ZnO纳米粒子通过线粒体通路抑制小鼠光感受器细胞Na~+/K~+-ATP酶表达和活性的作用研究

氧化锌(ZnO)纳米粒子已被发现具有生物毒性,氧化应激被认为是最重要的因素之一。前期实验证实,ZnO纳米粒子能显著减少锰超氧化物歧化酶(Mn SOD)蛋白的表达,降低Mn SOD活性。本文通过检测乳酸脱氢酶(LDH)释放、线粒体活性氧(ROS)水平和膜电位(Δφm)、延迟整流钾电流变化和Na~+/K~+-ATP酶的表达及活性等变化,检测ZnO纳米粒子对小鼠光感受器细胞的细胞毒作用。结果表明,ZnO纳米粒子可显著增强小鼠光感受器细胞中LDH的释放、增加线粒体内ROS水平并下调Δφm、阻断延迟整流钾电流,同时降低Na~+/K~+-ATP酶的表达及活性,从而对小鼠视网膜光感受器细胞产生细胞毒作用,提示ZnO纳米粒子可通过线粒体通路引起氧化应激,从而抑制小鼠光感受器细胞Na~+/K~+-ATP酶表达和活性,产生细胞毒性,导致细胞死亡。本文的研究结果有助于理解ZnO纳米粒子引起细胞毒性的作用机理。     

ROS介导的氧化应激在INH诱导的细胞毒性中的作用及槲皮素的干预

为探讨ROS介导的氧化应激在异烟肼(INH)诱导L-02细胞毒性中的作用及槲皮素的干预作用,建立体外培养INH诱导L-02细胞氧化损伤模型,实验分为对照组(A)、INH组(B)、槲皮素低剂量组(C)及槲皮素高剂量组(D)。采用生化分析法检测L-02细胞培养液中天冬氨酸氨基转移酶(AST)和丙氨酸氨基转移酶(ALT)的活性;利用荧光探针检测L-02细胞线粒体内活性氧(ROS)水平;应用比色法检测L-02细胞内丙二醛(MDA)、谷胱甘肽(GSH)的含量以及主要抗氧化物酶的活性。结果表明,与对照组相比,INH能显著增加L-02细胞培养液中AST和ALT的活性、细胞线粒体内ROS水平及细胞内MDA的含量(P0.01),并显著减少L-02细胞内GSH的含量及超氧化物歧化酶(SOD)、谷胱甘肽过氧化物酶(GSH-Px)的活性(P0.01)。与INH组比较,槲皮素低剂量组L-02细胞培养液中AST的活性、线粒体内ROS水平及细胞内MDA的含量明显降低(P0.05),而细胞内SOD的活性明显增加(P0.05);高剂量槲皮素能显著降低L-02细胞培养液中AST和ALT的活性、细胞线粒体内ROS水平及细胞内MDA的含量(P0.01),并能显著增高L-02细胞内GSH的含量和主要抗氧化物酶的活性(P0.01)。与槲皮素低剂量组相比,槲皮素高剂量组的保护效应更明显(P0.05)。可见,ROS介导的氧化应激在INH诱导的L-02细胞毒性中发挥了重要作用,且槲皮素对INH诱导的L-02细胞氧化损伤具有保护作用。     

纳米氧化锌对美国红鱼肝细胞的毒性效应及机制

纳米氧化锌(ZnO NPs)的广泛应用所引发的环境与健康风险备受关注。为探究ZnO NPs对水生生物的毒性影响,以美国红鱼的原代肝细胞为实验对象,通过MTT法和中性红摄取(NRU)法检测细胞存活率,以评估ZnO NPs的细胞毒性;美国红鱼肝细胞经ZnO NPs处理6 h后,检测肝细胞内丙二醛(MDA)含量,并用流式细胞仪检测细胞对ZnO NPs的吞噬、胞内活性氧(ROS)的释放以及细胞凋亡率的变化。结果表明,美国红鱼肝细胞暴露于37.5μg·mL~(-1)和50μg·mL~(-1)ZnO NPs 6h后,细胞存活率较对照组显著降低,且ZnO NPs的毒性具有浓度和时间依赖性。研究表明,ZnO NPs进入细胞后,细胞内ROS产量增加,引起氧化应激,诱导细胞凋亡。     

