血清淀粉样蛋白A经p38-MAPK/SR-BI途径促进巨噬细胞炎症反应北大核心CSCD

为探讨血清淀粉样蛋白A(serum amyloid A,SAA)对巨噬细胞B类I型清道夫受体(scavenger receptor class B type I,SR-BI)的表达以及炎症反应的影响及分子机制,采用SAA、p38丝裂原活化蛋白激酶(p38 mitogen-activated protein kinase,p38-MAPK)激动剂anisomycin或抑制剂SB203580处理THP-1巨噬细胞,以实时定量PCR、Western blot和ELISA分别检测细胞中SR-BI、炎症因子及磷酸化p38-MAPK的表达。结果显示,与对照组相比,SAA处理THP-1细胞后,SR-BI的表达下调,而炎症因子与磷酸化p38蛋白的表达则上调,且这种效应呈浓度和时间依赖性(P<0.05)。与SAA单独处理组比较,SAA与p38-MAPK激动剂anisomycin共孵育细胞后,细胞SR-BI表达下调,炎症因子及磷酸化p38蛋白表达增加(P<0.05);而SAA与p38-MAPK抑制剂SB203580共同处理细胞后,细胞SR-BI表达增加,炎症因子及磷酸化p38蛋白表达减少(P<0.05)。结果提示,SAA可促进THP-1巨噬细胞炎症反应,其机制与p38-MAPK的磷酸化及SR-BI表达的下调有关。     

血清淀粉样蛋白A经p38-MAPK/SR-BI途径促进巨噬细胞炎症反应

为探讨血清淀粉样蛋白A(serum amyloid A,SAA)对巨噬细胞B类I型清道夫受体(scavenger receptor class B type I,SR-BI)的表达以及炎症反应的影响及分子机制,采用SAA、p38丝裂原活化蛋白激酶(p38 mitogen-activated protein kinase,p38-MAPK)激动剂anisomycin或抑制剂SB203580处理THP-1巨噬细胞,以实时定量PCR、Western blot和ELISA分别检测细胞中SR-BI、炎症因子及磷酸化p38-MAPK的表达。结果显示,与对照组相比,SAA处理THP-1细胞后,SR-BI的表达下调,而炎症因子与磷酸化p38蛋白的表达则上调,且这种效应呈浓度和时间依赖性(P0.05)。与SAA单独处理组比较,SAA与p38-MAPK激动剂anisomycin共孵育细胞后,细胞SR-BI表达下调,炎症因子及磷酸化p38蛋白表达增加(P0.05);而SAA与p38-MAPK抑制剂SB203580共同处理细胞后,细胞SR-BI表达增加,炎症因子及磷酸化p38蛋白表达减少(P0.05)。结果提示,SAA可促进THP-1巨噬细胞炎症反应,其机制与p38-MAPK的磷酸化及SR-BI表达的下调有关。     

CREB和NF-κB在p38MAPK所致脊髓星形胶质细胞活化中的作用（英文）

目的：探讨CREB和NF-κB在p38MAPK所致脊髓星形胶质细胞活化中的作用,明确脊髓星形胶质细胞活化中p38MAPK细胞信号转导途径的作用。方法：分离培养SPF大鼠脊髓星形胶质细胞,设正常组、SP刺激组（SP组,10-7mol/L）、SP刺激＋SB203580（10μmol/L）阻断p38MAPK组（SP＋SB组）、SP刺激＋PD98059（10μmol/L）阻断CREB组（SP＋PD组）、SP刺激＋SN50（10μmol/L）阻断NF-κB（SP＋SN组）。WB法、免疫荧光法、ELISA法检测12 h和24 h时p-p38、p-CREB、NF-κBp65水平及GFAP、TNF-、IL-1β水平变化。结果：SP组脊髓星形胶质细胞p-p38、p-CREB、NF-κBp65显著升高,GFAP水平显著增高,同时TNF-和IL-1β水平显著增高。与SP组比较,用SB203580阻断p38MAPK通路后,SP＋SB组p-p38、p-CREB、NF-κBp65显著降低,GFAP、TNF-和IL-1β水平显著降低。用PD98059阻断CREB通路后,SP＋PD组p-p38、NF-κBp65无显著变化,p-CREB显著降低,GFAP水平降低,同时TNF-和IL-1β水平降低。用SN50阻断NF-κB通路后,SP＋SN组p-p38、p-CREB无显著变化,NF-κBp65显著降低,GFAP水平降低,同时TNF-和IL-1β水平降低。结论：体外培养中,SP刺激后脊髓星形胶质细胞显著活化,p38MAPK活化后通过CREB及NF-κB信号途径导致胶质细胞炎性因子水平显著升高。     

