# Profiling the Paralytic Effects and Lethality of Cone Snail Venom Toxins Using Nanofractionation Analytics with In Vivo Zebrafish Larvae Assays

**Authors:** Jeroen Kool, Arif Arrahman, Haifeng Xu, Jiaxing Liu, Richard J. Lewis, Christian Tudorache, Fernanda C. Cardoso

PMC · DOI: 10.3390/toxins17100504 · Toxins · 2025-10-13

## TL;DR

This study uses zebrafish embryos to identify which cone snail venom toxins cause paralysis and death, using advanced analytical techniques.

## Contribution

A novel pipeline combining nanofractionation analytics and in vivo zebrafish assays to identify paralytic and lethal cone snail venom toxins.

## Key findings

- Cone snail venom toxins were profiled for paralysis and lethality using zebrafish embryos.
- C. bandanus venom was the most lethal, while C. ebraeus venom was the most paralytic.
- Conopeptides were identified as the main paralyzing toxins based on mass spectrometry and behavior analysis.

## Abstract

This study presents nanofractionation analytics coupled with in vivo profiling of zebrafish embryo paralysis and lethality in response to toxins in cone snail venoms. The focus of this study is on the development of this approach using venoms of Conus marmoreus, Conus ebraeus, and Conus bandanus. In brief, cone snail venoms were separated using reversed-phase chromatography following high-resolution nanofractionation on microplates with parallel mass spectrometry, enabled via a post-column flow split. All collected fractions were dried overnight, followed by assays on zebrafish embryos. For the paralysis assessment, we monitored swimming behavior and swimming distance and found that exposure to cone snail toxins led to paralysis and decreased movement and swim distance. To correlate the masses of eluted toxins with their paralyzing effects and potency, we compared the fractionation retention time versus normalized swimming distance. This allowed identification of the masses of toxins with paralyzing bioactivity, which were predominantly conopeptides. To assess lethality, zebrafish embryos were exposed to fractionated toxins for 24 h, after which they were inspected. The lethal doses and correlated toxins were identified by comparing retention times of fractionation versus the lethal dose values calculated for each fraction. We found that the most lethal venom was from C. bandanus, displaying the largest number of lethal peptides, followed by C. marmoreus and C. ebraeus. On the other hand, the most paralytic venom was from C. ebraeus, presenting a higher number of peptides with non-lethal paralytic effects, followed by C. bandanus and C. marmoreus. This study provides a pipeline to rapidly identify paralytic and lethal cone snail venom toxins using the zebrafish embryo model.

## Linked entities

- **Species:** Conus marmoreus (taxon 42752), Conus ebraeus (taxon 89425), Conus bandanus (taxon 72279), Danio rerio (taxon 7955)

## Full-text entities

- **Diseases:** paralysis (MESH:D010243)
- **Chemicals:** Venom Toxins (-)
- **Species:** Conus bandanus (species) [taxon 72279], Conus ebraeus (species) [taxon 89425], Danio rerio (leopard danio, species) [taxon 7955], Conus marmoreus (species) [taxon 42752]

## Full text

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## Figures

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## References

66 references — full list in the complete paper: https://tomesphere.com/paper/PMC12567654/full.md

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Source: https://tomesphere.com/paper/PMC12567654