameter α = 0.441696. Bootstrap support values for ML equal to or greater than 70 % and clade credibility values equal to or greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Trematosphaeria pertusa (CBS 122368). The new isolates are indicated in red, and the ex-type strains are in bold.	Figure 2. Phylogram generated from maximum likelihood (ML) analysis based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 52 taxa, which comprised 4387 base pairs of LSU = 967, ITS = 516, SSU = 872, rpb 2 = 1024, tef 1 - α = 1008. The best-scoring RAxML tree with a final likelihood value of - 31596.745436 is presented. The matrix had 2090 distinct alignment patterns, with 47.13 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.249245, C = 0.257277, G = 0.271627, T = 0.221851; substitution rates: AC = 1.210949, AG = 2.948777, AT = 1.318881, CG = 0.897105, CT = 6.444599, GT = 1.0; gamma distribution shape parameter α = 0.441696. Bootstrap support values for ML equal to or greater than 70 % and clade credibility values equal to or greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Trematosphaeria pertusa (CBS 122368). The new isolates are indicated in red, and the ex-type strains are in bold.	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
F92CA6908D2150B1B93EE087EFFB5B9A.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217445	https://doi.org/10.3897/mycokeys.112.139831.figure6	Figure 6. Mangifericomes aquilariae (GMB-W 1008, holotype) A, B ascomata on the host (the arrow indicates the cross-section of the ascomata) C vertical sections through the ascomata D peridium E, K cellular pseudoparaphyses (E stained with cotton blue) F ocular chamber of asci G – J asci L – R ascospores (the arrows indicate the sheath of the ascospores) S germinated ascospore T, U colony on PDA obverse and reverse views. Scale bars: 200 µm (C); 20 µm (D, G, L – S); 10 µm (E, K); 100 µm (F, H – J).	Figure 6. Mangifericomes aquilariae (GMB-W 1008, holotype) A, B ascomata on the host (the arrow indicates the cross-section of the ascomata) C vertical sections through the ascomata D peridium E, K cellular pseudoparaphyses (E stained with cotton blue) F ocular chamber of asci G – J asci L – R ascospores (the arrows indicate the sheath of the ascospores) S germinated ascospore T, U colony on PDA obverse and reverse views. Scale bars: 200 µm (C); 20 µm (D, G, L – S); 10 µm (E, K); 100 µm (F, H – J).	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
F92CA6908D2150B1B93EE087EFFB5B9A.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217444	https://doi.org/10.3897/mycokeys.112.139831.figure5	Figure 5. Phylogram generated from ML analysis of Pleosporales based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 159 taxa, which comprised 4584 base pairs of LSU = 1201, ITS = 534, SSU = 1018, rpb 2 = 930, tef 1 - α = 901. The best-scoring RAxML tree with a final likelihood value of - 91408.743991 is presented. The matrix had 3121 distinct alignment patterns, with 41.32 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.246701, C = 0.244302, G = 0.274425, T = 0.234571; substitution rates: AC = 1.391138, AG = 3.919388, AT = 1.582417, CG = 1.094328, CT = 7.887132, GT = 1.0; gamma distribution shape parameter α = 0.418663. Bootstrap support values for maximum likelihood (ML) equal to or greater than 70 % and clade credibility values greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Orbilia auricolor (AFTOL-ID 906) and O. vinosa (AFTOL-ID 905). The new isolates are indicated in red, and the ex-type strains are in bold.	Figure 5. Phylogram generated from ML analysis of Pleosporales based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 159 taxa, which comprised 4584 base pairs of LSU = 1201, ITS = 534, SSU = 1018, rpb 2 = 930, tef 1 - α = 901. The best-scoring RAxML tree with a final likelihood value of - 91408.743991 is presented. The matrix had 3121 distinct alignment patterns, with 41.32 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.246701, C = 0.244302, G = 0.274425, T = 0.234571; substitution rates: AC = 1.391138, AG = 3.919388, AT = 1.582417, CG = 1.094328, CT = 7.887132, GT = 1.0; gamma distribution shape parameter α = 0.418663. Bootstrap support values for maximum likelihood (ML) equal to or greater than 70 % and clade credibility values greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Orbilia auricolor (AFTOL-ID 906) and O. vinosa (AFTOL-ID 905). The new isolates are indicated in red, and the ex-type strains are in bold.	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
FB92B032851251EEBC263F4A6C83A5B5.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1217444	https://doi.org/10.3897/mycokeys.112.139831.figure5	Figure 5. Phylogram generated from ML analysis of Pleosporales based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 159 taxa, which comprised 4584 base pairs of LSU = 1201, ITS = 534, SSU = 1018, rpb 2 = 930, tef 1 - α = 901. The best-scoring RAxML tree with a final likelihood value of - 91408.743991 is presented. The matrix had 3121 distinct alignment patterns, with 41.32 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.246701, C = 0.244302, G = 0.274425, T = 0.234571; substitution rates: AC = 1.391138, AG = 3.919388, AT = 1.582417, CG = 1.094328, CT = 7.887132, GT = 1.0; gamma distribution shape parameter α = 0.418663. Bootstrap support values for maximum likelihood (ML) equal to or greater than 70 % and clade credibility values greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Orbilia auricolor (AFTOL-ID 906) and O. vinosa (AFTOL-ID 905). The new isolates are indicated in red, and the ex-type strains are in bold.	Figure 5. Phylogram generated from ML analysis of Pleosporales based on combined LSU, ITS, SSU, tef 1 - α, and rpb 2 sequence data of 159 taxa, which comprised 4584 base pairs of LSU = 1201, ITS = 534, SSU = 1018, rpb 2 = 930, tef 1 - α = 901. The best-scoring RAxML tree with a final likelihood value of - 91408.743991 is presented. The matrix had 3121 distinct alignment patterns, with 41.32 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.246701, C = 0.244302, G = 0.274425, T = 0.234571; substitution rates: AC = 1.391138, AG = 3.919388, AT = 1.582417, CG = 1.094328, CT = 7.887132, GT = 1.0; gamma distribution shape parameter α = 0.418663. Bootstrap support values for maximum likelihood (ML) equal to or greater than 70 % and clade credibility values greater than 0.90 from Bayesian inference analysis are labelled at each node. The tree is rooted with Orbilia auricolor (AFTOL-ID 906) and O. vinosa (AFTOL-ID 905). The new isolates are indicated in red, and the ex-type strains are in bold.	2025-01-13	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck		Zenodo	biologists	Du, Tian-Ye;Karunarathna, Samantha C.;Hyde, Kevin D.;Nilthong, Somrudee;Mapook, Ausana;Dai, Dong-Qin;Rajeshkumar, Kunhiraman C.;Elgorban, Abdallah M.;Han, Li-Su;Wang, Hao-Han;Tibpromma, Saowaluck			
