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。     

基于Mn∶ZnS量子点-Cu~(2+)体系室温磷光猝灭-恢复方法测定水体中焦磷酸根离子

以谷胱甘肽(GSH)为稳定剂,成功合成了高性能的水溶性Mn∶ZnS量子点(Quantum dots,QDs).Mn∶ZnS QDs表面的羧基能与Cu~(2+)结合从而有效引发QDs电子转移,致使Mn∶ZnS QDs室温磷光显著猝灭.当体系中加入焦磷酸(PPi)时,由于Cu~(2+)与PPi的结合能力强于Mn∶ZnS QDs表面的羧基,Mn∶ZnS QDs磷光强度又逐渐恢复.据此建立一种基于Mn∶ZnS QDs-Cu~(2+)体系的室温磷光探针测定焦磷酸根离子的新方法.该方法灵敏、简单,线性范围为5.0×10~(-8)—1.0×10~(-4)mol·L~(-1),检测限为1.0×10~(-8)mol·L~(-1).经过干扰实验及添加回收率实验证实,该方法具有良好的选择性,满足于实际样品水体中焦磷酸的检测分析.     

基于Mn∶ZnS量子点荧光共振能量转移法测定水体中孔雀石绿

以L-半胱氨酸(L-Cys)为稳定剂水相直接合成了高荧光性能的Mn∶ZnS量子点(Quantum dots,QDs),以Mn∶ZnS QDs作为能量供体,孔雀石绿(Malachite green,MG)作为能量受体,通过它们间的静电作用,建立了荧光共振能量转移(Fluorescence resonance energy transfer,FRET)体系,从而实现了对孔雀石绿的定量检测,孔雀石绿在5.0×10-8—1.0×10-6mol·L-1浓度范围内与Mn∶ZnS QDs量子点荧光强度的对数值呈良好线性,检测限为1.0×10-8mol·L-1,经过干扰实验及添加回收率实验证实,该方法具有良好的选择性,满足实际样品水体中孔雀石绿的检测分析.     

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.     

量子点对Cu2+诱导L02细胞毒性的影响及机理研究

量子点(QDs)和Cu~(2+)可能共存于肝脏,对肝细胞产生联合毒性,威胁人体健康。本研究以人胚肝细胞(L02)为研究对象,考察了低/无毒的QDs(3.6%的细胞致死率)对Cu~(2+)诱导L02细胞毒性的影响及相关机理,为其可能的健康和环境风险提供参考。结果显示,QDs的加入使得Cu~(2+)的细胞毒性有了很大的提高,细胞存活率最高下降了26.0%,两者表现为协同作用;另外QDs存在使得Cu~(2+)细胞蓄积量增大,伴随着Cu~(2+)天然解毒蛋白CTR1和ATP7A等表达水平的升高,从侧面印证了Cu~(2+)的蓄积量增加对细胞的影响;同时,QDs的存在使得细胞乳酸脱氢酶(lactate dehyfrogenase,LDH)泄露相对于Cu~(2+)单独处理组提高,暗示QDs可能破坏了细胞膜,导致Cu~(2+)在细胞内蓄积量增加,从而使细胞毒性增加,两者的联合毒性表现为协同作用。     

碲化镉量子点细胞毒性研究进展

随着纳米技术和纳米医学的飞速发展,越来越多的纳米材料应用于生物医学领域。量子点(QDs)作为一种新型的荧光材料在工业和医学领域有着广阔的应用前景,而碲化镉量子点(cadmium telluride quantum dots,CdTeQDs)是目前常用的一种QDs,其生物安全性引起了极大的关注。体内外的研究表明CdTeQDs可以对生物体造成损害。CdTeQDs的细胞毒性主要表现为细胞活力和生存率降低,细胞正常形态被破坏,基因突变,染色体畸变以及细胞凋亡的出现。而毒性机制的研究集中于活性氧(ROS)水平的升高,线粒体形态和功能的破坏,DNA受损和自噬作用等方面。笔者综述了CdTeQDs对体外细胞造成的毒性作用及其机制,旨在为CdTeQDs的生物安全性研究和更好的应用提供有价值的参考。     

