taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
9D044F6E6D0EFF9AFCC548D2FD186DEB.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/7094080/files/figure.png	https://doi.org/10.5281/zenodo.7094080	Figure 4. The adult stage of Philophthalmus hechingeri n. sp. Line drawing of ventral view. Abbreviations: c, cirrus; ca, caecum; cs, cirrus sac; gp, genital pore; mg, Mehlis’ gland; mt, metraterm; o, ovary; os, oral sucker; p, pharynx; sr, seminal receptacle; sv, seminal vesicle; t, testis; u, uterus; v, vitellarium; vs, ventral sucker.	Figure 4. The adult stage of Philophthalmus hechingeri n. sp. Line drawing of ventral view. Abbreviations: c, cirrus; ca, caecum; cs, cirrus sac; gp, genital pore; mg, Mehlis’ gland; mt, metraterm; o, ovary; os, oral sucker; p, pharynx; sr, seminal receptacle; sv, seminal vesicle; t, testis; u, uterus; v, vitellarium; vs, ventral sucker.	2022-01-17	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru			
9D044F6E6D0EFF9AFCC548D2FD186DEB.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/7094078/files/figure.png	https://doi.org/10.5281/zenodo.7094078	Figure 5. The larval stages of Philophthalmus hechingeri n. sp. (A) Daughter redia. (B) Cercaria. (C) Excysted juvenile.	Figure 5. The larval stages of Philophthalmus hechingeri n. sp. (A) Daughter redia. (B) Cercaria. (C) Excysted juvenile.	2022-01-17	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru			
9D044F6E6D0EFF9AFCC548D2FD186DEB.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/7094082/files/figure.png	https://doi.org/10.5281/zenodo.7094082	Figure 6. The flask-shaped metacercariae of Philophthalmus hechingeri n. sp.	Figure 6. The flask-shaped metacercariae of Philophthalmus hechingeri n. sp.	2022-01-17	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru			
9D044F6E6D0EFF9AFCC548D2FD186DEB.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/7094074/files/figure.png	https://doi.org/10.5281/zenodo.7094074	Figure 2. A maximum likelihood phylogenetic tree of the family Philophthalmidae. The tree was made using sequences of 28S rDNA (874 nucleotide sites) under the substitution model GTRþI. The tree was rooted by the outgroup taxon, Sphaeridiotrema globulus (GQ890331). The outgroup was removed from the tree to save space. The isolates obtained in this study are highlighted in bold face. The DNA accession number of each philophthalmid is shown in parentheses. Bootstrap percentages are indicated at branching points. A scale bar indicates the number of substitutions per nucleotide site.	Figure 2. A maximum likelihood phylogenetic tree of the family Philophthalmidae. The tree was made using sequences of 28S rDNA (874 nucleotide sites) under the substitution model GTRþI. The tree was rooted by the outgroup taxon, Sphaeridiotrema globulus (GQ890331). The outgroup was removed from the tree to save space. The isolates obtained in this study are highlighted in bold face. The DNA accession number of each philophthalmid is shown in parentheses. Bootstrap percentages are indicated at branching points. A scale bar indicates the number of substitutions per nucleotide site.	2022-01-17	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru			
9D044F6E6D0EFF9AFCC548D2FD186DEB.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/7094076/files/figure.png	https://doi.org/10.5281/zenodo.7094076	Figure 3. Mitochondrial DNA-based genetic analyses of philophthalmid species. (A) A maximum likelihood phylogenetic tree of the genus Philophthalmus. The tree was made using sequences of COI (693 nucleotide sites) under the substitution model HKYþG. The DNA accession number of each taxon is shown in parentheses. The tree was rooted by the outgroup taxon, Fasciola hepatica (M93388). The outgroup was removed from the tree to save space. Bootstrap percentages are indicated at branching points. A scale bar indicates the number of substitutions per nucleotide site. (B) A parsimony network of COI haplotypes (849 nucleotide sites) of Philophthalmus hechingeri n. sp. in a seashore of the Seto Inland Sea. The size of circles indicates the frequency of the haplotypes. Numerals within the circles mean the number of haplotypes. A closed circle indicates a haplotype, which is identical to that of Philophthalmus sp. from human in Aichi Prefecture (Sato et al., 2019). Tiny circles are hypothetical haplotypes.	Figure 3. Mitochondrial DNA-based genetic analyses of philophthalmid species. (A) A maximum likelihood phylogenetic tree of the genus Philophthalmus. The tree was made using sequences of COI (693 nucleotide sites) under the substitution model HKYþG. The DNA accession number of each taxon is shown in parentheses. The tree was rooted by the outgroup taxon, Fasciola hepatica (M93388). The outgroup was removed from the tree to save space. Bootstrap percentages are indicated at branching points. A scale bar indicates the number of substitutions per nucleotide site. (B) A parsimony network of COI haplotypes (849 nucleotide sites) of Philophthalmus hechingeri n. sp. in a seashore of the Seto Inland Sea. The size of circles indicates the frequency of the haplotypes. Numerals within the circles mean the number of haplotypes. A closed circle indicates a haplotype, which is identical to that of Philophthalmus sp. from human in Aichi Prefecture (Sato et al., 2019). Tiny circles are hypothetical haplotypes.	2022-01-17	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru		Zenodo	biologists	Sasaki, Mizuki;Miura, Osamu;Nakao, Minoru			
