Analysis and Review of Downregulated Actin Cytoskeletal Proteins in Non-Small Cell Lung Cancer

Actin, a highly conserved protein, plays a dominant role in Non-small cell lung cancer (NSCLC). Late diagnosis and the aggressive nature of NSCLC pose a significant threat. Studying the clinic pathological properties of NSCLC proteins is a potential alternative for developing treatment strategies. Towards this, 35 downregulated actin cytoskeletal proteins on NSCLC prognosis and treatment were studied by examining their protein-protein interactions, gene ontology enrichment terms, and signaling pathways. Using PubMed, various proteins in NSCLC were identified. The protein-protein interactions and functional associations of these proteins were examined using the STRING database. The focal adhesion signaling pathway was selected from all available KEGG and Wiki pathways because of its role in regulating gene expression, facilitating cell movement and reproduction, and significantly impacting NSCLC. The protein-protein interaction network of the 35 downregulated actin cytoskeleton proteins revealed that ACTG1, ACTR2, ACTR3, ANXA2, ARPC4, FLNA, TLN1, CALD1, MYL6, MYH9, MYH10, TPM1, TPM3, TPM4, PFN1, IQGAP1, MSN, and ZXY exhibited the highest number of interactions. Whereas HSPB1, CTNNA1, KRT17, KRT7, FLNB, SEPT2, and TUBA1B displayed medium interactions, while UTRN, TUBA1B, and DUSP23 had relatively fewer interactions. It was discovered that focal adhesions are critical in connecting membrane receptors with the actin cytoskeleton. In addition, protein kinases, phosphatases, and adapter proteins were identified as key signaling molecules in this process, greatly influencing cell shape, motility, and gene expression. Our analysis shows that the focal adhesion pathway plays a crucial role in NSCLC and is essential for developing effective treatment strategies and improving patient outcomes.

Effect of glycosides of Cistanche on the expression of mitochondrial precursor protein and keratin type Ⅱ cytoskeletal 6A in a rat model of vascular dementia

Glycosides of Cistanche（GC）is a preparation used extensively for its neuroprotective effect against neurological diseases,but its mechanisms of action remains incompletely understood.Here,we established a bilateral common carotid artery occlusion model of vascular dementia in rats and injected the model rats with a suspension of GC（10 mg/kg/day,intraperitoneally）for 14 consecutive days.Immunohistochemistry showed that GC significantly reduced p-tau and amyloid beta（Aβ）immunoreactivity in the hippocampus of the model rats.Proteomic analysis demonstrated upregulation of mitochondrial precursor protein and downregulation of keratin type II cytoskeletal6A after GC treatment compared with model rats that had received saline.Western blot assay confirmed these findings.Our results suggest that the neuroprotective effect of GC in vascular dementia occurs via the promotion of neuronal cytoskeleton regeneration.

Acrylamide Alters Cytoskeletal Protein Level in Rat Serum

To study biomarker of acrylamide （ACR） induced neuropathy, Wistar rats received 20 or 40 mg/kg of ACR by ip injection and the levels of light neurofilament （NF-L）, middle NF （NF-M）, heavy NF （NF-H）, β-actin, α-tubulin, and β-tubulin proteins in serum were evaluated using both SDS-PAGE and Western blotting. Compared to controls, NF-L and NF-M decreased,

Gene expression of 49 kDa apyrase,cytoskeletal proteins,ATPase,ADPase and amino acid contents of Pisum sativum(L.)cells germinated in Euryops arabicus(Steud.ex Jaub.&Spach)water extract

