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Snakes evolve a magnetic way to be resistant to venom

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IMAGE: The Sudanase red spitting cobra, another predator analysed in Dr Fry’s study. view more 

Credit: Bonnerscar

Certain snakes have evolved a unique genetic trick to avoid being eaten by venomous snakes, according to University of Queensland research.

Associate Professor Bryan Fry from UQ’s Toxin Evolution Lab said the technique worked in a manner similar to the way two sides of a magnet repel each other.

“The target of snake venom neurotoxins is a strongly negatively charged nerve receptor,” Dr Fry said.

“This has caused neurotoxins to evolve with positively charged surfaces, thereby guiding them to the neurological target to produce paralysis.

“But some snakes have evolved to replace a negatively charged amino acid on their receptor with a positively charged one, meaning the neurotoxin is repelled.

“It’s an inventive genetic mutation and it’s been completely missed until now.

“We’ve shown this trait has evolved at least 10 times in different species of snakes.”

The researchers found that the Burmese python – a slow-moving terrestrial species vulnerable to predation by cobras – is extremely neurotoxin resistant.

“Similarly, the South African mole snake, another slow-moving snake vulnerable to cobras, is also extremely resistant,” Dr Fry said.

“But Asian pythons which live in trees as babies, and Australian pythons which do not live alongside neurotoxic snake-eating snake, do not have this resistance.

“We’ve long known that some species – like the mongoose – are resistant to snake venom through a mutation that physically blocks neurotoxins by having a branch-like structure sticking out of the receptor, but this is the first time the magnet-like effect has been observed.”

“It has also evolved in venomous snakes to be resistant to their own neurotoxins on at least two occasions.”

The discovery was made after the establishment of UQ’s new $2 million biomolecular interaction facility, the Australian Biomolecular Interaction Facility (ABIF).

“There’s some incredible technology at the ABIF allowing us to screen thousands of samples a day,” Dr Fry said.

“That facility means we can do the kinds of tests that would have just been science fiction before, they would have been completely impossible.”

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The research has been published in Proceedings of the Royal Society B (DOI: 10.1098/rspb.2020.2703).

The Australian Biomolecular Interaction Facility (ABIF) was funded through a $1 million Australian Research Council Linkage Infrastructure, Equipment and Facilities (LIEF) grant, with $1 million contributing funding from UQ, Griffith University, Queensland University of Technology, James Cook University, and the University of Sunshine Coast.

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