The Application of Analytical Techniques to Alpha-Synuclein in Parkinson’s Disease

Parkinson’s disease (PD) is a progressive neurodegenerative disorder characterized by motor symptoms such as tremors, rigidity, and bradykinesia, as well as non-motor symptoms including cognitive impairment and mood disorders. A hallmark of PD is the accumulation of alpha-synuclein, a presynaptic neuronal protein that aggregates to form Lewy bodies, leading to neuronal dysfunction and cell death. The study of alpha-synuclein and its pathological forms is crucial for understanding the etiology of PD and developing effective diagnostic and therapeutic strategies. Analytical techniques play a pivotal role in elucidating the structure, function, and aggregation mechanisms of alpha-synuclein. Biochemical methods such as Western blotting and enzyme-linked immunosorbent assay (ELISA) are employed to detect and quantify alpha-synuclein in biological samples, offering insights into its expression levels and post-translational modifications. Imaging techniques like immunohistochemistry and positron emission tomography (PET) allow for the visualization of alpha-synuclein aggregates in tissue samples and in vivo, respectively, facilitating the study of its spatial distribution and progression in PD Spectroscopic methods, including nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry, provide detailed structural information on alpha-synuclein and its isoforms, aiding in the identification of conformational changes associated with aggregation. Emerging techniques such as cryo-electron microscopy (Cryo-EM) and single-molecule fluorescence enable high-resolution structural analysis and real-time monitoring of alpha-synuclein aggregation dynamics, respectively. The application of these analytical techniques has significantly advanced our understanding of the pathophysiological role of alpha-synuclein in PD. They have contributed to the identification of potential biomarkers for early diagnosis and the evaluation of therapeutic interventions targeting alpha-synuclein aggregation. Despite technical limitations and challenges in clinical translation, ongoing advancements in analytical methodologies hold promise for improving the diagnosis, monitoring, and treatment of Parkinson’s disease through a deeper understanding of alpha-synuclein pathology.

Alpha-synuclein自身抗体用作帕金森病抗体治疗的探索研究

目的:通过从外周血中分离B细胞并进行培养,对外周血中存在的alpha-synuclein(α-syn)自身抗体进行分析,以探索用α-syn自身抗体开发治疗帕金森病(PD)抗体药物的可行性。方法:采集健康捐赠人的外周血并分离外周血B细胞进行培养,对B细胞培养上清进行ELISA结合活性分析,并用硫黄素T(ThT)法检测B细胞培养上清中α-syn自身抗体的生物学活性。结果:细胞培养13 d后,镜检发现B细胞扩增孔数可以达到90%以上,表明B细胞在实验条件下生长良好并能维持抗体分泌能力。ELISA结果表明检测的10530个样品中有48个可以和α-syn单体结合(OD 450>0.5),其中36个可以同时结合α-syn单体和聚合体(OD 450>0.5),并且该36个样品和α-syn家族蛋白β-synuclein以及γ-synuclein无交叉反应,具有α-syn结合特异性。用硫黄素T(ThT)法对该组样品进行的抑制聚合活性检测,结果表明36个样品中有9个样品能够显著性地抑制α-syn单体聚合,并且其中两个样品25G07和55F02的抑制率可以达到50%。结论:可以通过分离培养外周血B细胞获得具有生物学活性的α-syn自身抗体,用作治疗帕金森病的抗体药物研发。

表达alpha-synuclein A53T神经干细胞系的建立

目的建立表达alpha-synuleinA53T突变体的神经干细胞。方法采用Xho I/Hpa I双酶切paSynA53T-DsRed,将含SynA53T-DsRed片段连接到pBudCE4.1-1X-aSynA53T-DsRed的Xho I/PmeI位点构建pBudCE4.1-2X-aSynA53T-DsRed质粒。利用Lipofectamine2000介导转染2μg的pBudCE4.1-2X-aSynA53T-DsRed到鼠源性神经干细胞(mNSCs)后24 h和72 h观察转染结果。结果成功构建重组质粒pBudCE4.1-2X-aSynA53T-DsRed,转染24 h后其表达率达到(57±3.52)%,72 h的表达率达到了(27.14±3.21)%。结论通过质粒重组及转染技术,成功获得了表达aSynA53T的神经干细胞,为揭示α-synA53T导致帕金森氏症的病理过程提供了平台。

