Skin Speaks: Directing Nerve Growth for Sensation

Summary: Researchers found that the skin, not pre-existing genetic programming, instructs nerve cells on how to mature for specific sensory tasks.

The findings showcase that skin cues determine whether nerve endings develop to detect sensations in hairy or hairless skin. If corroborated by further research, this discovery could pave the way for therapies to mend damaged nerves or better comprehend congenital neuropathies.

The key revelation emphasizes how the body’s largest organ, the skin, plays a pivotal role in neural development.

Key Facts:

  1. Skin cues, rather than predetermined genetic instructions, direct nerve cells on their sensory development.
  2. Nerve endings in skin adapt their shape, size, and structure depending on their destination—hairy or hairless regions.
  3. Molecules known as BMP5 and BMP7, expressed predominantly in hairless skin, are vital for certain sensory nerve developments.

Source: Harvard

Nerve cells that sense touch grow the appropriate endings for hairy or hairless skin based on cues from the skin itself, rather than through predetermined programming, according to research led by Harvard Medical School scientists and published Aug. 21 in Developmental Cell

If affirmed in further studies, the findings could eventually help researchers develop therapies to regenerate damaged or diseased nerves, the authors say, or better understand what goes awry in congenital neuropathies, conditions in individuals born with sensory nerve defects.  

“The take-home message is that it’s the skin that tells unspecified neurons how to mature in shape, size, and structure to become the ending type appropriate for that specific skin region,” said study senior author David Ginty, chair of the Department of Neurobiology at the Blavatnik Institute at HMS and a Howard Hughes Medical Institute investigator.

The study was led by Charalampia Koutsioumpa, a former graduate student in the Ginty Lab who is now a neurology resident at Yale Medicine.

About 20 or so different types of neurons innervate the skin to detect a wide range of sensations, such as temperature, pain, or touch, Ginty explained. During development, these nerve cells send extensions, called axons, from cell bodies located near the spinal cord to the skin. 

When they reach their final destinations in the skin, the axons form so-called terminations, known as end organs, which are tailored to the neurons’ functions. For example, neurons that sense light touch (called low-threshold mechanoreceptors, or LTMRs) have end organs called Meissner corpuscles if they terminate in hairless skin, such as on the palms of the hands, giving them relatively high sensing acuity. 

In contrast, those that end up in hairy skin, which covers more than 90 percent of the body surface, have end organs called lanceolate complexes with lower sensing acuity but capable of detecting nonspecific stimuli, such as touching the skin or wind blowing through hair.

Although researchers have known about these different sensory nerve types for decades, said Koutsioumpa, it has remained unclear how they arise to become so specialized. 

Two theories have floated around: Either these nerve endings have a set fate when they’re generated, sending projections to their predetermined destination of hairless or hairy skin, or they arise unspecialized, developing into one type (the highly sensitive Meissner corpuscles) or the other (the less sensitive lanceolate complexes), based on cues from the skin itself.

To determine which of these theories was correct, Koutsioumpa, Ginty, and their colleagues used mice as a model system. These animals have hairless skin on their paw pads analogous to that on humans’ palms and soles and hairy skin that covers most of the rest of their bodies.

Using a genetic labeling technique, the researchers generated mice with sensory neurons that could be seen in the skin, allowing them to track the growth of these cells starting before birth.

Although the different nerve endings in hairless and hairy skin became distinguishable within a week after birth, these neurons looked identical in utero, which meant that their differences arise later in development.

This finding gave the first clue that development of the highly sensitive Meissner corpuscles, or the less sensitive lanceolate end organs,  is not predetermined but might be dictated by final-destination skin type, Koutsioumpa said.

Over the course of this experiment, the researchers spotted some individual sensory neurons that branched into multiple endings at border regions between hairless and hairy skin. Although these endings sprang from the same cell body, they developed Meissner corpuscles and lanceolate end organs depending on whether their endings were in hairless or hairy territory.

Again, this finding supported the notion that end organs developed based on signals from the skin the neurons ended up innervating. In other words, the shape, size, structure — and ultimately fate — of these neurons were modulated by cues from the skin type they served.

In another experiment, the researchers worked with mice carrying a mutation that gave them hairless skin not only on their paw pads, but on the tops of their paws as well. Although this mutation presumably affected just the skin itself, an examination of the sensory neurons innervating the paw tops showed that they developed highly sensitive Meissner corpuscles, just like those in the paw pad skin, suggesting that a signal from the skin had influenced neural type development.

When the researchers searched for molecules that might serve as that signal, previous research and their own experiments suggested two candidates, known as bone morphogenic proteins 5 and 7 (BMP5 and BMP7), that were heavily expressed in hairless skin. 

Sure enough, when the researchers genetically altered mice to remove the receptors for this family of proteins, their hairless skin had far fewer Meissner corpuscles, and those that remained developed abnormally.

Although BMP5 and BMP7 appear to be key for Meissner corpuscle development, the researchers did not identify any candidate signal molecules for lanceolate complexes.

Together, Koutsioumpa said, these findings suggest that skin type determines which end organs sensory neurons will develop, a finding that could influence efforts to regenerate sensory neurons in the skin. It could also eventually help researchers develop treatments for sensory neuropathies, one of the conditions that she plans to treat as a neurologist.

“Sensory neuropathies are some of the most common inherited neurological disorders,” Koutsioumpa said. “Our work might give some clues to therapies in the future.”

Authorship, funding, disclosures

Additional authors include Celine Santiago, Kiani Jacobs, Brendan P. Lehnert, Victor Barrera, John N. Hutchinson, Dhane Schmelyun, Jessica A. Lehoczky, and David L. Paul.

Funding: This work was funded by a Boehringer Ingelheim Fonds fellowship, an Onassis Scholarship, the Harvard Medical School Foundry Program, a grant from the National Institutes of Health (R35 5R35NS097344-05).

About this neuroscience research news

Author: Ekaterina Pesheva
Source: Harvard
Contact: Ekaterina Pesheva – Harvard
Image: The image is credited to Neuroscience News

Original Research: Open access.
“Skin-type-dependent development of murine mechanosensory neurons” by David Ginty et al. Developmental Cell


Abstract

Skin-type-dependent development of murine mechanosensory neurons

Mechanosensory neurons innervating the skin underlie our sense of touch. Fast-conducting, rapidly adapting mechanoreceptors innervating glabrous (non-hairy) skin form Meissner corpuscles, while in hairy skin, they associate with hair follicles, forming longitudinal lanceolate endings. How mechanoreceptors develop axonal endings appropriate for their skin targets is unknown.

We report that mechanoreceptor morphologies across different skin regions are indistinguishable during early development but diverge post-natally, in parallel with skin maturation. Neurons terminating along the glabrous and hairy skin border exhibit hybrid morphologies, forming both Meissner corpuscles and lanceolate endings.

Additionally, molecular profiles of neonatal glabrous and hairy skin-innervating neurons largely overlap. In mouse mutants with ectopic glabrous skin, mechanosensory neurons form end-organs appropriate for the altered skin type.

Finally, BMP5 and BMP7 are enriched in glabrous skin, and signaling through type I bone morphogenetic protein (BMP) receptors in neurons is critical for Meissner corpuscle morphology. Thus, mechanoreceptor morphogenesis is flexibly instructed by target tissues.

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