Determination of disulfide bridges of two spider toxins: hainantoxin-III and hainantoxin-IV

Wang, W; Liu, Z; Qian, Weikang; Fang, Yu-Min; Liang, Songping

doi:10.1590/s1678-91992009000200009

Cited by 3 publications

(2 citation statements)

References 11 publications

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“…Peptide toxins are usually highly bridged proteins with multiple pairs of intrachain disulfide bonds. The analysis of disulfide connectivity is important in protein structure determination [ 42 ]. The disulfide pattern in the venom peptides of C. taeniatus was estimated directly by LCMS-IT-TOF without venom fractionation.…”

Section: Discussionmentioning

confidence: 99%

Proteomic analysis of Red Sea Conus taeniatus venom reveals potential biological applications

Fouda

Abdel-Wahab

Mohammadien

et al. 2021

J. Venom. Anim. Toxins incl. Trop. Dis

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Background: Diverse and unique bioactive neurotoxins known as conopeptides or conotoxins are produced by venomous marine cone snails. Currently, these small and stable molecules are of great importance as research tools and platforms for discovering new drugs and therapeutics. Therefore, the characterization of Conus venom is of great significance, especially for poorly studied species. Methods: In this study, we used bioanalytical techniques to determine the venom profile and emphasize the functional composition of conopeptides in Conus taeniatus, a neglected worm-hunting cone snail. Results: The proteomic analysis revealed that 84.0% of the venom proteins were between 500 and 4,000 Da, and 16.0% were > 4,000 Da. In C. taeniatus venom, 234 peptide fragments were identified and classified as conotoxin precursors or non-conotoxin proteins. In this process, 153 conotoxin precursors were identified and matched to 23 conotoxin precursors and hormone superfamilies. Notably, the four conotoxin superfamilies T (22.87%), O1 (17.65%), M (13.1%) and O2 (9.8%) were the most abundant peptides in C. taeniatus venom, accounting for 63.40% of the total conotoxin diversity. On the other hand, 48 non-conotoxin proteins were identified in the venom of C. taeniatus. Moreover, several possibly biologically active peptide matches were identified, and putative applications of the peptides were assigned. Conclusion: Our study showed that the composition of the C. taeniatus-derived proteome is comparable to that of other Conus species and contains an effective mix of toxins, ionic channel inhibitors and antimicrobials. Additionally, it provides a guidepost for identifying novel conopeptides from the venom of C. taeniatus and discovering conopeptides of potential pharmaceutical importance.

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Section: Discussionmentioning

confidence: 99%

Proteomic analysis of Red Sea Conus taeniatus venom reveals potential biological applications

Fouda

Abdel-Wahab

Mohammadien

et al. 2021

J. Venom. Anim. Toxins incl. Trop. Dis

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“…Since its introduction, this method has been used to resolve the structures of many spider-venom toxins. [151][152][153][154] In one case, partial reduction and alkylation was used to solve the connectivity of a peptide toxin from the Blue Mountains funnel-web spider H. versuta, which revealed an extremely rare vicinal disulfide bond that proved to be critical for insecticidal activity. [153] Han et al [155] used a similar method to demonstrate that the M3 family of conotoxins has different connectivity to the M2 or M4 families.…”

Section: Disulfide Connectivitymentioning

confidence: 99%

Deadly Proteomes: A Practical Guide to Proteotranscriptomics of Animal Venoms

et al. 2020

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Animal venoms are renowned for their toxicity, biochemical complexity, and as a source of compounds with potential applications in medicine, agriculture, and industry. Polypeptides underlie much of the pharmacology of animal venoms, and elucidating these arsenals of polypeptide toxins—known as the venom proteome or venome—is an important step in venom research. Proteomics is used for the identification of venom toxins, determination of their primary structure including post‐translational modifications, as well as investigations into the physiology underlying their production and delivery. Advances in proteomics and adjacent technologies has led to a recent upsurge in publications reporting venom proteomes. Improved mass spectrometers, better proteomic workflows, and the integration of next‐generation sequencing of venom‐gland transcriptomes and venomous animal genomes allow quicker and more accurate profiling of venom proteomes with greatly reduced starting material. Technologies such as imaging mass spectrometry are revealing additional insights into the mechanism, location, and kinetics of venom toxin production. However, these numerous new developments may be overwhelming for researchers designing venom proteome studies. Here, the field of venom proteomics is reviewed and some practical solutions for simplifying mass spectrometry workflows to study animal venoms are offered.

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Purification and biochemical characterisation of a putative sodium channel agonist secreted from the South African Knobbly sea anemone Bunodosoma capense

Losenoord

Krause

Parker-Nance

et al. 2019

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Determination of disulfide bridges of two spider toxins: hainantoxin-III and hainantoxin-IV

Cited by 3 publications

References 11 publications

Proteomic analysis of Red Sea Conus taeniatus venom reveals potential biological applications

Proteomic analysis of Red Sea Conus taeniatus venom reveals potential biological applications

Deadly Proteomes: A Practical Guide to Proteotranscriptomics of Animal Venoms

Purification and biochemical characterisation of a putative sodium channel agonist secreted from the South African Knobbly sea anemone Bunodosoma capense

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