Implications of alpha-synuclein nitration at tyrosine 39 in methamphetamine-induced neurotoxicity in vitro and in vivo

Methamphetamine is an amphetamine-type psychostimulant that can damage dopaminergic neurons and cause characteristic pathological changes similar to neurodegenerative diseases such as Parkinson's disease. However, its specific mechanism of action is still unclear. In the present study, we established a Parkinson's disease pathology model by exposing SH-SY5 Y cells and C57 BL/6 J mice to methamphetamine. In vitro experiments were performed with 0, 0.5, 1.0, 1.5, 2.0 or 2.5 mM methamphetamine for 24 hours or 2.0 mM methamphetamine for 0-, 2-, 4-, 8-, 16-, and 24-hour culture of SH-SY5 Y cells. Additional experimental groups of SH-SY5 Y cells were administered a nitric oxide inhibitor, 0.1 mM N-nitro-L-arginine, 1 hour before exposure to 2.0 mM methamphetamine for 24 hours. In vivo experiments: C57 BL/6 J mice were intraperitoneally injected with N-nitro-L-arginine(8 mg/kg), eight times, at intervals of 12 hours. Methamphetamine 15 mg/kg was intraperitoneally injected eight times, at intervals of 12 hours, but 0.5-hour after each N-nitro-L-arginine injection in the combined group. Western blot assay was used to determine the expression of nitric oxide synthase, α-synuclein(α-Syn), 5 G4, nitrated α-synuclein at the residue Tyr39(nT39 α-Syn), cleaved caspase-3, and cleaved poly ADP-ribose polymerase(PARP) in cells and mouse brain tissue. Immunofluorescence staining was conducted to measure the positive reaction of NeuN, nT39 α-Syn and 5 G4. Enzyme linked immunosorbent assay was performed to determine the dopamine levels in the mouse brain. After methamphetamine exposure, α-Syn expression increased; the aggregation of α-Syn 5 G4 increased; nT39 α-Syn, nitric oxide synthase, cleaved caspase-3, and cleaved PARP expression increased in the cultures of SH-SY5 Y cells and in the brains of C57 BL/6 J mice; and dopamine levels were reduced in the mouse brain. These changes were markedly reduced when N-nitro-L-arginine was administered with methamphetamine in both SH-SY5 Y cells and C57 BL/6 J mice. These results suggest that nT39 α-Syn aggregation is involved in methamphetamine neurotoxicity.

Subcellular localization of alpha-synuclein aggregates and their interaction with membranes

For more than a decade numerous evidence has been reported on the mechanisms of toxicity of α-synuclein（αS） oligomers and aggregates in α-synucleinopathies.These species were thought to form freely in the cytoplasm but recent reports of αS multimer conformations when bound to synaptic vesicles in physiological conditions,have raised the question about where αS aggregation initiates.In this review we focus on recent literature regarding the impact on membrane binding and subcellular localization of αS toxic species to understand how regular cellular function of αS contributes to pathology.Notably αS has been reported to mainly associate with specific membranes in neurons such as those of synaptic vesicles,ER/Golgi and the mitochondria,while toxic species of αS have been shown to inhibit,among others,neurotransmission,protein trafficking and mitochondrial function.Strategies interfering with αS membrane binding have shown to improve αS-driven toxicity in worms and in mice.Thus,a selective membrane binding that would result in a specific subcellular localization could be the key to understand how aggregation and pathology evolves,pointing out to αS functions that are primarily affected before onset of irreversible damage.

