taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
E589579948FE59319CC5CA861302B00C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232708	https://doi.org/10.3897/mycokeys.113.140031.figure3	Figure 3. Dothiorella macadamiae (CMUB 40066, holotype) a – c appearance of ascomata on the host surface d vertical section of an ascoma e peridium f hamathecium g – i asci j – n ascospores (arrows indicate mucilaginous polar appendages) o a germinating ascospore p, q colony on PDA (p-front and q-reverse views). Scale bars: 200 µm (d); 100 µm (i); 50 µm (e, g, h); 10 µm (f, j – o).	Figure 3. Dothiorella macadamiae (CMUB 40066, holotype) a – c appearance of ascomata on the host surface d vertical section of an ascoma e peridium f hamathecium g – i asci j – n ascospores (arrows indicate mucilaginous polar appendages) o a germinating ascospore p, q colony on PDA (p-front and q-reverse views). Scale bars: 200 µm (d); 100 µm (i); 50 µm (e, g, h); 10 µm (f, j – o).	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
E589579948FE59319CC5CA861302B00C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232709	https://doi.org/10.3897/mycokeys.113.140031.figure4	Figure 4. Dothiorella macadamiae (SDBR-CMU 512, ex-type) a colony on PDA b, c sporulating colonies on PDA d, e chlamydospores f – h conidiogenous cells with conidia i – j Conidia. Scale bars: 100 µm (d); 50 µm (e); 20 µm (f – h, j); 5 µm (i).	Figure 4. Dothiorella macadamiae (SDBR-CMU 512, ex-type) a colony on PDA b, c sporulating colonies on PDA d, e chlamydospores f – h conidiogenous cells with conidia i – j Conidia. Scale bars: 100 µm (d); 50 µm (e); 20 µm (f – h, j); 5 µm (i).	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
E589579948FE59319CC5CA861302B00C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232706	https://doi.org/10.3897/mycokeys.113.140031.figure1	Figure 1. RAxML tree based on a combined dataset of ITS, tef 1 - α, and TUB 2 gene sequences data, which comprised 1265 base pairs (ITS = 1–527 bp, tef 1 - α = 528–818 bp, TUB 2 = 819–1265 bp). The best scoring RAxML tree with a final ML optimization likelihood value of - 8702.022443 is presented. The matrix had 696 distinct alignment patterns, with 16.83 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.209011, C = 0.306672, G = 0.250984, T = 0.233333; substitution rates: AC = 1.037189, AG = 2.254040, AT = 1.059283, CG = 1.045839, CT = 4.497195, GT = 1.000000; proportion of invariable sites I = 0.499857; gamma distribution shape parameter α = 0.610523. The ML analysis and Bayesian inference (BI) analyses showed nearly identical tree topologies, bootstrap support values for ML equal to or greater than 60 %, and BI analysis values equal to or greater than 0.90 PP are given at each node. The tree is rooted with Neofusicoccum luteum (CBS 562.92) and N. luteum (CMW 41365). Newly generated species are shown in red, while the ex-type species are shown in bold. Remarks: The ML bootstrap value less than 60 % is presented on the node of the new taxon.	Figure 1. RAxML tree based on a combined dataset of ITS, tef 1 - α, and TUB 2 gene sequences data, which comprised 1265 base pairs (ITS = 1–527 bp, tef 1 - α = 528–818 bp, TUB 2 = 819–1265 bp). The best scoring RAxML tree with a final ML optimization likelihood value of - 8702.022443 is presented. The matrix had 696 distinct alignment patterns, with 16.83 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.209011, C = 0.306672, G = 0.250984, T = 0.233333; substitution rates: AC = 1.037189, AG = 2.254040, AT = 1.059283, CG = 1.045839, CT = 4.497195, GT = 1.000000; proportion of invariable sites I = 0.499857; gamma distribution shape parameter α = 0.610523. The ML analysis and Bayesian inference (BI) analyses showed nearly identical tree topologies, bootstrap support values for ML equal to or greater than 60 %, and BI analysis values equal to or greater than 0.90 PP are given at each node. The tree is rooted with Neofusicoccum luteum (CBS 562.92) and N. luteum (CMW 41365). Newly generated species are shown in red, while the ex-type species are shown in bold. Remarks: The ML bootstrap value less than 60 % is presented on the node of the new taxon.	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