The present research reports of quick and marked changes induced by plant extract of Euryops arabicus in the gene expression of 49-kDa apyrases,cytoskeletal proteins,ATPases,ADPase and amount of amino acid of pea(Pisum sativum L.var.Alaska).Pellets of cytoskeletals proteins(27000 xg)were probed with anti-apyrase antibody,biotinylated anti-rat,actin and alpha and beta-tubulin for Western blotting.ATPase and ADPase activities were determined based on the hydrolytic efficacy of adenine triphosphate and adenine diphosphate.By 72 hours,the abundance of apyrases,cytoskeletal proteins and amount of amino acid in pellets of 27000 xg of germinated pea seeds in E.arabicus extracts were sharply increased than those sown in distilled water.All the samples exhibited that the stems had more amount from apyrases,cytoskeletal proteins,amino acids and ATPase and ADPase activities than primary leaves and primary roots that were germinated either on E.arabicus water extract or in distilled water.Based on the enzyme’s capability to hydrolyse nucleotide triphosphate and nucleotide diphosphate as well as the direct association between expression of 49-kDa apyrase and cytoskeletal proteins,E.arabicus water extract had an important effect on plant germinations.

Distinct Cytoskeletal Injuries Induced by As,Cd,Co,Cr,and Ni Compounds

The risks of metal compounds to human health are highlighted by the ubiquity of exposure and their persistence in the environment.Although compounds of As,Cd,Co,Cr,and Ni are known or“reasonably anticipated”to be carcinogenic to humans and/or experimental animals, the cellular targets of these health hazards and the underlying mechanisms of their carcinogenic- ity are still unclear.We show in this report that dramatic,time-and dose-dependent cytoskeletal perturbations,especially in the distribution and organization patterns of microtubules and mi- crofilaments,two of the principal components of the cytoskeleton,occurred in 3T3 cells upon exposure to these metal salts.Each metal salt appeared to induce a different,typical pattern of cytoskeletal injury,probably reflecting the specificity of action of each metal ion.These results suggest that the cytoskeleton can indeed act as a target for injury by epigenetic carcinogenic metal compounds in the environment.These findings should help our efforts to understand the mechanisms of action of metal compounds at the subcellular and molecular levels.1989 Academic Press,Inc.

Impact of chitosan-based nanocarriers on cytoskeleton dynamics:Current status and challenges

Chitosan-based nanocarriers(CS-NCs)show a promising role in improving drugs and bioactive compounds delivery for therapy.However,the effects exerted by CS-NCs at the cellular level,including their recognition and uptake,have not been fully investigated yet.Many factors,including size,shape,concentration,and surface chemistry of CS-NCs,play an important role in determining the types of intracellular signals triggered.The mechanism of uptake and the involvement of the cytoskeleton during the CS-NCs endocytosis variates among the different cell types as well as further effects observed inside cells.In the present work,we discuss the effects induced by CS-NCs per se on the cytoskeleton,a key component in cell architecture and physiology.The focus of this report is made on tumoral and normal biological models in which CS-NCs could differentially affect the cell cytoskeleton.The recent years reports regarding the impact of CS-NCs on cytoskeleton dynamics and the current techniques for its evaluation are summarized and discussed.Understanding mechanisms underlying cytoskeletal impact after cell exposure to CS-NCs is critical for the design of safest value-added formulations in the biomedical field.Furthermore,this revision points out some interesting aspects of cytoskeletal changes and cell death encompassing anti-tumoral effects.

Thermal Fluctuation Induced Piezoelectric Effect in Cytoskeletal Microtubules: Model for Energy Harvesting and Their Intracellular Communication

Cytoskeletal microtubules have long been conjectured to have piezoelectric properties. They have been shown to behave as nematic liquid crystals which oscillate along their director axis due to the prevalent thermal fluctuations. In this work, we develop a theoretical model of the mechanics of microtubules in the cytosolic space based on the buckling of its structure due to these thermal fluctuations. This cytosolic space has been considered as a viscoelastic medium in which microtubule oscillations have been considered. As a result of resilience of cytosol and neighbouring filaments from the axial force due to thermal fluctuations, the surface traction acting laterally on the microtubule structure has been further used to elucidate its piezoelectric behaviour in vivo. After the piezoelectric properties induced by thermal fluctuations (in addition to the buckling) of microtubules have been discussed, we propose a model discussing how microtubules behave as energy harvesters and communicate via electromagnetic radiation, with each other, in an intracellular environment.

