Science News by Laurel Hamers
9/15/16
Modern rattlesnakes have pared
down their weaponry stockpile from their ancestor’s massive arsenal. Today’s
rattlers have irreversibly lost entire toxin-producing genes over the course of
evolution, narrowing the range of toxins in their venom, scientists report
September 15 in Current Biology.
“After going through all the work
of evolving powerful toxins, over time, some snakes have dispensed with them,”
says study coauthor Sean B. Carroll, an investigator with the Howard Hughes
Medical Institute who is at the University of Wisconsin–Madison. These modern
rattlesnakes produce smaller sets of toxins that might be more specialized to
their prey.
Carroll, an evolutionary
biologist, and his colleagues focused on a family of enzymes called
phospholipase A2, or PLA2. Genes in the PLA2 family are one of the main sources
of toxic proteins in the deadly cocktail of rattlesnake venom. This set of
genes can be shuffled around, added to and deleted from to yield different
collections of toxins.
Data from the genome — the
complete catalog of an organism’s genetic material — can reveal how those
genetic gymnastics have played out over time. Carroll’s team looked at the
relevant genome regions in three modern rattlesnake species (western
diamondback, eastern diamondback and Mojave) and also measured molecules that
help turn genetic instructions into proteins. That showed not just how the
genes were arranged, but which genes the snakes were actually using. Then, the
scientists blended that data with genetic information about other closely
related rattlesnakes to construct a potential evolutionary story for the loss
of PLA2 genes in one group of snakes.
The most recent common ancestor
of this group probably had a large suite of PLA2 genes 22 million years ago,
the scientists found. That collection of genes, which probably came about
through many gene duplications, coded for toxins affecting the brain, blood and
muscles of the snake’s prey. But 4 million to 7 million years ago, some
rattlesnake species independently dropped different combinations of those genes
to get smaller and more specialized sets of venom toxins. For instance, three
closely related rattlesnake species in the group lost the genes that made their
venom neurotoxic.
“The surprise is [the genes’]
wholesale loss at two levels: complete disappearance from the venom and
complete disappearance from the genome,” Carroll says. In other words, some of
the genes are still lurking in the genome but aren’t turned on. The proteins
those genes produce don’t show up in the venom in modern snakes. But other
genes have left the genome entirely — a more dramatic strategy than simple
changes in gene regulation.
Environmental shifts might have
encouraged this offloading of evolutionary baggage, Carroll says. If a certain
snake species’ main food source stopped responding to a neurotoxin, the snake
would waste energy producing a protein that didn’t do anything helpful.
Plus, a rattlesnake doesn’t just
invest in producing venom. It also needs to produce antibodies and other
proteins to protect itself from its own poison, says Todd Castoe, an
evolutionary biologist at the University of Texas at Arlington who wasn’t
involved in the study. As a snake’s weapon becomes more complex, its shield
does too — and that protection can use up resources.
Researchers also found that venom
genes might not be consistent even within a single species of rattlesnake,
perhaps because snakes in different areas specialize in different prey. One
western diamondback rattlesnake that Carroll’s team sampled had unexpected
extra genes that the other western diamondbacks didn’t have. His lab is
currently looking into these within-species differences in venom composition to
see how dynamic the PLA2 genome region still is today.
As for the ancestral rattlesnake,
it’s impossible to say exactly how powerful the now-extinct reptile’s venom
was, Carroll says. But the wider variety of enzymes this rattlesnake could
hypothetically produce would have given it more flexibility to adapt its poison
to environmental curveballs — an ability that Castoe describes as “the pinnacle
of nastiness.”
Editor's note: Sean B. Carroll is
on the board of trustees of Society for Science & the Public, which
publishes Science News.
Citations
N. Dowell et al. The deep origin
and recent loss of venom toxin genes in rattlesnakes. Current Biology.
Published online September 15, 2016. doi:10.1016/j.cub/2016.07.038.
Further Reading
T.H. Saey. Evolution of venom,
binge eating seen in snake DNA. Science News, Vol. 185, January 11, 2014, p. 7.
L. Sanders. Venom hunters.
Science News. Vol. 176, August 15, 2009, p. 16.
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