Email Print Share

Research News

Toxic tiger rattlesnake venom advances genetic science techniques

Study of simplest yet most toxic venom will help explain array of genetic questions

Mark Margres photographs an Eastern Diamondback Rattlesnake

Biologist Mark Margres with an Eastern diamondback rattlesnake on Caladesi Island, Florida.


January 26, 2021

The tiger rattlesnake possesses the simplest, yet most toxic, venom of any rattlesnake species. Now new research led by a University of South Florida biologist explains the genetics behind the predator's fearsome bite.

The research is published in the journal Proceedings of the National Academy of Sciences. USF biologist Mark Margres and his colleagues sequenced the genome of the tiger rattlesnake to understand the genotype of the venom trait. Despite the simplicity of the rattlesnake's venom, Margres says it is roughly 40 times more toxic than the venom of the Eastern diamondback rattlesnake in Florida.

The U.S. National Science Foundation-funded work is the most complete characterization of the venom gene regulatory network to date, the researchers say. The identification of key mechanisms in producing the particularly toxic venom will help scientists explain a wide array of genetic questions.

"Simple genotypes can produce complex traits," Margres said. "Here, we have shown the opposite is also true -- a complex genotype can produce simple traits."

The project sought to explain whether trait differences are derived from differences in the number of genes, their sequence and how they are regulated.

An organism's genotype is the set of genes it carries; its phenotype is all its observable characteristics, which can be influenced by its genes, the environment in which it lives, and other factors. Evolutionary biologists work to understand how genes influence variations in phenotype among otherwise similar organisms. In this case, they looked at why different species of rattlesnakes differ in venom composition and toxicity.

"Advances in gene sequencing methods are allowing scientists to answer questions first asked by Darwin more than 150 years ago," says Sam Scheiner, a program director in NSF's Division of Environmental Biology. "This study is an important step forward in answering the question of where traits come from."

--  NSF Public Affairs, researchnews@nsf.gov