碲化镉量子点(CdTe QDs)对肝细胞的毒性效应及线粒体介导的毒性机制研究

本文探讨了碲化镉量子点(CdTe QDs)对肝细胞的毒性效应及其影响因素,为探索量子点的肝毒性机制提供一定依据。采用人肝癌细胞(Hep G2)和人正常肝细胞(L02)为细胞模型,设置0、25、50和100μmol·L-14个浓度组,采用CCK-8法检测细胞生存率,石墨炉法检测细胞内镉元素含量,采用流式细胞术,装载荧光探针DCFH-DA检测细胞内活性氧水平,采用FITC/PI检测细胞凋亡以及JC-1检测细胞ATP水平。研究结果显示:CdTe QDs诱导2种肝细胞生存率降低,细胞凋亡率升高,细胞对QDs的摄入水平具有时间依赖性,细胞内活性氧水平显著升高,线粒体膜电位降低和ATP含量显著减少,且2种肝细胞比较发现L02细胞损伤程度更为严重。CdTe QDs对2种肝细胞造成损伤,对L02细胞损伤更明显,其原因是L02细胞对CdTe QDs摄取更多,导致进入细胞的QDs引发更为严重的损伤效应。     

三氯乙烯和四氯乙烯的细胞毒性及氧化应激机制研究

采用离体细胞测试技术,研究三氯乙烯(TCE)、四氯乙烯(PCE)对中国仓鼠卵巢细胞(CHO)的细胞毒性作用。3-(4,5-二甲基噻唑-2)-2,5-二苯基四氮唑溴盐(MTT)试验结果显示三氯乙烯、四氯乙烯对CHO细胞的半数生长抑制浓度(IC_(50))分别为590 mg·L~(-1)、281 mg·L~(-1)。三氯乙烯、四氯乙烯暴露可导致CHO细胞膜损伤,并且诱导细胞活性氧的产生。经不同浓度的三氯乙烯、四氯乙烯作用24 h后,细胞内超氧化物歧化酶(SOD)活性受到抑制;染毒浓度较低时细胞过氧化氢酶(CAT)活性呈激活势,染毒浓度过高CAT酶活性受到抑制。研究表明在体外培养条件下,氯乙烯类污染物诱导氧化应激可能是其产生细胞毒性的作用机制之一。     

纳米ZnO对鲫鱼肝脏的毒性

鲫鱼(Carassius auratus)腹腔注射不同浓度纳米ZnO(5mg·kg-1、12.5mg·kg-1、25mg·kg-1、50mg·kg-1和125mg·kg-1,以鲫鱼体重计)14d后,研究了鲫鱼肝脏中的自由基(ROS)强度变化、氧化应激反应及其毒性机制.结果表明:纳米ZnO显著诱导鲫鱼肝脏自由基产生;自由基信号强度和脂质过氧化物(MDA)随纳米ZnO浓度的升高呈先升高后降低趋势;而还原型谷胱甘肽(GSH)含量和GSH/GSSG随纳米ZnO浓度的升高呈先降低后升高趋势;纳米ZnO的毒性主要表现在引起鲫鱼肝脏氧化损伤,其毒性机制为诱导鲫鱼肝脏产生活性氧自由基.     

腐殖酸(HA)作用下纳米氧化锌对鲫鱼的毒性效应

通过静态模拟实验,研究不同浓度(0、1、1.5、2.5 mg L-1)腐殖酸(Humic acid,HA)对纳米ZnO(5 mg L–1)毒性效应的影响.将鲫鱼暴露于HA与纳米ZnO混合体系中7 d后,分析Zn在鲫鱼体内的富集分布,及对鲫鱼脑部和肝脏自由基含量、抗氧化系统等的影响.结果显示:随HA浓度的增加,鲫鱼鳃部和肌肉中Zn的含量增高,眼、脑和肝部Zn含量则随之下降.纳米ZnO诱导鲫鱼肝脏和脑产生羟基自由基,HA浓度增大诱导鲫鱼肝脏和脑中SOD活性升高,MDA、GSH含量增加.纳米ZnO胁迫导致鲫鱼肝脏和脑氧化损伤,HA的浓度增加会促进纳米ZnO对鲫鱼肝脏和脑部的氧化损伤.研究表明HA改变了纳米ZnO在环境中的生物效应,因此在关注纳米材料的水生态安全时,不能忽视环境因子的影响.     

