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Decreased excitability of locus coeruleus neurons during hypercapnia is exaggerated in the streptozotocin-model of Alzheimer's disease.
高碳酸血症时蓝斑神经元兴奋性降低在阿尔茨海默病的链脲佐菌素模型中被夸大。
- 影响因子:4.30
- DOI:10.1016/j.expneurol.2020.113250
- 作者列表:"Vicente MC","Humphrey CM","Gargaglioni LH","Ostrowski TD
- 发表时间:2020-02-20
Abstract
:The locus coeruleus (LC) is a pontine nucleus important for respiratory control and central chemoreception. It is affected in Alzheimer's disease (AD) and alteration of LC cell function may account for respiratory problems observed in AD patients. In the current study, we tested the electrophysiological properties and CO2/pH sensitivity of LC neurons in a model for AD. Sporadic AD was induced in rats by intracerebroventricular injection of 2 mg/kg streptozotocin (STZ), which induces behavioral and molecular impairments found in AD. LC neurons were recorded using the patch clamp technique and tested for responses to CO2 (10% CO2, pH = 7.0). The majority (~60%) of noradrenergic LC neurons in adult rats were inhibited by CO2 exposure as indicated by a significant decrease in action potential (AP) discharge to step depolarizations. The STZ-AD rat model had a greater sensitivity to CO2 than controls. The increased CO2-sensitivity was demonstrated by a significantly stronger inhibition of activity during hypercapnia that was in part due to hyperpolarization of the resting membrane potential. Reduction of AP discharge in both groups was generally accompanied by lower LC network activity, depolarized AP threshold, increased AP repolarization, and increased current through a subpopulation of voltage-gated K+ channels (KV). The latter was indicated by enhanced transient KV currents particularly in the STZ-AD group. Interestingly, steady-state KV currents were reduced under hypercapnia, a change that would favor enhanced AP discharge. However, the collective response of most LC neurons in adult rats, and particularly those in the STZ-AD group, was inhibited by CO2.
摘要
: 蓝斑 (LC) 是对呼吸控制和中枢化学感受重要的脑桥核。它在阿尔茨海默病 (AD) 中受到影响,LC 细胞功能的改变可能是 AD 患者观察到的呼吸问题的原因。在目前的研究中,我们在 AD 模型中测试了 LC 神经元的电生理特性和 CO2/pH 敏感性。通过侧脑室注射 2 mg/kg 链脲佐菌素 (STZ) 诱导大鼠散发性 AD,引起 AD 的行为和分子损伤。使用膜片钳技术记录 LC 神经元,并检测对 CO2 (10% CO2,ph = 7.0) 的反应。成年大鼠去甲肾上腺素能 LC 神经元的大部分 (~ 60%) 被 CO2 暴露抑制,表现为动作电位 (AP) 放电显著降低至阶跃去极化。STZ-AD 大鼠模型对 CO2 的敏感性高于对照组。在高碳酸血症期间,CO2-sensitivity 的增加表现为活性的显著增强抑制,部分是由于静息膜电位的超极化。两组 AP 放电减少一般均伴有较低的 LC 网络活性、去极化 AP 阈值、 AP 复极增加、通过电压门控 K + 通道 (KV) 亚群的电流增加。后者由增强的瞬态 KV 电流表示,特别是在 STZ-AD 组。有趣的是,稳态 KV 电流在高碳酸血症下降低,这种变化有利于增强 AP 放电。然而,成年大鼠,特别是 STZ-AD 组的大多数 LC 神经元的集体反应被 CO2 抑制。
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