Nanomolar concentration of alpha-synuclein enhances dopaminergic neuronal survival via Akt pathway

Although alpha-synuclein is generally thought to have a pathological role in Parkinson＇s disease, accumulative evidence exists that alpha-synuclein has a neuroprotective effect. The aim of this study was to evaluate the effect of extracellular alpha-synuclein on dopaminergic cell survival. We assessed cell viability using the 3-（4,5-dimethyt-thiazol-2-yt）-2,5-diphenyltertazolium bromide （MTT） assay both in undifferentiated SH-SY5Y （SHSY） cells and neuronally-differentiated SH-SY5Y （ndSHSY） cells after 24 hour treatment with monomeric alpha-synuclein at various concentrations （0 [control], 50, 100 nmol/L, 1 IJmol/L）. To determine whether cell viability assessed by MTT assay was affected by cell proliferation, 5-bromo-2＇-deoxyuridine （BrdU） incorporation assay was per- formed. Level of both Akt and phosphorylated Akt was measured using western blot method in ndSHSY cells with or without 24 hour alpha-synuclein treatment. Cell viability was increased in ndSHSY cells at the nanomolar concentration of alpha-synuclein, but not in SHSY cells. Proportion of BrdU-positive ndSHSY cells was decreased in alpha-synuclein-treated group compared with control group. Level of phosphorylated Akt in alpha-synuclein-treated group was higher compared with the control group. Our study shows that extracellular alpha-synuclein at nanomolar concentra- tion benefits dopaminergic cell survival via Akt pathway.

Navigating the dynamic landscape of alpha-synuclein morphology: a review of the physiologically relevant tetrameric conformation

N-acetylatedα-synuclein(αSyn)has long been established as an intrinsically disordered protein associated with a dysfunctional role in Parkinson’s disease.In recent years,a physiologically relevant,higher order conformation has been identified as a helical tetramer that is tailored by buried hydrophobic interactions and is distinctively aggregation resistant.The canonical mechanism by which the tetramer assembles remains elusive.As novel biochemical approaches,computational methods,pioneering purification platforms,and powerful imaging techniques continue to develop,puzzling information that once sparked debate as to the veracity of the tetramer has now shed light upon this new counterpart inαSyn neurobiology.Nuclear magnetic resonance and computational studies on multimericαSyn structure have revealed that the protein folding propensity is controlled by small energy barriers that enable large scale reconfiguration.Alternatively,familial mutations ablate tetramerization and reconfigure polymorphic fibrillization.In this review,we will discuss the dynamic landscape ofαSyn quaternary structure with a focus on the tetrameric conformation.

Alpha-synuclein truncation and disease

Alpha-synuclein is the major component of Lewy bodies, insoluble protein aggregates, found in patients with Parkinson’s disease, diffuse Lewy body disease, and the Lewy body variant of Alzheimer’s disease. Alpha-synuclein has been found within Lewy bodies to contain many different modifications, including nitration, phosphorylation, ubiquitination, and truncation. C-terminally truncated forms of alpha-synuclein aggregate faster than the full-length protein in vitro, and are thus believed to play a role in Lewy body formation and disease progression. Pathological studies of post mortem brain tissue and the generation of transgenic mouse models further support a role of C-terminally truncated forms of alpha-synuclein in disease. Several enzymes, some of which function extracellularly, have been implicated in the production of these C-terminally truncated forms of alpha-synuclein. However, the enzymes responsible for alphasynuclein truncation in vivo have not yet been firmly established.

Effects of lead exposure on alpha-synuclein and p53 transcription

Objective: Epidemiological studies have found that lead exposure increases the risk for Park-inson’s disease and patients with Parkinson’s disease have lower odds of developing non-smoking-related cancer (1). It would be inter-esting therefore to find the molecular links be-tween Parkinson’s disease and cancer. To do this, we studied mRNA expression of alpha-synuclein gene, a promising genetic marker for Parkinson’s disease, and expression of the tu-mor suppressor gene p53 after oxidative stress induced by lead. Methods: We used ATDC5 cell line as a model of tumor and treated by lead nitrate for 0, 2, 4, 16, 24 and 48 hours. The mRNAs of alpha-synuclein and p53 were quan-tified by reverse transcriptase polymerase chain reaction and expressed as mean (±SD) for 3 samples at each time point. Results: Ex-pression of both of alpha-synuclein and p53 mRNA increased with increasing exposure of lead treatment. The levels of alpha-synuclein and p53 mRNA were correlated with each other (r=0.9830;P<0.001). Conclusion: We propose that lead’s neurotoxicity in PD is caused by al-pha-synuclein expression and aggregation, which releases the inhibitory influence of al-pha-synuclein on p53 expression, thereby al-lowing p53 to act as the cell’s guardian of the genome and reduce tumorigenic potential. Treatments that reduce alpha-synuclein aggre-gation may need to account for a concomitant reduction in p53’s protective effect.

