Evans Andrew K, Park Heui Hye, Woods Claire E, Lam Rachel K, Rijsketic Daniel Ryskamp, Xu Christine, Chu Emily, Ciari Peter, Blumenfeld Sarah, Vidano Laura M, Saw Nay L, Heifets Boris D, Shamloo Mehrdad
Stanford University.
Stanford Universityf.
Res Sq. 2024 Oct 30:rs.3.rs-5328229. doi: 10.21203/rs.3.rs-5328229/v1.
Norepinephrine (NE) modulates cognitive function, arousal, attention, and responses to novelty and stress, and also regulates neuroinflammation. We previously demonstrated behavioral and immunomodulatory effects of beta-adrenergic pharmacology in mouse models of Alzheimer's disease (AD). The current studies were designed to block noradrenergic signaling in 5XFAD mice through chemogenetic inhibition of the locus coeruleus (LC), pharmacologic blocking of β-adrenergic receptors, and conditional deletion of β1- or β2-adrenergic receptors (adrb1 or adrb2) in microglia. First, brain-wide AD pathology was mapped in 3D by imaging immunolabeled, cleared 5XFAD brains to assess the overlap between Aβ pathology, reactive microglia, and the loss of tyrosine hydroxylase (TH) expression in the catecholaminergic system. To examine the effects of inhibiting the LC NE system in the 5XFAD model, inhibitory (Gi) DREADD receptors were expressed specifically in LC NE neurons. LC NE neurons were chronically inhibited through the subcutaneous pump administration of the DREADD agonist clozapine-N-oxide (CNO). Plasma and brains were collected for assessment of neuroinflammation and pathology. A separate cohort of 5XFAD mice was chronically dosed with the beta-adrenergic antagonist propranolol or vehicle and evaluated for behavior, as well as post-mortem neuroinflammation and pathology. Finally, we used 5XFAD mice with conditional deletion of either adrb1 or adrb2 in microglia to assess neuroinflammation and pathology mediated by β-adrenergic signaling. Using iDISCO, light sheet fluorescence microscopy, and novel analyses, we detected widespread microgliosis and amyloid pathology, along with modest TH downregulation in fibers across multiple brain regions, in contrast to the spatially limited TH downregulation observed in neurons. Both chemogenetic inhibition of LC adrenergic signaling and pharmacological inhibition of beta-adrenergic receptors potentiated neuroinflammation without altering amyloid beta pathology. Conditional deletion of adrb1 in microglia did not affect neuroinflammation. Conditional deletion of adrb2 in microglia attenuated inflammation and pathology in females but had no effect in males. Overall, these data support previous observations demonstrating the immunomodulatory effects of beta-adrenergic signaling in the pathophysiology of brain disorders and suggest that adrenergic receptors on cell types other than microglia, such as astrocytes, may predominantly mediate the disease-modifying effects of β-adrenergic agonists in the brain.
去甲肾上腺素(NE)调节认知功能、觉醒、注意力以及对新奇事物和压力的反应,还能调节神经炎症。我们之前在阿尔茨海默病(AD)小鼠模型中证明了β-肾上腺素能药理学的行为和免疫调节作用。当前的研究旨在通过化学遗传学抑制蓝斑(LC)、药理学阻断β-肾上腺素能受体以及在小胶质细胞中条件性缺失β1或β2肾上腺素能受体(adrb1或adrb2)来阻断5XFAD小鼠中的去甲肾上腺素能信号传导。首先,通过对免疫标记、清除的5XFAD脑进行成像,以三维方式绘制全脑AD病理学图谱,以评估Aβ病理学、反应性小胶质细胞以及儿茶酚胺能系统中酪氨酸羟化酶(TH)表达缺失之间的重叠情况。为了研究在5XFAD模型中抑制LC NE系统的作用,抑制性(Gi)DREADD受体在LC NE神经元中特异性表达。通过皮下泵给予DREADD激动剂氯氮平-N-氧化物(CNO),长期抑制LC NE神经元。收集血浆和脑样本以评估神经炎症和病理学。另一组5XFAD小鼠长期给予β-肾上腺素能拮抗剂普萘洛尔或赋形剂,并评估其行为以及死后的神经炎症和病理学情况。最后,我们使用在小胶质细胞中条件性缺失adrb1或adrb2的5XFAD小鼠来评估由β-肾上腺素能信号传导介导的神经炎症和病理学。使用iDISCO、光片荧光显微镜和新颖的分析方法,我们检测到广泛的小胶质细胞增生和淀粉样蛋白病理学,以及多个脑区纤维中适度的TH下调,这与在神经元中观察到的空间上有限的TH下调形成对比。对LC肾上腺素能信号的化学遗传学抑制和β-肾上腺素能受体的药理学抑制均增强了神经炎症,而未改变淀粉样β病理学。小胶质细胞中adrb1的条件性缺失不影响神经炎症。小胶质细胞中adrb2的条件性缺失减轻了雌性小鼠的炎症和病理学,但对雄性小鼠没有影响。总体而言这些数据支持了之前的观察结果,即β-肾上腺素能信号在脑部疾病病理生理学中的免疫调节作用,并表明除小胶质细胞外其他细胞类型(如星形胶质细胞)上的肾上腺素能受体可能主要介导β-肾上腺素能激动剂在脑中的疾病修饰作用。
