Disengaging spinal afferent nerve communication with the brain in live mice

Melinda A. Kyloh; Timothy J. Hibberd; Joel Castro; Andrea M. Harrington; Lee Travis; Kelsi N. Dodds; Lukasz Wiklendt; Stuart M. Brierley; Vladimir P. Zagorodnyuk; Nick J. Spencer

doi:10.1038/s42003-022-03876-x

Disengaging spinal afferent nerve communication with the brain in live mice

Melinda A. Kyloh, Timothy J. Hibberd, Joel Castro, Andrea M. Harrington, Lee Travis, Kelsi N. Dodds, Lukasz Wiklendt, Stuart M. Brierley, Vladimir P. Zagorodnyuk, Nick J. Spencer

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

Our understanding of how abdominal organs (like the gut) communicate with the brain, via sensory nerves, has been limited by a lack of techniques to selectively activate or inhibit populations of spinal primary afferent neurons within dorsal root ganglia (DRG), of live animals. We report a survival surgery technique in mice, where select DRG are surgically removed (unilaterally or bilaterally), without interfering with other sensory or motor nerves. Using this approach, pain responses evoked by rectal distension were abolished by bilateral lumbosacral L5-S1 DRG removal, but not thoracolumbar T13-L1 DRG removal. However, animals lacking T13-L1 or L5-S1 DRG both showed reduced pain sensitivity to distal colonic distension. Removal of DRG led to selective loss of peripheral CGRP-expressing spinal afferent axons innervating visceral organs, arising from discrete spinal segments. This method thus allows spinal segment-specific determination of sensory pathway functions in conscious, free-to-move animals, without genetic modification.

Original language	English
Article number	915
Journal	Communications Biology
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s42003-022-03876-x
Publication status	Published or Issued - Dec 2022

ASJC Scopus subject areas

Medicine (miscellaneous)
General Biochemistry,Genetics and Molecular Biology
General Agricultural and Biological Sciences

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title = "Disengaging spinal afferent nerve communication with the brain in live mice",

abstract = "Our understanding of how abdominal organs (like the gut) communicate with the brain, via sensory nerves, has been limited by a lack of techniques to selectively activate or inhibit populations of spinal primary afferent neurons within dorsal root ganglia (DRG), of live animals. We report a survival surgery technique in mice, where select DRG are surgically removed (unilaterally or bilaterally), without interfering with other sensory or motor nerves. Using this approach, pain responses evoked by rectal distension were abolished by bilateral lumbosacral L5-S1 DRG removal, but not thoracolumbar T13-L1 DRG removal. However, animals lacking T13-L1 or L5-S1 DRG both showed reduced pain sensitivity to distal colonic distension. Removal of DRG led to selective loss of peripheral CGRP-expressing spinal afferent axons innervating visceral organs, arising from discrete spinal segments. This method thus allows spinal segment-specific determination of sensory pathway functions in conscious, free-to-move animals, without genetic modification.",

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AU - Hibberd, Timothy J.

AU - Castro, Joel

AU - Harrington, Andrea M.

AU - Travis, Lee

AU - Dodds, Kelsi N.

AU - Wiklendt, Lukasz

AU - Brierley, Stuart M.

AU - Zagorodnyuk, Vladimir P.

AU - Spencer, Nick J.

PY - 2022/12

Y1 - 2022/12

N2 - Our understanding of how abdominal organs (like the gut) communicate with the brain, via sensory nerves, has been limited by a lack of techniques to selectively activate or inhibit populations of spinal primary afferent neurons within dorsal root ganglia (DRG), of live animals. We report a survival surgery technique in mice, where select DRG are surgically removed (unilaterally or bilaterally), without interfering with other sensory or motor nerves. Using this approach, pain responses evoked by rectal distension were abolished by bilateral lumbosacral L5-S1 DRG removal, but not thoracolumbar T13-L1 DRG removal. However, animals lacking T13-L1 or L5-S1 DRG both showed reduced pain sensitivity to distal colonic distension. Removal of DRG led to selective loss of peripheral CGRP-expressing spinal afferent axons innervating visceral organs, arising from discrete spinal segments. This method thus allows spinal segment-specific determination of sensory pathway functions in conscious, free-to-move animals, without genetic modification.

AB - Our understanding of how abdominal organs (like the gut) communicate with the brain, via sensory nerves, has been limited by a lack of techniques to selectively activate or inhibit populations of spinal primary afferent neurons within dorsal root ganglia (DRG), of live animals. We report a survival surgery technique in mice, where select DRG are surgically removed (unilaterally or bilaterally), without interfering with other sensory or motor nerves. Using this approach, pain responses evoked by rectal distension were abolished by bilateral lumbosacral L5-S1 DRG removal, but not thoracolumbar T13-L1 DRG removal. However, animals lacking T13-L1 or L5-S1 DRG both showed reduced pain sensitivity to distal colonic distension. Removal of DRG led to selective loss of peripheral CGRP-expressing spinal afferent axons innervating visceral organs, arising from discrete spinal segments. This method thus allows spinal segment-specific determination of sensory pathway functions in conscious, free-to-move animals, without genetic modification.

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Disengaging spinal afferent nerve communication with the brain in live mice

Abstract

ASJC Scopus subject areas

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