Abstract

Marine cone snails have developed sophisticated chemical strategies to capture prey and defend themselves against predators. Among the vast array of bioactive molecules in their venom, peptide components called conotoxins or conopeptides dominate, with many binding with high affinity and selectivity to a broad range of cellular targets, including receptors and transporters of the nervous system. Whereas the conopeptide gene precursor organization has a conserved topology, the peptides in the venom duct are highly processed. Indeed, deep sequencing transcriptomics has uncovered on average fewer than 100 toxin gene precursors per species, whereas advanced proteomics has revealed >10-fold greater diversity at the peptide level. In the present study, second-generation sequencing technologies coupled to highly sensitive mass spectrometry methods were applied to rapidly uncover the conopeptide diversity in the venom of a worm-hunting species, Conus miles. A total of 662 putative conopeptide encoded sequences were retrieved from transcriptomic data, comprising 48 validated conotoxin sequences that clustered into 10 gene superfamilies, including 3 novel superfamilies and a novel cysteine framework (C-C-C-CCC-C-C) identified at both transcript and peptide levels. A surprisingly large number of conopeptide gene sequences were expressed at low levels, including a series of single amino acid variants, as well as sequences containing deletions and frame and stop codon shifts. Some of the toxin variants generate alternative cleavage sites, interrupted or elongated cysteine frameworks, and highly variable isoforms within families that could be identified at the peptide level. Together with the variable peptide processing identified previously, background genetic and phenotypic levels of biological messiness in venoms contribute to the hypervariability of venom peptides and their ability to evolve rapidly.

Highlights

  • Cone snails are predatory marine gastropods that feed on a variety of prey, including fish and invertebrates

  • Conopeptides are produced as mRNA precursors displaying a mostly conserved topological organization comprising an N-terminus signal sequence followed by an intervening propeptide region, the mature toxin region, and, for some, an additional C-terminal propeptide region [11]

  • A more impressive molecular diversity has been described at the peptide level in cone snail venoms, with Ͼ1000 detected masses observed in a single specimen [19, 24], and even closely related species can display a completely different set of conopeptides in their venom [24]

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Summary

EXPERIMENTAL PROCEDURES

RNA Extraction, cDNA Library, 454 Sequencing, and Assembly— One single adult specimen of C. miles collected from the Great Barrier Reef (Queensland, Australia) and measuring 6 cm was dissected on ice. The venom duct was removed and directly placed in a 1.5-ml tube with 1 ml of TRIZOL reagent (Invitrogen). Conopeptide Sequence Analysis—Raw cDNA reads (expressed sequence tags) and isotigs were up-loaded in a Web-based searchable database set up by the Australian Genomic Research Facility. The dissected venom extracted as described above (ϳ8 ␮l supernatant) was directly subjected to LC-ESI-MS in order to obtain a complete mass list of underivatized peptides. We used ProteinPilot 4.0 software for peaklist generation and sequence identification by searching the LC-ESI-MS/MS spectra against the raw cDNA database (1,534,974 entries) generated by the Roche 454 GS FLX Titanium sequencer.

RESULTS
XX III XXIV V XI IX XIII
DISCUSSION

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