Abstract
Distinct firing properties among touch receptors are influenced by multiple, interworking anatomical structures. Our understanding of the functions and crosstalk of Merkel cells and their associated neurites—the end organs of slowly adapting type I (SAI) afferents—remains incomplete. Piezo2 mechanically activated channels are required both in Merkel cells and in sensory neurons for canonical SAI responses in rodents; however, a central unanswered question is how rapidly inactivating currents give rise to sustained action potential volleys in SAI afferents. The computational model herein synthesizes mechanotransduction currents originating from Merkel cells and neurites, in context of skin mechanics and neural dynamics. Its goal is to mimic distinct spike firing patterns from wildtype animals, as well as Atoh1 knockout animals that completely lack Merkel cells. The developed generator function includes a Merkel cell mechanism that represents its mechanotransduction currents and downstream voltage-activated conductances (slower decay of current) and a neurite mechanism that represents its mechanotransduction currents (faster decay of current). To mimic sustained firing in wildtype animals, a longer time constant was needed than the 200 ms observed for mechanically activated membrane depolarizations in rodent Merkel cells. One mechanism that suffices is to introduce an ultra-slowly inactivating current, with a time constant on the order of 1.7 s. This mechanism may drive the slow adaptation of the sustained response, for which the skin’s viscoelastic relaxation cannot account. Positioned within the sensory neuron, this source of current reconciles the physiology and anatomical characteristics of Atoh1 knockout animals.
Highlights
A diverse array of touch receptors signal information from the periphery to the central nervous system, enabling the detection of objects we encounter at our skin surface [1,2]
Slowly-adapting type I (SAI) cutaneous afferents help us discriminate fine spatial details. Their physiology and anatomy are distinguished by their slow adaptation in firing to held stimuli and innervation of Merkel cells, respectively
As well as Atoh1 conditional knockout animals that lack Merkel cells, this effort employs a computational modeling approach constrained by biological measurements
Summary
A diverse array of touch receptors signal information from the periphery to the central nervous system, enabling the detection of objects we encounter at our skin surface [1,2]. At least four classes of afferents serve to signal mechanical interactions, each tuned to extract specific features of a tactile stimulus. These classes of mechanosensory afferents encode tactile stimuli as trains of action potentials, or spikes, each with distinctive firing properties. One class of mechanosensitive neurons, myelinated Aβ slowly-adapting type I (SAI) afferents, are gentle touch receptors that encode edges and curvature. These mechanoreceptors localize to skin regions specialized for high tactile acuity, including fingertips, whisker follicles and touch domes. Several physiological characteristics distinguish SAI afferents from other mechanosensitive classes of neurons: 1) association with epidermal Merkel cells, 2) high frequency responses to moving stimuli, 3) slowly adapting responses to held stimuli, 4) irregular firing patterns with large variability in inter-spike intervals, and 5) sensitivities to a wide range of stimulus forces
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