Date: January 8, 2015-Source: Genetics Society of America
Venom
from an eastern diamondback rattlesnake in the Everglades is distinct
from the cocktail of toxins delivered by the same species in the Florida
panhandle area, some 500 miles away. But no matter where you go in the
Southeastern United States, the venom of the eastern coral snake is
always the same. The results of a large-scale survey of venom variation
in the two snake species, published January 8, 2015 in the journal
Genetics, challenge common assumptions in venom evolution research,
provide crucial information for rattlesnake conservation, and will help
coral snake antivenom development.
Each
venomous snake species produces a unique venom, a mixture of around
50-200 toxic proteins and protein fragments that co-evolve with the
typical prey of the snake, such as the smaller reptiles eaten by the
eastern coral snake or the rodents preferred by rattlesnakes. In this
cycle of evolutionary attack and counterattack, any genetic variants
that enhance venom resistance tend to spread through the prey
population, prompting tweaks to the snake venom recipe that restore its
effectiveness.
The
result should be distinctive local co-adaptations between predator and
prey, as well as considerable regional diversity in the types and
amounts of the different venom proteins. But when Darin Rokyta (Florida
State University) and his colleagues collected and profiled venom from
eastern coral snakes at many sites within Florida, they found no
variation at all. The mix of proteins in coral snake venom from one part
of the state was indistinguishable from that collected anywhere else.
In contrast, eastern diamondbacks, which live in the same parts of the
country as the coral snakes, produce venom with different ratios of
toxic proteins in nearly every sub-population across their range. For
example, two venom components, including one known to cause paralysis in
prey, are found at high levels in the northernmost populations, and
were completely absent in the snakes from Caladesi Island, near Tampa.
"We
were shocked," Rokyta said. "This is the first time anyone has looked
at venom variation at this scale, and everybody has assumed that the
co-evolutionary arms race would cause local populations to diverge
quickly."
Rokyta
says there could be several explanations for the lack of variation in
eastern coral snake venom. For example, a small population of the
species might have recently expanded and taken over the entire range,
displacing other populations and reducing genetic diversity. Or it could
reflect a difference in co-evolutionary dynamics between the species
and its typically reptilian prey, compared to the small mammals
preferred by rattlesnakes. The team is now using genetic clues to the
population histories of each species to investigate possible
explanations.
The
results of the study will be helpful to researchers developing eastern
coral snake antivenom. Making an antivenom requires samples of venom,
but if the mix varies substantially from place to place, this will
affect the drug's effectiveness and reliability. For this species,
sampling from many populations should not be necessary. "This tells us
it doesn't matter where we catch these relatively elusive snakes; we can
stick to using those locations where they're easy to find," Rokyta
said.
The
variation between eastern diamondback populations could provide crucial
information to authorities managing the conservation of this species,
which is in decline and under consideration for listing as threatened
under the Endangered Species Act. Eastern diamondback rattlesnake
declines are thought to have been caused by habitat loss compounded by
hunting and persecution by humans. The data from this study can be used
for population management, to ensure the full range of venom subtypes
are conserved for the long-term viability of the species.
"The
received wisdom was that venoms are rapidly-evolving, but now we know
that's not necessarily the case." said Mark Johnston, Editor-in-Chief of
GENETICS. "Clearly, venom evolution in these two snake species has been
shaped by different forces. The next challenge is to understand why."
Story Source:
The above story is based on materials provided by Genetics Society of America. Note: Materials may be edited for content and length.
Journal Reference:
- M. J. Margres, J. J. McGivern, M. Seavy, K. P. Wray, J. Facente, D. R. Rokyta. Contrasting Modes and Tempos of Venom Expression Evolution in Two Snake Species. Genetics, 2014; DOI: 10.1534/genetics.114.172437
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