AI Article Synopsis
- Venomous marine gastropods in the Conoidea superfamily, particularly Raphitomidae, have a variety of toxins, but their venom is not well-studied.
- This research produced transcriptomes from different body parts of a northeastern Atlantic species and identified a new vermivorous diet through gut barcoding.
- The study uncovered over a hundred potential venom components, including 69 neurotoxins and 20 new toxin families, highlighting the significance of salivary gland secretions in the evolution of conoidean venom.
Article Abstract
Venomous marine gastropods of the superfamily Conoidea possess a rich arsenal of toxins, including neuroactive toxins. Venom adaptations might have played a fundamental role in the radiation of conoideans; nevertheless, there is still no knowledge about the venom of the most diversified family of the group: Raphitomidae Bellardi, 1875. In this study, transcriptomes were produced from the carcase, salivary glands, and proximal and distal venom ducts of the northeastern Atlantic species (Montagu, 1803). Using a gut barcoding approach, we were also able to report, for the first time, molecular evidence of a vermivorous diet for the genus. Transcriptomic analyses revealed over a hundred putative venom components (PVC), including 69 neurotoxins. Twenty novel toxin families, including some with high levels of expansion, were discovered. No significant difference was observed between the distal and proximal venom duct secretions. Peptides related to cone snail toxins (Cerm06, Pgam02, and turritoxin) and other venom-related proteins (disulfide isomerase and elevenin) were retrieved from the salivary glands. These salivary venom components may constitute ancestral adaptations for venom production in conoideans. Although often neglected, salivary gland secretions are of extreme importance for understanding the evolutionary history of conoidean venom.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11359391 | PMC |
| http://dx.doi.org/10.3390/toxins16080348 | DOI Listing |
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