Meissner Anja, Visanji Naomi P, Momen M Abdul, Feng Rui, Francis Beverly M, Bolz Steffen-Sebastian, Hazrati Lili-Naz
Department of Physiology, University of Toronto, Ontario, Canada (A.M., S.S.B.) Department of Brain Ischemia and Neurodegeneration, Institut d'Investigacions Biomediques August Pi i Sunyer (IDIBAPS), Barcelona, Spain (A.M.).
Morten and Gloria Shulman Movement Disorders Centre, Toronto Western Hospital, Toronto, Ontario, Canada (N.P.V.).
J Am Heart Assoc. 2015 May 6;4(5):e001920. doi: 10.1161/JAHA.115.001920.
Heart failure (HF) is a progressive disorder characterized by reduced cardiac output and increased peripheral resistance, ultimately leading to tissue perfusion deficits and devastating consequences for several organs including the brain. We previously described a tumor necrosis factor-α (TNF-α)-dependent enhancement of posterior cerebral artery tone and concomitant reduced cerebral blood flow in a mouse model of early HF in which blood pressure remains minimally affected. HF is often associated with cognitive impairments such as memory deficits, even before any overt changes in brain structure and function occur. The pathophysiology underlying the development of cognitive impairments in HF is unknown, and appropriate treatment strategies are lacking.
We used a well-established mouse model in which HF was induced by experimental myocardial infarction produced by permanent surgical ligation of the left anterior descending coronary artery (infarct size ≈25% of the left ventricular wall). Ligated mice developed enlarged hearts, congested lungs, and reduced cardiac output and blood pressure, with elevated peripheral resistance within 6 to 8 weeks after ligation. In this study, we demonstrated the significance of the proinflammatory cytokine TNF-α during HF-mediated neuroinflammation and associated impaired hippocampus-independent nonspatial episodic memory function. Augmented cerebral TNF-α expression and microglial activation in HF mice, indicative of brain inflammation, were accompanied by morphological changes and significant reduction of cortical dendritic spines (61.39±8.61% for basal and 61.04±9.18% for apical spines [P<0.001]). The significance of TNF-α signaling during the observed HF-mediated neurodegenerative processes is supported by evidence showing that sequestration or genetic deletion of TNF-α ameliorates the observed reduction of cortical dendritic spines (33.51±7.63% for basal and 30.13±6.98% for apical spines in wild-type mice treated with etanercept; 17.09±6.81% for basal and 17.21±7.29% for apical spines in TNF-α(-/-)). Moreover, our data suggest that alterations in cerebral serum and glucocorticoid-inducible kinase 1 (SgK1) expression and phosphorylation during HF may be TNF-α dependent and that an increase of SgK1 phosphorylation potentially plays a role in the HF-associated reduction of dendritic spine density.
Our findings demonstrate that TNF-α plays a pivotal role in HF-mediated neuroinflammation and associated alterations of cortical dendritic spine density and has the potential to reveal novel treatment strategies for HF-associated memory deficits.
心力衰竭(HF)是一种进行性疾病,其特征为心输出量减少和外周阻力增加,最终导致组织灌注不足,并对包括大脑在内的多个器官造成严重后果。我们之前在一个早期HF小鼠模型中描述了肿瘤坏死因子-α(TNF-α)依赖性的大脑后动脉张力增强以及随之而来的脑血流量减少,在该模型中血压受影响极小。HF常与认知障碍如记忆缺陷相关,甚至在大脑结构和功能出现任何明显变化之前就已存在。HF中认知障碍发生发展的病理生理学尚不清楚,且缺乏合适的治疗策略。
我们使用了一个成熟的小鼠模型,通过永久性手术结扎左冠状动脉前降支诱导HF(梗死面积约为左心室壁的25%)。结扎后的小鼠在结扎后6至8周内心脏增大、肺部充血、心输出量和血压降低,外周阻力升高。在本研究中,我们证明了促炎细胞因子TNF-α在HF介导的神经炎症以及相关的海马非依赖性非空间情景记忆功能受损过程中的重要性。HF小鼠大脑中TNF-α表达增加和小胶质细胞激活,提示存在脑部炎症,同时伴有形态学变化以及皮质树突棘显著减少(基底树突棘为61.39±8.61%,顶端树突棘为61.04±9.18%[P<0.001])。TNF-α信号在观察到的HF介导的神经退行性过程中的重要性得到了证据支持,这些证据表明TNF-α的螯合或基因缺失改善了观察到的皮质树突棘减少(接受依那西普治疗的野生型小鼠基底树突棘为33.51±7.63%,顶端树突棘为30.13±6.98%;TNF-α基因敲除小鼠基底树突棘为17.09±6.81%,顶端树突棘为17.21±7.29%)。此外,我们的数据表明,HF期间脑血清和糖皮质激素诱导激酶1(SgK1)表达及磷酸化的改变可能依赖于TNF-α,并且SgK1磷酸化增加可能在HF相关的树突棘密度降低中起作用。
我们的研究结果表明,TNF-α在HF介导的神经炎症以及相关的皮质树突棘密度改变中起关键作用,并且有可能揭示针对HF相关记忆缺陷的新治疗策略。