苯并[a]芘和1-羟基芘诱导人胚胎干细胞分化心肌细胞ROS、CYP基因表达和DNA损伤

多环芳烃(PAHs)化合物中的苯并[a]芘和PAHs暴露检测标志物1-羟基芘与心脏功能障碍有关,但其生物学机制尚不清楚。为研究苯并[a]芘和1-羟基芘对心脏的毒性作用,基于人胚胎干细胞分化心肌细胞(hESC-CM)研究了苯并[a]芘和1-羟基芘对心肌细胞活性氧(ROS)生成、CYP基因表达和DNA损伤等的影响。结果表明,苯并[a]芘和1-羟基芘对h ESC-CM活性无影响,但能显著增强细胞ROS水平,诱导DNA损伤。此外,苯并[a]芘还能诱导细胞线粒体促凋亡基因的表达。研究表明,苯并[a]芘和1-羟基芘能通过诱导氧化应激和DNA损伤事件导致h ESC-CM损伤,在一定程度上解释了多环芳烃暴露导致心脏疾病的分子机制。     

纳米氧化锌对羊角月牙藻毒性效应及其在藻细胞内外的分布

为研究纳米氧化锌(ZnO NP)的毒性效应及其在细胞内外分布,以羊角月牙藻(Selenastrum capricornutum)为模型藻类,研究了不同浓度ZnO NP对羊角月牙藻生长、叶绿素含量、可溶性蛋白含量、超氧化物岐化酶(SOD)及过氧化物酶(POD)活性、丙二醛(MDA)含量及细胞内外ZnO NP含量变化。结果表明,ZnO NP对羊角月牙藻的生长抑制与处理浓度呈现正相关。在45 mg·L~(-1)ZnO NP暴露24 h后,其生长抑制率已达到95%。当ZnO NP处理藻细胞72 h后,羊角月牙藻细胞的叶绿素含量与处理浓度之间存在剂量-效应关系。低浓度(0.5 mg·L~(-1))ZnO NP处理后藻细胞可溶性蛋白质含量、SOD和POD活性明显下降,MDA含量升高,其产生的毒性效应高于高浓度组(5 mg·L~(-1)、45 mg·L~(-1))。细胞培养液溶出Zn2+量及藻细胞外吸附的ZnO NP量与ZnO NP处理浓度成正比,但是藻细胞内ZnO NP量与ZnO NP浓度没有相关性,胞内积累量基本维持不变。研究表明,各浓度组对藻细胞毒性的差异,不仅与细胞内Zn2+量有关,还与细胞外粘附的ZnO NP有关。     

纳米ZnO对鲫鱼肝脏的毒性(Toxicity of Nano-ZnO on Liver of Goldfish（Carassius auratus） )

鲫鱼（Carassius auratus）腹腔注射不同浓度纳米ZnO（5mg·kg-1、12.5mg·kg-1、25mg·kg-1、50mg·kg-1和125mg·kg-1,以鲫鱼体重计）14d后,研究了鲫鱼肝脏中的自由基（ROS）强度变化、氧化应激反应及其毒性机制. 结果表明：纳米ZnO显著诱导鲫鱼肝脏自由基产生;自由基信号强度和脂质过氧化物（MDA）随纳米ZnO浓度的升高呈先升高后降低趋势;而还原型谷胱甘肽（GSH）含量和GSH/GSSG随纳米ZnO浓度的升高呈先降低后升高趋势;纳米ZnO的毒性主要表现在引起鲫鱼肝脏氧化损伤,其毒性机制为诱导鲫鱼肝脏产生活性氧自由基.     

