中枢神经系统离子通道受体P2X7的研究进展

在ATP门控离子通道P2X受体家族中,P2X7受体由于在结构和功能上与其他(P2X1-P2X6)受体的显著差别而备受关注.P2X7受体是由3个同源亚基组成的多聚体,其C端为P2X受体家族中最长的,与其他已知蛋白没有同源性.P2X7受体具有独特的双功能性,被ATP激活后形成非选择性阳离子通道,允许钾、钠、钙等阳离子跨膜流动,而对二价阳离子表现出相对较强的选择性,在低浓度二价阳离子环境及ATP的持续刺激下,激活的P2X7受体能形成大的孔通道.P2X7受体广泛分布在血液系统、免疫系统和骨组织等多种组织器官中,通过信号转导参与细胞增殖、蛋白合成和细胞凋亡等事件.近年来在中枢神经系统中的研究发现,P2X7受体参与神经突触传递等生理过程,并在神经性退变等病理过程中发挥重要的调节作用.其中,多种假说支持它与少突胶质细胞的损伤有密切关系.     

P2X7受体与炎性细胞因子

P2X7受体是嘌呤受体中功能独特的一个亚型,为ATP控制的离子通道,在单核细胞、巨噬细胞、中性粒细胞中高表达,被ATP激活后导致K＋外流和Ca^2＋内流、非选择性膜孔形成,启动一系列信号途径如炎症小体NALP3的活化,丝裂原蛋白激酶途径激活NF-κB增强炎性细胞因子转录,ROS和氮介质的产生,介导IL-1β、IL-6、IL-18、TNF-α、MIP-2、CCL2、HMGB1等多种炎性细胞因子的释放,参与炎症的发生发展,与真菌感染及阿尔茨海默病、类风湿性关节炎、哮喘等炎症性疾病密切相关.     

P2X7受体与炎症相关性疾病

P2X7是一种在多种免疫细胞中广泛表达的以ATP为配体的阳离子通道受体,它的激活能引起和加重炎症反应。当细胞处于损伤、缺氧或炎症状态时, P2X7受体可被释放到胞外的大量ATP激活,进而通过活化NLRP3炎症小体、调节基因转录等方式,影响炎症介质(IL-1β、IL-18等)的释放从而参与多种炎症性疾病,如糖尿病肾病、系统性红斑狼疮(systemic lupus erythematosus,SLE)等。近年来,细胞外ATP-P2X7受体信号通路已成为炎症性疾病研究较多的通路之一。大量研究表明, P2X7受体是治疗炎症性疾病的潜在靶点。该文将对P2X7受体及其参与的炎症相关性疾病的关系作一综述。     

P2X7受体与炎症性肠病

P2X7受体与炎症密切相关,且在肠道细胞广泛表达。动物实验表明,ATP/P2X7信号主要介导加重肠炎,众多细胞参与这一作用,包括巨噬细胞、树突状细胞、T细胞、肥大细胞以及肠道神经元等。也有证据表明在弓形虫引起的肠炎中,P2X7信号则发挥抑制炎症的作用,其具体机制还有待进一步研究。本文就P2X7受体与炎症性肠病(inflammatory bowel disease,IBD)的相关研究进展作一综述,希望能为P2X7受体与IBD的进一步研究提供指导和借鉴。     

P2X7受体与疾病的相关性

P2X受体是一类离子型配体门控通道,分为7个不同的亚型(P2X1～7)。嘌呤能离子通道型受体7(purinergic ligand-gated ion channel 7 receptor, P2X7R)是ATP门控的,非选择性的阳离子通道,属于嘌呤受体P2X家族。P2X7受体广泛表达于神经系统、肌肉组织和免疫系统。在胞外ATP作用下,P2X7受体偶联多种胞内信号通路,参与细胞增殖、凋亡及炎症因子的释放等多种生理功能。研究发现,P2X7受体与诸多疾病有着密切联系,包括自身免疫性疾病(如关节炎和炎症性肠病)、神经退行性疾病、慢性疼痛、情绪障碍和癌症等。P2X7受体异常表达会导致这些疾病的发生,增加疾病的易感性与病变程度。现就P2X7受体的生物学特征、P2X7受体与疾病的关系及其特异性阻断剂和激动剂进行综述。     

P2X2和P2X4受体的调制位点

P2X受体是非选择性阳离子通道,广泛分布于中枢及外周神经系统。近年来,本实验室侧重研究重金属、质子、酒精等对P2X2和P2X4受体的调制。研究发现不同的因素对同一种受体介导的ATP-激活电流有不同的调制作用,如增强效应、抑制效应或者两种效应兼有,而且同一种因素对这两种受体的调制效应也不相同。因此,我们推测P2X受体上存在不同的结合位点,本文主要阐述P2X2和P2X4受体不同的调制位点。     