两种有机酸存在下铜对中华圆田螺肝脏的氧化应激效应

为探讨不同水平EDTA和柠檬酸(CA)作用下沉积物中铜对底栖无脊椎动物生态毒理学效应,以中华圆田螺为受试生物,研究了肝脏中活性氧(ROS)、丙二醛(MDA)含量、超氧化物歧化酶(SOD)以及过氧化氢酶(CAT)活性的变化规律。研究结果表明:有机酸存在下,铜污染底泥可诱导中华圆田螺肝脏产生ROS。电子顺磁共振(EPR)技术得出的3组双重峰分裂谱线为典型的α-苯基-N-叔丁基甲亚胺-N-氧化物(PBN)捕获羟自由基(·OH)形成PBN/·OH的EPR波谱。有机酸存在下,低剂量铜(≤100 mg·kg-1)对MDA产量影响不显著。较高剂量铜暴露下,EDTA的存在抑制MDA产生,CA的添加则均使MDA含量增加。EDTA存在下铜可显著抑制中华圆田螺肝脏中SOD和CAT活性。相对而言,CA的加入可减缓高剂量铜暴露下中华圆田螺肝脏SOD与CAT酶活性的剧烈变化。     

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.     

邻苯二甲酸二乙基己酯(DEHP)对THP-1细胞IL-1β和MMP-8表达及ROS的影响

为探讨邻苯二甲酸二乙基己酯((DEHP)的细胞免疫毒性作用与机制,采用RT-PCR和ELISA方法,考察了0.05～1μmol·L-1浓度范围内的DEHP对THP-1细胞白细胞介素-1β(IL-1β)及基质金属蛋白酶-8(MMP-8)基因和蛋白表达的影响;采用免疫印迹WesternBlot方法检测DE-HP对ERK1/2磷酸化水平的影响;以2,'7-'二氯荧光素二乙酸酯(DCFH-DA)为荧光探针检测1～50μmol·L-1DEHP对细胞内活性氧(ROS)产生的影响。结果显示,0.05和0.2μmol·L-1DEHP在6h内显著诱导IL-1β和MMP-8基因表达(P<0.05或0.01);0.05～1μmol·L-1DEHP刺激细胞48h,可诱导IL-1β蛋白表达,并表现出明显的剂量-效应关系,线性拟合的确定系数为0.937;0.05μmol·L-1DEHP刺激细胞6或12h,显著诱导MMP-8蛋白表达(P<0.05);0.2μmol·L-1DEHP在15～30min内快速诱导ERK1/2磷酸化;1～50μmol·L-1DEHP浓度依赖性刺激细胞中ROS的产生;ERK/MAPK抑制剂PD98059显著抑制DEHP诱导的MMP-8分泌,但对IL-1β分泌未表现出抑制作用。研究表明,DEHP可能是经ERK/MAPK信号路径诱导MMP-8基因和蛋白的表达,经其他路径诱导IL-1β基因和蛋白的表达,诱导细胞内ROS的产生,从而激发炎症反应,进而损害免疫系统功能引发哮喘等炎症性疾病。此研究结果可为DEHP的暴露风险评估提供参考。     

双酚A对小鼠肝脏和肾脏细胞的氧化损伤

为探究双酚A(BPA)的氧化毒性,分别以剂量为20、40和80mg·kg~(-1)·d~(-1)的BPA对雄性昆明小鼠灌胃处理1周,并测定了小鼠体内活性氧自由基(ROS)水平、还原型谷胱甘肽(GSH)含量、丙二醛(MDA)含量和DNA-蛋白质交联系数(DPC)。与对照组相比,各BPA暴露组小鼠肝脏和肾脏细胞中的ROS生成量、MDA含量和DPC系数均升高,而GSH含量下降(P<0.05或P<0.01)。ROS生成量、GSH含量和DPC系数均显示出剂量-效应关系。研究表明,BPA可扰乱小鼠肝脏和肾脏细胞的氧化应激平衡,诱导细胞氧化损伤。     