IgA1 from HSP Patients Trigger Apoptosis and Inhibit Cytoskeletal Proteins in HUVEC

Background: Henoch-Schonlein purpura (HSP) is a kind of systemic small vessel vasculitis in children. Endothelium cells injury induced by IgA1 is considered important in the pathogenesis of HSP. Research found that the apoptosis of vein endothelial cells was related to the vasculitis in HSP patients. Purpose: To observe the effect of IgA1 from HSP patients on the apoptosis of HUVEC and firstly analyze the mechanism of the apoptosis of HUVEC induced by IgA1. Methods: HUVECs were cultured in 3 different conditional media with IgA1 from HSP patients, normal healthy children and simply medium (blank control). Serum IgA1 was purified by jacalin affinity chromatography. The rates of apoptosis in HUVEC incubated with IgA1 were determined by TUNEL method and flow cytometry, respectively. The expression of the cytoskeletal proteins, such as FAK, Vinculin and MLCK was detected with the methods of Real-time PCR and Westernblot, respectively. Results: The present study showed that the apoptosis rate of HUVEC by IgA1 isolated from HSP patients was higher than blank control (14.77% ± 2.23% vs 2.25% ± 0.77%) (P < 0.01) and the rate of HUVEC by IgA1 from normal healthy children was higher than blank control (9.97% ± 1.48% vs 2.25% ± 0.77%) (P < 0.01). The cytoskeletal proteins, such as FAK, Vinculin and MLCK expression were down-regulated in HUVEC co-cultured with IgA1 isolated from HSP patients for 24h. Conclusion: These findings firstly on IgA1 from HSP patients may induce apoptosis of vascular endothelial cells through inhibiting the cytoskeletal proteins expression. IgA1 may accelerate progression of HSP by inducing apoptosis of vascular endothelial cells.

Effect of focal adhesion kinase on cytoskeletal arrangement of HepG2 cells induced by hypoxia

对在 hypoxic HepG2 房间和 HepG2 房间的细胞骨架安排上的 FAK siRNA 的效果的焦点的粘附 kinase (FAK ) 表示由组织缺氧导致了的学习客观。方法 HepG2 房间在 21% O 2 和 1% O 2 是有教养的。词法变化在组织缺氧处理以后被观察。西方的污点被用来测量 FAK 表示。指向 FAK 和向量 pGensil-2 的 mRNA 的 siRNA 表示向量 pshRNA-FAK (作为控制) 被构造，然后 transfected 进 HepG2 房间。西方的污点被用来检测 FAK。有组织缺氧导致的 pshRNA-FAK 的 HepG2 房间 transfected 的细胞骨架安排被 phalloidin 分析。有组织缺氧导致的 pshRNA-FAK 的 HepG2 房间 transfected 的迁移的能力被房间迁居试金分析。结果对待组织缺氧的房间与房间分开的大度显示了更多的伸长的形状。FAK 表示在 hypoxic HepG2 房间增加了。FAK 蛋白质水平被 75.64% ±减少 3.12%(P 【 0.01 ) 在 pshRNA-FAK transfection 以后。组织缺氧导致了 HepG2 房间的细胞骨架安排。然而，有组织缺氧导致的 pshRNA-FAK 的 HepG2 房间 transfected 的细胞骨架安排在 1% O 2 被禁止。当房间移植试金出现了，有 pshRNA-FAK 的 HepG 房间 transfected 的移居的数字比控制的显著地低(P 【 0.05 ) 。在 hypoxic HCC 的 FAK 的表示可能有一种靠近的关系到 HepG2 房间的细胞骨架安排的结论由组织缺氧导致了。FAK 表示的起来规定可以是细胞骨架安排的机制和组织缺氧导致的 hepatocellular 癌的侵略之一。

