ABSTRACT: Phylogenomic reappraisal of the suckermouth armored catfish family Loricariidae (Teleostei: Siluriformes) using thousands of ultraconserved elements
Project description:Phylogenomics of bumblebee catfishes of the family Pseudopimelodidae using ultraconserved elements (Teleostei: Siluriformes)
| PRJNA724721 | ENA
Project description:New perspectives on the evolutionary history of the catfish family Heptapteridae using genome-scale analyses ultraconserved elements (Teleostei, Siluriformes)
| PRJNA723556 | ENA
Project description:Phylogenomic analysis of trichomycterids catfishes (Teleostei: Siluriformes) inferred from ultra conserved elements
| PRJNA530617 | ENA
Project description:Phylogenomic analysis of evolutionary relationships in Ranitomeya poison frogs (Family Dendrobatidae) using ultraconserved elements
| PRJNA779027 | ENA
Project description:The complete mitochondrial genome of the soldier catfish Osteogeneiosus militaris from Vietnam (Teleostei; Siluriformes)
Project description:Channel catfish (Ictalurus punctatus) and tra catfish (Pangasianodon hypophthalmus) both belong to the order Siluriformes. Channel catfish does not possess an air-breathing organ (ABO), and thus cannot breathe in the air, while tra catfish is a facultative air-breather and use the swim bladder as its air-breathing organ, which provides for aerial breathing in low oxygen conditions. Tra and channel catfish serve as a great comparative model for studying the transition of life from water to terrestrial living, as well as for understanding genes that are crucial for development of the swim bladder and the function of air-breathing in tra catfish. We selected seven developmental stages in tra catfish for RNA-Seq analysis based on their transition to a stage that could live at 0 ppm oxygen. More than 587 million sequencing clean reads were generated in tra catfish, and a total of 21, 448 unique genes were detected. A comparative genomic analysis was conducted between channel catfish and tra catfish. Gene expression analysis was performed for these tra catfish specific genes. Hypoxia challenge and microtomy experiments collectively suggested that there are critical timepoints for the development of the air-breathing function and swim bladder development stages in tra catfish. Key genes were identified to be the best candidates of genes related to the air-breathing ability in tra catfish. This study provides a large data resource for functional genomic studies in air-breathing function in tra catfish, and sheds light on the adaption of aquatic organisms to the terrestrial environment.
2021-01-12 | GSE154904 | GEO
Project description:Using ultraconserved elements to unravel lagomorph phylogenetic relationships
| PRJNA756230 | ENA
Project description:Evolutionary Relationships of Anglerfishes (Lophiiformes) Reconstructed using Ultraconserved Elements
Project description:Walking catfish (Clarias macrocephalus) and channel catfish (Ictalurus punctatus) are freshwater fish species of the Siluriformes order. C. macrocephalus has both gills and modified gill structures serving as an air breathing organ (ABO) which allows them aerial breathing (AB), while I. punctatus does not possess an air-breathing organ (ABO), and thus cannot breathe in air. These two species provide an excellent model for studying the molecular basis of accessory air-breathing organ development in teleost fish. In this study, seven development stages in C. macrocephalus were selected for RNA-seq analysis to compare with channel catfish as the time when air breathing organ developed and became functional. Through comparative genetic contents analysis, 1,458 genes were identified to be present in C. macrocephalus, but absent from I. punctatus. Gene expression analysis and protein-protein intersection (PPI) analysis were performed, 26 genes were selected in C. macrocephalus, including mb, ngb, hbae genes, which are mainly associated with oxygen carrier activity, oxygen binding and heme binding activities. Our work provides a large data resource for exploring the genomic basis of air breathing function in C. macrocephalus and offers an insight into the adaption of aquatic organisms to hypoxia and high ammonia environment.