Proteins for anxiety in humans and moulting in insects have common origin

April 21, 2015, Queen Mary, University of London
Sea urchin. Credit: MR Elphick/QMUL

Neuropeptides are small proteins in the brains of all animals that bind to receptor proteins and cause activity in cells. The researchers at Queen Mary University of London, led by Professor Maurice Elphick, were investigating whether a particular sea urchin neuropeptide was an evolutionary link between neuropeptides in humans and insects.

The last of humans, and insects probably lived over 600 million years ago but we'll almost certainly never know what it looked like or even find an example of it in the fossil record but we can tell a lot about it by looking at genes and proteins in its evolutionary descendants.

Neuropeptide molecules are difficult to study in this way because they are small, often only a few long, much shorter than most proteins, and therefore patterns can be difficult to identify.

Dean Semmens, a PhD student at QMUL and first author of the paper said:

"The remarkable process of evolution means that molecules that once had the same function can, over hundreds of millions of years, change to control such different processes as anxiety in humans and moulting in insects.

"Despite their alien looking shape sea urchins are comparatively close relatives of humans, certainly much closer than insects. For this reason, as with this discovery, they can help us determine the evolutionary history and origins of important molecules in our brain."

A chart showing the make-up of proteins with common evolutionary ancestors. Credit: MR Elphick/QMUL

Explore further: Complex nerve-cell signaling traced back to common ancestor of humans and sea anemones

More information: Semmens DC, Beets I, Rowe ML, Blowes LM, Oliveri P, Elphick MR. 2015, Discovery of sea urchin NGFFFamide receptor unites a bilaterian neuropeptide family. Open Biol. 5: 150030.

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Or share one engineering solution. Just as standard parts from the technical catalog.

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