Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites

Shirin Ahmadi; Nick J Burlet; Melisa Benard-Valle; Alid Guadarrama-Martínez; Samuel Kerwin; Iara A Cardoso; Amy E Marriott; Rebecca J Edge; Edouard Crittenden; Edgar Neri-Castro; Monica L Fernandez-Quintero; Giang T T Nguyen; Carol O'Brien; Yessica Wouters; Konstantinos Kalogeropoulos; Suthimon Thumtecho; Tasja Wainani Ebersole; Camilla Holst Dahl; Emily U Glegg-Sørensen; Tom Jansen; Kim Boddum; Evangelia Manousaki; Esperanza Rivera-de-Torre; Andrew B Ward; J Preben Morth; Alejandro Alagón; Stephen P Mackessy; Stuart Ainsworth; Stefanie K Menzies; Nicholas R Casewell; Timothy P Jenkins; Anne Ljungars; Andreas H Laustsen

doi:10.1038/s41586-025-09661-0

Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites

Shirin Ahmadi, Nick J Burlet, Melisa Benard-Valle, Alid Guadarrama-Martínez, Samuel Kerwin, Iara A Cardoso, Amy E Marriott, Rebecca J Edge, Edouard Crittenden, Edgar Neri-Castro, Monica L Fernandez-Quintero, Giang T T Nguyen, Carol O'Brien, Yessica Wouters, Konstantinos Kalogeropoulos, Suthimon Thumtecho, Tasja Wainani Ebersole, Camilla Holst Dahl, Emily U Glegg-Sørensen, Tom JansenKim Boddum, Evangelia Manousaki, Esperanza Rivera-de-Torre, Andrew B Ward, J Preben Morth, Alejandro Alagón, Stephen P Mackessy, Stuart Ainsworth, Stefanie K Menzies, Nicholas R Casewell, Timothy P Jenkins^*, Anne Ljungars^*, Andreas H Laustsen^*

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

4 Citations (Scopus)

Abstract

Each year, snakebite envenoming claims thousands of lives and causes severe injury to victims across sub-Saharan Africa, many of whom depend on antivenoms derived from animal plasma as their sole treatment option1. Traditional antivenoms are expensive, can cause adverse immunological reactions, offer limited efficacy against local tissue damage and are often ineffective against all medically relevant snake species2. There is thus an urgent unmet medical need for innovation in snakebite envenoming therapy. However, developing broad-spectrum treatments is highly challenging owing to the vast diversity of venomous snakes and the complex and variable composition of their venoms3. Here we addressed this challenge by immunizing an alpaca and a llama with the venoms of 18 different snakes, including mambas, cobras and a rinkhals, constructing phage display libraries, and identifying high-affinity broadly neutralizing nanobodies. We combined eight of these nanobodies into a defined oligoclonal mixture, resulting in an experimental polyvalent recombinant antivenom that was capable of neutralizing seven toxin families or subfamilies. This antivenom effectively prevented venom-induced lethality in vivo across 17 African elapid snake species and markedly reduced venom-induced dermonecrosis for all tested cytotoxic venoms. The recombinant antivenom performed better than a currently used plasma-derived antivenom and therefore shows considerable promise for comprehensive, continent-wide protection against snakebites by all medically relevant African elapids.

Original language	English
Pages (from-to)	716-725
Number of pages	27
Journal	Nature
Volume	647
Issue number	8090
Early online date	29 Oct 2025
DOIs	https://doi.org/10.1038/s41586-025-09661-0
Publication status	Published - 20 Nov 2025

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Publisher Copyright:
© 2025. The Author(s).