周围神经损伤中P2Y12受体-p38MAPK通路的研究进展

周围神经损伤是临床中常见的神经损伤之一,神经胶质细胞和信号通路转导在周围神经损伤和再生修复中发挥重要作用。小胶质细胞的活化与周围神经损伤导致的神经损伤及疼痛密切相关,小胶质细胞是周围神经损伤与修复的关键场所。脊髓背角的小胶质细胞可被嘌呤信号通路的P2Y_(12)受体活化,进而导致p38MAPK磷酸化,造成相关神经损伤及感觉功能障碍。以脊髓背角的小胶质细胞为靶点,从P2Y_(12)受体-p38MAPK通路的角度可揭示周围神经损伤的部分可能机制。探究从嘌呤信号通路与小胶质细胞活化的新角度,将神经损伤后的P2Y_(12)受体与p38MAPK的磷酸化表达联系为P2Y_(12)受体-p38MAPK通路,可为临床治疗周围神经损伤提供新的思路。本文就周围神经损伤中P2Y_(12)受体-p38MAPK通路的研究进展作一综述。     

脑微血管内皮细胞条件培养液对MIP-1β诱导大鼠小胶质细胞迁移影响的机制

目的:研究经通络方药作用后的脑微血管内皮细胞条件培养液对MIP-1β诱导的大鼠小胶质细胞迁移的影响,以及由MIP-1β在小胶质细胞上的受体-CCR5介导细胞信号转导通路的调控作用.方法:将通络方药作用后的大鼠脑微血管内皮细胞条件培养液加入到由5nM MIP-1β刺激6h后的原代大鼠小胶质细胞中,利用Transwell细胞迁移系统来观察小胶质细胞迁移,用Western blot法检测小胶质细胞CCR5,p-p38,P-JNK表达情况.结果:脑微血管内皮细胞条件培养液能够显著减少小胶质细胞迁移到Transwell下层的细胞数量(P<0.01),降低小胶质细胞上MIP-1β的受体CCR5表达,同时抑制了其下游信号蛋白p38和JNK的磷酸化.结论:通络方药作用后的脑微血管内皮细胞务件培养液可抑制由MIP-1β诱导的大鼠小胶质细胞迁移,其作用发挥可能是通过抑制MIP-1β的受体CCR5表达,降低了其下游通路上p38和JNK蛋白磷酸化程度实现.     

低分子量透明质酸片段通过toll样受体4信号途径激活枯否细胞

高分子量透明质酸（high-molecular-weight hyaluronic acid,HMW-HA）是重要的肝脏基质,分子量高达2×10^6Da以上,可被活性氧分子（reactive oxygen species,ROS）等降解成低分子量透明质酸片段（hyaluronic acid fragments,HA fragments）,后者能被toll样受体4（toll-like receptor4,TLR4）识别并激活免疫细胞诱发炎症反应。基于枯否细胞表达TLR4,推测HA fragments通过激活枯否细胞TLR4信号系统而启动肝脏缺血再灌注损伤。从TLR4基因突变型（C3H／HeJ,TLR4^Mut/Mut）及野生型（C3H／HeN,TLR4^＋/＋）小鼠分离肝脏枯否细胞常规培养,用酶降解及色谱柱分离方法制备HA fragments,观察HMW-HA及HA fragments激活枯否细胞的差异,检测培养上清肿瘤坏死因子-α或白介素-1β水平变化;枯否细胞p38MAPK信号通路的活化;用特异性p38MAPK阻断剂—SB-203580,阻断p38MAPK活化后,观察培养上清中肿瘤坏死因子-α或白介素-1β水平变化。结果显示HA fragments可以促进TLR4^＋/＋枯否细胞分泌促炎因子,不能诱导TLR4^Mut/Mut枯否细胞分泌促炎因子。而HMW-HA既不能促进TLR4^＋/＋枯否细胞也不能促进TLR4^Mut/Mut枯否细胞分泌促炎因子。采用多黏菌素中和脂多糖后,HA fragments促进TLR4^＋/＋枯否细胞分泌促炎因子的能力不变,这一过程伴随p38MAPK信号通路的活化。当运用p38MAPK信号通路的特异性阻断剂SB-203580,抑制p38MAPK活性时,HA fragments促进TLR4^＋/＋枯否细胞分泌促炎因子的能力显著下降。因此与基质组成成分HMW-HA不同,HA fragments可以通过TLR4激活枯否细胞,促进其分泌促炎因子诱发炎症反应,这一过程依赖于p38MAPK的激活。     

