Dual Proteomics Strategies to Dissect and Quantify the Components of Nine Medically Important African Snake Venoms

Biomedical and Life Sciences

Text available via DOI:

https://doi.org/10.3390/toxins17050243
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

Dual Proteomics Strategies to Dissect and Quantify the Components of Nine Medically Important African Snake Venoms. / Redureau, Damien; Amorim, Fernanda Gobbi; Crasset, Thomas et al.
In: Toxins, Vol. 17, No. 5, 243, 13.05.2025.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Bibtex

@article{ff46490d07cc4d0c8aa0ec4b981eaddd,

title = "Dual Proteomics Strategies to Dissect and Quantify the Components of Nine Medically Important African Snake Venoms",

abstract = "Snakebite envenoming constitutes a significant global health issue, particularly in Africa, where venomous species such as Echis vipers and Dendroaspis mambas pose substantial risks to human health. This study employs a standardized venomics workflow to comprehensively characterize and comparatively quantify the venom composition of nine medically relevant snake species chosen from among the deadliest in Africa. Utilizing shotgun venom proteomics and venom gland transcriptomics, we report detailed profiles of venom complexity, highlighting the relative abundance of dominant toxin families such as three-finger toxins and Kunitz-type proteins in Dendroaspis, and metalloproteinases and phospholipases A2 in Echis. We delineate here the relative abundance and structural diversity of venom components. Key to our proteomic approach is the implementation of Multi-Enzymatic Limited Digestion (MELD), which improved protein sequence coverage and enabled the identification of rare toxin families such as hyaluronidases and renin-like proteases, by multiplying the overlap of generated peptides and enhancing the characterization of both toxin and non-toxin components within the venoms. The culmination of these efforts resulted in the construction of a detailed toxin database, providing insights into the biological roles and potential therapeutic targets of venom proteins and peptides. The findings here compellingly validate the MELD technique, reinforcing its reproducibility as a valuable characterization approach applied to venomics. This research significantly advances our understanding of venom complexity in African snake species, including representatives of both Viperidae and Elapidae families. By elucidating venom composition and toxin profiles, our study paves the way for the development of targeted therapies aimed at mitigating the morbidity and mortality associated with snakebite envenoming globally.",

author = "Damien Redureau and Amorim, {Fernanda Gobbi} and Thomas Crasset and Imre Berger and Christiane Schaffitzel and Menzies, {Stefanie Kate} and Casewell, {Nicholas R.} and Lo{\"i}c Quinton",

year = "2025",

month = may,

day = "13",

doi = "10.3390/toxins17050243",

language = "English",

volume = "17",

journal = "Toxins",

issn = "2072-6651",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "5",

}

RIS

TY - JOUR

T1 - Dual Proteomics Strategies to Dissect and Quantify the Components of Nine Medically Important African Snake Venoms

AU - Redureau, Damien

AU - Amorim, Fernanda Gobbi

AU - Crasset, Thomas

AU - Berger, Imre

AU - Schaffitzel, Christiane

AU - Menzies, Stefanie Kate

AU - Casewell, Nicholas R.

AU - Quinton, Loïc

PY - 2025/5/13

Y1 - 2025/5/13

N2 - Snakebite envenoming constitutes a significant global health issue, particularly in Africa, where venomous species such as Echis vipers and Dendroaspis mambas pose substantial risks to human health. This study employs a standardized venomics workflow to comprehensively characterize and comparatively quantify the venom composition of nine medically relevant snake species chosen from among the deadliest in Africa. Utilizing shotgun venom proteomics and venom gland transcriptomics, we report detailed profiles of venom complexity, highlighting the relative abundance of dominant toxin families such as three-finger toxins and Kunitz-type proteins in Dendroaspis, and metalloproteinases and phospholipases A2 in Echis. We delineate here the relative abundance and structural diversity of venom components. Key to our proteomic approach is the implementation of Multi-Enzymatic Limited Digestion (MELD), which improved protein sequence coverage and enabled the identification of rare toxin families such as hyaluronidases and renin-like proteases, by multiplying the overlap of generated peptides and enhancing the characterization of both toxin and non-toxin components within the venoms. The culmination of these efforts resulted in the construction of a detailed toxin database, providing insights into the biological roles and potential therapeutic targets of venom proteins and peptides. The findings here compellingly validate the MELD technique, reinforcing its reproducibility as a valuable characterization approach applied to venomics. This research significantly advances our understanding of venom complexity in African snake species, including representatives of both Viperidae and Elapidae families. By elucidating venom composition and toxin profiles, our study paves the way for the development of targeted therapies aimed at mitigating the morbidity and mortality associated with snakebite envenoming globally.

AB - Snakebite envenoming constitutes a significant global health issue, particularly in Africa, where venomous species such as Echis vipers and Dendroaspis mambas pose substantial risks to human health. This study employs a standardized venomics workflow to comprehensively characterize and comparatively quantify the venom composition of nine medically relevant snake species chosen from among the deadliest in Africa. Utilizing shotgun venom proteomics and venom gland transcriptomics, we report detailed profiles of venom complexity, highlighting the relative abundance of dominant toxin families such as three-finger toxins and Kunitz-type proteins in Dendroaspis, and metalloproteinases and phospholipases A2 in Echis. We delineate here the relative abundance and structural diversity of venom components. Key to our proteomic approach is the implementation of Multi-Enzymatic Limited Digestion (MELD), which improved protein sequence coverage and enabled the identification of rare toxin families such as hyaluronidases and renin-like proteases, by multiplying the overlap of generated peptides and enhancing the characterization of both toxin and non-toxin components within the venoms. The culmination of these efforts resulted in the construction of a detailed toxin database, providing insights into the biological roles and potential therapeutic targets of venom proteins and peptides. The findings here compellingly validate the MELD technique, reinforcing its reproducibility as a valuable characterization approach applied to venomics. This research significantly advances our understanding of venom complexity in African snake species, including representatives of both Viperidae and Elapidae families. By elucidating venom composition and toxin profiles, our study paves the way for the development of targeted therapies aimed at mitigating the morbidity and mortality associated with snakebite envenoming globally.

U2 - 10.3390/toxins17050243

DO - 10.3390/toxins17050243

M3 - Journal article

VL - 17

JO - Toxins

JF - Toxins

SN - 2072-6651

IS - 5

M1 - 243

ER -

Research

Links

Text available via DOI: