taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
C30487CAFFF1FFB1838AED5BFE544E1D.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/16903367/files/figure.png	https://doi.org/10.5281/zenodo.16903367	Figure.1. (A) The 16S rRNA phylogeny of all available sequences of the genus Nanorana displays the positions of N. huangi and N. parkeri and their recently described synonyms/conspecific taxa. Numbers indicate branch support (posterior probability) for the main clades. (B) Haplotypes network of the COI gene fragment generated by the median-joining method for N. huangi and N. laojunshanensis (n = 25). (C) The geographic position and distance between type localities of two newly described species (Google Earth). (D) The median-joining COI network (n = 66) of major lineages (West and East) and their haplotypes related to taxa N. bangdaensis (green) and N. parkeri (orange) and its geographic position. (E). Alongside networks, GenBank accession numbers (with special highlighting of four subpopulations E1-4; Zhou et al. 2014, Wang et al. 2018) and genetic distances (uncorrected p-distance with the maximum composite likelihood, MCL, in parentheses) within and between sequences/taxa are presented.Dots in the network of N. parkeri and N. bangdaensis represent the East subpopulation (D) and its geographic position (E). Inset photographs: The member of the genus Nanorana from the western Himalaya (by Daniel Jablonski).	Figure.1. (A) The 16S rRNA phylogeny of all available sequences of the genus Nanorana displays the positions of N. huangi and N. parkeri and their recently described synonyms/conspecific taxa. Numbers indicate branch support (posterior probability) for the main clades. (B) Haplotypes network of the COI gene fragment generated by the median-joining method for N. huangi and N. laojunshanensis (n = 25). (C) The geographic position and distance between type localities of two newly described species (Google Earth). (D) The median-joining COI network (n = 66) of major lineages (West and East) and their haplotypes related to taxa N. bangdaensis (green) and N. parkeri (orange) and its geographic position. (E). Alongside networks, GenBank accession numbers (with special highlighting of four subpopulations E1-4; Zhou et al. 2014, Wang et al. 2018) and genetic distances (uncorrected p-distance with the maximum composite likelihood, MCL, in parentheses) within and between sequences/taxa are presented.Dots in the network of N. parkeri and N. bangdaensis represent the East subpopulation (D) and its geographic position (E). Inset photographs: The member of the genus Nanorana from the western Himalaya (by Daniel Jablonski).	2024-02-19	Daniel JABLONSKI;Sylvia HOFMANN		Zenodo	biologists	Daniel JABLONSKI;Sylvia HOFMANN			
C30487CAFFF6FFB08327EEC0FA9848BE.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/16903367/files/figure.png	https://doi.org/10.5281/zenodo.16903367	Figure.1. (A) The 16S rRNA phylogeny of all available sequences of the genus Nanorana displays the positions of N. huangi and N. parkeri and their recently described synonyms/conspecific taxa. Numbers indicate branch support (posterior probability) for the main clades. (B) Haplotypes network of the COI gene fragment generated by the median-joining method for N. huangi and N. laojunshanensis (n = 25). (C) The geographic position and distance between type localities of two newly described species (Google Earth). (D) The median-joining COI network (n = 66) of major lineages (West and East) and their haplotypes related to taxa N. bangdaensis (green) and N. parkeri (orange) and its geographic position. (E). Alongside networks, GenBank accession numbers (with special highlighting of four subpopulations E1-4; Zhou et al. 2014, Wang et al. 2018) and genetic distances (uncorrected p-distance with the maximum composite likelihood, MCL, in parentheses) within and between sequences/taxa are presented.Dots in the network of N. parkeri and N. bangdaensis represent the East subpopulation (D) and its geographic position (E). Inset photographs: The member of the genus Nanorana from the western Himalaya (by Daniel Jablonski).	Figure.1. (A) The 16S rRNA phylogeny of all available sequences of the genus Nanorana displays the positions of N. huangi and N. parkeri and their recently described synonyms/conspecific taxa. Numbers indicate branch support (posterior probability) for the main clades. (B) Haplotypes network of the COI gene fragment generated by the median-joining method for N. huangi and N. laojunshanensis (n = 25). (C) The geographic position and distance between type localities of two newly described species (Google Earth). (D) The median-joining COI network (n = 66) of major lineages (West and East) and their haplotypes related to taxa N. bangdaensis (green) and N. parkeri (orange) and its geographic position. (E). Alongside networks, GenBank accession numbers (with special highlighting of four subpopulations E1-4; Zhou et al. 2014, Wang et al. 2018) and genetic distances (uncorrected p-distance with the maximum composite likelihood, MCL, in parentheses) within and between sequences/taxa are presented.Dots in the network of N. parkeri and N. bangdaensis represent the East subpopulation (D) and its geographic position (E). Inset photographs: The member of the genus Nanorana from the western Himalaya (by Daniel Jablonski).	2024-02-19	Daniel JABLONSKI;Sylvia HOFMANN		Zenodo	biologists	Daniel JABLONSKI;Sylvia HOFMANN			
