杏吧原创

Snakes outpacing other vertebrates in race to evolve

The king cobra and Burmese python are the first snakes to have their genome sequenced, and the results show their genes are unusually prone to change
RUns rings around a mongoose, at least when it comes to evolving
RUns rings around a mongoose, at least when it comes to evolving
(Image: Michael D. Kern/naturepl.com)

It seems the slitherers got off to a fast start. The first two full snake genomes to be sequenced 鈥 belonging to the and the 鈥 show that they have one of the fastest rates of genetic evolution among vertebrates.

Snakes鈥 shape and penchant for infrequent, huge meals suggest they must have undergone a lot of evolutionary change since they diverged from other vertebrates. They also undergo enormous metabolic swings when they eat, activating thousands of genes after a meal and then shutting them down again to allow their internal organs to shrink during fasting periods.

鈥淭hey鈥檝e had to make so many changes to adapt to life as a tube,鈥 says , a geneticist at the University of Colorado at Denver.

When Pollock鈥檚 team compared nearly 7500 genes from the Burmese python and the king cobra with their counterparts in other vertebrates, they found that the snakes鈥 versions had an unusually high number of evolutionary changes, rivalling the mouse as the highest seen for any vertebrate. 鈥淭hat is extremely impressive, and a surprise even to us,鈥 says of the University of Texas at Arlington, another member of the team.

Evolutionarily nimble

Of the genes undergoing the strongest evolutionary change, many are involved in body shape and organ development, metabolism, venom production and the sense of smell.

Many of those changes were in the parts of the genes that code for proteins, rather than in the regulatory sequences that turn genes on and off. This runs counter to a long-held theory that most evolutionary change happens by altering not genes themselves but when they become active.

Pollock says that snakes鈥 genomes may be unusually prone to change because they contain many repeated sequences that promote misalignment of chromosomes and so make gene duplications more common. Many of the genes controlling the cobra鈥檚 venom gland seem to have arisen from duplications of genes otherwise used in other organs such as stomach, spleen, testes and ovaries, the team found.

This evolutionary nimbleness may make snakes more able to adapt to future challenges too, says , an evolutionary biologist at Harvard. However, he adds, snakes鈥 鈥渇ast鈥 evolutionary changes still took millions of years to accumulate. 鈥淲hether they鈥檙e labile enough to resist all the challenges of habitat loss and climate change is unclear,鈥 he says. 鈥淚t鈥檚 a different timescale.鈥

Journal reference:

Topics: Biology / Evolution / Genetics