P2X7受体在病理性疼痛中的研究进展

病理性疼痛主要包括组织损伤或炎症引起的炎症痛、神经系统损伤或疾病引起的神经病理性疼痛和恶性肿瘤及治疗引起的癌症痛三大类。病理性疼痛对常规的镇痛药物反应不理想,迫切需要寻找新的对病理性疼痛更有效和更特异的治疗手段。P2X7受体作为离子通道型嘌呤能受体,在炎症痛、神经病理性疼痛和癌症痛中都具有重要作用。靶向P2X7受体的新药物将为病理性疼痛的治疗带来新的希望。该文综述了P2X7受体在三类病理性疼痛中的研究进展。     

Bone phenotype of P2X4 receptor knockout mice: implication of a P2X7 receptor mutation?

Transgenic and knockout animal models are widely used to investigate the role of receptors, signaling pathways, and other peptides and proteins. Varying results are often published on the same model from different groups, and much effort has been put into understanding the underlying causes of these sometimes conflicting results. Recently, it has been shown that a P2X4R knockout model carries a so-called passenger mutation in the P2X7R gene, potentially affecting the interpretation of results from studies using this animal model. We therefore report this case to raise awareness about the potential pitfalls using genetically modified animal models, especially within P2 receptor research. Although purinergic signaling has been recognized as an important contributor to the regulation of bone remodeling, the process that maintains the bone quality during life, little is known about the role of the P2X4 receptor (P2X4R) in regulation of bone remodeling in health and disease. To address this, we analyzed the bone phenotype of P2rx4tm1Rass (C57BL/6J) knockout mice and corresponding wildtype using microCT and biomechanical testing. Overall, we found that the P2X4R knockout mice displayed improved bone microstructure and stronger bones in an age- and gender-dependent manner. While cortical BMD, trabecular BMD, and bone volume were higher in the 6-month-old females and 3-month-old males, this was not the case for the 3-month-old females and the 6-month-old males. Bone strength was only affected in the females. Moreover, we found that P2X4R KO mice carried the P2X7 receptor 451P wildtype allele, whereas the wildtype mice carried the 451L mutant allele. In conclusion, this study suggests that P2X4R could play a role in bone remodeling, but more importantly, it underlines the potential pitfalls when using knockout models and highlights the importance of interpreting results with great caution. Further studies are needed to verify any specific effects of P2X4R on bone metabolism.

     

P2X受体研究进展

P2X受体为配体门控离子通道,属于P2受体家族。P2X受体的配体是ATP,胞外ATP结合时P2X受体通道打开,允许阳离子(Na 、Ca2 等)通过。目前已克隆了7个哺乳动物的P2X(P2X1-7)受体,并阐明了它们的药理学特性。天然P2X受体可以组装成同型或异型聚合体,形成功能性离子通道。对有关P2X受体的结构、分布、功能、生物物理学特性等研究的最新进展进行了综述。     

P2X7: a growth-promoting receptor—implications for cancer

The P2X₇ receptor is widely referred to as the paradigmatic cytotoxic nucleotide receptor, and is often taken as an epitome of cytotoxic receptors as a whole. However, cytotoxicity is the result of sustained pharmacological stimulation, which is likely to occur in vivo only under severe pathological conditions. Over the years, we have gathered robust experimental proof that led us to adopt an entirely different view, pointing to P2X₇ as a survival/growth-promoting rather than death-inducing receptor. Evidence in favour of this role is manifold: (1) extracellular ATP and benzoyl ATP support cell proliferation in peripheral T lymphocytes via a P2X₇-like receptor; (2) P2X₇ transfection into several cell lines confers growth advantage; (3) HEK293 cells transfected with P2X₇ show enhanced mitochondrial metabolic activity and growth; (4) lipopolysaccharide (LPS)-dependent growth arrest of microglia is mediated via P2X₇ down-modulation; (5) several malignant tumours express high P2X₇ levels and (6) the ATP concentration in tumour interstitium is several-fold higher than in healthy tissues, to a level in principle sufficient to activate the P2X₇ receptor. The molecular basis of P2X₇-mediated growth-promoting activity is poorly known, but mitochondria appear to play a central role. A deeper understanding of the role played by P2X₇ in cell proliferation might provide an insight into the mechanism of normal and malignant cell growth and suggest novel anti-tumour therapies.     

