Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles

Phylogenetic tree of the CYP26 subfamily, with CYP51 as outgroup. Tree calculated with the Bayesian Inference (BI) and Maximum Likelihood (ML) methods based on 15 vertebrate species (42 CYP26 sequences), 1 tunicate species (2 CYP26 sequences), 3 cephalochordate species (9 CYP26 sequences), 3 ambulac...

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Main Authors:	JoĂŁo Carvalho, Theodosiou, Maria, Chen, Jie, Chevret, Pascale, Alvarez, Susana, Lera, Angel De, Laudet, Vincent, Croce, Jenifer, Schubert, Michael
Format:	Report
Language:	unknown
Published:	Figshare 2017
Subjects:	Evolutionary Biology FOS Biological sciences 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Ecology 69999 Biological Sciences not elsewhere classified Developmental Biology Inorganic Chemistry FOS Chemical sciences Crassostrea gigas
Online Access:	https://dx.doi.org/10.6084/m9.figshare.c.3669937_d5 https://springernature.figshare.com/articles/journal_contribution/Additional_file_2_of_Lineage-specific_duplication_of_amphioxus_retinoic_acid_degrading_enzymes_CYP26_resulted_in_sub-functionalization_of_patterning_and_homeostatic_roles/4568890

id	ftdatacite:10.6084/m9.figshare.c.3669937_d5
record_format	openpolar
spelling	ftdatacite:10.6084/m9.figshare.c.3669937_d5 2023-05-15T15:59:00+02:00 Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles JoĂŁo Carvalho Theodosiou, Maria Chen, Jie Chevret, Pascale Alvarez, Susana Lera, Angel De Laudet, Vincent Croce, Jenifer Schubert, Michael 2017 https://dx.doi.org/10.6084/m9.figshare.c.3669937_d5 https://springernature.figshare.com/articles/journal_contribution/Additional_file_2_of_Lineage-specific_duplication_of_amphioxus_retinoic_acid_degrading_enzymes_CYP26_resulted_in_sub-functionalization_of_patterning_and_homeostatic_roles/4568890 unknown Figshare CC BY + CC0 https://creativecommons.org/licenses/by/4.0 CC0 Evolutionary Biology FOS Biological sciences 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Ecology 69999 Biological Sciences not elsewhere classified Developmental Biology Inorganic Chemistry FOS Chemical sciences Paper Text article-journal ScholarlyArticle 2017 ftdatacite https://doi.org/10.6084/m9.figshare.c.3669937_d5 2021-11-05T12:55:41Z Phylogenetic tree of the CYP26 subfamily, with CYP51 as outgroup. Tree calculated with the Bayesian Inference (BI) and Maximum Likelihood (ML) methods based on 15 vertebrate species (42 CYP26 sequences), 1 tunicate species (2 CYP26 sequences), 3 cephalochordate species (9 CYP26 sequences), 3 ambulacrarian species (6 CYP26 sequences), 5 lophotrochozoan species (12 CYP26 sequences), and 1 ecdysozoan species (2 CYP26 sequences) (for details see Additional file 1). The robustness of each node was assessed by posterior probability (for the BI phylogeny) and bootstrap (for the ML phylogeny) analyses, which are indicated at each node: posterior probabilities (ranging from 0 to 1)/bootstrap percentages (ranging from 0 to 100). â --â indicates nodes where the ML tree did not recover the branching pattern of the BI tree or nodes with bootstrap support inferior to 50%. Branch lengths are representative of the amino acid substitution rate. Species name abbreviations: B.b., Branchiostoma belcheri (in blue); B.f., Branchiostoma floridae (in red); B.l., Branchiostoma lanceolatum (in green); C.g., Crassostrea gigas; C.i., Ciona intestinalis; C.m., Callorhinchus milii; C.t., Capitella teleta; D.r., Danio rerio; G.a., Gasterosteus aculeatus; G.g., Gallus gallus; H.s., Homo sapiens; L.a. Lingula anatina; L.c., Latimeria chalumnae; L.e., Leucoraja erinacea; L.g., Lottia gigantea; L.j., Lethenteron japonicum; L.o., Lepisosteus oculatus; M.d., Monodelphis domestica; M.m., Mus musculus; O.b., Octopus bimaculoides; O.l., Oryzias latipes; P.c., Priapulus caudatus; P.f., Ptychodera flava; P.m., Petromyzon marinus; S.k., Saccoglossus kowalevskii; S.p., Strongylocentrotus purpuratus; T.r., Takifugu rubripes; X.t., Xenopus tropicalis. (PDF 559 kb) Report Crassostrea gigas DataCite Metadata Store (German National Library of Science and Technology)
institution	Open Polar
collection	DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id	ftdatacite
language	unknown