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Ahmadi, S., Burlet, N. J., Benard-Valle, M., Guadarrama-Martínez, A., Kerwin, S., Cardoso, I. A., Marriott, A. E., Edge, R. J., Crittenden, E., Neri-Castro, E., Fernandez-Quintero, M. L., Nguyen, G. T. T., O'Brien, C., Wouters, Y., Kalogeropoulos, K., Thumtecho, S., Ebersole, T. W., Dahl, C. H., Glegg-Sørensen, E. U., ... Laustsen, A. H. (2025). Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites. Nature, 647(8090), 716-725. https://doi.org/10.1038/s41586-025-09661-0

@article{44a04b12f276493a80136fc78e395c21,

title = "Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites",

abstract = "Each year, snakebite envenoming claims thousands of lives and causes severe injury to victims across sub-Saharan Africa, many of whom depend on antivenoms derived from animal plasma as their sole treatment option1. Traditional antivenoms are expensive, can cause adverse immunological reactions, offer limited efficacy against local tissue damage and are often ineffective against all medically relevant snake species2. There is thus an urgent unmet medical need for innovation in snakebite envenoming therapy. However, developing broad-spectrum treatments is highly challenging owing to the vast diversity of venomous snakes and the complex and variable composition of their venoms3. Here we addressed this challenge by immunizing an alpaca and a llama with the venoms of 18 different snakes, including mambas, cobras and a rinkhals, constructing phage display libraries, and identifying high-affinity broadly neutralizing nanobodies. We combined eight of these nanobodies into a defined oligoclonal mixture, resulting in an experimental polyvalent recombinant antivenom that was capable of neutralizing seven toxin families or subfamilies. This antivenom effectively prevented venom-induced lethality in vivo across 17 African elapid snake species and markedly reduced venom-induced dermonecrosis for all tested cytotoxic venoms. The recombinant antivenom performed better than a currently used plasma-derived antivenom and therefore shows considerable promise for comprehensive, continent-wide protection against snakebites by all medically relevant African elapids.",

author = "Shirin Ahmadi and Burlet, \{Nick J\} and Melisa Benard-Valle and Alid Guadarrama-Mart{\'i}nez and Samuel Kerwin and Cardoso, \{Iara A\} and Marriott, \{Amy E\} and Edge, \{Rebecca J\} and Edouard Crittenden and Edgar Neri-Castro and Fernandez-Quintero, \{Monica L\} and Nguyen, \{Giang T T\} and Carol O'Brien and Yessica Wouters and Konstantinos Kalogeropoulos and Suthimon Thumtecho and Ebersole, \{Tasja Wainani\} and Dahl, \{Camilla Holst\} and Glegg-S{\o}rensen, \{Emily U\} and Tom Jansen and Kim Boddum and Evangelia Manousaki and Esperanza Rivera-de-Torre and Ward, \{Andrew B\} and Morth, \{J Preben\} and Alejandro Alag{\'o}n and Mackessy, \{Stephen P\} and Stuart Ainsworth and Menzies, \{Stefanie K\} and Casewell, \{Nicholas R\} and Jenkins, \{Timothy P\} and Anne Ljungars and Laustsen, \{Andreas H\}",

note = "Publisher Copyright: {\textcopyright} 2025. The Author(s).",

year = "2025",

month = nov,

day = "20",

doi = "10.1038/s41586-025-09661-0",

language = "English",

volume = "647",

pages = "716--725",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8090",

}

Ahmadi, S, Burlet, NJ, Benard-Valle, M, Guadarrama-Martínez, A, Kerwin, S, Cardoso, IA, Marriott, AE, Edge, RJ, Crittenden, E, Neri-Castro, E, Fernandez-Quintero, ML, Nguyen, GTT, O'Brien, C, Wouters, Y, Kalogeropoulos, K, Thumtecho, S, Ebersole, TW, Dahl, CH, Glegg-Sørensen, EU, Jansen, T, Boddum, K, Manousaki, E, Rivera-de-Torre, E, Ward, AB, Morth, JP, Alagón, A, Mackessy, SP, Ainsworth, S, Menzies, SK, Casewell, NR, Jenkins, TP, Ljungars, A & Laustsen, AH 2025, 'Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites', Nature, vol. 647, no. 8090, pp. 716-725. https://doi.org/10.1038/s41586-025-09661-0

