星形胶质细胞在脊髓损伤中的研究展望

近年来星形胶质细胞(astrocyte,AS)已经逐渐成为中枢神经系统(CNS)疾病研究中的热点之一。激活星形胶质细胞会产生和释放神经递质、神经营养因子和促炎因子等,对神经元既有保护作用也有毒性作用。现综述星形胶质细胞的形态、功能以及与脊髓损伤(spinal cord injury,SCI)的联系等,为进一步研究星形胶质细胞和脊髓损伤提供依据。     

脑能量代谢：星形胶质细胞-神经元耦合

脑是能量需求旺盛器官,能量底物的传递保证了神经元正常活化。星形胶质细胞在脑能量的产生、传递、利用和储存中具有重要功能。星形胶质细胞和神经元相互作用是脑能量代谢的核心,也是神经能量学研究的重点。本文简要综述星形胶质细胞和神经元各自的代谢特点及两者之间的代谢耦合和代谢机制。     

靶向星形胶质细胞治疗缺血性脑卒中的研究进展

缺血性脑卒中(ischemic stroke, IS)发生后,缺血区星形胶质细胞(astrocyte)活化,这些反应性星形胶质细胞对缺血区神经元发挥有利和有害双重作用。星形胶质细胞与IS诱导的谷氨酸功能障碍、线粒体功能障碍和胶质瘢痕形成密切相关,并且在IS后神经元网络重构中发挥重要调节作用。现重点探讨如何利用星形胶质细胞对IS发挥保护作用的研究进展。     

谷氨酸-谷氨酰胺循环异常与孤独症谱系障碍研究进展

孤独症谱系障碍（autism spectrum disorder,ASD）是一种多病因神经发育性疾病,人群患病率高,病因复杂多样,包括炎症、自身免疫、基因异常等,但具体发病机制尚不清楚。在哺乳动物中枢神经系统（central nervous system,CNS）中,谷氨酸是最主要的兴奋性神经递质,也是一种潜在的神经毒素,其引起的兴奋毒性可能导致神经细胞的死亡。而星形胶质细胞和神经元之间谷氨酸-谷氨酰胺的代谢偶联,防止了过量的谷氨酸扩散到周围神经元上,进而避免了神经元的过度兴奋,对神经元起到保护作用。有研究表明,谷氨酸-谷氨酰胺循环异常可能为ASD发生的核心机制。因此,对炎症、自身免疫、基因异常等孤独症谱系障碍经典病因与谷氨酸-谷氨酰胺循环之间的联系进行综述,以期为孤独症谱系障碍分型和治疗提供一种新思路。     

星形胶质细胞

目录一、星形胶质细胞的生物学特性(一 )星形胶质细胞的异质性(二 )胶质网络二、星形胶质细胞的功能(一 )分泌功能(二 )星形胶质细胞与神经的发育及再生(三 )星形胶质细胞具有对神经元微环境调控的能力(四 )免疫功能与血脑屏障调控三、星形胶质细胞功能的新近进展(一 )星形胶质细胞也具有可兴奋性(二 )星形胶质细胞与神经元的通讯或对话(三 )在突触形成和突触可塑性中的作用(四 )星形胶质细胞与神经发生胶质细胞是神经系统内数量众多的一大类细胞群体 ,约占中枢神经系统 (CNS)细胞总数的 90 % ,星形胶质细胞 (astrocyte)是其中主要的组成…     

神经系统内水通道蛋白4的功能研究进展

水通道蛋白4 (aquaporin 4,AQP4) 是中枢神经系统内重要的水通道蛋白之一,除了在海马、视上核和室旁核等部位的少数神经元上有分布外,主要表达在星形胶质细胞和室管膜上皮细胞中.近期的研究发现,AQP4除了参与脑脊液(cerebrospinal fluid,CSF)分泌、吸收等中枢神经系统内水代谢平衡的调节外,还有许多令人感兴趣的功能表现.AQP4能够影响星形胶质细胞的迁移和胶质疤痕的愈合;影响神经信号的传导;还能够调节星形胶质细胞对K 和谷氨酸的重摄取;改变神经元神经递质的释放;参与突触以及细胞间隙连接的形成等.上述发现表明AQP4不仅是影响中枢神经系统内水和电解质平衡的关键因素,而且是决定星形胶质细胞结构功能的重要分子基础之一.因此AQP4为众多脑疾病的治疗提供具有重要价值的潜在药物作用靶点,调控AQP4的表达与功能将成为治疗许多神经系统疾病的新策略.     

