Most animal neurons pick up information through branching structures, called dendrites, before sending sensory signals to the neuron's axon, which then passes the signal to the central nervous system for processing. But not all neurons are constructed this way. The neurons of many invertebrates pick up sensory signals through slender structures called cilia, which can communicate the senses of vision, smell and body position. While the damaged axons of conventional neurons are capable of regeneration, no one knew whether injured ciliated neuron axons could recover. As Drosophila larvae are packed full of sensory ciliated neurons and the insects come complete with a box of molecular tools – which allows researchers to answer specific physiological questions – Melissa Rolls and her colleagues, Michelle Stone and Abigail Mauger, all from Pennsylvania State University, USA, decided to find out whether the severed axons of Drosophila larva ciliated neurons could recover and, if so, how.But first the trio had to select the ideal type of neuron for their experiment. Realising that they would require one that was close to the surface of the larva's body, so they could see it with ease, they selected the lateral monoscolopidial chordotonal organ (lch1), which projects cilia into the side of the larva and detects stretching as it moves. Then, the team severed several lch1 axons with a high-precision UV laser, to be sure that the neuron could survive the injury. Fortunately, 24 h after the procedure, the neurons were still alive. Cutting them had not been fatal, but could they regrow a new axon?Cutting the lch1 axons of 33 larvae near the tip – 70 μm along the length of each – the team was impressed to see that more than half of the severed axon stumps regrew, with some re-joining the same bundle of nerves, while others joined a different nerve nearby, just like the regrowing axons of neurons with dendrites. But what would happen if a ciliated neuron's axon was removed entirely, after being severed close to the cell body at the heart of the neuron? Could the ciliated neuron recover from this more severe damage?Impressively, yes. Almost all of the severed ciliated neurons began sprouting new structures called neurites – which can eventually grow into axons – 96 h later and they did this from different locations on the neuron, including the cell body, the remaining axon stump and even the base of the sensory cilium. The team admits that this was surprising, as conventional neurons regrow axons from the base of dendrites. In addition, newly grown axons from neurons with dendrites follow the path of other axons and are unbranched, whereas the ciliated neuron's regrown neurites were branched. And when the team checked whether the ciliated neurons were using the same cellular mechanism as conventional neurons to trigger neurite growth, they found they were, even though the resulting neurite growth looked so different from conventional axon regrowth.But would the new neurites of ciliated neurons eventually develop into axons or some other cellular component, such as a dendrite? Checking for signs that the neurites were destined to become axons, the team found strong evidence that they were, although some of the branching structures also had the characteristics of dendrites.Having suspected that insect ciliated neurons wouldn't be capable of regrowing damaged axons as effectively as conventional neurons, Rolls and her colleagues were impressed by the cell's versatility. Not only can they regenerate completely severed axons, but they do so using the same mechanism as damaged conventional neurons to successfully rebuild injured insect sensory systems.
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