E589579948FE59319CC5CA861302B00C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232707	https://doi.org/10.3897/mycokeys.113.140031.figure2	Figure 2. Results of the PHI test of Dothiorella macadamiae and closely related species using both LogDet transformation and splits decomposition. The PHI test results (Φw) < 0.05 indicate significant recombination within the dataset. The new taxa are in red font, and bold indicates holotype or ex-type strains.	Figure 2. Results of the PHI test of Dothiorella macadamiae and closely related species using both LogDet transformation and splits decomposition. The PHI test results (Φw) < 0.05 indicate significant recombination within the dataset. The new taxa are in red font, and bold indicates holotype or ex-type strains.	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
94D6638637F85FBCA297EA7D71410B91.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232713	https://doi.org/10.3897/mycokeys.113.140031.figure8	Figure 8. Melomastia puerensis (GMB 1173, new host record) a, b appearance of ascomata on the host surface c section of peridium d vertical section of an ascoma e ocular chamber in lactophenol cotton blue reagent f, k hamathecium g – j asci l – p ascospores. Scale bars: 200 µm (d); 100 µm (g – j); 50 µm (k); 20 µm (c, f); 10 µm (l – p).	Figure 8. Melomastia puerensis (GMB 1173, new host record) a, b appearance of ascomata on the host surface c section of peridium d vertical section of an ascoma e ocular chamber in lactophenol cotton blue reagent f, k hamathecium g – j asci l – p ascospores. Scale bars: 200 µm (d); 100 µm (g – j); 50 µm (k); 20 µm (c, f); 10 µm (l – p).	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
94D6638637F85FBCA297EA7D71410B91.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232712	https://doi.org/10.3897/mycokeys.113.140031.figure7	Figure 7. RAxML tree based on a combined dataset of LSU + SSU + tef 1 - α gene sequences. The topology of the trees generated by both maximum likelihood (ML) and Bayesian inference (BI) analyses exhibited high similarity. The RAxML tree with a final ML optimization likelihood value of - 12726.117171. The aligned matrix had 933 distinct alignment patterns, with 22.57 % of undetermined characters or gaps. Parameters for the GTR + I + G model of the combined LSU, tef 1 - α, and the SYM + I + G model of the combined SSU were as follows: estimated base frequencies A = 0.239385, C = 0.263871, G = 0.289634, T = 0.207110; substitution rates AC = 0.851550, AG = 2.071762, AT = 1.124966, CG = 0.971448, CT = 7.978925, GT = 1.000000; the proportion of invariable sites I = 0.478880; and gamma distribution shape parameter α = 0.661129. Bootstrap support values for ML equal to or greater than 60 % and PP equal to or greater than 0.90 are given above the nodes. New records are in blue, while the ex-type species are in bold.	Figure 7. RAxML tree based on a combined dataset of LSU + SSU + tef 1 - α gene sequences. The topology of the trees generated by both maximum likelihood (ML) and Bayesian inference (BI) analyses exhibited high similarity. The RAxML tree with a final ML optimization likelihood value of - 12726.117171. The aligned matrix had 933 distinct alignment patterns, with 22.57 % of undetermined characters or gaps. Parameters for the GTR + I + G model of the combined LSU, tef 1 - α, and the SYM + I + G model of the combined SSU were as follows: estimated base frequencies A = 0.239385, C = 0.263871, G = 0.289634, T = 0.207110; substitution rates AC = 0.851550, AG = 2.071762, AT = 1.124966, CG = 0.971448, CT = 7.978925, GT = 1.000000; the proportion of invariable sites I = 0.478880; and gamma distribution shape parameter α = 0.661129. Bootstrap support values for ML equal to or greater than 60 % and PP equal to or greater than 0.90 are given above the nodes. New records are in blue, while the ex-type species are in bold.	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