慢病毒介导SRB-1 受体基因沉默对人脑小胶质细胞吞噬Aβ蛋白能力的影响

目的:利用慢病毒载体筛选人脑小胶质细胞(HM1900)清道夫受体SRB1基因敲减稳定细胞系,检测该细胞系对AD致病蛋白Aβ的吞噬水平变化。方法:采用反转录PCR确认人脑小胶质细胞(HM1900)SRB1(Gene ID:949)基因表达情况,利用软件设计三组不同序列的针对人SRB1基因的慢病毒sh RNA干扰载体,包装为慢病毒感染HM1900细胞,实时荧光定量PCR检测各慢病毒干扰载体的靶基因干扰效率。选用干扰效果最佳的RNA干扰慢病毒筛选并获得SRB1基因敲减细胞系,稳定传代后用realtime-PCR检测SRB1受体表达下调情况。通过蛋白内吞实验测定基因敲减后该细胞系对病理蛋白Aβ的吞噬能力,与正常小胶质细胞进行比较。结果:利用筛选出的干扰载体完成对HM1900细胞系的SRB1基因敲减,荧光定量PCR检测显示SRB1基因在靶细胞HM1900中表达抑制率达83.7%。蛋白内吞实验显示该基因敲减细胞系对病理蛋白Aβ的吞噬能力下降到对照组的57%(P0.05)。结论:通过慢病毒载体成功建立SRB1基因稳定敲减的人脑小胶质细胞系,SRB1受体参与了小胶质细胞对病理蛋白Aβ的吞噬及清除过程。     

膜周蛋白PICK1促进细胞膜上P2Y6受体表达及小胶质细胞的吞噬功能

膜周蛋白PICK1(protein interactingC-kinase-1)参与多种膜受体与膜上蛋白的运输并影响细胞的功能。本研究旨在探索小胶质细胞PICK1与P2Y6受体之间的相互作用是否可改变P2Y6受体在细胞膜上的表达,以及对小胶质细胞吞噬功能的影响。采用小鼠脑内皮层原代培养的小胶质细胞进行免疫共沉淀实验揭示,与PICK1敲除小鼠比较,野生小鼠皮层小胶质细胞内存在PICK1-P2Y6受体相互作用。生物素化、密度梯度离心结合蛋白质印迹实验证明,PICK1基因敲除小鼠的小胶质细胞膜表面P2Y6受体表达水平降低。荧光胶珠吞噬实验结合免疫组织化学染色显示,PICK1基因敲除小鼠的小胶质细胞对UDP（刺激）引起的荧光胶珠吞噬作用减弱。蛋白质印迹实验显示,与野生型小鼠比较,PICK1基因敲除小鼠小胶质细胞中的Akt 308T磷酸化水平明显降低|使用Akt抑制剂API-2能有效抑制Akt 在小胶质细胞内的（磷酸化）激活及UDP刺激引起的吞噬作用。上述结果表明,敲除PICK1能下调小胶质细胞膜上P2Y6受体的表达,并降低小胶质细胞的吞噬功能,且这一过程依赖Akt磷酸化修饰。总之,PICK1可促进P2Y6受体在细胞膜上的表达,是小胶质细胞吞噬功能的重要调节子|敲除PICK1可下调P2Y6膜受体表达,并降低小胶质细胞的吞噬功能。这一结果可加深对小胶质细胞的吞噬功能及机制的认识。     