Solar-induced generation of singlet oxygen and hydroxyl radical in sewage wastewaters

Singlet oxygen (¹O₂) and hydroxyl radical (·OH) play an important role in the degradation of pollutants in surface waters. However, the mechanism underlying the photochemical generation of ¹O₂ and ·OH in wastewaters is poorly known. Here we studied the photo-induced generation of ¹O₂ and ·OH in different sewage treatment plant units. The correlation between the generation of ¹O₂ and ·OH and the water constituents was discussed. Our results show that in sewage units the ¹O₂ formation rate ranges from 2.19 × 10^?8 to 6.74 × 10^?8 mol L^?1 s^?1, and the ·OH formation rate ranges from 1.7 × 10^?11 to 3.06 × 10^?10 mol L^?1 s^?1. The average ¹O₂ formation rates in the various sewage units are similar to those in wetland and estuarine waters containing rich dissolved organic matter and 2–4 times higher than those in lake and seawater samples. The average ·OH formation rates of the sewage units are 5–50 times higher than for other water samples reported. The ·OH generation rate increased with the iron content with a correlation coefficient of 0.85, which indicates that the photo-Fenton reaction plays a dominant role in ·OH generation in sewage wastewater.     

Suppression of inhibition of substrate photodegradation by scavengers of hydroxyl radicals: the solvent-cage effect of bromide on nitrate photolysis

In this paper we show that bromide scavenges the ^·OH radicals formed upon photolysis of nitrate, before they leave the solvent cage. Bromide can thus inhibit the in-cage recombination between ^·OH and ^·NO₂. The consequence is an increased generation of ^·NO₂ and nitrite and of Br₂ ^?· + ^·OH, compared to ^·OH alone in the absence of bromide. We show that this effect compensates for the lower reactivity of Br ₂ ^?· compared to ^·OH toward certain organic substrates, e.g. phenol and tryptophan. Our findings could lead to a deep revision of the present views of the role of bromide in saltwater photochemistry.     

Effect of natural aquatic humic substances on the photodegradation of bisphenol A

The photochemical degradation of bisphenol A (BPA) was studied in the presence of natural humic substances from different origins under simulated solar irradiation. BPA underwent insignificant direct photolysis in neutral water, but rapid photosensitized degradation in four humic substances solutions via pseudo-first-order reaction occurred. The photo-degradation rate of BPA was insensitive to the different initial BPA concentrations and was inhibited in aerated solution compared with the deoxygenated medium. The reactive oxygen species (ROS) such as ·OH and ¹O₂ produced from excitation of humic substances under irradiation was determined from the quenching kinetic experiment using molecular probe. The five main intermediate photoproducts of BPA in Nordic lake fulvic acid (NOFA) were tentatively identified using gas chromatography/mass spectrometer (GC/MS). Based on the identification of ROS and the analysis of photoproduct formation, the possible phototransformation pathways of BPA were proposed, involving the direct photolysis due to the energy transfer from the triplet state humic substance (³HS*) to BPA molecules and hydroxyl radical addition and oxidation as well.     

Rice seedlings under cadmium stress: effect of silicon on growth,cadmium uptake,oxidative stress,antioxidant capacity and root and leaf structures