Use of artificial neural networks to identify and analyze polymerized actin-based cytoskeletal structures in 3D confocal images

Background:Living cells need to undergo subtle shape adaptations in response to the topography of their substrates.These shape changes are mainly determined by reorganization of their internal cytoskeleton,with a major contribution from filamentous(F)actin.Bundles of F-actin play a major role in determining cell shape and their interaction with substrates,either as“stress fibers,”or as our newly discovered“Concave Actin Bundles”(CABs),which mainly occur while endothelial cells wrap micro-fibers in culture.Methods:To better understand the morphology and functions of these CABs,it is necessary to recognize and analyze as many of them as possible in complex cellular ensembles,which is a demanding and time-consuming task.In this study,we present a novel algorithm to automatically recognize CABs without further human intervention.We developed and employed a multilayer perceptron artificial neural network(“the recognizer”),which was trained to identify CABs.Results:The recognizer demonstrated high overall recognition rate and reliability in both randomized training,and in subsequent testing experiments.Conclusion:It would be an effective replacement for validation by visual detection which is both tedious and inherently prone to errors.

急性脑缺血/再灌注损伤后神经元细胞骨架蛋白的动态变化

目的探讨急性脑缺血/再灌注大鼠神经元细胞骨架蛋白时空动态变化。方法线栓法阻断大鼠大脑中动脉90 min后实现再灌注,在不同再灌注时间点观察及取材。尼氏染色观察神经细胞损伤,采用神经功能缺损评分和前肢放置实验评估神经功能;免疫组化染色、免疫印迹法观察细胞骨架成分微管相关蛋白2(microtubule associated protein 2,MAP2)、神经丝重链(neurofilament heavy chain,NF-H)的变化;透射电镜观察轴突、树突和神经丝亚显微结构。结果随着再灌注时间的延长,脑损伤和神经行为功能损害逐渐加重。纹状体损伤比皮层出现的更早、更严重。缺血区域的MAP2相关免疫反应强度降低,NF-H相关免疫反应强度升高。超微结构观察显示细胞骨架排列受损,密度降低。结论不同脑区对缺血/再灌注损伤的耐受性不同。神经元细胞骨架的主要成分对缺血和再灌注表现出动态反应,这可能进一步促进脑损伤和神经功能缺损。

Towards a better recording of microtubule cytoskeletal spatial organization and dynamics in plant cells

Numerous fluorescent marker lines are currently available to visualize microtubule(MT)architecture and dynamics in living plant cells, such as markers expressing p35S::GFP-MBD or p35S::GFP-TUB6.However, these MT marker lines display obvious defects that affect plant growth or produce unstable fluorescent signals. Here, a series of new marker lines were developed, including the pTUB6::VisGreen-TUB6-expressing line in which TUB6 is under the control of its endogenous regulatory elements and e GFP is replaced with VisGreen, a brighter fluorescent protein. Moreover, two different markers were combined into one expression vector and developed two dual-marker lines.These marker lines produce bright, stable fluorescent signals in various tissues, and greatly shorten the screening process for generating dual-marker lines.These new marker lines provide a novel resource for MT research.

The p21-activated kinases in neural cytoskeletal remodeling and related neurological disorders

The serine/threonine p21-activated kinases(PAKs),as main effectors of the Rho GTPases Cdc42 and Rac,represent a group of important molecular switches linking the complex cytoskeletal networks to broad neural activity.PAKs show wide expression in the brain,but they differ in specific cell types,brain regions,and developmental stages.PAKs play an essential and differential role in controlling neural cytoskeletal remodeling and are related to the development and fate of neurons as well as the structural and functional plasticity of dendritic spines.PAK-mediated actin signaling and interacting functional networks represent a common pathway frequently affected in multiple neurodevelopmental and neurodegenerative disorders.Considering specific small-molecule agonists and inhibitors for PAKs have been developed in cancer treatment,comprehensive knowledge about the role of PAKs in neural cytoskeletal remodeling will promote our understanding of the complex mechanisms underlying neurological diseases,which may also represent potential therapeutic targets of these diseases.