Unfolded annealing molecular dynamics conformers for wild-type and disease-associated variants of alpha-synuclein show no propensity for beta-sheetformation

Aggregation of alpha-synuclein leads to the formation of Lewy bodies in the brains of patients affected by Parkinson's disease (PD). Native human alpha-synuclein is unfolded in solution but assumes a partial alpha-helical conformation upon transient binding to lipid membranes. Annealing Molecular Dynamics (AMD) was used to generate a diverse set of unfolded conformers of free monomeric wild-type alpha-synuclein and PD-associated mutants A30P and A53T. The AMD conformers were compared in terms of secondary structure, hydrogen bond network, solvent-accessible surface per residue, and molecular volume. The objective of these simulations was to identify structural properties near mutation sites and the non-amyloid component (NAC) region that differ between wild- type and disease-associated variants and may be associated to aggregation of alpha- synuclein. Based on experimental evidence, a hypothesis exists that aggregation involves the formation of intermolecular beta sheets. According to our results, disease-associated mutants of alpha-synuclein are no more propense to contain extended beta regions than wild-type alpha-synuclein. Moreover, extended beta structures (necessary for beta sheet formation) were not found at or around positions 30 and 53, or the NAC region in any unfolded conformer of wild-type, A30P or A53T alpha-synuclein, under the conditions of the simulations. These results do not support the hypothesis that the mutant's higher propensity to aggregation results solely from changes in amino acid sequence leading to changes in secondary structure folding propensity.

内源性神经毒素Salsolinol和N-甲基-(R)-salsolinol诱导共培养SH-SY5Y细胞中Alpha-synuclein的聚集

路易氏小体是帕金森病(PD)患者典型的病理特征,其主要由alpha-synuclein(α-syn)蛋白组成。α-syn蛋白在PD患者脑内的聚集通常伴随着T细胞的浸润和神经元细胞的退化。已有的研究表明1-甲基-4-苯基-1,2,3,4-四氢异喹啉(Salsolinol,Sal)N-甲基转移酶与内源性神经毒素1(R),2(N)-二甲基-6,7-二羟基-1,2,3,4-四氢异喹啉(N-甲基-(R)-salsolinol,NMSal)在PD患者淋巴细胞中的升高有关。本文采用稳定转染EGFP的人母细胞瘤SH-SY5Y(SH-EGFP)细胞和人多形性胶质母细胞瘤U87细胞和外周T淋巴细胞Jurkat三种细胞共培养模型来研究内源性神经毒素Sal和NMSal对共同培养体系中SH-EGFP细胞中α-syn蛋白的聚集作用。结果表明,Sal和NMSal可以诱导三细胞共培养体系中SH-EGFP细胞中α-syn的聚集,但不会引起与U87或是Jurkat共培养中SH-EGFP细胞中α-syn的聚集。同时我们还发现Sal和NMSal处理的三细胞共培养体系中SH-EGFP细胞中自噬蛋白LC3表达水平的升高,而自噬诱导剂雷帕霉素可以减少α-syn的聚集。以上结果表明,Jurkat细胞可以影响Sal和NMSal诱导的共培养体系SH-EGFP细胞中α-syn的聚集,并且自噬可能通过清除错误折叠的α-syn蛋白来保护神经元细胞。

帕金森病中铁与Alpha-突触核蛋白的相互作用

帕金森病(Parkinson's disease,PD)的特异标志物Alpha-突触核蛋白的异常聚集往往伴有铁的沉积,说明铁与Alpha-突触核蛋白聚集之间存在一定联系。铁可以通过增加Alpha-突触核蛋白的产生及抑制其降解从而促进Alpha-突触核蛋白聚集。Alpha-突触核蛋白作为一种高铁还原酶也可以影响细胞铁的代谢。本文就铁与Alpha-突触核蛋白参与PD的发病以及两者之间相互作用的机制进行综述。

