Project description:Conus magus Transcriptome or Gene expression

Project description:Marine cone snails have attracted researchers from all disciplines but early life stages have received limited attention due to difficulties accessing or rearing juvenile specimens. Here, we document the culture of Conus magus from eggs through metamorphosis to reveal dramatic shifts in predatory feeding behaviour between post-metamorphic juveniles and adult specimens. Adult C. magus capture fish using a set of paralytic venom peptides combined with a hooked radular tooth used to tether envenomed fish. In contrast, early juveniles feed exclusively on polychaete worms using a unique “sting-and-stalk” foraging behaviour facilitated by short, unbarbed radular teeth and a distinct venom repertoire that induces hypoactivity in prey. Our results demonstrate how coordinated morphological, behavioural and molecular changes facilitate the shift from worm- to fish-hunting in C. magus, and showcase juvenile cone snails as a rich and unexplored source of novel venom peptides for ecological, evolutionary and biodiscovery studies.

Project description:Conus virgo, marmoreus, magus, striatus, textile, terebra Raw sequence reads

Project description:Conus purpurascens RNA Seq

Project description:RNA-seq of Conus textile

Project description:Gibbula magus overview

Project description:The first GSSM of V. vinifera was reconstructed (MODEL2408120001). Tissue-specific models for stem, leaf, and berry of the Cabernet Sauvignon cultivar were generated from the original model, through the integration of RNA-Seq data. These models have been merged into diel multi-tissue models to study the interactions between tissues at light and dark phases.

Project description:Conus quercinus Conus caracteristicus Conus textile Raw sequence reads

Project description:Instraspecific venomics of Conus purpurascens. We employ a functional proteogenomic approach to maximize conopeptide identification from the injected venom of Conus purpurascens.

Project description:Employing Conus betulinus as a representative, we sequenced and assembled the first Conus genome. After integration of multi-omics data, we provide novel insights into the genetic central dogma of conotoxins, assuming a number ratio of ~1:1:10s for genes/transcripts/peptides.