星形胶质细胞在阿尔茨海默病中的功能变化及分子机制

星形胶质细胞在脑内数量最多,分布最广,对神经元有营养支持的作用,并且能够调控神经元的活性。越来越多的证据表明星形胶质细胞激活参与阿尔茨海默病(Alzheimer's disease,AD)的发生和发展。在AD病理情况下,星形胶质细胞在多种因子如β淀粉样蛋白(beta-amyloid,Aβ)和促炎细胞因子的作用下被激活,激活的星形胶质细胞进一步释放一氧化氮(Nitric oxide,NO)和多种炎性因子增强炎症级联反应。功能失常的星形胶质细胞会促进Aβ的产生,减弱对Aβ的摄取和清除,导致Aβ聚集沉积形成老年斑。激活的星形胶质细胞释放的炎症因子还能显著增加神经元内tau蛋白的异常过度磷酸化,产生神经纤维缠结。本文对星形胶质细胞在AD中参与神经变性的功能变化和分子机制进行总结,为星形胶质细胞作为靶点预防及治疗AD提供一定的理论依据。     

星形胶质细胞糖代谢对神经元的支持及保护作用

脑组织有着极其复杂的功能,这些功能的完成有赖于神经元细胞与胶质细胞之间的广泛合作。星形胶质细胞作为人脑内数量最多的细胞,其与神经元细胞之间的相互作用就显得十分重要。葡萄糖代谢途径包括糖酵解,有氧氧化及磷酸戊糖三条途径。其为脑组织维持其正常功能的前提。研究表明星形胶质细胞和神经元在糖代谢方面有着各自的特点,神经元在能量底物及抗氧化应激中对星形胶质细胞糖代谢途径存在一定的依赖性,干扰星形胶质细胞与神经元之间的代谢过程会导致疾病的发生。本综述主要从糖酵解及磷酸戊糖两条糖代谢途径阐述了星形胶质细胞与神经元的关系。这或许会对研究脑的代谢,脑疾病中神经元的损伤机制及如何保护神经元提供全新的视角,并可能为一些疾病的治疗开辟了新的途径。     

星形胶质细胞和神经元之间谷氨酸-谷氨酰胺的代谢偶联

谷氨酸-谷氨酰胺循环是星形胶质细胞和神经元代谢偶联最重要的途径之一。在中枢神经系统中葡萄糖经糖酵解和三羧酸循环,合成三羧酸循环的中间产物。神经元因缺乏丙酮酸羧化酶,不能由葡萄糖直接合成谷氨酸,而必须依赖于星形胶质细胞的三羧酸循环来产生作为谷氨酸前体的三羧酸循环中间代谢产物。星形胶质细胞的谷氨酸载体从突触间隙摄取谷氨酸,在星形胶质细胞中转变成谷氨酰胺并释放到细胞外,然后重新被神经元摄取,转变成谷氨酸进入新一轮的循环。本文介绍了该循环,以及星形胶质细胞谷氨酸载体的功能、特性及调控。     

星形胶质细胞在阿尔茨海默病中的作用及其分子机制

阿尔茨海默病(Alzheimer’s disease,AD)是一种多因素导致的神经退行性疾病。随着社会的老龄化,阿尔茨海默病的发病率呈逐渐上升的趋势,给患者以及社会带来极大的生理痛苦和经济负担。星形胶质细胞在中枢神经系统中数量最多、分布最广,对神经元有营养支持作用,并且还能够调控神经元的活性。在AD的病理情况下,星形胶质细胞能参与Aβ代谢影响老年斑的形成,分泌多种炎症因子和趋化因子参与AD的病理进程,并且还能通过影响突触谷氨酸循环来调节神经元的活性。近年来,星形胶质细胞在AD的病理生理机制中的作用受到越来越多的关注。现就星形胶质细胞在AD发病机制中的作用进行综述。     

