How the Bug Has Its Wings: Scientists (Finally!) Tell the Story



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WOODS HOLE, Mass. – Sounds like “Just So Story” – “How the Insect Got its Wings” – but it’s truly a mystery that has puzzled biologists for over a century. Intriguing and conflicting theories about the evolution of insect wings have emerged in recent years, but none have been entirely satisfactory. Finally, a team from the Marine Biological Laboratory (MBL), Woods Hole, resolved the controversy, using clues from long-ago scientific papers and cutting-edge genomic approaches. The study, led by MBL Research Associate Heather Bruce and MBL Director Nipam Patel, was published this week in Nature, ecology and evolution.

Insect wings, the team confirmed, evolved from a growth or ‘lobe’ on the legs of an ancestral crustacean (yes, crustacean). After this marine animal moved to Earth’s home some 300 million years ago, the leg segments closest to its body were incorporated into the body wall during embryonic development, perhaps to better support its weight on earth. “The leg lobes then moved to the insect’s back, and those later formed wings,” says Bruce.

One of the reasons it took a century to figure this out, Bruce says, is that it wasn’t appreciated until about 2010 that insects are more closely related to crustaceans within the arthropod phylum, as revealed by genetic similarities.

“Previously, based on morphology, everyone had classified insects into the myriapod group, along with millipedes and millipedes,” says Bruce. “And if you search myriapods for the origin of insect wings, you won’t find anything,” he says. ‘So the insect wings were thought of as’ new ‘structures that arose in insects and didn’t have a corresponding structure in the ancestor, because the researchers were looking for the insect’s ancestor in the wrong place.’

“People are very excited about the idea that something like insect wings may have been a new breakthrough of evolution,” says Patel. “But one of the stories that emerges from genomic comparisons is that nothing is brand new; everything came from somewhere. And you can, in fact, figure out where.”

Bruce caught the smell of his now reported discovery as he compared the genetic instructions for the segmented legs of a crustacean, the tiny beach jumper Parhyaleand the segmented legs of insects, including the fruit fly Drosophila and the scarab Tribolium. Using CRISPR-Cas9 gene editing, he systematically disabled five leg modeling genes shared in Parhyale and in insects, and I found that those genes corresponded to the six leg segments that are furthest from the body wall. Parhyale, however, he has an additional seventh leg segment near his body wall. Where did that segment go, he wondered? “And so I started digging into the literature, and I found this really old idea that was proposed in 1893, that insects had incorporated their [closest to body] leg region in the body wall, “he says.

“But I didn’t have the story wing part yet,” he says. “So I kept reading and reading, and I came across this 1980s theory that not only did insects embed their proximal leg region into the body wall, but the small lobes on the leg later moved to the back. and they formed wings., wow, my genomic and embryonic data support these old theories. “

It would have been impossible to solve this long-standing conundrum without the tools now available to probe the genomes of a myriad of organisms, including Parhyale, which the Patel laboratory has developed as the most genetically tractable research organism among crustaceans.

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The Marine Biological Laboratory (MBL) is dedicated to scientific discovery by exploring fundamental biology, understanding marine biodiversity and the environment, and informing the human condition through research and education. Founded in Woods Hole, Massachusetts in 1888, the MBL is a private nonprofit institution affiliated with the University of Chicago.

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