News Release 11-187
A Tale of (More Than) Two Butterflies
Appalachian tiger swallowtail butterfly is hybrid of other swallowtails
September 8, 2011
This material is available primarily for archival purposes. Telephone numbers or other contact information may be out of date; please see current contact information at media contacts.
Flitting among the cool slopes of the Appalachian Mountains is a tiger swallowtail butterfly that evolved when two other species of swallowtails hybridized long ago.
It's a rarity in the animal world, biologists have found.
They discovered that the Appalachian tiger swallowtail, Papilio appalachiensis, evolved from mixing between the Eastern tiger swallowtail, P. glaucus, and the Canadian tiger swallowtail, P. canadensis.
The Appalachian tiger swallowtail rarely reproduces with its parental species and is a unique mixture of the two in both its outward traits and inward genetic makeup.
The research, published today in the journal PLoS Genetics, is funded by the National Science Foundation (NSF) and the National Institutes of Health.
"Understanding species formation is central to explaining the vast diversity of life on Earth," says Sam Scheiner, program director in NSF's Division of Environmental Biology.
"But we are just beginning to understand the process," says Scheiner. "These researchers made use of an unusual hybrid to unlock knowledge of the genetic basis of species formation."
How new species form is one of the central questions in evolutionary biology, says biologist Krushnamegh Kunte of Harvard University, lead author of the paper.
"Hybrid speciation is more common in plants, but there are very few cases in animals," says Kunte. "This study may create the fullest picture we have to date of hybrid speciation occurring in an animal."
"This is a remarkable demonstration of how hybridization can create populations with a new combination of life history and morphological traits, allowing colonization of novel environments by a 'mosaic genome,'" says biologist Larry Gilbert of the University of Texas at Austin, a co-author of the paper.
"Importantly," he says, "it demonstrates one way that new species can form."
Kunte and colleagues studied several of the eight species of North American tiger swallowtail butterflies.
These large insects are generally recognized by yellow wings with black stripes and small "tails" on their hind wings.
Of the three species, Eastern tiger swallowtails prefer warmer climes and lower elevations, and the females come in two different forms.
They are either striped--yellow and black--or almost entirely black, the latter mimicking a poisonous butterfly called the Pipevine swallowtail, Battus philenor.
Canadian tigers are only striped yellow and black, and found in cooler habitats at higher latitudes and elevations.
The Appalachian tiger exhibits a mix of those traits.
It shares an affinity for cooler habitats with the Canadian tiger, while sharing the ability to mimic the black Pipevine swallowtail with the Eastern tiger.
Digging into the butterflies' genomes, the scientists found that the Appalachian tiger inherited genes associated with cold habitats from males of the Canadian tiger, and inherited a gene for mimicry from Eastern tiger females.
They also found that the Appalachian tiger's genome has become distinct from the genomes of its two parental species, even though the butterflies come into contact with each other in the wild.
"Hybrid speciation is a controversial phenomenon, and this is especially true in animals, where clear-cut examples are exceedingly rare," says Marcus Kronforst of Harvard University, also a co-author of the paper.
The Appalachian tiger's range nudges against the Canadian tiger in the northern Appalachian Mountains, and against the Eastern tiger in the lower elevations surrounding the mountains.
The conventional view of speciation is that one species splits into two over time. With time, the species become more and more reproductively isolated from each other.
In the case of hybrid speciation, new species are formed when two species interbreed to create viable hybrids that then evolve on their own.
It can occur when two young species haven't yet evolved over a long enough period to be completely reproductively isolated.
Kunte says this is probably the case with these tiger swallowtails.
The Eastern and Canadian tigers diverged from each other a mere 600,000 years ago. The Appalachian tiger seems to have diverged from both parental species only about 100,000 years ago.
"That's not a very long time," says Kunte, "but still we found that the Appalachian tiger has been isolated long enough to have a different appearance and genetic makeup than its parent species."
As for identifying the species in the wild, Appalachian tigers are twice the size of Canadian tigers. Kunte says it's more difficult to tell apart the Eastern and Appalachian tigers.
The Eastern tiger has more blue on the hind wing and a spotted yellow band on its fore wing underside compared with a solid broad band on the Appalachian tiger.
"Once you train your eyes to tell them apart," says Kunte, "they are relatively easy to distinguish."
Other co-authors include Tom Juenger at the University of Texas at Austin.
-NSF-
-
Close-up image of the wing scales of a male eastern tiger swallowtail butterfly.
Credit and Larger Version -
Canadian tiger swallowtail butterflies are found in Canada and bordering areas of the United States.
Credit and Larger Version -
Male Appalachian tiger swallowtail feeding in Rhododendron flowers atop Spruce Knob, W.Va.
Credit and Larger Version -
Pipevine swallowtail butterfly in the Great Smoky Mountains National Park, Tennessee.
Credit and Larger Version -
Black female form, Appalachian tiger swallowtail; its wing pattern is like the pipevine swallowtail.
Credit and Larger Version
Media Contacts
Cheryl Dybas, NSF, (703) 292-7734, email: cdybas@nsf.gov
Lee Clippard, UT-Austin, (512) 232-0675, email: lclippard@mail.utexas.edu
The U.S. National Science Foundation propels the nation forward by advancing fundamental research in all fields of science and engineering. NSF supports research and people by providing facilities, instruments and funding to support their ingenuity and sustain the U.S. as a global leader in research and innovation. With a fiscal year 2023 budget of $9.5 billion, NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and institutions. Each year, NSF receives more than 40,000 competitive proposals and makes about 11,000 new awards. Those awards include support for cooperative research with industry, Arctic and Antarctic research and operations, and U.S. participation in international scientific efforts.
Connect with us online
NSF website: nsf.gov
NSF News: nsf.gov/news
For News Media: nsf.gov/news/newsroom
Statistics: nsf.gov/statistics/
Awards database: nsf.gov/awardsearch/
Follow us on social
Twitter: twitter.com/NSF
Facebook: facebook.com/US.NSF
Instagram: instagram.com/nsfgov