Distinct intracellular signaling mediates C‐MET regulation of dendritic growth and synaptogenesis

Hepatocyte growth factor (HGF) activation of the MET receptor tyrosine kinase influences multiple neurodevelopmental processes. Evidence from human imaging and mouse models shows that, in the forebrain, disruptions in MET signaling alter circuit formation and function. One likely means of modulation is by controlling neuron maturation. Here, we examined the signaling mechanisms through which MET exerts developmental effects in the neocortex. In situ hybridization revealed that hgf is located near MET‐expressing neurons, including deep neocortical layers and periventricular zones. Western blot analyses of neocortical crude membranes demonstrated that HGF‐induced MET autophosphorylation peaks during synaptogenesis, with a striking reduction in activation between P14 and P17 just before pruning. In vitro analysis of postnatal neocortical neurons assessed the roles of intracellular signaling following MET activation. There is rapid, HGF‐induced phosphorylation of MET, ERK1/2, and Akt that is accompanied by two major morphological changes: increases in total dendritic growth and synapse density. Selective inhibition of each signaling pathway altered only one of the two distinct events. MAPK/ERK pathway inhibition significantly reduced the HGF‐induced increase in dendritic length, but had no effect on synapse density. In contrast, inhibition of the PI3K/Akt pathway reduced HGF‐induced increases in synapse density, with no effect on dendritic length. The data reveal a key role for MET activation during the period of neocortical neuron growth and synaptogenesis, with distinct biological outcomes mediated via discrete MET‐linked intracellular signaling pathways in the same neurons. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 76: 1160–1181, 2016     

Neuronal labeling patterns in the spinal cord of adult transgenic Zebrafish

We describe neuronal patterns in the spinal cord of adult zebrafish. We studied the distribution of cells and processes in the three spinal regions reported in the literature: the 8th vertebra used as a transection injury site, the 15th vertebra mainly used for motor cell recordings and also for crush injury, and the 24th vertebra used to record motor nerve activity. We used well‐known transgenic lines in which expression of green fluorescent protein (GFP) is driven by promoters to hb9 and isl1 in motoneurons, alx/chx10 and evx1 interneurons, ngn1 in sensory neurons and olig2 in oligodendrocytes, as well as antibodies for neurons (HuC/D, NF and SV2) and glia (GFAP). In isl1:GFP fish, GFP‐positive processes are retained in the upper part of ventral horns and two subsets of cell bodies are observed. The pattern of the transgene in hb9:GFP adults is more diffuse and fibers are present broadly through the adult spinal cord. In alx/chx10 and evx1 lines we respectively observed two and three different GFP‐positive populations. Finally, the ngn1:GFP transgene identifies dorsal root ganglion and some cells in dorsal horns. Interestingly some GFP positive fibers in ngn1:GFP fish are located around Mauthner axons and their density seems to be related to a rostrocaudal gradient. Many other cell types have been described in embryos and need to be studied in adults. Our findings provide a reference for further studies on spinal cytoarchitecture. Combined with physiological, histological and pathological/traumatic approaches, these studies will help clarify the operation of spinal locomotor circuits of adult zebrafish. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 642–660, 2016     

Focus: The Aging Brain: Neurocardiovascular Instability and Cognition

Neurocardiovascular instability (NCVI) refers to abnormal neural control of the cardiovascular system affecting blood pressure and heart rate behavior. Autonomic dysfunction and impaired cerebral autoregulation in aging contribute to this phenomenon characterized by hypotension and bradyarrhythmia. Ultimately, this increases the risk of falls and syncope in older people. NCVI is common in patients with neurodegenerative disorders including dementia. This review discusses the various syndromes that characterize NCVI icluding hypotension, carotid sinus hypersensitivity, postprandial hypotension and vasovagal syncope and how they may contribute to the aetiology of cognitive decline. Conversely, they may also be a consequence of a common neurodegenerative process. Regardless, recognition of their association is paramount in optimizing management of these patients.     