In this study, the effect of silicon (Si) addition on cadmium (Cd) toxicity in rice seedlings was investigated. After a series of screening experiments, 50 μmol·L^?1 of Cd and 10 μ mol·L^?1 of Si were selected. Treatment of rice seedlings with Cd (50 μ mol·L^?1) resulted in significant accumulation of this metal in roots and shoots. The data revealed that accumulation of Cd resulted in oxidative stress in rice seedlings as evidenced by increased accumulation of hydrogen peroxide (H₂O₂) and malondialdehyde (MDA; a peroxidation product of lipids). However, addition of Si (10 μ mol·L^?1) together with Cd prevented accumulation of Cd, H₂O₂ and MDA. Antioxidant capacity was decreased by Cd but enhanced by Si addition. Cd decreased the length and frequency of root hairs, stomatal frequency, and distorted leaf mesophyll cells and vascular bundles. However, addition of Si together with Cd reduced these abnormalities. The results showed that addition of exogenous Si protected rice seedlings against Cd toxicity by preventing Cd accumulation and oxidative stress (H₂O₂ and MDA accumulation) by increasing Si accumulation and antioxidant capacity, which maintained the structure and integrity of leaf and root.     

Inhibitory effect of the iron chelator desferrioxamine (Desferal) on the generation of activated oxygen species by Chattonella marina

Recent studies demonstrated that the toxic red tide phytoplankton Chattonella spp. produce activated oxygen species such as superoxide anion (O ₂ ^- ), hydrogen peroxide (H₂O₂), and hydroxyl radicals (·OH), which may be responsible for the toxicity of this flagellate. However, the mechanism behind the production of these oxygen radicals and H₂O₂ by Chattonella spp. is largely unknown, and the physiological significance of activated oxygen species for Chattonella spp. is also unclear. In the present study, we investigated the involvement of iron in the generation of O ₂ ^- and H₂O₂ by C. marina. The generation of O ₂ ^- by C. marina was related to the growth phase; the highest rate of O ₂ ^- production was observed during the exponential growth phase. However, no such increase during the exponential growth phase was observed in C. marina growing in an iron-deficient medium, even though the growth of C. marina was not significantly affected by iron-deficiency during the first 4 d. In addition, the iron chelator desferrioxamine (Desferal) strongly inhibited the generation of both O ₂ ^- and H₂O₂ by C. marina in a concentration-dependent manner. The growth of C. marina was also inhibited by Desferal. Furthermore, in the presence of 500 M Desferal, C. marina-induced growth inhibition of the marine bacteria Vibrio alginolyticus was almost completely abolished. These results suggest that iron is required for the generation of activated oxygen species by C. marina, as well as for its own growth.     

Quantification of singlet oxygen and hydroxyl radicals upon UV irradiation of surface water

We measured the formation rate and the steady-state concentration of hydroxyl radicals and of singlet oxygen upon irradiation of lake water. There is controversy about the importance of singlet oxygen in the environmental photochemistry, but here we show that the steady-state concentration of ¹O₂ under irradiation can be higher by about two orders of magnitude compared to the hydroxyl radical. The higher occurrence of singlet oxygen in surface waters is mainly due to a higher rate of formation, because the transformation rate constants of ¹O₂ (collision with the solvent) and of ^·OH (reaction with dissolved compounds) are comparable.     

臭氧污染胁迫下植物的抗氧化系统调节机制

工业和农业的快速发展导致近地层O3浓度不断提高,这对陆地生态系统的动物、植物、微生物和人类健康造成伤害。O3对植物的影响尤其是对农作物的影响将关系到世界粮食的安全生产。O3污染胁迫可诱导植物产生活性氧物质,破坏植物的膜系统,影响植物的光合作用等正常生理功能。植物在自然适应过程中,可形成一套抗氧化机制来缓解O3胁迫伤害。综述了国内外近年来有关O3胁迫下植物抗氧化系统调节机制的研究进展,包括植物通过调节体内的抗氧化酶活性和非酶类物质含量来缓解O3对植物伤害的机制。O3污染胁迫下植物可调节其叶片超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)、抗坏血酸过氧化物酶(APX)、脱氢抗坏血酸还原酶(DHAR)和单脱氢抗坏血酸还原酶(MDAR)等抗氧化酶的活性。抗坏血酸(AsA)、类胡萝卜素(Car)和谷胱甘肽(GSH)等非酶类物质在清除O3胁迫产生活性氧方面具有重要的作用。另外,根据目前的研究进展,提出了一些需要继续深入探讨的问题。