Astrocyte Mitochondrial Mechanisms of Ischemic Brain Injury and Neuroprotection

Research on ischemic brain injury has established a central role of mitochondria in neuron death. Astrocytes are also damaged by ischemia, although the participation of mitochondria in their injury is ill defined. As astrocytes are responsible for neuronal metabolic and trophic support, astrocyte dysfunction will compromise postischemic neuronal survival. Ischemic alterations to astrocyte energy metabolism and the uptake and metabolism of the excitatory amino acid transmitter glutamate may be particularly important. Despite the significance of ischemic astrocyte injury, little is known of the mechanisms responsible for astrocyte death and dysfunction. This review focuses on differences between astrocyte and neuronal metabolism and mitochondrial function, and on neuronal-glial interactions. The potential for astrocyte mitochondria to serve as targets of neuroprotective interventions is also discussed.     

Neonatal astrocyte damage is sufficient to trigger progressive striatal degeneration in a rat model of glutaric acidemia-I

Background

We have investigated whether an acute metabolic damage to astrocytes during the neonatal period may critically disrupt subsequent brain development, leading to neurodevelopmental disorders. Astrocytes are vulnerable to glutaric acid (GA), a dicarboxylic acid that accumulates in millimolar concentrations in Glutaric Acidemia I (GA-I), an inherited neurometabolic childhood disease characterized by degeneration of striatal neurons. While GA induces astrocyte mitochondrial dysfunction, oxidative stress and subsequent increased proliferation, it is presently unknown whether such astrocytic dysfunction is sufficient to trigger striatal neuronal loss.

Methodology/Principal Findings

A single intracerebroventricular dose of GA was administered to rat pups at postnatal day 0 (P0) to induce an acute, transient rise of GA levels in the central nervous system (CNS). GA administration potently elicited proliferation of astrocytes expressing S100β followed by GFAP astrocytosis and nitrotyrosine staining lasting until P45. Remarkably, GA did not induce acute neuronal loss assessed by FluoroJade C and NeuN cell count. Instead, neuronal death appeared several days after GA treatment and progressively increased until P45, suggesting a delayed onset of striatal degeneration. The axonal bundles perforating the striatum were disorganized following GA administration. In cell cultures, GA did not affect survival of either striatal astrocytes or neurons, even at high concentrations. However, astrocytes activated by a short exposure to GA caused neuronal death through the production of soluble factors. Iron porphyrin antioxidants prevented GA-induced astrocyte proliferation and striatal degeneration in vivo, as well as astrocyte-mediated neuronal loss in vitro.

Conclusions/Significance

Taken together, these results indicate that a transient metabolic insult with GA induces long lasting phenotypic changes in astrocytes that cause them to promote striatal neuronal death. Pharmacological protection of astrocytes with antioxidants during encephalopatic crisis may prevent astrocyte dysfunction and the ineluctable progression of disease in children with GA-I.     

GABAergic interneuron to astrocyte signalling: a neglected form of cell communication in the brain

GABAergic interneurons represent a minority of all cortical neurons and yet they efficiently control neural network activities in all brain areas. In parallel, glial cell astrocytes exert a broad control of brain tissue homeostasis and metabolism, modulate synaptic transmission and contribute to brain information processing in a dynamic interaction with neurons that is finely regulated in time and space. As most studies have focused on glutamatergic neurons and excitatory transmission, our knowledge of functional interactions between GABAergic interneurons and astrocytes is largely defective. Here, we critically discuss the currently available literature that hints at a potential relevance of this specific signalling in brain function. Astrocytes can respond to GABA through different mechanisms that include GABA receptors and transporters. GABA-activated astrocytes can, in turn, modulate local neuronal activity by releasing gliotransmitters including glutamate and ATP. In addition, astrocyte activation by different signals can modulate GABAergic neurotransmission. Full clarification of the reciprocal signalling between different GABAergic interneurons and astrocytes will improve our understanding of brain network complexity and has the potential to unveil novel therapeutic strategies for brain disorders.     

