Abstract
Estrogens are presumed to underlie, at least in part, the greater pain sensitivity and chronic pain prevalence that women experience compared to men. Although previous studies revealed populations of estrogen receptor‐expressing neurons in primary afferents and in superficial dorsal horn neurons, there is little to no information as to the contribution of these neurons to the generation of acute and chronic pain. Here we molecularly characterized neurons in the mouse superficial spinal cord dorsal horn that express estrogen receptor α (ERα) and explored the behavioral consequences of their ablation. We found that spinal ERα‐positive neurons are largely excitatory interneurons and many coexpress substance P, a marker for a discrete subset of nociceptive, excitatory interneurons. After viral, caspase‐mediated ablation of spinal ERα‐expressing cells, we observed a significant decrease in the first phase of the formalin test, but in male mice only. ERα‐expressing neuron‐ablation also reduced pruritogen‐induced scratching in both male and female mice. There were no ablation‐related changes in mechanical or heat withdrawal thresholds or in capsaicin‐induced nocifensive behavior. In chronic pain models, we found no change in Complete Freund's adjuvant‐induced thermal or mechanical hypersensitivity, or in partial sciatic nerve injury‐induced mechanical allodynia. We conclude that ERα labels a subpopulation of excitatory interneurons that are specifically involved in chemically evoked persistent pain and pruritogen‐induced itch.
Highlights
For our estrogen receptor α (ERα) cell ablation experiments, we set a threshold of 25% for ablation; that is, if an ERα-Cre mouse had less than 25% of ERα cells remaining, we considered it to be a successful ablation and included data generated from this mouse in our analysis, but if more than 25% of cells remained, data from this mouse were excluded
We previously reported that TR4-Nestin knockout mice exhibit an extensive loss of excitatory interneurons in laminae I and IIo, and that this results in insensitivity to mechanical stimuli as well as to capsaicin and several pruritogens (Wang et al, 2013)
We cannot exclude the possibility that the few ERα spinal neurons that survived the ablation procedure contributed to residual function, our results argue strongly that ERα marks a subpopulation of excitatory interneurons that are involved in chemically evoked persistent pain and pruritogen-induced itch
Summary
All experiments were approved by and performed according to the guidelines of the University of California, San Francisco's Institutional Animal Care and Use Committee. After completion of behavioral testing, the animals were perfused for immunohistochemistry to quantify numbers of ERα+ cells remaining in the lumbar spinal cord dorsal horn. The pattern of Rabbit anti-Pax immunostaining that we observe completely agrees with previous reports that characterized spinal cord dorsal horn Pax2-expressing cells as inhibitory interneurons (Kardon et al, 2014; Punnakkal, von Schoultz, Haenraets, Wildner, & Zeilhofer, 2014) For this particular antibody, Western blot from human fetal kidney tissue recognizes a band at the proper expected size of 45 kDa (manufacturer's information). Anti-PKCγ antibodies were raised in guinea pigs and when used in formaldehyde-fixed animals generated the following pattern of spinal cord immunostaining: dense immunoreactivity in lamina IIi and the corticospinal tract of wildtype mice. Mann–Whitney U tests under the same guidelines described for the anatomical studies
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