Reorganization of cytoskeletal proteins of mouse oocytes mediated by integrins

To study whether integrins on cell membrane ligate with intracellular cytoskeletal proteins and mediate their reorganization in egg activation, female mice were used for su- perovulation. The zona-free oocytes were incubated separately with specific ligand of integrins, an active RGD peptide, in vitro for certain period of time. RGE peptide and mouse capacitated sperm were used as controls. Freshly ovulated oocytes and those treated with different factors were immunostained with FITC-labeled anti-actin antibody, then detected with confocal micro- scope. The results demonstrated that freshly ovulated mouse oocytes, oocytes incubated for 2 h in vitro and those treated with control RGE peptide for 15 min showed hardly visible fluorescene or only thin fluorescence in plasma membrane region. Oocytes coincubated with sperms for 15 min and those treated with active RGD peptide for 10 min, 30 min and 2 hours respectively had strong and thick fluorescence in the plasma membrane and cortical region of oocytes, and some of them showed asymmetrically fluorescent distribution. It is proved that integrins on membrane are ligated directly with cytoskeletal protein. Integrins binding with their ligands regulate reor- ganization of cytoskelal protein, which may be involved in transmembrane signaling in egg acti- vation.

动态细胞骨架网络的自组织与力学性能

细胞骨架是由微管、肌动蛋白丝和中间纤维三种蛋白丝为主要成分组成的复合动态网络结构,在结合蛋白、辅助调节蛋白和马达蛋白的参与下帮助细胞实现运动、分裂和生长等基本生命过程。研究体外纯化的细胞骨架蛋白和马达蛋白网络,可以深入了解控制自组织亚细胞结构动力学行为的基本原理,为设计类似生命的活性物质和机器提供方向。本文综述了近年来基于纯化蛋白在体外简化环境中实现的细胞骨架蛋白-马达蛋白网络,重点介绍其非平衡本质、活性应力和动态网络的产生,以及这种动态网络对亚细胞结构和宏观尺度活性材料自组织过程的影响。此外,还简要介绍了细胞骨架蛋白-马达蛋白网络在构建体外仿生系统中的应用。

CXCL1通过促进蛋白激酶B磷酸化导致bEND.3小鼠脑微血管内皮细胞骨架收缩和通透性增加

目的探讨脓毒症脑病炎症中CXC趋化因子配体1(CXCL1)及其受体CXC趋化因子受体2(CXCR2)对脑内皮细胞骨架重排和通透性的影响及其相关机制。方法野生型小鼠腹腔注射脂多糖(LPS)(10 mg/kg)建立脓毒症脑病模型,ELISA检测全脑组织肿瘤坏死因子α(TNF-α)和CXCL1含量。使用500 ng/mL LPS和200 ng/mL TNF-α刺激bEND.3脑微血管内皮细胞后,Western blot法检测细胞CXCR2的表达。以150 ng/mL CXCL1刺激bEND.3细胞,免疫荧光染色观察脑内皮细胞骨架纤维型肌动蛋白(F-actin)重排的变化。脑内皮细胞通透性实验中,将bEND.3细胞随机分为PBS对照组、CXCL1组、CXCL1联合选择性CXCR2拮抗剂SB225002组,Transwell^(TM)小室检测各组通透性变化情况。CXCL1刺激bEND.3细胞后,Western blot法检测细胞中蛋白激酶B(AKT)和磷酸化AKT(p-AKT)蛋白表达。结果腹腔注射LPS导致小鼠全脑组织中TNF-α和CXCL1水平显著升高;LPS和TNF-α刺激可增高bEND.3细胞CXCR2蛋白的表达。CXCL1刺激bEND.3细胞使其细胞骨架收缩,细胞间隙形成增加,且细胞渗透性增加,而CXCR2拮抗剂SB225002预处理可显著抑制CXCL1引起的脑内皮细胞肌动蛋白应力纤维和细胞间隙的形成、以及通透性的增高,同时CXCL1(150 ng/mL)刺激使得脑内皮细胞AKT的磷酸化水平明显升高。结论CXCL1通过AKT磷酸化激活引起脑内皮细胞骨架收缩、细胞通透性增加,CXCR2拮抗剂SB225002可有效抑制CXCL1诱导的细胞骨架收缩和通透性升高。

