taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
03B50F5C7106FF8082AFFE81FD12D201.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806916/files/figure.png	https://doi.org/10.5281/zenodo.14806916	Figure 3. A, general soft tissue organization of Plakina arletensis sp. nov. B, detailed view of the mesohyl, showing the aquiferous system. C, transmission electron micrograph of a choanocyte chamber. D transmission electron micrograph with archeocytes and pinacocytes. E, transmission electron micrograph showing the abundance of prokaryotic cells inside the mesohyl and the three main morphotypes (1–3). F, transmission electron micrograph with a detailed view of the prokaryote symbionts (1–3). Ar, archeocytes; cc, choanocyte chamber; Ch, choanocyte; en, endosome; EC, exhalant canal; Mb, basement membrane; M, mesohyl; ph, phagosome; Pi, pinacocytes; Pk, prokaryotes.	Figure 3. A, general soft tissue organization of Plakina arletensis sp. nov. B, detailed view of the mesohyl, showing the aquiferous system. C, transmission electron micrograph of a choanocyte chamber. D transmission electron micrograph with archeocytes and pinacocytes. E, transmission electron micrograph showing the abundance of prokaryotic cells inside the mesohyl and the three main morphotypes (1–3). F, transmission electron micrograph with a detailed view of the prokaryote symbionts (1–3). Ar, archeocytes; cc, choanocyte chamber; Ch, choanocyte; en, endosome; EC, exhalant canal; Mb, basement membrane; M, mesohyl; ph, phagosome; Pi, pinacocytes; Pk, prokaryotes.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
03B50F5C7105FF8A8294FA0BFEF8D05C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806920/files/figure.png	https://doi.org/10.5281/zenodo.14806920	Figure 5. Aspiculophora madinina gen. nov. sp. nov. A, in situ pictures of three specimens collected in La Martinique. B, general histological organization, with a detailed view of the mesohyl and the collagen layer (arrow). cc, choanocyte chamber; EC exhalant canal; M, mesohyl; vc, vacuolar cells.	Figure 5. Aspiculophora madinina gen. nov. sp. nov. A, in situ pictures of three specimens collected in La Martinique. B, general histological organization, with a detailed view of the mesohyl and the collagen layer (arrow). cc, choanocyte chamber; EC exhalant canal; M, mesohyl; vc, vacuolar cells.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
03B50F5C7105FF8A8294FA0BFEF8D05C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806922/files/figure.png	https://doi.org/10.5281/zenodo.14806922	Figure 6. A, light micrograph of the ectosome and choanosome of Aspiculophora madinina gen. nov., sp. nov. B, transmission electron micrograph showing the high prokaryotic density in a part of the mesohyl located between two choanocyte chambers. C, transmission electron micrographs of vacuolar cells and pinacocytes. D, prokaryote morphotypes associated with the mesohyl of Aspiculophora madinina. Ch, choanocyte; cc, choanocyte chamber; EC, exhalant canal; exo, exopinacoderm; M, mesohyl; Pk, prokaryotes.	Figure 6. A, light micrograph of the ectosome and choanosome of Aspiculophora madinina gen. nov., sp. nov. B, transmission electron micrograph showing the high prokaryotic density in a part of the mesohyl located between two choanocyte chambers. C, transmission electron micrographs of vacuolar cells and pinacocytes. D, prokaryote morphotypes associated with the mesohyl of Aspiculophora madinina. Ch, choanocyte; cc, choanocyte chamber; EC, exhalant canal; exo, exopinacoderm; M, mesohyl; Pk, prokaryotes.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
03B50F5C7105FF8A8294FA0BFEF8D05C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806924/files/figure.png	https://doi.org/10.5281/zenodo.14806924	Figure 7. Phylogenetic reconstruction of the universal Folmer portion of the CO1 gene using neighbour-joining analysis and indicating maximum-likelihood (ML) values. Bootstrap values are given for both analyses; ML values are in parenthesis. The accession numbers of each download sequence are next to the species name.	Figure 7. Phylogenetic reconstruction of the universal Folmer portion of the CO1 gene using neighbour-joining analysis and indicating maximum-likelihood (ML) values. Bootstrap values are given for both analyses; ML values are in parenthesis. The accession numbers of each download sequence are next to the species name.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
03B50F5C7105FF8A8294FA0BFEF8D05C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806926/files/figure.png	https://doi.org/10.5281/zenodo.14806926	Figure 8. Phylogenetic reconstruction of the I3-M11 portion of the CO1 gene using neighbour-joining (NJ) analysis and indicating maximum-likelihood (ML) values. Bootstrap values are given for both analyses; ML values are in parenthesis. The accession numbers of each download sequence are next to the species name.	Figure 8. Phylogenetic reconstruction of the I3-M11 portion of the CO1 gene using neighbour-joining (NJ) analysis and indicating maximum-likelihood (ML) values. Bootstrap values are given for both analyses; ML values are in parenthesis. The accession numbers of each download sequence are next to the species name.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
03B50F5C7105FF8A8294FA0BFEF8D05C.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/14806930/files/figure.png	https://doi.org/10.5281/zenodo.14806930	Figure 9. Phylogenetic reconstruction concatenating the Folmer and I3-M11 fragments of the CO1 using maximumlikelihood analysis. All sequences from this study were aligned with both fragments (F+E), Folmer (F) and I3-M11 (E). The accession number of each downloaded sequence is next to the species name.	Figure 9. Phylogenetic reconstruction concatenating the Folmer and I3-M11 fragments of the CO1 using maximumlikelihood analysis. All sequences from this study were aligned with both fragments (F+E), Folmer (F) and I3-M11 (E). The accession number of each downloaded sequence is next to the species name.	2017-12-31	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry		Zenodo	biologists	Ruiz, César;Muricy, Guilherme;Lage, Anaíra;Domingos, Celso;Chenesseau, Sandrine;Pérez, Thierry			