Toll样受体4在吗啡应用和耐受中的作用

Toll样受体4(Toll-like receptor 4) 是主要表达于小胶质细胞表面开启哺乳动物先天免疫反应的重要受体.近年研究表明,TLR4参与疼痛及炎症的形成.TLR4 能够被吗啡激活,其结果导致小胶质细胞活化,细胞因子合成和释放增加,从而提高疼痛感受细胞的兴奋性,减小或抵消吗啡的镇痛作用,即形成吗啡耐受.抑制TLR4可以增加吗啡的镇痛作用,减缓吗啡耐受的形成.TLR4与经典阿片受体之间存在立体选择特异性差异,(-)和(+)吗啡均能使之激活.吗啡-TLR4-胶质细胞作用链的研究为治疗吗啡耐受产生提供新的路径.     

TLR9与先天性免疫反应

TLR9（Toll-likereceptor9）是一种微生物病原相关分子结构模式识别受体,TLR9能够识别CpG—ODN（胞嘧啶磷酸鸟甘-寡聚脱氧核苷酸）,使病原相关受体在先天性免疫细胞上表达,并激活下游炎性通路。研究表明,TLR9在先天性免疫反应中产生了重要作用,如脓毒血症、自身免疫性疾病、刀豆体球蛋白A介导肝炎性肝脏损伤、炎性泡沫细胞形成、缺血再灌注损伤等,并且与多种致病因子相关联,如肝x受体、甲酰多肽受体、线粒体DNA等。     

TLR2 is a primary receptor for Alzheimer's amyloid β peptide to trigger neuroinflammatory activation

Microglia activated by extracellularly deposited amyloid β peptide (Aβ) act as a two-edged sword in Alzheimer's disease pathogenesis: on the one hand, they damage neurons by releasing neurotoxic proinflammatory mediators (M1 activation); on the other hand, they protect neurons by triggering anti-inflammatory/neurotrophic M2 activation and by clearing Aβ via phagocytosis. TLRs are associated with Aβ-induced microglial inflammatory activation and Aβ internalization, but the mechanisms remain unclear. In this study, we used real-time surface plasmon resonance spectroscopy and conventional biochemical pull-down assays to demonstrate a direct interaction between TLR2 and the aggregated 42-aa form of human Aβ (Aβ42). TLR2 deficiency reduced Aβ42-triggered inflammatory activation but enhanced Aβ phagocytosis in cultured microglia and macrophages. By expressing TLR2 in HEK293 cells that do not endogenously express TLR2, we observed that TLR2 expression enabled HEK293 cells to respond to Aβ42. Through site-directed mutagenesis of tlr2 gene, we identified the amino acids EKKA (741-744) as a critical cytoplasmic domain for transduction of inflammatory signals. By coexpressing TLR1 or TLR6 in TLR2-transgenic HEK293 cells or silencing tlrs genes in RAW264.7 macrophages, we observed that TLR2-mediated Aβ42-triggered inflammatory activation was enhanced by TLR1 and suppressed by TLR6. Using bone marrow chimeric Alzheimer's amyloid precursor transgenic mice, we observed that TLR2 deficiency in microglia shifts M1- to M2-inflammatory activation in vivo, which was associated with improved neuronal function. Our study demonstrated that TLR2 is a primary receptor for Aβ to trigger neuroinflammatory activation and suggested that inhibition of TLR2 in microglia could be beneficial in Alzheimer's disease pathogenesis.     

Nucleotides released from Aβ₁₋₄₂ -treated microglial cells increase cell migration and Aβ₁₋₄₂ uptake through P2Y₂ receptor activation