喉癌治疗后复发的影响因素分析及预测模型构建

目的分析喉癌(LC)治疗后复发的影响因素,并构建LC治疗后复发的预测模型。方法接受手术切除、放化疗或靶向治疗等治疗方案的LC患者80例,按照随访期内复发情况分为复发组17例、未复发组63例。收集患者的年龄、性别、体质量指数(BMI)、吸烟史、饮酒史、LC家族史、基础疾病、肿瘤分期、肿瘤位置、肿瘤病理分型、肿瘤直径、肿瘤浸润深度、治疗方案等基本资料,采用qRT-PCR法检测血清细胞骨架蛋白4(CKAP4)、N-乙酰氨基半乳糖转移酶2(pp-GalNAc-T2)、跨膜蛋白2(TMEM2)mRNA。采用COX回归分析法分析LC患者治疗后复发的影响因素,采用Logistic回归分析法构建LC治疗后复发的预测模型,采用受试者工作特征曲线(ROC)评估预测模型对LC治疗后复发的预测价值。结果复发组患者肿瘤分期Ⅲ~Ⅳ期占比、血清CKAP4 mRNA相对表达量、血清pp-GalNAc-T2 mRNA相对表达量、血清TMEM2 mRNA相对表达量均显著高于未复发组(P均<0.05)。血清CKAP4 mRNA相对表达量、血清pp-GalNAc-T2 mRNA相对表达量、血清TMEM2 mRNA相对表达量是LC患者治疗后复发的影响因素(P均<0.05)。构建了LC治疗后复发的预测模型,预测概率=-8.967+0.724×血清CKAP4 mRNA相对表达量+0.081×血清pp-GalNAc-T2 mRNA相对表达量+1.132×血清TMEM2 mRNA相对表达量。预测模型的ROC结果显示,该模型对于LC治疗后复发具有较好的预测价值(AUC=0.872,95%CI=0.779~0.962,Cut off值≥0.229,P<0.001),该模型预测LC治疗后复发的灵敏度为88.23%、特异度为79.36%、阴性预测值为96.13%、阳性预测值为53.57%。结论血清CKAP4mRNA相对表达量、血清pp-GalNAc-T2mRNA相对表达量、血清TMEM2 mRNA相对表达量是LC患者治疗后复发的影响因素,基于上述影响因素构建的预测模型对LC治疗后复发具有较高的预测价值。