白血病细胞系来源的P2X7受体的功能研究

P2X7受体是ATP门控的离子通道。从白血病细胞系J6-1细胞中扩增P2X7受体编码区全序列,克隆到pTARGET真核表达载体,经DNA序列分析后转染Ramos细胞,获得稳定表达细胞株;应用RT-PCR、Westernblot和流式细胞术检测P2X7受体在Ramos中的表达;荧光分光光度计检测P2X7受体介导的胞内钙离子浓度变化。结果显示,J6-1细胞来源的P2X7受体在第559位有一个A→G的有义突变,导致Asn187→Asp187,可在Ramos细胞中表达,在特异性激动剂BzATP作用下可引起胞内钙离子浓度的升高,但所需激动剂浓度高于常规浓度。     

P2X7受体敲除对小鼠骨癌痛的影响

癌痛是临床晚期恶性肿瘤患者常见的临床表现之一。其中,以肺癌、乳腺癌和前列腺癌等骨转移引起疼痛尤为严重。P2X7受体是ATP门控离子通道型嘌呤能受体的一个亚型,在脊髓背角主要表达在胶质细胞。P2X7受体激活可以促进胶质细胞释放多种炎症介质,介导脊髓中枢敏化。该受体在炎症痛及神经病理性疼痛中的作用已多有报道,但在癌痛中的作用尚有争议。本研究采用C57BL/6J小鼠股骨骨髓腔内接种Lewis肺癌细胞所诱导的骨癌痛小鼠模型,分析对比了野生型小鼠和P2X7受体基因敲除(P2rx7-/-)小鼠骨癌痛的发生、发展。野生型C57BL/6J小鼠股骨骨髓腔内接种Lewis肺癌细胞后,患侧后肢分别在第7和14天开始出现明显的触诱发痛和热痛过敏,并呈进行性加重;Cat Walk步态分析显示骨癌第21和28天,小鼠患侧脚印面积明显减小,站立时相持续时间缩短,举步时相持续时间显著延长;组织病理学结果显示受累骨骨髓腔有大量肿瘤细胞浸润,骨髓质正常结构消失,伴有髓质骨和皮质骨的破坏。与研究设计时的预期相反,P2rx7-/-小鼠接种瘤细胞后,患肢痛行为检测结果与野生型小鼠相似,甚至在Cat Walk步态分析检测值变化发生的时间上较野生小鼠有所提前。这与本研究组前期在大鼠骨癌痛模型观察到的阻断P2X7受体明显对抗骨癌痛的结果完全不同,提示P2X7受体在大、小鼠骨癌痛中可能发挥不同的作用,并再次提示疾病动物模型上的研究结果与人类疾病机理之间还存在巨大差异。     

P2X7受体与炎症性肠病北大核心CSCD

P2X7受体与炎症密切相关,且在肠道细胞广泛表达。动物实验表明,ATP/P2X7信号主要介导加重肠炎,众多细胞参与这一作用,包括巨噬细胞、树突状细胞、T细胞、肥大细胞以及肠道神经元等。也有证据表明在弓形虫引起的肠炎中,P2X7信号则发挥抑制炎症的作用,其具体机制还有待进一步研究。本文就P2X7受体与炎症性肠病(inflammatory bowel disease,IBD)的相关研究进展作一综述,希望能为P2X7受体与IBD的进一步研究提供指导和借鉴。     

P2X7受体短肽单克隆抗体的制备及鉴定

旨在制备与鉴定鼠抗P2X7受体的蛋白单克隆抗体.以人P2X7受体的胞外段制备短肽作为抗原,皮下注射免疫Balb/c小鼠.分离小鼠脾脏B淋巴细胞与骨髓瘤细胞融合并培养,挑选阳性杂交瘤细胞,扩大培养,制备和鉴定P2X7其生物学效应.结果显示,获得1株稳定分泌抗人P2X7受体的单克隆抗体的杂交瘤细胞株,所分泌的单抗类型重链为IgG1,轻链为κ;该株杂交瘤细胞腹水效价为1∶6.4×104;传30代及液氮中保存6个月,抗体效价稳定;Western blotting检测证明该单抗与人细胞表面的P2X7受体蛋白特异地结合.所制备的抗人P2X7受体的单克隆抗体具有高度的特异性及稳定性,为针对P2X7受体为靶点的抗体药物的开发应用、疾病的辅助诊断奠定了基础.     