以α-synuclein为靶点的抗帕金森病药物研究进展

帕金森病(Parkinsons disease,PD)是常见的神经退行性疾病,目前对PD的药物治疗仅限于改善症状,尚缺乏能够延缓疾病进程并具有神经保护作用的药物。α-突触核蛋白(α-synuclein,α-syn)是一种位于神经元突触前末端、由140个氨基酸组成的蛋白质,它的突变、聚集和过度积累与包括PD在内的一系列神经退行性疾病密切相关。开发针对α-syn及其相关靶点的药物,可能是控制PD等突触核蛋白病进程的有效途径。该文主要从抑制α-syn表达和聚集、促进其解聚和降解、调节其修饰状态等方面,对以α-syn为靶点的药物研究进展进行综述。

优化人alpha-syn基因疫苗免疫MPTP慢性PD小鼠的神经保护作用

目的：探讨优化高分泌型人α-突触核蛋白（human alpha—synuclein，ha—syn）基因疫苗免疫MPTP慢性帕金森病小鼠的治疗效果和神经免疫保护作用．方法：建立慢性PD小鼠模型，采用神经毒素MPTP25mg／（kg·d），2次／wk，累计共10次．建模后随机分为3组：优化基因疫苗组、疫苗组、PBS对照组；每次治疗前，每只动物分别在双侧后肢胫骨前肌部位注射5g／L布比卡因50μL，注射72h后，3组动物分别于同部位同深度注射优化基因疫苗、基因疫苗或PBS各50μL，1次／3wk，共3次．末次免疫后2wk观察行为学改变后，处死取脑．运用免疫荧光、免疫组化等方法观察酪氨酸羟化酶阳性细胞数，以及α-syn表达变化．结果：优化基因疫苗组、疫苗组小鼠爬杆能力与PBS对照组比较都得到明显改善，有统计学差异（P〈0．05）；但优化基因疫苗组与疫苗组行为学评分间差异无统计学意义．优化基因疫苗组酪氨酸羟化酶阳性细胞数与其它两组相比增多约20％-68％（P〈0．05），α-syn表达减少约15％～45％（P〈0．05）．结论：优化基因疫苗具有较强改善帕金森小鼠行为学的作用，能增强疫苗的免疫原性，促进受损黑质细胞修复，对帕金森病小鼠有更好的免疫治疗作用．

脑源性神经营养因子介导帕金森病的运动防治:作用与机制

背景:运动干预作为经济有效的非物理疗法,可有效上调脑源性神经营养因子表达进而防治帕金森病发生发展,但目前关于靶向脑源性神经营养因子的运动治疗策略在延缓帕金森病发生发展的潜在作用机制尚不明晰。目的:以脑源性神经营养因子和帕金森病的关系为切入点,分析帕金森病病理状态下运动对脑源性神经营养因子表达的特异性调控作用及机制,梳理脑源性神经营养因子介导下不同运动方式对帕金森病的改善效果,并阐明靶向脑源性神经营养因子的运动治疗策略在防治帕金森病的潜在作用机制,旨在为运动防治帕金森病提供新的理论依据。方法:以“帕金森病,脑源性神经营养因子,神经保护,多巴胺,神经元异常凋亡,神经炎症反应,突触可塑性,运动”等为中文检索词;以“Parkinson’s disease,BDNF,Neuroprotection,neuroinflammation,synaptic plasticity”等为英文检索词,分别检索中国知网、万方数据库、PubMed和Web of Science数据库,搜寻各数据库建库至2024年2月发表的所有研究文献,根据纳排标准共获得核心相关文献98篇。结果与结论:①在帕金森病理背景下,运动可通过促进肌因子鸢尾素大量分泌,并降低色氨酸-犬尿氨酸代谢途径紊乱特异性调控脑源性神经营养因子表达。②有氧运动,尤其是特殊有氧运动(动物:旋转杆步行/人类:北欧健走)以及多模式运动可显著上调脑源性神经营养因子表达,进而改善帕金森病的运动症状,此外脑源性神经营养因子还介导身心运动(太极拳)对帕金森病患者认知障碍和睡眠障碍等非运动症状的有效调节。③运动诱导的高表达脑源性神经营养因子可能通过上调抗炎因子白细胞介素10、神经生长因子β和转化生长因子β表达,下调促炎因子肿瘤坏死因子α及白细胞介素1β表达,并抑制核转录因子κB信号通路表达降低小胶质细胞活性减轻神经炎症反应;增加酪氨酸羟化酶活性以促进多巴胺合成释放,并通过下调基质金属蛋白酶3及糖原合成酶激酶3β表达抑制α-突触核蛋白在丝氨酸129位点的磷酸化修饰,以防止神经异常凋亡;诱导突触效能的长时程增强发生,促进突触后致密区蛋白95及突触素大量表达以改善突触可塑性,发挥神经保护作。④鉴于脑源性神经营养因子在帕金森病发病进程及治疗中发挥重要作用,靶向脑源性神经营养因子的运动治疗策略将有助于推动帕金森病疾病“运动+药物”精准医疗的发展。但由于目前研究采用的运动处方较为单一,且研究焦点主要围绕运动症状而缺乏对非运动症状的考察,因此亟待学者采用更加统一和系统的运动处方,围绕非有氧运动类型对同一批帕金森病患者进行长期纵向跟踪研究,以此完善帕金森病运动防治领域研究的不足。