双氢青蒿素对蓝氏贾第鞭毛虫滋养体蛋白质的损伤

目的探讨双氢青蒿素(dihydroartemisinin,DHA)对体外培养的蓝氏贾第鞭毛虫(Giardialamblia)滋养体蛋白质的损伤作用。方法用改良TYI-S-33培养基培养蓝氏贾第鞭毛虫滋养体;设立实验组(DHA组)和正常对照组(C组)。实验组用含双氢青蒿素的培养基(含LC50=200μg/mL的DHA)培养;对照组培养基不含药物。提取各组虫体总蛋白,经Brad-ford法进行蛋白质定量,样本经2D-电泳和硝酸银染色后,扫描检测凝胶电泳图蛋白点的数量和种类,获取蛋白质点匹配信息,挑选匹配性高的蛋白点,进行质谱(MALDI-TOF MS)分析。结果经双氢青蒿素作用后虫体总蛋白质含量(0.6993μg/mL)明显低于对照组(4.8241μg/mL),二者差异有显著性(P<0.001)。蛋白质二维电泳凝胶图分析结果显示,正常对照组(C组)蛋白点密集,约1253个点,布满整块凝胶,蛋白表达量高(蛋白点颜色深且清晰、明亮);与此相反,实验组(DHA组)蛋白点显著减少,DHA作用6h后约617个点,作用12h后约326个点,蛋白表达量明显降低(蛋白点颜色浅,不清晰)。其次,正常对照组与双氢青蒿素组的12kDa^30kDa、等电点pI3.0~7.6范围内蛋白点表达量存在明显差异,即实验组该范围内大多数蛋白点完全消失,45kD^60kDa的蛋白点仅剩6个点。质谱分析鉴定结果显示,在正常对照组胶图所选的80个匹配良好的蛋白点中,鉴定出6种骨架蛋白(14个点),而实验组(DHA组)蛋白胶图中相对应的蛋白点消失。结论双氢青蒿素对蓝氏贾第鞭毛虫滋养体的蛋白质具有明显的损伤作用,其中包括细胞骨架蛋白。

三邻甲苯基磷酸酯对鸡大脑组织细胞骨架蛋白含量的影响

目的 探讨三邻甲苯基磷酸酯(TOCP)中毒引起迟发性神经毒性的机制。方法 用Western印迹方法测定了TOCP中毒后鸡大脑组织中高分子量神经丝蛋白(NF H)、中分子量神经丝蛋白(NF M)、低分子量神经丝蛋白(NF L)、α微管蛋白、β微管蛋白及β微丝蛋白6种细胞骨架蛋白的相对含量。结果鸡大脑组织沉淀中,NF H在TOCP 3 75和75 0mg·kg- 1 组分别降低2 3 %和4 7%(P <0 .0 1 ) ;而在上清中,分别升高3 1 %(P <0 .0 5 )和2 1 5 %(P <0 .0 1 )。NF M在沉淀中75 0mg·kg- 1 组降低4 7%(P <0 .0 1 ) ;而在上清中分别升高2 4 8%和2 3 3 %(P <0 .0 1 )。NF L在沉淀中75 0mg·kg- 1 组升高1 7%(P <0 .0 5 ) ;在上清中也分别升高2 2 0 %和1 97%(P <0 .0 1 )。α微管蛋白、β微管蛋白和β微丝蛋白在上清和沉淀中相对含量均无明显改变(P >0 .0 5 )。结论 大脑组织中神经丝含量改变较微管和微丝蛋白明显。

冬凌草甲素对胰腺癌细胞骨架蛋白F-actin的影响

背景与目的:中医药治疗肿瘤不良反应低且疗效显著,在防治胰腺癌方面有较大的潜力与优势,日益受到国内、外医学界的关注。本研究观察中草药冬凌草的有效成分冬凌草甲素对人胰腺癌SW1990凋亡及细胞骨架蛋白F-actin的影响。方法:以不同浓度的冬凌草甲素作用于体外培养的SW1990细胞,采用MTT法检测细胞生长抑制率,DAPI染色法染色后荧光显微镜观察细胞核凋亡、流式细胞仪检测细胞凋亡率,激光共聚焦显微镜观察F-actin形态学变化。结果:冬凌草甲素对人胰腺癌SW1990细胞具有明显的增殖抑制作用,荧光显微镜见到典型的凋亡形态学改变。流式细胞仪检测结果显示,25、50μmol/L冬凌草甲素给药组早期凋亡的百分率显著高于对照组(3.78±0.46,9.51±0.63 vs 0.73±0.06,P<0.05),晚期凋亡和坏死细胞的百分率也显著高于未给药组(14.40±1.78,20.53±2.54 vs 4.16±0.31,P<0.05)。细胞骨架蛋白F-actin呈现解聚状态。结论:冬凌草甲素可抑制胰腺癌SW1990细胞增殖,促进肿瘤细胞凋亡,其作用机制可能是药物引起了细胞骨架蛋白F-actin解聚。