Hepatic encephalopathy: An update of pathophysiologic mechanisms

Hepatic encephalopathy (HE) is a neuropsychiatric disorder that occurs in both acute and chronic liver failure. Although the precise pathophysiologic mechanisms responsible for HE are not completely understood, a deficit in neurotransmission rather than a primary deficit in cerebral energy metabolism appears to be involved. The neural cell most vulnerable to liver failure is the astrocyte. In acute liver failure, the astrocyte undergoes swelling resulting in increased intracranial pressure; in chronic liver failure, the astrocyte undergoes characteristic changes known as Alzheimer type II astrocytosis. In portal-systemic encephalopathy resulting from chronic liver failure, astrocytes manifest altered expression of several key proteins and enzymes including monoamine oxidase B, glutamine synthetase, and the so-called peripheral-type benzodiazepine receptors. In addition, expression of some neuronal proteins such as monoamine oxidase A and neuronal nitric oxide synthase are modified. In acute liver failure, expression of the astrocytic glutamate transporter GLT-1 is reduced, leading to increased extracellular concentrations of glutamate. Many of these changes have been attributed to a toxic effect of ammonia and/or manganese, two substances that are normally removed by the hepatobiliary route and that in liver failure accumulate in the brain. Manganese deposition in the globus pallidus in chronic liver failure results in signal hyperintensity on T1-weighted Magnetic Resonance Imaging and may be responsible for the extrapyramidal symptoms characteristic of portal-systemic encephalopathy. Other neurotransmitter systems implicated in the pathogenesis of hepatic encephalopathy include the serotonin system, where a synaptic deficit has been suggested, as well as the catecholaminergic and opioid systems. Further elucidation of the precise nature of these alterations could result in the design of novel pharmacotherapies for the prevention and treatment of hepatic encephalopathy.     

Mitochondrial bioenergetics and dynamics in Huntington’s disease: tripartite synapses and selective striatal degeneration

Preferential striatal neurodegeneration is a hallmark of Huntington’s disease (HD) pathogenesis, which has been associated with mitochondrial dysfunction. Evidence from genetic HD models suggest that mutant huntingtin (mHtt) compromises mitochondrial bioenergetics and dynamics, preventing efficient calcium handling and ATP generation in neuronal networks. Striatal neurons receive abundant glutamatergic input from the cortex, forming tripartite synapses with astrocytic partners. These are involved in bidirectional communication, play neuroprotective roles, and emerging evidence suggests that astrocyte dysfunction supports non-cell autonomous neurodegeneration. In addition to mHtt effects, inherent mitochondria vulnerability within striatal neurons and astrocytes may contribute for preferential neurodegeneration in HD. Dysfunctional astrocytic mitochondria in cortico-striatal tripartite synapses might be particularly relevant in the pathogenesis of juvenile/infantile HD, frequently associated with seizures and abnormally large mHtt polyglutamine expansions. This review discusses our work, primarily addressing in situ mitochondrial function in neurons and astrocytes, in the context of related work within the HD-mitochondria field.     

Stretch-induced injury alters mitochondrial membrane potential and cellular ATP in cultured astrocytes and neurons

Energy deficit after traumatic brain injury (TBI) may alter ionic homeostasis, neurotransmission, biosynthesis, and cellular transport. Using an in vitro model for TBI, we tested the hypothesis that stretch-induced injury alters mitochondrial membrane potential (delta(psi)m) and ATP in astrocytes and neurons. Astrocytes, pure neuronal cultures, and mixed neuronal plus glial cultures grown on Silastic membranes were subjected to mild, moderate, and severe stretch. After injury, delta(psi)m was measured using rhodamine-123, and ATP was quantified with a luciferin-luciferase assay. In astrocytes, delta(psi)m dropped significantly, and ATP content declined 43-52% 15 min after mild or moderate stretch but recovered by 24 h. In pure neurons, delta(psi)m declined at 15 min only in the severely stretched group. At 48 h postinjury, delta(psi)m remained decreased in severely stretched neurons and dropped in moderately stretched neurons. Intracellular ATP content did not change in any group of injured pure neurons. We also found that astrocytes and neurons release ATP extracellularly following injury. In contrast to pure neurons, delta(psi)m in neurons of mixed neuronal plus glial cultures declined 15 min after mild, moderate, or severe stretch and recovered by 24-48 h. ATP content in mixed cultures declined 22-28% after mild to severe stretch with recovery by 24 h. Our findings demonstrate that injury causes mitochondrial dysfunction in astrocytes and suggest that astrocyte injury alters mitochondrial function in local neurons.     