Indium tin oxide nanoparticles-mediated DNA fragmentation and cell death by apoptosis in human lung epithelial cells

Indium tin oxide (ITO) nanoparticles (NP) have extensive applications in industrial fields, and concerns regarding their potential toxicity in humans and environmental impact have increased. Since exposure to ITO NP is mainly via skin and inhalation, this study was conducted utilizing human lung epithelial (A549) cell line. Cells were exposed to different concentrations of the ITO NP for 24 and 48 hr. A severe cytotoxic response of ITO NP was observed as evident by the (3-4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide and neutral red uptake assays after 48 hr exposure. ITO NP significantly reduced glutathione levels with a concomitant increase in lipid hydroperoxide levels, superoxide activity, and reactive oxygen species (ROS) generation after exposure. A significant induction in caspase activity and formation of condensed chromosomal bodies was also observed after ITO NP (10 or 25 µg/ml) exposure. Furthermore, a significant induction in DNA damage was observed by the Comet assay in cells exposed to ITO NP. Our data demonstrate that ITO NP display cytotoxic and genotoxic potential. However, increase in ROS levels and oxidative stress leading to oxidative DNA damage and condensed chromosomal bodies formation, suggests involvement of apotosis. Thus, ITO NP-mediated effects on cell viability indicate cytotoxicity, and therefore, exposures need to be carefully monitored in the industrial sector.     

Single walled carbon nanotubes induce cytotoxicity and oxidative stress in HEK293 cells

The aim of the present study was to evaluate the potential toxicity and general mechanisms involved in single walled carbon nanotubes (SWCNTs)-induced cytotoxicity using human embryonic kidney cell line (HEK293) cells. Carbon nanotubes (coded as CNT) used in this study were synthesized by the chemical vapor deposition method. To elucidate the possible mechanisms underlying SWCNT-induced cytotoxicity, cell viability, cell membrane damage (lactate dehydrogenase activity (LDH) assay), reduced glutathione (GSH), interleukin-8 (IL-8) and lipid peroxidation products levels were quantitatively assessed following SWCNT exposure for 48 hr using HEK293 cells. Exposure of cells to SWCNT at 3–300 μg/ml produced significant reduction in cell viability in a concentration-dependent manner. The IC₅₀ value of SWCNT was found to be 87.58 μg/ml. Exposure of HEK cells to SWCNT at 10–100 μg/ml resulted in concentration-dependent cell membrane damage, increased production of IL-8, elevated levels of thiobarbituric acid reactive substances like malondialdehyde and decreased intracellular GSH levels. In summary, exposure to SWCNT resulted in a concentration-dependent cytotoxicity in cultured HEK293 cells that was associated with increased oxidative stress.     

纳米硫化镉量子点细胞毒性作用机制

为初步探讨硫化镉量子点(CdS QDs)的细胞毒性作用机制,采用MTT毒性实验比较了CdS QDs和常规CdS对仓鼠肺细胞(CHL)的毒性效应以及细胞内外活性氧水平.结果表明,1)在较低暴露浓度(≤20μg·mL-1)时,CdS QDs细胞毒性显著高于常规CdS,而在较高暴露浓度(>20μg·mL-1)时,两者相差不大.2)在较低暴露浓度(≤40μg·mL-1)时,添加N-乙酰半胱氨酸(NAC)可显著降低CdS QDs的细胞毒性,而在较高暴露浓度(>40μg·mL-1)时,添加NAC对CdS QDs的细胞毒性没有明显影响.添加NAC对常规CdS细胞毒性没有显著影响.综合实验结果推测CdS QDs的细胞毒性与暴露剂量有关:在低浓度(<20μg·mL-1)时,主要是活性氧的氧化损伤作用;在中等浓度(20~40μg·mL-1)时,活性氧和Cd2+的释放共同作用;在高浓度(>40μg·mL-1)时,则是Cd2+的释放占主导地位.     