携带人alpha-突触核蛋白真核重组质粒构建及其SK-N-SH细胞表达

目的构建携带人alpha-突触核蛋白真核重组质粒,检测其在人神经母细胞瘤SK-N-SH细胞中的表达及对细胞存活率的影响。方法 PCR扩增alpha-突触核蛋白基因,产物纯化后与pcDNA3.1(+)载体进行连接反应,构建pcDNA3.1(+)/alpha-突触核蛋白真核重组质粒。Lipofectamine法转染人神经母细胞瘤SK-N-SH细胞,RT-PCR方法检测SK-N-SH细胞中alpha-突触核蛋白mRNA的表达,四甲基偶氮唑盐(MTT)法检测其对细胞存活率的影响。结果酶切鉴定及基因测序证明人alpha-突触核蛋白基因已被完整、正确地插入到pcDNA3.1(+)载体中。RT-PCR结果显示该表达载体转染SK-N-SH细胞后,细胞内alpha-突触核蛋白mRNA的表达水平明显增高,MTT方法检测结果显示该表达载体转染并未引起细胞存活率的改变。结论 alpha-突触核蛋白真核重组质粒构建成功,并可在SK-N-SH细胞内表达,且对细胞的存活率不产生任何影响,从而为进一步研究alpha-突触核蛋白在帕金森病发病机制中的作用奠定了基础。

pEGFP-N1-α-synuclein真核表达载体的构建

【目的】构建pEGFP-N1-α-synuclein真核表达载体,为研究帕金森病奠定基础。【方法】设计特异引物,PCR扩增α-synuclein cDNA并引入FLAG标签,克隆入pEGFP-N1质粒,对重组质粒进行酶切及测序,鉴定正确后转化Ecoli.DH5(大肠杆菌),大量扩增重组质粒。试剂盒纯化重组质粒。用Lipofectamine TM2000将重组质粒转染2937细胞,Western blotting检测融合蛋白在细胞内的表达。【结果】pEGFP-N1-α-synuclein重组质粒构建成功,Western blotting检测融合蛋白分子量为47kd,符合预期值。【结论】成功构建了人野生型α-synuclein与绿色荧光蛋白基因融合并加入FLAG标签的真核表达载体pEGFP-N1-α-synuclein。