topic	Evolutionary Biology FOS Biological sciences 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Ecology 69999 Biological Sciences not elsewhere classified Developmental Biology Inorganic Chemistry FOS Chemical sciences
spellingShingle	Evolutionary Biology FOS Biological sciences 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Ecology 69999 Biological Sciences not elsewhere classified Developmental Biology Inorganic Chemistry FOS Chemical sciences JoĂŁo Carvalho Theodosiou, Maria Chen, Jie Chevret, Pascale Alvarez, Susana Lera, Angel De Laudet, Vincent Croce, Jenifer Schubert, Michael Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
topic_facet	Evolutionary Biology FOS Biological sciences 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Ecology 69999 Biological Sciences not elsewhere classified Developmental Biology Inorganic Chemistry FOS Chemical sciences
description	Phylogenetic tree of the CYP26 subfamily, with CYP51 as outgroup. Tree calculated with the Bayesian Inference (BI) and Maximum Likelihood (ML) methods based on 15 vertebrate species (42 CYP26 sequences), 1 tunicate species (2 CYP26 sequences), 3 cephalochordate species (9 CYP26 sequences), 3 ambulacrarian species (6 CYP26 sequences), 5 lophotrochozoan species (12 CYP26 sequences), and 1 ecdysozoan species (2 CYP26 sequences) (for details see Additional file 1). The robustness of each node was assessed by posterior probability (for the BI phylogeny) and bootstrap (for the ML phylogeny) analyses, which are indicated at each node: posterior probabilities (ranging from 0 to 1)/bootstrap percentages (ranging from 0 to 100). â --â indicates nodes where the ML tree did not recover the branching pattern of the BI tree or nodes with bootstrap support inferior to 50%. Branch lengths are representative of the amino acid substitution rate. Species name abbreviations: B.b., Branchiostoma belcheri (in blue); B.f., Branchiostoma floridae (in red); B.l., Branchiostoma lanceolatum (in green); C.g., Crassostrea gigas; C.i., Ciona intestinalis; C.m., Callorhinchus milii; C.t., Capitella teleta; D.r., Danio rerio; G.a., Gasterosteus aculeatus; G.g., Gallus gallus; H.s., Homo sapiens; L.a. Lingula anatina; L.c., Latimeria chalumnae; L.e., Leucoraja erinacea; L.g., Lottia gigantea; L.j., Lethenteron japonicum; L.o., Lepisosteus oculatus; M.d., Monodelphis domestica; M.m., Mus musculus; O.b., Octopus bimaculoides; O.l., Oryzias latipes; P.c., Priapulus caudatus; P.f., Ptychodera flava; P.m., Petromyzon marinus; S.k., Saccoglossus kowalevskii; S.p., Strongylocentrotus purpuratus; T.r., Takifugu rubripes; X.t., Xenopus tropicalis. (PDF 559 kb)
format	Report
author	JoĂŁo Carvalho Theodosiou, Maria Chen, Jie Chevret, Pascale Alvarez, Susana Lera, Angel De Laudet, Vincent Croce, Jenifer Schubert, Michael
author_facet	JoĂŁo Carvalho Theodosiou, Maria Chen, Jie Chevret, Pascale Alvarez, Susana Lera, Angel De Laudet, Vincent Croce, Jenifer Schubert, Michael
author_sort	JoĂŁo Carvalho
title	Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
title_short	Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
title_full	Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
title_fullStr	Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
title_full_unstemmed	Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles
title_sort	additional file 2: of lineage-specific duplication of amphioxus retinoic acid degrading enzymes (cyp26) resulted in sub-functionalization of patterning and homeostatic roles
publisher	Figshare
publishDate	2017
url	https://dx.doi.org/10.6084/m9.figshare.c.3669937_d5 https://springernature.figshare.com/articles/journal_contribution/Additional_file_2_of_Lineage-specific_duplication_of_amphioxus_retinoic_acid_degrading_enzymes_CYP26_resulted_in_sub-functionalization_of_patterning_and_homeostatic_roles/4568890
genre	Crassostrea gigas
genre_facet	Crassostrea gigas
op_rights	CC BY + CC0 https://creativecommons.org/licenses/by/4.0
op_rightsnorm	CC0
op_doi	https://doi.org/10.6084/m9.figshare.c.3669937_d5
_version_	1766394791737688064

Additional file 2: of Lineage-specific duplication of amphioxus retinoic acid degrading enzymes (CYP26) resulted in sub-functionalization of patterning and homeostatic roles

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