When immature neurons are placed on a microscopic running track, where flanking lanes are carpeted with repellent factors, their growing axons remain in their lanes (top). Neurons from mice lacking p75 are unreceptive to repulsive cues: when placed on the track, their axons meander all over the field, crossing lanes and running down repellent-covered stripes (bottom). Credit: Courtesy of Dr. Yoo-Shick Lim, Salk Institute for Biological Studies.
But the clincher was the "stripe assay," a classical screen for guidance molecules that repel growing axons. In it, an immature neuron is placed on a microscopic running track, just as it starts to develop an axon. When flanking lanes are carpeted with repellent factors, the sprouting axon bursts from the block but remains in its lane like a well-coached runner, avoiding neighbouring tracks. Constructing tracks made from the repulsive factor sensed by ephrin-A, the researchers confirmed that axons from normal retinal neurons stayed in their lanes when flanked by the repellent. But neurons from mice lacking p75 were unreceptive to repulsive cues: when placed on the track their axons meandered all over the field, crossing lanes and running down repellent-covered stripes. Why retinal neurons missed the target in the p75-minus mice became clear: they lacked the cellular machinery to respond to critical repellent signals encountered in the brain and stopped migrating prematurely. Among its myriad functions, p75's new role is a critical one. "Repulsion is probably the dominant force in axon guidance and a stronger influence than attraction," explains McLaughlin, noting that providing axons with a lot of options is not the way to build a brain. "Attraction is like finding the best seat in an empty movie theatre, but repulsion is like picking the lone empty seat in a full theatre." "We have shown that ephrin-A cannot transduce an intracellular signal by itself and instead requires the co-receptor p75," summarizes Yoo-Shick Lim, Ph.D., a postdoctoral fellow in the O'Leary lab and co-first author. "This interaction could operate in numerous events in neural development." O'Leary believes that identifying mechanisms underlying developmental events is fundamental to understanding the basis of any biological disorder. "These studies establish that two distinct molecular systems, neurotrophins and axon guidance, both critical for neural development directly collaborate to develop neural connectivity”. “Findings such as these lend critical insight into how one might repair damage to the nervous system due to genetic defects, tumours or wounds to the brain or spinal cord," he says. "We hope one day to be able to repair these defects and get cells to form functional connections again." About The Salk Institute: The Salk Institute for Biological Studies in La Jolla, California, is an independent non-profit organization dedicated to fundamental discoveries in the life sciences, the improvement of human health and the training of future generations of researchers. Jonas Salk, MD, whose polio vaccine all but eradicated the crippling disease poliomyelitis in 1955, opened the Institute in 1965 with a gift of land from the City of San Diego and the financial support of the March of Dimes. Reference: p75NTR Mediates Ephrin-A Reverse Signaling Required for Axon Repulsion and Mapping Yoo-Shick Lim, Todd McLaughlin, Tsung-Chang Sung, Alicia Santiago, Kuo-Fen Lee, and Dennis D.M. O'Leary Neuron, Vol 59, 746-758, 11 September 2008 ......... ZenMaster
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