Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming

Tian Y. Du; Steven R. Hall; Felicity Chung; Sergey Kurdyukov; Edouard Crittenden; Karishma Patel; Charlotte Dawson; Adam Westhorpe; Keirah Bartlett; Sean A. Rasmussen; Cesar L. Moreno; Christopher E. Denes; Laura-Oana Albulescu; Amy Marriott; Joel P. Mackay; Mark Wilkinson; José María Gutiérrez; Nick Casewell; G. Gregory Neely

doi:10.1126/scitranslmed.adk4802

Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming

Tian Y. Du, Steven R. Hall, Felicity Chung, Sergey Kurdyukov, Edouard Crittenden, Karishma Patel, Charlotte Dawson, Adam Westhorpe, Keirah Bartlett, Sean A. Rasmussen, Cesar L. Moreno, Christopher E. Denes, Laura-Oana Albulescu, Amy Marriott, Joel P. Mackay, Mark Wilkinson, José María Gutiérrez, Nick Casewell, G. Gregory Neely

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10 Citations (Scopus)

Abstract

Snakebites affect about 1.8 million people annually. The current standard of care involves antibody-based antivenoms, which can be difficult to access and are generally not effective against local tissue injury, the primary cause of morbidity. Here, we used a pooled whole-genome CRISPR knockout screen to define human genes that, when targeted, modify cell responses to spitting cobra venoms. A large portion of modifying genes that conferred resistance to venom cytotoxicity was found to control proteoglycan biosynthesis, including EXT1 , B4GALT7 , EXT2 , EXTL3 , XYLT2 , NDST1 , and SLC35B2 , which we validated independently. This finding suggested heparinoids as possible inhibitors. Heparinoids prevented venom cytotoxicity through binding to three-finger cytotoxins, and the US Food and Drug Administration–approved heparinoid tinzaparin was found to reduce tissue damage in mice when given via a medically relevant route and dose. Overall, our systematic molecular dissection of cobra venom cytotoxicity provides insight into how we can better treat cobra snakebite envenoming.

Original language	English
Article number	eadk4802
Journal	Science Translational Medicine
Volume	16
Issue number	756
DOIs	https://doi.org/10.1126/scitranslmed.adk4802
Publication status	Published - 17 Jul 2024

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Du, T. Y., Hall, S. R., Chung, F., Kurdyukov, S., Crittenden, E., Patel, K., Dawson, C., Westhorpe, A., Bartlett, K., Rasmussen, S. A., Moreno, C. L., Denes, C. E., Albulescu, L.-O., Marriott, A., Mackay, J. P., Wilkinson, M., Gutiérrez, J. M., Casewell, N., & Neely, G. G. (2024). Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming. Science Translational Medicine, 16(756), Article eadk4802. https://doi.org/10.1126/scitranslmed.adk4802

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title = "Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming",

abstract = "Snakebites affect about 1.8 million people annually. The current standard of care involves antibody-based antivenoms, which can be difficult to access and are generally not effective against local tissue injury, the primary cause of morbidity. Here, we used a pooled whole-genome CRISPR knockout screen to define human genes that, when targeted, modify cell responses to spitting cobra venoms. A large portion of modifying genes that conferred resistance to venom cytotoxicity was found to control proteoglycan biosynthesis, including EXT1 , B4GALT7 , EXT2 , EXTL3 , XYLT2 , NDST1 , and SLC35B2 , which we validated independently. This finding suggested heparinoids as possible inhibitors. Heparinoids prevented venom cytotoxicity through binding to three-finger cytotoxins, and the US Food and Drug Administration–approved heparinoid tinzaparin was found to reduce tissue damage in mice when given via a medically relevant route and dose. Overall, our systematic molecular dissection of cobra venom cytotoxicity provides insight into how we can better treat cobra snakebite envenoming.",

author = "Du, \{Tian Y.\} and Hall, \{Steven R.\} and Felicity Chung and Sergey Kurdyukov and Edouard Crittenden and Karishma Patel and Charlotte Dawson and Adam Westhorpe and Keirah Bartlett and Rasmussen, \{Sean A.\} and Moreno, \{Cesar L.\} and Denes, \{Christopher E.\} and Laura-Oana Albulescu and Amy Marriott and Mackay, \{Joel P.\} and Mark Wilkinson and Guti{\'e}rrez, \{Jos{\'e} Mar{\'i}a\} and Nick Casewell and Neely, \{G. Gregory\}",

year = "2024",

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doi = "10.1126/scitranslmed.adk4802",

