Project description:Dendrobates auratus (green and black poison frog) transcriptome, aDenAur2

Project description:Dendrobates auratus (green and black poison frog) transcriptome, aDenAur3

Project description:Dendrobates auratus (green and black poison frog) genome, aDenAur1

Project description:Dendrobates auratus (green and black poison frog) genome, aDenAur1, paternal haplotype

Project description:Dendrobates auratus (green and black poison frog) genome, aDenAur1, maternal haplotype

Project description:Variation in pigmentation gene expression is associated with distinct aposematic color morphs in the poison frog, Dendrobates auratus

Project description:Dendrobates auratus overview

Project description:Poison frog transcriptomes

Project description:Poison frogs sequester chemical defenses from their diet of leaf litter arthropods for defense against predation. Little is known about the physiological adaptations that confer this unusual bioaccumulation ability. We conducted an alkaloid-feeding experiment with the Diablito poison frog (Oophaga sylvatica) to determine how quickly alkaloids are accumulated and how toxins modify frog physiology using quantitative proteomics. Diablito frogs rapidly accumulated the alkaloid decahydroquinoline within four days, and dietary alkaloid exposure modified protein abundance in the intestines, liver, and skin. Many proteins that increased in abundance with toxin accumulation are plasma glycoproteins, including the complement system and the toxin-binding protein saxiphilin. Other protein classes that change in abundance with toxin accumulation are membrane proteins involved in small molecule transport and metabolism. Overall, this work shows poison frogs can rapidly accumulate alkaloids, which alter carrier protein abundance, initiate an immune response, and alter small molecule transport and metabolism dynamics across tissues

Project description:Poison Frog Tadpole Gut Microbiomes