taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
482787C8FFDE4B6CF6BA854BFE90E614.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739041/files/figure.png	https://doi.org/10.5281/zenodo.5739041	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDE4B6CF6BA854BFE90E614.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739039/files/figure.png	https://doi.org/10.5281/zenodo.5739039	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDE4B6CF6BA854BFE90E614.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739043/files/figure.png	https://doi.org/10.5281/zenodo.5739043	Fig. 4. A maximum-likelihood phylogenetic tree of the genus Hymenolepis. The tree was made with sequences of mitochondrial cox1 (456 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (18AK285, 19AK270, H22B, JA173, JA175, JA220, and JA244) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Rodentolepis nana (accession no. LC063187) was used as an outgroup taxon.	Fig. 4. A maximum-likelihood phylogenetic tree of the genus Hymenolepis. The tree was made with sequences of mitochondrial cox1 (456 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (18AK285, 19AK270, H22B, JA173, JA175, JA220, and JA244) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Rodentolepis nana (accession no. LC063187) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDC4B6DF41385AAFECEE87E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739041/files/figure.png	https://doi.org/10.5281/zenodo.5739041	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDC4B6DF41385AAFECEE87E.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739045/files/figure.png	https://doi.org/10.5281/zenodo.5739045	Fig. 5. A maximum-likelihood phylogenetic tree of the genus Arostrilepis. The tree was made with sequences of mitochondrial cytb (558 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (19AK170, 19AK439, 19AK454, and 19AK459) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Hymenolepis diminuta (accession no. AF314223) was used as an outgroup taxon.	Fig. 5. A maximum-likelihood phylogenetic tree of the genus Arostrilepis. The tree was made with sequences of mitochondrial cytb (558 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (19AK170, 19AK439, 19AK454, and 19AK459) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Hymenolepis diminuta (accession no. AF314223) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDD4B62F6BA8760FDADE7B9.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739041/files/figure.png	https://doi.org/10.5281/zenodo.5739041	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	Fig. 3. Adult tapeworms of Hymenolepis sp. 1, Arostrilepis tenuicirrosa, and Microsomacanthus sp. A, Scolex of Hymenolepis sp. 1; B, mature proglottids of Hymenolepis sp. 1; C, scolex of A. tenuicirrosa; D, mature proglottid of A. tenuicirrosa; E, gravid proglottid of A. tenuicirrosa; F, whole body of Microsomacanthus sp.; G, scolex of Microsomacanthus sp.; H, mature proglottids of Microsomacanthus sp. Scale bars: A, C, G, 200µm; B, D, 500µm; E, 1mm; F, 2mm; G, 100µm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFDD4B62F6BA8760FDADE7B9.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739039/files/figure.png	https://doi.org/10.5281/zenodo.5739039	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD24B63F66C87E2FC6AE533.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739047/files/figure.png	https://doi.org/10.5281/zenodo.5739047	Fig. 6. Adult tapeworms of Paranoplocephala kalelai, Catenotaenia sp., and Raillietina sp. A, Scolex of P. kalelai; B, mature proglottid of P. kalelai; C, gravid proglottid of P. kalelai; D, scolex of Catenotaenia sp.; E, mature proglottid Catenotaenia sp.; F, gravid proglottids of Catenotaenia sp.; G, scolex of Raillietina sp.; H, mature proglottids of Raillietina sp. Scale bars: A–C, E, H, 500µm; D, G, 200µm; F, 1mm.	Fig. 6. Adult tapeworms of Paranoplocephala kalelai, Catenotaenia sp., and Raillietina sp. A, Scolex of P. kalelai; B, mature proglottid of P. kalelai; C, gravid proglottid of P. kalelai; D, scolex of Catenotaenia sp.; E, mature proglottid Catenotaenia sp.; F, gravid proglottids of Catenotaenia sp.; G, scolex of Raillietina sp.; H, mature proglottids of Raillietina sp. Scale bars: A–C, E, H, 500µm; D, G, 200µm; F, 1mm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD24B63F66C87E2FC6AE533.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739049/files/figure.png	https://doi.org/10.5281/zenodo.5739049	Fig. 7. A maximum-likelihood phylogenetic tree of the genus Paranoplocephala. The tree was made with mitochondrial cox1 sequences (546 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (19AK378, 19AK412, 19AK419, 19AK436, 19AK454-2, and 19AK454-3) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Hymenolepis diminuta (accession no. AF314223) was used as an outgroup taxon.	Fig. 7. A maximum-likelihood phylogenetic tree of the genus Paranoplocephala. The tree was made with mitochondrial cox1 sequences (546 nucleotide sites) under the substitutional model GTR+G+I. The isolates of this study (19AK378, 19AK412, 19AK419, 19AK436, 19AK454-2, and 19AK454-3) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Hymenolepis diminuta (accession no. AF314223) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD24B63F66C87E2FC6AE533.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739039/files/figure.png	https://doi.org/10.5281/zenodo.5739039	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	Fig. 2. A maximum likelihood phylogenetic tree of the families Hymenolepididae, Anoplocephalidae, Catenotaeniidae, and Davaineidae. The tree was made with sequences of 28S rDNA (1137 nucleotide sites) under the substitutional model GTR+G. The isolates of this study (19AK270, JA175, 19AK170, JA313, 19AK378, AMU, and Para33SI) are shown in bold face. The DNA accession number of each taxon is shown in parenthesis. Bootstrap percentages are shown on each node. Scale bar indicates the number of substitutions per nucleotide site. Dibothriocephalus nihonkaiensis (accession no. LC474508) was used as an outgroup taxon.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD14B61F439854BFAC3E40F.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739053/files/figure.png	https://doi.org/10.5281/zenodo.5739053	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD14B61F42C8025FE5CE657.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739053/files/figure.png	https://doi.org/10.5281/zenodo.5739053	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
482787C8FFD14B67F6B58782FD47E676.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/5739053/files/figure.png	https://doi.org/10.5281/zenodo.5739053	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	Fig. 9. Larvae of the family Taeniidae. A, The proliferated cysticerci of Taenia crassiceps in the subcutaneous tissue of Myodes rufocanus; B, the strobilocercus of Hydatigera taeniaeformis from the liver of Rattus norvegicus; C, the disseminated alveolar hydatid of Echinococcus multilocularis in peritoneal organs of My. rufocanus. Scale bars: 20mm.	2021-09-10	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Anders, Jason Lee;Nakao, Minoru			