A tale of two stories: astrocyte regulation of synaptic depression and facilitation

Short-term presynaptic plasticity designates variations of the amplitude of synaptic information transfer whereby the amount of neurotransmitter released upon presynaptic stimulation changes over seconds as a function of the neuronal firing activity. While a consensus has emerged that the resulting decrease (depression) and/or increase (facilitation) of the synapse strength are crucial to neuronal computations, their modes of expression in vivo remain unclear. Recent experimental studies have reported that glial cells, particularly astrocytes in the hippocampus, are able to modulate short-term plasticity but the mechanism of such a modulation is poorly understood. Here, we investigate the characteristics of short-term plasticity modulation by astrocytes using a biophysically realistic computational model. Mean-field analysis of the model, supported by intensive numerical simulations, unravels that astrocytes may mediate counterintuitive effects. Depending on the expressed presynaptic signaling pathways, astrocytes may globally inhibit or potentiate the synapse: the amount of released neurotransmitter in the presence of the astrocyte is transiently smaller or larger than in its absence. But this global effect usually coexists with the opposite local effect on paired pulses: with release-decreasing astrocytes most paired pulses become facilitated, namely the amount of neurotransmitter released upon spike i+1 is larger than that at spike i, while paired-pulse depression becomes prominent under release-increasing astrocytes. Moreover, we show that the frequency of astrocytic intracellular Ca(2+) oscillations controls the effects of the astrocyte on short-term synaptic plasticity. Our model explains several experimental observations yet unsolved, and uncovers astrocytic gliotransmission as a possible transient switch between short-term paired-pulse depression and facilitation. This possibility has deep implications on the processing of neuronal spikes and resulting information transfer at synapses.     

Glutamine in the pathogenesis of acute hepatic encephalopathy

Hepatic encephalopathy (HE) is the major neurological disorder associated with liver disease. It presents in chronic and acute forms, and astrocytes are the major neural cells involved. While the principal etiological factor in the pathogenesis of HE is increased levels of blood and brain ammonia, glutamine, a byproduct of ammonia metabolism, has also been implicated in its pathogenesis. This article reviews the current status of glutamine in the pathogenesis of HE, particularly its involvement in some of the events triggered by ammonia, including mitochondrial dysfunction, generation of oxidative stress, and alterations in signaling mechanisms, including activation of mitogen-activated protein kinases (MAPKs) and nuclear factor-kappaB (NF-κB). Mechanisms by which glutamine contributes to astrocyte swelling/brain edema associated with acute liver failure (ALF) will also be described.     

Neuronal survival depends on EGFR signaling in cortical but not midbrain astrocytes

Mice lacking epidermal growth factor receptor (EGFR) develop a neurodegeneration of unknown etiology affecting exclusively the frontal cortex and olfactory bulbs. Here, we show that EGFR signaling controls cortical degeneration by regulating cortical astrocyte apoptosis. Whereas EGFR(-/-) midbrain astrocytes are unaffected, mutant cortical astrocytes display increased apoptosis mediated by an Akt-caspase-dependent mechanism and are unable to support neuronal survival. The expression of many neurotrophic factors is unaltered in EGFR(-/-) cortical astrocytes suggesting that neuronal loss occurs as a consequence of increased astrocyte apoptosis rather than impaired secretion of trophic factors. Neuron-specific expression of activated Ras can compensate for the deficiency of EGFR(-/-) cortical astrocytes and prevent neuronal death. These results identify two functionally distinct astrocyte populations, which differentially depend on EGFR signaling for their survival and also for their ability to support neuronal survival. These spatial differences in astrocyte composition provide a mechanism for the region-specific neurodegeneration in EGFR(-/-) mice.