Amyloid β-protein (Aβ) deposits in brains of Alzheimer's disease patients generate proinflammatory cytokines and chemokines that recruit microglial cells to phagocytose Aβ. Nucleotides released from apoptotic cells activate P2Y(2) receptors (P2Y(2) Rs) in macrophages to promote clearance of dead cells. In this study, we investigated the role of P2Y(2) Rs in the phagocytosis and clearance of Aβ. Treatment of mouse primary microglial cells with fibrillar (fAβ(1-42) ) and oligomeric (oAβ(1-42) ) Aβ(1-42) aggregation solutions caused a rapid release of ATP (maximum after 10 min). Furthermore, fAβ(1-42) and oAβ(1-42) treatment for 24 h caused an increase in P2Y(2) R gene expression. Treatment with fAβ(1-42) and oAβ(1-42) aggregation solutions increased the motility of neighboring microglial cells, a response inhibited by pre-treatment with apyrase, an enzyme that hydrolyzes nucleotides. The P2Y(2) R agonists ATP and UTP caused significant uptake of Aβ(1-42) by microglial cells within 30 min, which reached a maximum within 1 h, but did not increase Aβ(1-42) uptake by primary microglial cells isolated from P2Y(2) R(-/-) mice. Inhibitors of α(v) integrins, Src and Rac decreased UTP-induced Aβ(1-42) uptake, suggesting that these previously identified components of the P2Y(2) R signaling pathway play a role in Aβ phagocytosis by microglial cells. Finally, we found that UTP treatment enhances Aβ(1-42) degradation by microglial cells, but not in cells isolated from P2Y(2) R(-/-) mice. Taken together, our findings suggest that P2Y(2) Rs can activate microglial cells to enhance Aβ clearance and highlight the P2Y(2) R as a therapeutic target in Alzheimer's disease.     

Toll-like receptor 9 is required for opioid-induced microglia apoptosis

Opioids have been widely applied in clinics as one of the most potent pain relievers for centuries, but their abuse has deleterious physiological effects beyond addiction. However, the underlying mechanism by which microglia in response to opioids remains largely unknown. Here we show that morphine induces the expression of Toll-like receptor 9 (TLR9), a key mediator of innate immunity and inflammation. Interestingly, TLR9 deficiency significantly inhibited morphine-induced apoptosis in microglia. Similar results were obtained when endogenous TLR9 expression was suppressed by the TLR9 inhibitor CpGODN. Inhibition of p38 MAPK by its specific inhibitor SB203580 attenuated morphine-induced microglia apoptosis in wild type microglia. Morphine caused a dramatic decrease in Bcl-2 level but increase in Bax level in wild type microglia, but not in TLR9 deficient microglia. In addition, morphine treatment failed to induce an increased levels of phosphorylated p38 MAPK and MAP kinase kinase 3/6 (MKK3/6), the upstream MAPK kinase of p38 MAPK, in either TLR9 deficient or μ-opioid receptor (μOR) deficient primary microglia, suggesting an involvement of MAPK and μOR in morphine-mediated TLR9 signaling. Moreover, morphine-induced TLR9 expression and microglia apoptosis appears to require μOR. Collectively, these results reveal that opioids prime microglia to undergo apoptosis through TLR9 and μOR as well. Taken together, our data suggest that inhibition of TLR9 and/or blockage of μOR is capable of preventing opioid-induced brain damage.     

Oligomeric Aβ-Induced Microglial Activation is Possibly Mediated by NADPH Oxidase

Recent studies have shown that oligomeric amyloid-β (oAβ) peptide can potentially activate microglia in addition to inducing more potent neurotoxicity compared with fibrillar Aβ (fAβ); however, its mechanisms of action remain unclear. This study was designed to investigate the possible mechanisms involved in the microglial activation induced by oAβ in BV-2 microglial cells. The results showed that oAβ induced activated properties of microglia, including higher proliferative capacity as well as increased production of reactive oxygen species, nitric oxide (NO), tumor necrosis factor-α (TNF-α), and interleukin-1β (IL-1β). NADPH oxidase inhibitors [diphenylene iodonium (DPI) and apocynin (4-hydroxy-3-methoxy-acetophenone)] prevented the microglial activation induced by oAβ, suggesting that NADPH oxidase activation was involved in microglial activation. In addition, TNF-α and IL-1β, which are massively released by activated microglia, significantly induced the activation of microglia, thereby resulting in the production of NO and proliferation of microglia, respectively. These effects could be inhibited by diphenylene iodonium and apocynin, indicating a self-cycle regulated by NADPH oxidase in microglial activation in response to oAβ. In conclusion, microglial activation induced by oAβ is possibly mediated by NADPH oxidase, suggesting that oAβ, which is normally considered a neurotoxin, may also lead to indirect neuronal damage through the pro-inflammation activation of microglia in Alzheimer’s disease and that NADPH oxidase could be a potential target to prevent oAβ-induced inflammatory neurodegeneration.     

