Preventing the death of neurons during brain growth means these ‘zombie’ cells can develop into functioning neurons, according to research in fruit flies from the Crick, the University of Lausanne (UNIL) and the Max Planck Institute for Chemical Ecology.

During brain development, a large number of neurons destroy themselves as part of an essential regulatory mechanism that removes excess cells. In certain areas of the human brain, this cellular “suicide”, which is called apoptosis, affects about 50% of neurons.

This research, published in Science Advances and conducted in fruit flies (Drosophila melanogaster), found that by stopping the death of these cells they later developed new networks of neurons, with roles and properties that are not identical to those of existing neurons.

The researchers genetically inhibited the last stage of apoptosis in neurons of the fly olfactory system. They found that the rescued ‘zombie’ cells, which would have otherwise been destroyed, developed into functioning olfactory neurons that were able to detect smells. However, the ‘zombie’ neurons expressed different olfactory receptors than their standard counterparts. For example, some of the ‘zombie’ neurons found in an olfactory organ called the maxillary palp, had receptors to detect carbon dioxide, a cue used by insects to sense the presence of animals and humans, as these exhale carbon dioxide when breathing. These extra neurons gave the flies similar characteristics to mosquitos (Anopheles gambiae), which, unlike flies, also have carbon dioxide-sensing olfactory neurons in their maxillary palps. The two species have a common ancestor that lived around 250 million years ago.

“When the neurons that normally die were protected from apoptosis they developed into ‘zombie’ neurons that have similar characteristics as certain neurons in mosquitos. Apoptosis therefore is one factor responsible for how mosquitos and fruit flies have adapted over time to their different environments,” says Lucia Prieto-Godino, co-first author and group leader of the Crick’s Neural Circuits and Evolution Laboratory.

“From an evolutionary point of view, our results suggest that changes in patterns of cell death in the nervous system could allow a species to adapt to new pressures from its environment, by enabling the evolution of new populations of neurons with novel structural and functional properties,” said Richard Benton, senior author and group leader at the Center for Integrative Genomics at UNIL.

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