0F259A37CB2E5BEC923DEFA468A7C75E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232711	https://doi.org/10.3897/mycokeys.113.140031.figure6	Figure 6. Phaeoacremonium chiangmaiense (CMUB 40065, holotype) a, b appearance of ascomata on the host surface c vertical section of ascomata d ostiolar canal e section of peridium f, g hamathecium h – j ascogenous hyphae with asci attached k – n ascospores o germinated ascospores p, q colonies on PDA (p-front and q-reverse views). Scale bars: 100 µm (c); 40 µm (d); 20 µm (e, f, h – j); 10 µm (g, o); 5 µm (k – n).	Figure 6. Phaeoacremonium chiangmaiense (CMUB 40065, holotype) a, b appearance of ascomata on the host surface c vertical section of ascomata d ostiolar canal e section of peridium f, g hamathecium h – j ascogenous hyphae with asci attached k – n ascospores o germinated ascospores p, q colonies on PDA (p-front and q-reverse views). Scale bars: 100 µm (c); 40 µm (d); 20 µm (e, f, h – j); 10 µm (g, o); 5 µm (k – n).	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
0F259A37CB2E5BEC923DEFA468A7C75E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://binary.pensoft.net/fig/1232710	https://doi.org/10.3897/mycokeys.113.140031.figure5	Figure 5. RAxML tree based on a combined dataset of ITS + TUB 2 + ACT + tef 1 - α + LSU gene sequences data, which comprised 2709 base pairs (ITS = 1–600 bp, TUB 2 = 601–1237 bp, ACT = 1238–1499 bp, tef 1 - α = 1500–1816 bp, LSU = 1817–2709 bp). The best-scoring RAxML tree with a final ML optimization likelihood value of - 29286.426085 is presented. The matrix had 1400 distinct alignment patterns, with 45.73 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.224680, C = 0.290688, G = 0.252826, T = 0.231806; substitution rates: AC = 1.466922, AG = 3.673841, AT = 1.453901, CG = 1.188614, CT = 5.325402, GT = 1.000000; proportion of invariable sites I = 0.385193; gamma distribution shape parameter α = 0.691947. The bootstrap support values for ML are equal to or greater than 60 %, and BI analysis values are equal to or greater than 0.90 PP at each node. The tree is rooted with Flabellascus tenuirostris (CBS 138680) and Jattaea algeriensis (STE-U 6201). Newly generated species are shown in red, while the ex-type species are shown in bold.	Figure 5. RAxML tree based on a combined dataset of ITS + TUB 2 + ACT + tef 1 - α + LSU gene sequences data, which comprised 2709 base pairs (ITS = 1–600 bp, TUB 2 = 601–1237 bp, ACT = 1238–1499 bp, tef 1 - α = 1500–1816 bp, LSU = 1817–2709 bp). The best-scoring RAxML tree with a final ML optimization likelihood value of - 29286.426085 is presented. The matrix had 1400 distinct alignment patterns, with 45.73 % of undetermined characters or gaps. Estimated base frequencies were as follows: A = 0.224680, C = 0.290688, G = 0.252826, T = 0.231806; substitution rates: AC = 1.466922, AG = 3.673841, AT = 1.453901, CG = 1.188614, CT = 5.325402, GT = 1.000000; proportion of invariable sites I = 0.385193; gamma distribution shape parameter α = 0.691947. The bootstrap support values for ML are equal to or greater than 60 %, and BI analysis values are equal to or greater than 0.90 PP at each node. The tree is rooted with Flabellascus tenuirostris (CBS 138680) and Jattaea algeriensis (STE-U 6201). Newly generated species are shown in red, while the ex-type species are shown in bold.	2025-01-24	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han		Zenodo	biologists	Zhang, Xian;Tibpromma, Saowaluck;Karunarathna, Samantha C.;Du, Tian-Ye;Han, Li-Su;Elgorban, Abdallah M.;Kumla, Jaturong;Senwanna, Chanokned;Dai, Dong-Qin;Suwannarach, Nakarin;Wang, Hao-Han			