Insulin signaling leading to proliferation, survival, and membrane ruffling in C2C12 myoblasts

We have recently shown that insulin induced myogenesis in the mouse C2C12 skeletal muscle cell line by activation of phosphatidylinositol (PI) 3-kinase/p70S6-kinase and p38-mitogen-activated protein kinase (MAPK) and downregulation of p42/p44-MAPK. This study investigated the insulin-signaling pathways involved in mitogenesis, survival, and membrane ruffling in C2C12 myoblasts, a cellular system that besides IGF-I receptors, expressed a high number of functional insulin receptors. Insulin (10 nM) rapidly stimulated beta-chain insulin receptor and IRS-1 tyrosine phosphorylation, IRS-2 being poorly and SHC not phosphorylated at all. However, an association of SHC with IRS-1 was found under insulin stimulation. Insulin stimulated IRS-1 association with p85alpha leading to the activation of PI3-kinase, and, subsequently AKT and p70S6-kinases. Moreover, both p42/p44- and p38-MAPKs resulted in phosphorylation after insulin stimulation. Insulin treatment for 24 h produced mitogenesis, as demonstrated by the increase in ((3)H)-thymidine incorporation, DNA content, the expression of PCNA and cyclin D1 proteins, and the proportion of cells in S + G2/M phases of the cell cycle. This mitogenic effect of insulin was precluded by inhibition of p70S6-kinase (either by rapamycin or by the PI3-kinase inhibitor LY294002) as well as by inhibition of p44/p42-MAPK with PD098059, but was not affected by inhibition of p38-MAPK. Serum deprivation of C2C12 myoblasts resulted in growth arrest at the GO/G1 phases of the cell cycle and apoptosis, as detected either by DNA laddering or by increase in the percentage of hypodiploid cells. Insulin rescued serum-deprived cells from apoptosis in an AKT-dependent manner, as demonstrated by the inhibition of AKT-activity by the use of LY294002 and ML-9, meanwhile neither inhibition of p70S6-kinase, nor MAPK affected insulin-induced survival. Finally, we evaluated the capacity of insulin to modulate actin cytoskeleton rearrangement. Insulin stimulation of myoblasts produced membrane ruffling and decreased actin stress fibers; this biological response being dependent of p38-MAPK, as demonstrated by the use of the p38-MAPK inhibitors SB203580 or PD169316, but independent of PI3-kinase and p42/p44-MAPK.     

Amyloid-β induced membrane damage instigates tunneling nanotube-like conduits by p21-activated kinase dependent actin remodulation

Alzheimer's disease (AD) pathology progresses gradually via anatomically connected brain regions. Direct transfer of amyloid-β_1–42 oligomers (oAβ) between connected neurons has been shown, however, the mechanism is not fully revealed. We observed formation of oAβ induced tunneling nanotubes (TNTs)-like nanoscaled f-actin containing membrane conduits, in differentially differentiated SH-SY5Y neuronal models. Time-lapse images showed that oAβ propagate from one cell to another via TNT-like structures. Preceding the formation of TNT-like conduits, we detected oAβ₋induced plasma membrane (PM) damage and calcium-dependent repair through lysosomal-exocytosis, followed by massive endocytosis to re-establish the PM. Massive endocytosis was monitored by an influx of the membrane-staining dye TMA-DPH and PM damage was quantified by propidium iodide influx in the absence of Ca²⁺. The massive endocytosis eventually caused accumulation of internalized oAβ in Lamp1 positive multivesicular bodies/lysosomes via the actin cytoskeleton remodulating p21-activated kinase1 (PAK1) dependent endocytic pathway. Three-dimensional quantitative confocal imaging, structured illumination superresolution microscopy, and flowcytometry quantifications revealed that oAβ induces activation of phospho-PAK1, which modulates the formation of long stretched f-actin extensions between cells. Moreover, the formation of TNT-like conduits was inhibited by preventing PAK1-dependent internalization of oAβ using the small-molecule inhibitor IPA-3, a highly selective cell-permeable auto-regulatory inhibitor of PAK1. The present study reveals that the TNT-like conduits are probably instigated as a consequence of oAβ induced PM damage and repair process, followed by PAK1 dependent endocytosis and actin remodeling, probably to maintain cell surface expansion and/or membrane tension in equilibrium.