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Du, TY, Hall, SR, Chung, F, Kurdyukov, S, Crittenden, E, Patel, K, Dawson, C , Westhorpe, A, Bartlett, K, Rasmussen, SA, Moreno, CL, Denes, CE, Albulescu, L-O, Marriott, A, Mackay, JP, Wilkinson, M, Gutiérrez, JM, Casewell, N & Neely, GG 2024, 'Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming', Science Translational Medicine, vol. 16, no. 756, eadk4802. https://doi.org/10.1126/scitranslmed.adk4802

TY - JOUR

T1 - Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming

AU - Du, Tian Y.

AU - Hall, Steven R.

AU - Chung, Felicity

AU - Kurdyukov, Sergey

AU - Crittenden, Edouard

AU - Patel, Karishma

AU - Dawson, Charlotte

AU - Westhorpe, Adam

AU - Bartlett, Keirah

AU - Rasmussen, Sean A.

AU - Moreno, Cesar L.

AU - Denes, Christopher E.

AU - Albulescu, Laura-Oana

AU - Marriott, Amy

AU - Mackay, Joel P.

AU - Wilkinson, Mark

AU - Gutiérrez, José María

AU - Casewell, Nick

AU - Neely, G. Gregory

PY - 2024/7/17

Y1 - 2024/7/17

N2 - Snakebites affect about 1.8 million people annually. The current standard of care involves antibody-based antivenoms, which can be difficult to access and are generally not effective against local tissue injury, the primary cause of morbidity. Here, we used a pooled whole-genome CRISPR knockout screen to define human genes that, when targeted, modify cell responses to spitting cobra venoms. A large portion of modifying genes that conferred resistance to venom cytotoxicity was found to control proteoglycan biosynthesis, including EXT1 , B4GALT7 , EXT2 , EXTL3 , XYLT2 , NDST1 , and SLC35B2 , which we validated independently. This finding suggested heparinoids as possible inhibitors. Heparinoids prevented venom cytotoxicity through binding to three-finger cytotoxins, and the US Food and Drug Administration–approved heparinoid tinzaparin was found to reduce tissue damage in mice when given via a medically relevant route and dose. Overall, our systematic molecular dissection of cobra venom cytotoxicity provides insight into how we can better treat cobra snakebite envenoming.

AB - Snakebites affect about 1.8 million people annually. The current standard of care involves antibody-based antivenoms, which can be difficult to access and are generally not effective against local tissue injury, the primary cause of morbidity. Here, we used a pooled whole-genome CRISPR knockout screen to define human genes that, when targeted, modify cell responses to spitting cobra venoms. A large portion of modifying genes that conferred resistance to venom cytotoxicity was found to control proteoglycan biosynthesis, including EXT1 , B4GALT7 , EXT2 , EXTL3 , XYLT2 , NDST1 , and SLC35B2 , which we validated independently. This finding suggested heparinoids as possible inhibitors. Heparinoids prevented venom cytotoxicity through binding to three-finger cytotoxins, and the US Food and Drug Administration–approved heparinoid tinzaparin was found to reduce tissue damage in mice when given via a medically relevant route and dose. Overall, our systematic molecular dissection of cobra venom cytotoxicity provides insight into how we can better treat cobra snakebite envenoming.

U2 - 10.1126/scitranslmed.adk4802

DO - 10.1126/scitranslmed.adk4802

M3 - Article

SN - 1946-6234

VL - 16

JO - Science Translational Medicine

JF - Science Translational Medicine

IS - 756

M1 - eadk4802

ER -

Molecular dissection of cobra venom highlights heparinoids as an antidote for spitting cobra envenoming

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