P2X7 receptor agonists pre- and postcondition the heart against ischemia-reperfusion injury by opening pannexin-1/P2X₇ channels

Protection of the heart from ischemia-reperfusion injury can be achieved by ischemic preconditioning and ischemic postconditioning. Previous studies revealed that a complex of pannexin-1 with the P2X(7) receptor forms a channel during ischemic preconditioning and ischemic postconditioning that results in the release of endogenous cardioprotectants. ATP binds to P2X(7) receptors, inducing the formation of a channel in association with pannexin-1. We hypothesized that this channel would provide a pathway for the release of these same cardioprotectants. Preconditioning-isolated perfused rat hearts with 0.4 μM ATP preceding 40 min of ischemia minimized infarct size upon subsequent reperfusion (5% of risk area) and resulted in >80% recovery of left ventricular developed pressure. Postconditioning with ATP after ischemia during reperfusion was also protective (6% infarct and 72% recovery of left ventricular developed pressure). Antagonists of both pannexin-1 (carbenoxolone and mefloquine) and P2X(7) receptors (brilliant blue G and A438079) blocked ATP pre- and postconditioning, indicating that ATP protection was elicited via the opening of a pannexin-1/P2X(7) channel. An antagonist of binding of the endogenous cardioprotectant sphingosine 1-phosphate to its G protein-coupled receptor diminished protection by ATP, which is also consistent with an ATP-dependent release of cardioprotectants. Suramin, an antagonist of binding of ATP (and ADP) to P2Y receptors, was without effect on ATP protection. Benzoyl benzoyl-ATP, a more specific P2X(7) agonist, was also a potent pre- and postconditioning agent and sensitive to blockade by pannexin-1/P2X(7) channel antagonists. The data point out for the first time the potential of P2X(7) agonists as cardioprotectants.     

Opposite effects of P2X7 and P2Y2 nucleotide receptors on α-secretase-dependent APP processing in Neuro-2a cells

The amyloid precursor protein (APP) is proteolytically processed by β- and γ-secretases to release amyloid-β peptide (Aβ), the main component found in senile plaques of Alzheimer's disease (AD) patient brains. Alternatively, APP can be cleaved within the Aβ sequence by α-secretase, thus precluding the generation of Aβ. We have demonstrated that activation of the P2X7 receptor leads to a reduction of α-secretase activity in Neuro-2a cells. Moreover, the P2X7 ligand 2'(3')-O-(4-benzoylbenzoyl) ATP (BzATP) can also activate a different P2 receptor in these cells. This receptor, whose pharmacology resembles that of the P2Y(2) receptor, has an opposite effect, leading to increases in α-secretase activity. Our study suggests that P2X7R and P2Y(2)R could be novel therapeutic targets in AD.     

P2X7 receptor positively regulates MyD88-dependent NF-κB activation

Recent studies have demonstrated that P2X7 plays a critical role in the immune system. Here, our results showed that P2X7 activated a NF-κB - but not an IFN-β-dependent luciferase reporter gene in HEK293T cells. P2X7 was involved in the LPS- and ATP-induced NF-κB activation but did not significantly impact the response to Zymosan in RAW264.7 cells. The activation of NF-κB and IFN-β induced by myeloid differentiation primary-response protein 88 (MyD88) was enhanced by P2X7 co-expression. The siRNA silencing MyD88 almost abolished the NF-κB activation induced by P2X7, and co-immunoprecipitation showed that P2X7 interacted with MyD88. The amino acids in the C-terminus, especially the LPS-binding region of P2X7, were critical for the cellular localization and immune function of P2X7. P2X7ΔC (190 amino acids deleted in the C-terminus) and P2X7 G586A variants localized throughout the cytoplasma with a little aggregation, which differs from the cell membrane localization of wild type P2X7. Both of them could not localize to Golgi or endoplasmic reticulum. P2X7ΔC and P2X7 G586A had impaired proteolytic cleavage of caspase-1 into the functional p20 subunit, which can activate pro-inflammatory cytokines such as IL-1β. P2X7 G586A also showed a slight interaction with MyD88 in our co-immunoprecipitation experiment. This interaction might result in the attenuated activation of NF-κB and IFN-β induced by MyD88.     

P2X嘌呤受体及其调制

嘌呤受体可分为Ｐ１（腺苷）和Ｐ２（ＡＴＰ）受体,在后者的诸亚型中仅Ｐ２Ｘ受体属配体门控离子通道受体超家族成员,Ｐ２Ｙ受体及其它亚型均为Ｇ蛋白偶联受体。本文介绍有关Ｐ２Ｘ嘌呤受体的特性,功能及其调制,包括变构性和胞内磷酸化调制。