EMBARGO: February 7, 2019 11 AM Pacific / 2 PM Eastern Time
Newswise — Male butterflies have genes which give them a sexual preference for a partner with a similar appearance to themselves, according to new research. In a study publishing February 7th in the open-access journal PLOS Biology, a team of academics from the University of Cambridge, in collaboration with the Smithsonian Tropical Research Institute in Panama, observed the courtship rituals and sequenced the DNA from nearly 300 butterflies to find out how much of the genome was responsible for their mating behavior.
This is one of the first ever genome studies to look at butterfly behavior and it unlocks the secrets of evolution to help explain how new species are formed. The scientists sequenced the DNA from two different species of Heliconius butterflies which live either side of the Andes mountains in Colombia. Heliconians have evolved to produce their own cyanide which makes them highly poisonous and they have distinct and brightly colored wings which act as a warning to would-be predators.
Professor Chris Jiggins of the University of Cambridge, one of the lead authors on the paper, said: “There has previously been lots of research done on finding genes for things like color patterns on the butterfly wing, but it’s been more difficult to locate the genes that underlie changes in behavior.
“What we found was surprisingly simple – three regions of the genome explain a lot of their behaviors. There’s a small region of the genome that has some very big effects.”
The male butterflies were introduced to female butterflies of two species and were scored for their levels of sexual interest directed towards each. The scientists rated each session based on the number of minutes of courtship by the male – shown by sustained hovering near or actively chasing the females.
Unlike many butterflies which use scented chemical signals to identify a mate, Heliconians use their long-range vision to locate the females, which is why it’s important each species has distinct wing markings.
When a hybrid between the two species was introduced, the male would most commonly show a preference for a mate with similar markings to itself. The research showed the same area of the genome that controlled the coloration of the wings was responsible for defining a sexual preference for those same wing patterns.
Dr Richard Merrill, one of the authors of the paper, based at Ludwig-Maximilians-
The paper is one of two publishing together in PLOS Biology; the second study investigated how factors — including mate preference — act to prevent genetic mixing between the same two species of butterfly. They discovered that despite the rarity of hybrid butterflies — as a result of their reluctance to mate with one another — a surprisingly large amount of DNA has been shared between the species through hybridization. There has been ten times more sharing between these butterfly species than occurred between Neanderthals and humans.
Dr Simon Martin, one of the authors of the second paper, from the University of Edinburgh, explained: “Over a million years a very small number of hybrids in a generation is enough to significantly reshape the genomes of these butterflies.”
Despite this genetic mixing, the distinct appearance and behaviors of the two species remain intact, and have not become blended. The researchers found that there are many areas of the genome that define each species, and these are maintained by natural selection, which weeds out the foreign genes. In particular, the part of the genome that defines the sex of the butterflies is protected from the effects of inter-species mating.
As with the genetics that control mating behavior, these genes enable each butterfly type to maintain its distinctiveness and help ensure long-term survival of the species.
But can the findings translate into other species, including humans? Professor Jiggins said: “In terms of behavior, humans are unique in their capacity for learning and cultural changes, but our behavior is also influenced by our genes. Studies of simpler organisms such as butterflies can shed light on how our own behavior has evolved. Some of the patterns of gene sharing we see between the butterflies have also been documented in comparisons of the human and Neanderthal genomes, so there is another link to our own evolution.”
“Next we would like to know how novel behavior can arise and what kind of genetic changes you need to alter behavior. We already know that you can make different wing patterns by editing the genes. These studies suggest that potentially new behaviors could come about by putting different genes together in new combinations.”
In your coverage please use these URLs to provide access to the freely available articles in PLOS Biology: http://journals.plos.org/
Research article, Merrill: https://plos.io/2t8Euhm
Research article, Martin: https://plos.io/2SxNgUQ
Primer, Westerman: https://plos.io/2MP2uzb
Merrill: Merrill RM, Rastas P, Martin SH, Melo MC, Barker S, Davey J, et al. (2019) Genetic dissection of assortative mating behavior. PLoS Biol 17(2): e2005902. https://doi.org/10.1371/
Martin: Martin SH, Davey JW, Salazar C, Jiggins CD (2019) Recombination rate variation shapes barriers to introgression across butterfly genomes. PLoS Biol 17(2): e2006288. https://doi.org/10.1371/
Merrill: ERC https://erc.europa.eu (
Martin: European Research Council https://erc.europa.eu/ (grant number 339873). Funding awarded to CDJ. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Universidad del Rosariohttp://www.urosario.edu.co/ (grant number 2016-PIN-2017-001). Funding awarded to CS. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Merrill: The authors have declared that no competing interests exist.