Summary: Researchers believe the PIEZO2 gene may control specific aspects of human touch and proprioception.
NIH study of rare genetic disorder reveals importance of touch and body awareness.
With the help of two young patients with a unique neurological disorder, an initial study by scientists at the National Institutes of Health suggests that a gene called PIEZO2 controls specific aspects of human touch and proprioception, a “sixth sense” describing awareness of one’s body in space. Mutations in the gene caused the two to have movement and balance problems and the loss of some forms of touch. Despite their difficulties, they both appeared to cope with these challenges by relying heavily on vision and other senses.
“Our study highlights the critical importance of PIEZO2 and the senses it controls in our daily lives,” said Carsten G. Bönnemann, M.D., senior investigator at the NIH’s National Institute of Neurological Disorders and Stroke (NINDS) and a co-leader of the study published in the New England Journal of Medicine. “The results establish that PIEZO2 is a touch and proprioception gene in humans. Understanding its role in these senses may provide clues to a variety of neurological disorders.”
Dr. Bönnemann’s team uses cutting edge genetic techniques to help diagnose children around the world who have disorders that are difficult to characterize. The two patients in this study are unrelated, one nine and the other 19 years old. They have difficulties walking; hip, finger and foot deformities; and abnormally curved spines diagnosed as progressive scoliosis.
Working with the laboratory of Alexander T. Chesler, Ph.D., investigator at NIH’s National Center for Complementary and Integrative Health (NCCIH), the researchers discovered that the patients have mutations in the PIEZO2 gene that appear to block the normal production or activity of Piezo2 proteins in their cells. Piezo2 is what scientists call a mechanosensitive protein because it generates electrical nerve signals in response to changes in cell shape, such as when skin cells and neurons of the hand are pressed against a table. Studies in mice suggest that Piezo2 is found in the neurons that control touch and proprioception.
“As someone who studies Piezo2 in mice, working with these patients was humbling,” said Dr. Chesler. “Our results suggest they are touch-blind. The patient’s version of Piezo2 may not work, so their neurons cannot detect touch or limb movements.”
Further examinations at the NIH Clinical Center suggested the young patients lack body awareness. Blindfolding them made walking extremely difficult, causing them to stagger and stumble from side to side while assistants prevented them from falling. When the researchers compared the two patients with unaffected volunteers, they found that blindfolding the young patients made it harder for them to reliably reach for an object in front of their faces than it was for the volunteers. Without looking, the patients could not guess the direction their joints were being moved as well as the control subjects could.
The patients were also less sensitive to certain forms of touch. They could not feel vibrations from a buzzing tuning fork as well as the control subjects could. Nor could they tell the difference between one or two small ends of a caliper pressed firmly against their palms. Brain scans of one patient showed no response when the palm of her hand was brushed.
Nevertheless, the patients could feel other forms of touch. Stroking or brushing hairy skin is normally perceived as pleasant. Although they both felt the brushing of hairy skin, one claimed it felt prickly instead of the pleasant sensation reported by unaffected volunteers. Brain scans showed different activity patterns in response to brushing between unaffected volunteers and the patient who felt prickliness.
Despite these differences, the patients’ nervous systems appeared to be developing normally. They were able to feel pain, itch, and temperature normally; the nerves in their limbs conducted electricity rapidly; and their brains and cognitive abilities were similar to the control subjects of their age.
“What’s remarkable about these patients is how much their nervous systems compensate for their lack of touch and body awareness,” said Dr. Bönnemann. “It suggests the nervous system may have several alternate pathways that we can tap into when designing new therapies.”
Previous studies found that mutations in PIEZO2 may have various effects on the Piezo2 protein that may result in genetic musculoskeletal disorders, including distal arthrogryposis type 5, Gordon Syndrome, and Marden-Walker Syndrome. Drs. Bönnemann and Chesler concluded that the scoliosis and joint problems of the patients in this study suggest that Piezo2 is either directly required for the normal growth and alignment of the skeletal system or that touch and proprioception indirectly guide skeletal development.
“Our study demonstrates that bench and bedside research are connected by a two-way street,” said Dr. Chesler. “Results from basic laboratory research guided our examination of the children. Now we can take that knowledge back to the lab and use it to design future experiments investigating the role of PIEZO2 in nervous system and musculoskeletal development.”