松果菊苷对6-OHDA帕金森病模型大鼠海马α-Synuclein、β-actin蛋白表达影响随机平行对照研究

[目的]观察松果菊苷对6-OHDA帕金森病模型大鼠海马α-Synuclein、β-actin蛋白表达影响。[方法]使用随机平行对照方法,将72只SPF级SD雄性大鼠适应性饲养14d,按随机数字表法分为6组,空白对照组、假手术组、模型组、松果菊苷(低、中、高剂量)组,12只/组。各组大鼠腹腔注射10%水合氯醛(30mg/kg)麻醉,固定于颅脑定位仪,消毒,沿颅顶正中线切开皮肤,钝性分离颅骨外膜,暴露大鼠颅骨前囟门;以前囟为坐标原点(大鼠脑定位立体图谱),确定前脑内侧束(MFB)坐标,MFB:前囟后4.8mm,矢状缝右侧1.2mm,硬脑下7.8mm;颅骨钻钻孔,立体定向靶点微量注射6-OHDA(2ug/uL,溶于0.1%抗坏血酸生理盐水),注射速度1uL/min,留针15min;骨蜡封闭大鼠脑部颅骨孔,消毒缝合皮肤,复制帕金森病模型,松果菊苷(低、中、高剂量)组(8 ug)、模型组(2ug);空白对照组、假手术组(与模型组等量生理盐水)。灌胃干预:复制成功模型,松果菊苷组(低20mg/kg、中40mg/kg,高80mg/kg),余各组均等体积生理盐水,1次/d,连续10d。PAGE胶蛋白电泳;免疫印迹(Western Blot,WB)法检测α-Synuclein、β-actin蛋白。[结果]模型复制48只大鼠,麻醉过度死亡3只,模型复制不成功2只,最终纳入结果分析43只,模型组10只,松果菊苷组低、中、高剂量组各11只。α-Synuclein蛋白水平假手术组、松果菊苷各组(低中高)均低于空白对照组(P<0.01);β-actin各组间无明显差异(P>0.05);α-Synuclein/β-actin假手术组、松果菊苷低剂量组、松果菊苷中剂量组、松果菊苷高剂量组均低于空白对照组(P<0.01)。[结论]松果菊苷干预帕金森病模型大鼠,可降低海马α-Synuclein表达。

双重结合肽段协助胞内蛋白酶体系统降解alpha-突触核蛋白

alpha-突触核蛋白(alpha-synuclein,α-syn)异常累积与聚集是帕金森病的重要致病因素之一。目前,已有的降低细胞内α-syn的方法多是从抑制新蛋白质合成角度进行,而无法干预已经存在并产生毒性的蛋白质。该研究旨在探索一种可以降解α-syn的新方法,从而挽救α-syn造成的细胞损伤。本研究依据Trim-Away方法设计了2种针对α-syn降解的肽段,即Pep1和Pep2,并将其过表达至HEK293T以及SH-SY5Y细胞中。Western印迹检测和免疫荧光分析以及免疫共沉淀结果表明,Pep1和Pep2可以在上述细胞系中表达,并与α-syn形成复合物,协助胞内蛋白酶体系统降解α-syn(P<0.05,P<0.0001)。进一步的细胞活力以及细胞毒性结果显示,Pep1和Pep2可以挽救α-syn引起的细胞活力的下降(P<0.0001),并且可以缓解α-syn造成的细胞毒性的增加(P<0.0001)。总之,本文的结果提示,肽段可以协助胞内蛋白酶体系统降解α-syn,并缓解α-syn造成的细胞损伤。本研究为短肽的研发、应用以及帕金森病的干预提供新的思路。

α硫辛酸抑制6-羟基多巴胺诱导的PC12细胞中α突触核蛋白(α-synuclein)表达及机制

目的研究α硫辛酸(α-LA)对6-羟基多巴胺(6-OHDA)诱导的帕金森病细胞模型中α突触核蛋白(α-syn)表达的影响及其机制。方法采用6-OHDA诱导PC12细胞建立帕金森病细胞模型,用α-LA处理。噻唑蓝(MTT)法检测细胞活性,比色法检测细胞内铁含量和细胞内丙二醛(MDA)含量,荧光探针2,7-二氯二氢荧光素二乙酸酯(DCFH-DA)染色法检测细胞内活性氧(ROS)水平,Western blot法检测α-syn蛋白表达水平。结果与正常对照组相比,模型组细胞活性显著降低,细胞内铁含量、MDA含量、ROS水平均显著增高,α-syn蛋白水平显著增加;与模型组相比,α-LA处理的细胞活性显著升高,细胞内铁含量、MDA含量、ROS水平显著降低,α-syn蛋白水平显著降低。结论α-LA能抑制α-syn过表达,减轻6-OHDA诱导所致的PC12细胞损伤,这可能与α-LA降低细胞内铁含量、氧化应激水平有关。