Inhibition of Endoplasmic Reticulum Oxidoreductin 1 Modulates Neuronal Excitability and Nociceptive Sensitivity in Mice.

IF 9.1 1区医学 Q1 ANESTHESIOLOGY

Anesthesiology Pub Date : 2025-07-01 Epub Date: 2025-03-19 DOI:10.1097/ALN.0000000000005453

Aislinn D Maguire, Shawn M Lamothe, Muhammad Saad Yousuf, Kree Goss, Jayadeep Rao, Gustavo Tenorio, Sridhar R Kaulagari, Lori Hazlehurst, Jason R Plemel, Anna M W Taylor, Harley T Kurata, Thomas Simmen, Bradley J Kerr

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引用次数: 0

Abstract

Background: In the peripheral nervous system, nociceptors become hyperexcitable in both acute and chronic pain conditions. This phenotype can be mediated by dysregulated calcium, which occurs if the endoplasmic reticulum and mitochondria fail to buffer it appropriately. The redox enzyme endoplasmic reticulum oxidoreductin 1 (ERO1) regulates calcium transfer at endoplasmic reticulum-mitochondria contact sites (ERMCSs). This study hypothesized that inhibiting ERO1 and thereby dampening ERMCS calcium transfer might lower nociceptor hyperexcitability in sensory neurons and pain-like behaviors in mice.

Methods: C57BL/6 mice were used for histology, behavior, and cell culture experiments. Behavior included thermal tail flick, the formalin hind paw injection model of acute inflammatory pain, and hind paw incision postsurgical pain. Postmortem human dorsal root ganglia (DRGs) were used for immunohistochemistry and in vitro calcium imaging.

Results: This study demonstrates that the α isoform of ERO1 is expressed in mouse DRGs across multiple subtypes of mouse sensory neurons. This led us to peripherally administer an ERO1 inhibitor in mice, which acutely reversed nociception in acute inflammatory and postsurgical pain models. The hypothesis was that this may be due to reduced excitability of DRG neurons and tested ERO1 inhibition in vitro. In cultured DRGs, ERO1 inhibition dampened nociceptor excitability and mitochondrial function, suggesting that reduced calcium transfer through ERMCS could be responsible for the behavior observed in vivo . ERO1α expression was also found in human DRGs using immunohistochemistry and previously published single-cell RNA-sequencing data. Finally, the study showed that ERO1 inhibition modulates human sensory neuronal excitability in cultured post-mortem DRGs.

Conclusions: This study found that ERO1 inhibition dampens mitochondrial function, sensory neuron excitability, and acute pain-like behavior in mice. Additionally, ERO1 inhibition decreases sensory neuron excitability in post-mortem human sensory neurons in vitro. The results indicate that targeting ERO1 may be a viable strategy for non-narcotic acute pain relief.

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抑制内质网氧化还原蛋白1调节小鼠神经元兴奋性和伤害性敏感性。

背景：在周围神经系统中，伤害感受器在急性和慢性疼痛条件下都变得过度兴奋。如果内质网（ER）和线粒体不能适当缓冲钙，这种表型可以由钙失调介导。氧化还原酶内质网氧化还原蛋白1 （ERO1）调节内质网线粒体接触位点（ERMCS）的钙转移。在本研究中，我们假设抑制ERO1从而抑制ERMCS钙转移可能会降低小鼠感觉神经元中伤害感受器的高兴奋性和疼痛样行为。方法：采用C57BL/6小鼠进行组织学、行为学和细胞培养实验。行为包括热甩尾、注射福尔马林后爪急性炎性疼痛模型、后爪切口术后疼痛。采用人死后背根神经节（DRGs）进行免疫组化和体外钙显像。结果：本研究表明，ERO1的α亚型在小鼠背根神经节（DRGs）中跨多种小鼠感觉神经元亚型表达。这导致我们在小鼠中外周施用一种ERO1抑制剂，该抑制剂在急性炎症和术后疼痛模型中急剧逆转伤害感觉。我们假设这可能是由于DRG神经元兴奋性降低，并在体外测试了ERO1的抑制作用。在培养的DRGs中，ERO1抑制抑制了伤害感受器的兴奋性和线粒体功能，这表明通过ERMCS减少钙转移可能是我们在体内观察到的行为的原因。我们还利用免疫组织化学和先前发表的单细胞RNA测序数据发现了人DRGs中ERO1 α的表达。最后，我们发现在培养的死后DRGs中，ERO1抑制调节人类感觉神经元的兴奋性。结论：我们发现ERO1抑制抑制小鼠线粒体功能、感觉神经元兴奋性和急性疼痛样行为。此外，ERO1抑制降低了人死后感觉神经元的兴奋性。我们认为靶向ERO1可能是非麻醉性急性疼痛缓解的可行策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Anesthesiology 医学-麻醉学

CiteScore

10.40

自引率

5.70%

发文量

542

审稿时长

3-6 weeks

期刊介绍： With its establishment in 1940, Anesthesiology has emerged as a prominent leader in the field of anesthesiology, encompassing perioperative, critical care, and pain medicine. As the esteemed journal of the American Society of Anesthesiologists, Anesthesiology operates independently with full editorial freedom. Its distinguished Editorial Board, comprising renowned professionals from across the globe, drives the advancement of the specialty by presenting innovative research through immediate open access to select articles and granting free access to all published articles after a six-month period. Furthermore, Anesthesiology actively promotes groundbreaking studies through an influential press release program. The journal's unwavering commitment lies in the dissemination of exemplary work that enhances clinical practice and revolutionizes the practice of medicine within our discipline.