Project description:RNAseq of Asellus aquaticus infernus and Asellus aquaticus (Surface limanu bridge stream location)

Project description:Cave and Surface Transcriptomes of Asellus aquaticus & Niphargus hrabei from Molnar Janos Cave (Hungary)

Project description:Asellus aquaticus samples collected and studied from cave, surface streams, and lake ecotypes on Gotland, Sweden

Project description:Asellus aquaticus overview

Project description:Asellus aquaticus embryonic transcriptomes

Project description:Asellus aquaticus (water hoglouse)

Project description:Asellus aquaticus Raw sequence reads

Project description:we report a transcriptome-wide comparative investigation between surface and cave species in Sinocyclocheilus. De novo transcriptome assemblies were performed on surface and cave species; then the Sinocyclocheilus contigs were annotated with Gene Ontology. RNA-Seq assays revealed reduced transcription of a series of visual phototransduction and retinal disease related genes in cave-dwelling species compared with surface species. Degeneration of the retina in Sinocyclocheilus cavefish might occur in a lens-independent way by the down-regulation of several transcriptional factors, which have direct roles in retina development and maintenance, such as crx, rorb and Wnt pathway members. Examination of 2 different eye samples in 2 Sinocyclocheilus species.

Project description:Asellus aquaticus Microbiome Raw sequence reads

Project description:Organisms adapt to and survive in environments with varying nutrient availability. Cis-regulatory changes play important roles in adaptation and phenotypic evolution. To what extent cis-regulatory elements contribute to metabolic adaptation is less understood. Here we have utilized a unique vertebrate model, Astyanax mexicanus, that survives in nutrient rich surface and nutrient deprived cave water to uncover gene regulatory networks in metabolic adaptation. We performed genome-wide analysis of accessible chromatin and histone modifications in the liver tissue of one surface and two independently derived cave populations, providing the first genome-wide epigenetic landscape in this organism. We find that many cis-regulatory elements differ between surface and the cavefish, while the two independently derived cave populations have evolved remarkably similar regulatory signatures. Changes in gene regulatory networks between the surface and cave morphotypes point to global changes in key metabolic pathways.