An Assessment of InP/ZnS as Potential Anti-Cancer Therapy: Quantum Dot Treatment Increases Apoptosis in HeLa Cells

V. Davenport, Cullen Horstmann, Rishi B. Patel, Qi-Hui Wu, Kyoungtae Kim
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引用次数: 7

Abstract

InP/ZnS quantum dots (QDs) are an emerging option in QD technologies for uses of fluorescent imaging as well as targeted drug and anticancer therapies based on their customizable properties. In this study we explored effects of InP/ZnS when treated with HeLa cervical cancer cells. We employed XTT viability assays, reactive oxygen species (ROS) analysis, and apoptosis analysis to better understand cytotoxicity extents at different concentrations of InP/ZnS. In addition, we compared the transcriptome profile from the QD-treated HeLa cells with that of untreated HeLa cells to identify changes to the transcriptome in response to the QD. RT-qPCR assay was performed to confirm the findings of transcriptome analysis, and the QD mode of action was illustrated. Our study determined both IC50 concentration of 69 µg/mL and MIC concentration of 167 µg/mL of InP/ZnS. It was observed via XTT assay that cell viability was decreased significantly at the MIC. Production of superoxide, measured by ROS assay with flow cytometry, was decreased, whereas levels of nitrogen radicals increased. Using analysis of apoptosis, we found that induced cell death in the QD-treated samples was shown to be significantly increased when compared to untreated cells. We conclude InP/ZnS QD to decrease cell viability by inducing stress via ROS levels, apoptosis induction, and alteration of transcriptome.
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InP/ZnS作为潜在抗癌疗法的评估:量子点治疗增加HeLa细胞的凋亡
InP/ZnS量子点(QDs)是QD技术中的一种新兴选择,用于荧光成像以及基于其可定制特性的靶向药物和抗癌治疗。在本研究中,我们探讨了InP/ZnS在HeLa宫颈癌症细胞治疗中的作用。我们采用XTT活力分析、活性氧(ROS)分析和细胞凋亡分析来更好地了解不同浓度InP/ZnS的细胞毒性程度。此外,我们比较了QD处理的HeLa细胞和未处理的HeLa细胞的转录组谱,以确定转录组对QD的反应变化。进行RT-qPCR测定以证实转录组分析的结果,并说明了QD的作用模式。我们的研究确定了InP/ZnS的IC50浓度为69µg/mL,MIC浓度为167µg/mL。通过XTT测定观察到细胞活力在MIC下显著降低。通过流式细胞术ROS测定,超氧化物的产生减少,而氮自由基的水平增加。通过对细胞凋亡的分析,我们发现QD处理的样品中诱导的细胞死亡与未处理的细胞相比显著增加。我们得出结论,InP/ZnS QD通过ROS水平、细胞凋亡诱导和转录组的改变诱导应激,从而降低细胞活力。
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