Sonic hedgehog is a regulator of extracellular glutamate levels and epilepsy

Sonic hedgehog (Shh), both as a mitogen and as a morphogen, plays an important role in cell proliferation and differentiation during early development. Here, we show that Shh inhibits glutamate transporter activities in neurons, rapidly enhances extracellular glutamate levels, and affects the development of epilepsy. Shh is quickly released in response to epileptic, but not physiological, stimuli. Inhibition of neuronal glutamate transporters by Shh depends on heterotrimeric G protein subunit Gα_i and enhances extracellular glutamate levels. Inhibiting Shh signaling greatly reduces epileptiform activities in both cell cultures and hippocampal slices. Moreover, pharmacological or genetic inhibition of Shh signaling markedly suppresses epileptic phenotypes in kindling or pilocarpine models. Our results suggest that Shh contributes to the development of epilepsy and suppression of its signaling prevents the development of the disease. Thus, Shh can act as a modulator of neuronal activity, rapidly regulating glutamate levels and promoting epilepsy.     

降钙素基因相关肽、血管活性肠肽在复合应激大鼠模型阴茎组织中表达及伊木萨克干预的研究

目的:检测复合应激大鼠模型阴茎组织中降钙素基因相关肽(CGRP)、血管活性肠肽(VIP)的表达,并观察伊木萨克片对二者表达的影响。方法:选用56只正常雄性SD大鼠,其中10只为正常对照组(N),余46只为造模组,采用富含环境雌激素饲料+寒冷环境的干预条件建立复合性应激大鼠模型(20 w),并随机将其分为模型组(B1)、自然恢复组(B2)和伊木萨克干预组(B3),药物干预2 w后,免疫组化及Western blot方法检测大鼠阴茎组织中CGRP、VIP的表达。结果:①大鼠阴茎组织中CGRP表达:B1、B2组较N组明显减少(P0.05);B3组较B1、B2组明显增多(P0.05)。②大鼠阴茎组织中VIP表达:B1、B2组较N组显著降低(P0.05);B3组较B1、B2组显著升高(P0.05)。结论:复合应激大鼠模型阴茎组织中CGRP、VIP明显减少,伊木萨克片干预可抑制此变化。     

OSAHS风险对患者静脉麻醉术后认知功能障碍的影响

目的:探讨OSAHS风险与静脉麻醉手术患者术后发生认知功能障碍的关系。方法:采用No SAS评分对55例静脉麻醉手术患者进行OSAHS风险评估,并将其分为对照组23例(NoSAS 8分)和OSAHS组32例(No SAS≥8分),以蒙特利尔认知评估量表(MoCA)对两组患者在术前和术后第一天进行认知功能评估,计算每位患者手术前后Mo CA评分的差值△Mo CA(术前MoCA-术后MoCA),比较两组患者手术前后的MoCA评分及△MoCA。结果:OSAHS组术前MoCA评分(25.83±1.80)明显低于对照组术前MoCA评分(28.05±1.31)(P0.05)。OSAHS组术后MoCA评分(25.13±1.64)较术前无明显变化(P0.05),对照组术后Mo CA评分(26.73±1.17)明显低于术前(P0.05)。OSAHS组△MoCA(0.39±1.03)明显低于对照组(1.32±1.08),主要表现为视空间与执行功能[(0.09±0.29) vs.(0.30±0.32)]、注意力[(0.09±0.60) vs.(0.47±0.70)]和延时回忆力[(0.17±0.39) vs.(0.47±0.51)]两方面(P0.05)。结论:OSAHS高风险患者静脉麻醉术后认知功能障碍的程度较OSAHS低风险人群显著降低。     

Alpha lipoic acid inhibits oxidative stress‐induced apoptosis by modulating of Nrf2 signalling pathway after traumatic brain injury

Alpha lipoic acid (ALA) is a powerful antioxidant which has been widely used in the treatment of different system diseases, such as cardiovascular and cerebrovascular diseases. But, there are few studies that refer to protective effects and potential mechanisms on traumatic brain injury (TBI). This study was carried out to investigate the neuroprotective effect following TBI and illuminate the underlying mechanism. Weight drop‐injured model in rats was induced by weight‐drop. ALA was administrated via intraperitoneal injection after TBI. Neurologic scores were examined following several tests. Neurological score was performed to measure behavioural outcomes. Nissl staining and TUNEL were performed to evaluate the neuronal apoptosis. Western blotting was engaged to analyse the protein content of the Nuclear factor erythroid 2‐related factor 2 (Nrf2) and its downstream protein factors, including hemeoxygenase‐1 (HO‐1) and quinine oxidoreductase‐1 (NQO1). ALA treatment alleviated TBI‐induced neuron cell apoptosis and improved neurobehavioural function by up‐regulation of Nrf2 expression and its downstream protein factors after TBI. This study presents new perspective of the mechanisms responsible for the neuronal apoptosis of ALA, with possible involvement of Nrf2 pathway.