Assessing combined toxic effects of tetracycline and P25 titanium dioxide nanoparticles using Allium cepa bioassay

• UVA pre-irradiation to TiO₂ NPs enhanced its toxicity toward plant A. cepa. • UVA TiO₂ NPs increased intracellular ROS, resulting in more cell damage. • Cell death enhanced cell permeability and increased uptake of NPs. • Being highly toxic (EC₅₀ = 0.097 µmol/L), TC did not increase ROS generation. • Even at a low dose, TC enhanced the toxic potential of TiO₂ NPs significantly. Usage of titanium dioxide nanoparticles (TiO₂ NPs) and tetracycline (TC) has increased significantly in the present era. This leads to their release and accumulation in the environment. Both the compounds, individually, can have adverse toxic effects on the plants. Their binary mixtures can increase this degree of damage. The present study aimed to evaluate the toxicity of both the contaminants in individual and binary mixtures in Allium cepa. Further, the toxicity of TiO₂ NPs upon UVA pre-irradiation was also measured. Results showed that UVA pre-irradiated NPs (UVA-TiO₂ NPs) had a significant decrease in cell viability than their non-irradiated counterparts (NI-TiO₂), denoting an increase in photocatalytic activity upon UVA pre-irradiation. Very low concentrations of TC (EC₁₀ = 0.016 µmol/L) mixed with TiO₂ NPs significantly increased the toxicity for both UVA-TiO₂ and NI-TiO₂ NPs. Intracellular ROS generation was significantly high for UVA-TiO₂ NPs. However, TC did not have any effects on ROS production. Both the compounds exhibited genotoxic potential in A. cepa. Different chromosomal abnormalities like anaphase bridges, telophase bridges, laggard chromosomes, binucleate cells, etc. were observed. The binary mixture of UVA-TiO₂ NPs and TC showed the highest chromosomal aberrations (64.0%±1.26%) than the mixture with NI-TiO₂ or the individual contaminants. This decreased significantly after recovery (46.8%±1.92%), denoting the self-repair processes. This study proved that UVA-TiO₂ NPs were more toxic and could be enhanced further when mixed with a sub-lethal concentration of TC. This work will help to assess the risk of both compounds in the environment.     

Biotoxicity evaluation of zinc oxide nanoparticles on bacterial performance of activated sludge at COD,nitrogen, and phosphorus reduction

• ZnO-NP disrupted metabolic/catabolic balance of bacteria by affecting DHA activity. • ZnO-NPs toxicity was related to Zn²⁺ ion, interaction with cell and ROS generation. • Exposure to ZnO-NPs resulted in changed bacterial community structure at sludge. • The change in the EPS content was observed during exposure to ZnO-NPs. The unique properties and growing usage of zinc oxide nanoparticles increase their release in municipal wastewater treatment plants. Therefore, these nanoparticles, by interacting with microorganisms, can fail the suitable functioning of biological systems in treatment plants. For this reason, research into the toxicity of ZnO is urgent. In the present study, the toxicity mechanism of ZnO-NPs towards microbial communities central to granular activated sludge (GAS) performance was assessed over 120-day exposure. The results demonstrate that the biotoxicity of ZnO-NPs is dependent upon its dosage, exposure time, and the extent of reactive oxygen species (ROS) production. Furthermore, GAS performance and the extracellular polymeric substances (EPS) content were significantly reduced at 50 mg/L ZnO-NPs. This exposure led to decreases in the activity of ammonia monooxygenase (25.2%) and nitrate reductase (11.9%) activity. The Field emission scanning electron microscopy images confirmed that ZnO-NPs were able to disrupt the cell membrane integrity and lead to cell/bacterial death via intracellular ROS generation which was confirmed by the Confocal Laser Scanning Microscopy analysis. After exposure to the NPs, the bacterial community composition shifted to one dominated by Gram-positive bacteria. The results of this study could help to develop environmental standards and regulations for NPs applications and emissions.     