About this genetics research article
Funding: This work was supported by the NCCIH and NINDS intramural research programs.
Source: Christopher G. Thomas – NIH Image Source: NeuroscienceNews.com image is credited to Bönnemann Lab, NIH/NINDS, Bethesda, MD. Original Research: Full open access research for “The Role of PIEZO2 in Human Mechanosensation” by Alexander T. Chesler, Ph.D., Marcin Szczot, Ph.D., Diana Bharucha-Goebel, M.D., Marta Čeko, Ph.D., Sandra Donkervoort, M.S., C.G.C., Claire Laubacher, B.A., Leslie H. Hayes, M.D., Katharine Alter, M.D., Cristiane Zampieri, Ph.D., Christopher Stanley, M.S., A. Micheil Innes, M.D., Jean K. Mah, M.D., Carla M. Grosmann, M.D., Nathaniel Bradley, B.S., David Nguyen, B.S., A. Reghan Foley, M.D., Claire E. Le Pichon, Ph.D., and Carsten G. Bönnemann, M.D. in New England Journal of Medicine. Published online September 21 2016 doi:10.1056/NEJMoa1602812
Cite This NeuroscienceNews.com Article
[cbtabs][cbtab title=”MLA”]NIH “”Sixth Sense” May Be More Than Just a Feeling.” NeuroscienceNews. NeuroscienceNews, 22 September 2016. <https://neurosciencenews.com/genetics-sixth-sense-neuroscience-5105/>.[/cbtab][cbtab title=”APA”]NIH (2016, September 22). “Sixth Sense” May Be More Than Just a Feeling. NeuroscienceNew. Retrieved September 22, 2016 from https://neurosciencenews.com/genetics-sixth-sense-neuroscience-5105/[/cbtab][cbtab title=”Chicago”]NIH “”Sixth Sense” May Be More Than Just a Feeling.” https://neurosciencenews.com/genetics-sixth-sense-neuroscience-5105/ (accessed September 22, 2016).[/cbtab][/cbtabs]
BACKGROUND The senses of touch and proprioception evoke a range of perceptions and rely on the ability to detect and transduce mechanical force. The molecular and neural mechanisms underlying these sensory functions remain poorly defined. The stretch-gated ion channel PIEZO2 has been shown to be essential for aspects of mechanosensation in model organisms.
METHODS We performed whole-exome sequencing analysis in two patients who had unique neuromuscular and skeletal symptoms, including progressive scoliosis, that did not conform to standard diagnostic classification. In vitro and messenger RNA assays, functional brain imaging, and psychophysical and kinematic tests were used to establish the effect of the genetic variants on protein function and somatosensation.
RESULTS Each patient carried compound-inactivating variants in PIEZO2, and each had a selective loss of discriminative touch perception but nevertheless responded to specific types of gentle mechanical stimulation on hairy skin. The patients had profoundly decreased proprioception leading to ataxia and dysmetria that were markedly worse in the absence of visual cues. However, they had the ability to perform a range of tasks, such as walking, talking, and writing, that are considered to rely heavily on proprioception.
CONCLUSIONS Our results show that PIEZO2 is a determinant of mechanosensation in humans. (Funded by the National Institutes of Health Intramural Research Program.)
“The Role of PIEZO2 in Human Mechanosensation” by Alexander T. Chesler, Ph.D., Marcin Szczot, Ph.D., Diana Bharucha-Goebel, M.D., Marta Čeko, Ph.D., Sandra Donkervoort, M.S., C.G.C., Claire Laubacher, B.A., Leslie H. Hayes, M.D., Katharine Alter, M.D., Cristiane Zampieri, Ph.D., Christopher Stanley, M.S., A. Micheil Innes, M.D., Jean K. Mah, M.D., Carla M. Grosmann, M.D., Nathaniel Bradley, B.S., David Nguyen, B.S., A. Reghan Foley, M.D., Claire E. Le Pichon, Ph.D., and Carsten G. Bönnemann, M.D. in New England Journal of Medicine. Published online September 21 2016 doi:10.1056/NEJMoa1602812