By Kristin Baldwin, Ph.D. -



A team led by scientists from The Scripps Research Institute (TSRI) has found a simple method to convert human skin cells into the specialized neurons that detect pain, itch, touch and other bodily sensations. These neurons are also affected by spinal cord injury and involved in Friedreich's ataxia, a devastating and currently incurable neurodegenerative disease that largely strikes children.



The discovery allows this broad class of human neurons and their sensory mechanisms to be studied relatively easily in the laboratory. The "induced sensory neurons" generated by this method should also be useful in the testing of potential new therapies for pain, itch and related conditions.



The discovery allows this broad class of human neurons and their sensory mechanisms to be studied relatively easily in the laboratory. The “induced sensory neurons” generated by this method should also be useful in the testing of potential new therapies for pain, itch and related conditions.



“Following on the work of TSRI Professor Ardem Patapoutian, who has identified many of the genes that endow these neurons with selective responses to temperature, pain and pressure, we have found a way to produce induced sensory neurons from humans where these genes can be expressed in their ‘normal’ cellular environment,” said Associate Professor Kristin K. Baldwin, an investigator in TSRI’s Dorris Neuroscience Center. “This method is rapid, robust and scalable. Therefore we hope that these induced sensory neurons will allow our group and others to identify new compounds that block pain and itch and to better understand and treat neurodegenerative disease and spinal cord injury.”



The report by Baldwin’s team appears as an advance online publication in Nature Neuroscience on November 24, 2014.



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Ref: Joel W Blanchard, Kevin T Eade, Attila Szűcs, Valentina Lo Sardo, Rachel K Tsunemoto, Daniel Williams, Pietro Paolo Sanna, Kristin K Baldwin. Selective conversion of fibroblasts into peripheral sensory neurons. Nature Neuroscience, 2014; DOI: 10.1038/nn.3887