氟虫双酰胺对蚯蚓的生化毒性与细胞毒性研究

双酰胺类杀虫剂已成为全世界第4大类最常用的杀虫剂,具有非常广阔的应用前景。然而,目前关于双酰胺类杀虫剂生态毒性评估方面的研究还比较少。为探究双酰胺类杀虫剂对非靶标生物的毒性作用,选取赤子爱胜蚓(Eisenia fetida)为受试生物,研究了典型双酰胺类杀虫剂氟虫双酰胺对非靶标动物蚯蚓的生化毒性和细胞毒性以及其在人工土和蚯蚓体内的浓度变化情况。结果表明,氟虫双酰胺在人工土壤中十分稳定,在整个暴露期间氟虫双酰胺的浓度变化不超过20%。氟虫双酰胺在蚯蚓体内的含量随染毒浓度的升高和暴露时间的推移而增加,呈明显的时间和剂量-效应关系;在染毒浓度为0.1和1.0 mg·kg-1的处理组中,氟虫双酰胺未对蚯蚓产生明显的氧化胁迫效应。在染毒浓度为5.0和10.0 mg·kg-1的处理组中,蚯蚓体内活性氧(ROS)含量显著高于其他处理组,过量的ROS诱导蚯蚓体内各种抗氧化酶活性发生异常变化,并在蚯蚓体内造成了脂质过氧化、蛋白质羰基化和DNA损伤。研究表明,当土壤中氟虫双酰胺的浓度为5.0和10.0 mg·kg-1时可能会对蚯蚓产生很高的风险。此外,彗星实验对氟虫双酰胺诱导的氧化胁迫较为敏感,可以作为敏感生物标志物对氟虫双酰胺造成的土壤污染进行预警。     

活性氧参与多壁碳纳米管诱导的RAW264.7细胞毒性

碳纳米管以其独特的结构和性能,在生物医药和电子等领域广泛应用,而其生态安全性也成为科学界关注的焦点。为探究多壁碳纳米管(MWCNTs)诱导的细胞毒性机制,将小鼠肺泡巨噬细胞(RAW264.7)暴露于6个浓度梯度(0、25、50、100、150和200μg.mL-1)的MWCNTs中,应用噻唑蓝(MTT)法测定细胞存活率,用2’,7’-二氯荧光素二乙酸(DCFH-DA)荧光染色法测定细胞内活性氧的生产量,用流式细胞方法测定MWCNTs对细胞周期的影响。同时使用抗氧化剂氮乙酰半胱氨酸(NAC)验证MWCNTs诱导的细胞氧化损伤的作用机理。结果显示,MWCNTs对RAW264.7的细胞毒性呈剂量依赖性。暴露于不同浓度的MWCNTs(25、50、100、150和200μg.mL-1)下24h后,细胞活力分别为对照的74%、62%、59%、51%和45%。MWCNTs对RAW264.7的周期阻滞作用主要发生在G0/G1期。200μg.mL-1的MWCNTs处理3h后活性氧较对照组上升6.6倍。NAC对MWCNTs细胞毒作用有明显的抑制作用,且NAC能减弱MWCNTs对RAW264.7的细胞周期阻滞作用。研究表明,活性氧能够介导MWCNTs对小鼠巨噬细胞RAW264.7的损伤,并且MWCNTS通过细胞周期G0/G1期的阻滞,诱导细胞凋亡。     

BDE-47对人胚肾细胞HEK293的毒理效应及作用机制

2,2’,4,4’-四溴联苯醚(BDE-47)是生物体中含量最高且毒性最强的PBDEs之一,有关BDE-47对肾细胞的毒性及其作用机制的研究仍有待补充。选取3个剂量组(低:10-6mol·L-1、中:10-5mol·L-1、高:10-4mol·L-1)及溶剂对照组,研究了BDE-47对人胚肾细胞(HEK293)的细胞凋亡率及活性氧(ROS)水平的影响;并从分子水平对细胞氧化损伤、凋亡相关蛋白(APE1及p53)及凋亡相关基因m RNA(p53、Bax、Caspase 3、Caspase 8)的表达量进行测定。实验结果显示:与对照组相比,中、高剂量组细胞凋亡率显著增加(P0.05);ROS水平在中剂量组显著上升(P0.01);随BDE-47浓度的变化,APE1蛋白表达量与细胞ROS水平存在一致性;p53、Bax、Caspase 8 m RNA表达量与BDE-47的浓度间存在剂量-效应关系。结果表明,BDE-47可诱导HEK293细胞凋亡及氧化应激,APE1可能是细胞ROS升高与细胞凋亡间重要的中介因子;BDE-47可以通过影响Caspase 8及线粒体途径中p53及Bax的表达诱导细胞凋亡。