Long-term male-specific chronic pain via telomere- and p53‑mediated spinal cord cellular senescence
Arjun Muralidharan, Susana G. Sotocinal, Noosha Yousefpour, Nur Akkurt, Lucas V. Lima, Shannon Tansley, Marc Parisien, Chengyang Wang, Jean-Sebastien Austin, Boram Ham, Gabrielle M.G.S. Dutra, Philippe Rousseau, Sioui Maldonado-Bouchard, Teleri Clark, Sarah F. Rosen, Mariam R. Majeed, Olivia Silva, Rachel Nejade, Xinyu Li, Stephania Donayre Pimentel, Christopher S. Nielsen, G. Gregory Neely, Chantal Autexier, Luda Diatchenko, Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil
Arjun Muralidharan, Susana G. Sotocinal, Noosha Yousefpour, Nur Akkurt, Lucas V. Lima, Shannon Tansley, Marc Parisien, Chengyang Wang, Jean-Sebastien Austin, Boram Ham, Gabrielle M.G.S. Dutra, Philippe Rousseau, Sioui Maldonado-Bouchard, Teleri Clark, Sarah F. Rosen, Mariam R. Majeed, Olivia Silva, Rachel Nejade, Xinyu Li, Stephania Donayre Pimentel, Christopher S. Nielsen, G. Gregory Neely, Chantal Autexier, Luda Diatchenko, Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil
View: Text | PDF
Research Article Neuroscience

Long-term male-specific chronic pain via telomere- and p53‑mediated spinal cord cellular senescence

Abstract

Mice with experimental nerve damage can display long‑lasting neuropathic pain behavior. We show here that 4 months and later after nerve injury, male but not female mice displayed telomere length (TL) reduction and p53‑mediated cellular senescence in the spinal cord, resulting in maintenance of pain and associated with decreased lifespan. Nerve injury increased the number of p53‑positive spinal cord neurons, astrocytes, and microglia, but only in microglia was the increase male‑specific, matching a robust sex specificity of TL reduction in this cell type, which has been previously implicated in male‑specific pain processing. Pain hypersensitivity was reversed by repeated intrathecal administration of a p53‑specific senolytic peptide, only in male mice and only many months after injury. Analysis of UK Biobank data revealed sex-specific relevance of this pathway in humans, featuring male‑specific genetic association of the human p53 locus (TP53) with chronic pain and a male-specific effect of chronic pain on mortality. Our findings demonstrate the existence of a biological mechanism maintaining pain behavior, at least in males, occurring much later than the time span of virtually all extant preclinical studies.

Authors

Arjun Muralidharan, Susana G. Sotocinal, Noosha Yousefpour, Nur Akkurt, Lucas V. Lima, Shannon Tansley, Marc Parisien, Chengyang Wang, Jean-Sebastien Austin, Boram Ham, Gabrielle M.G.S. Dutra, Philippe Rousseau, Sioui Maldonado-Bouchard, Teleri Clark, Sarah F. Rosen, Mariam R. Majeed, Olivia Silva, Rachel Nejade, Xinyu Li, Stephania Donayre Pimentel, Christopher S. Nielsen, G. Gregory Neely, Chantal Autexier, Luda Diatchenko, Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil

×

Figure 5

Sex-dependent upregulation of p53 by distinct spinal cord cell type 14 months after SNI.

Options: View larger image (or click on image) Download as PowerPoint
Sex-dependent upregulation of p53 by distinct spinal cord cell type 14 m...
(A) Three-dimensional representative image of neurons (blue), astrocytes (red), microglia (magenta), and p53 (green) captured from the lumbar ipsilateral dorsal horn of an SNI-treated mouse. Insets in A show individual cells (1, 2, and 3) sampled from the image, and for each selected cell, a surface-rendered view is shown to demonstrate p53 expression in each cell type. Scale bar: 10 μm. (B) Quantification of p53‑positive cells by surgery (sham vs. SNI) and sex. Bars represent mean ± SEM number of cells containing p53 signal; n = 3–4 mice/surgery/sex, with each point representing an average of 3–7 scored sections per mouse. (CE) Percentage of p53-positive cells also showing immunofluorescence for NeuN (C, neurons), GFAP (D, astrocytes), or Iba1 (E, microglia). Bars as in B. **P < 0.01, ***P < 0.001 compared with all other groups, or as indicated, via 2-way ANOVA.