TY - JOUR

T1 - Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites

AU - Ahmadi, Shirin

AU - Burlet, Nick J

AU - Benard-Valle, Melisa

AU - Guadarrama-Martínez, Alid

AU - Kerwin, Samuel

AU - Cardoso, Iara A

AU - Marriott, Amy E

AU - Edge, Rebecca J

AU - Crittenden, Edouard

AU - Neri-Castro, Edgar

AU - Fernandez-Quintero, Monica L

AU - Nguyen, Giang T T

AU - O'Brien, Carol

AU - Wouters, Yessica

AU - Kalogeropoulos, Konstantinos

AU - Thumtecho, Suthimon

AU - Ebersole, Tasja Wainani

AU - Dahl, Camilla Holst

AU - Glegg-Sørensen, Emily U

AU - Jansen, Tom

AU - Boddum, Kim

AU - Manousaki, Evangelia

AU - Rivera-de-Torre, Esperanza

AU - Ward, Andrew B

AU - Morth, J Preben

AU - Alagón, Alejandro

AU - Mackessy, Stephen P

AU - Ainsworth, Stuart

AU - Menzies, Stefanie K

AU - Casewell, Nicholas R

AU - Jenkins, Timothy P

AU - Ljungars, Anne

AU - Laustsen, Andreas H

PY - 2025/11/20

Y1 - 2025/11/20

N2 - Each year, snakebite envenoming claims thousands of lives and causes severe injury to victims across sub-Saharan Africa, many of whom depend on antivenoms derived from animal plasma as their sole treatment option1. Traditional antivenoms are expensive, can cause adverse immunological reactions, offer limited efficacy against local tissue damage and are often ineffective against all medically relevant snake species2. There is thus an urgent unmet medical need for innovation in snakebite envenoming therapy. However, developing broad-spectrum treatments is highly challenging owing to the vast diversity of venomous snakes and the complex and variable composition of their venoms3. Here we addressed this challenge by immunizing an alpaca and a llama with the venoms of 18 different snakes, including mambas, cobras and a rinkhals, constructing phage display libraries, and identifying high-affinity broadly neutralizing nanobodies. We combined eight of these nanobodies into a defined oligoclonal mixture, resulting in an experimental polyvalent recombinant antivenom that was capable of neutralizing seven toxin families or subfamilies. This antivenom effectively prevented venom-induced lethality in vivo across 17 African elapid snake species and markedly reduced venom-induced dermonecrosis for all tested cytotoxic venoms. The recombinant antivenom performed better than a currently used plasma-derived antivenom and therefore shows considerable promise for comprehensive, continent-wide protection against snakebites by all medically relevant African elapids.

AB - Each year, snakebite envenoming claims thousands of lives and causes severe injury to victims across sub-Saharan Africa, many of whom depend on antivenoms derived from animal plasma as their sole treatment option1. Traditional antivenoms are expensive, can cause adverse immunological reactions, offer limited efficacy against local tissue damage and are often ineffective against all medically relevant snake species2. There is thus an urgent unmet medical need for innovation in snakebite envenoming therapy. However, developing broad-spectrum treatments is highly challenging owing to the vast diversity of venomous snakes and the complex and variable composition of their venoms3. Here we addressed this challenge by immunizing an alpaca and a llama with the venoms of 18 different snakes, including mambas, cobras and a rinkhals, constructing phage display libraries, and identifying high-affinity broadly neutralizing nanobodies. We combined eight of these nanobodies into a defined oligoclonal mixture, resulting in an experimental polyvalent recombinant antivenom that was capable of neutralizing seven toxin families or subfamilies. This antivenom effectively prevented venom-induced lethality in vivo across 17 African elapid snake species and markedly reduced venom-induced dermonecrosis for all tested cytotoxic venoms. The recombinant antivenom performed better than a currently used plasma-derived antivenom and therefore shows considerable promise for comprehensive, continent-wide protection against snakebites by all medically relevant African elapids.

U2 - 10.1038/s41586-025-09661-0

DO - 10.1038/s41586-025-09661-0

M3 - Article (Academic Journal)

C2 - 41162699

SN - 0028-0836

VL - 647

SP - 716

EP - 725

JO - Nature

JF - Nature

IS - 8090

ER -

Nanobody-based recombinant antivenom for cobra, mamba and rinkhals bites

Abstract

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