Joshi Abhayraj S, Bapat Mugdha V, Singh Priyanka, Mijakovic Ivan
The Novo Nordisk Foundation Center for Biosustainability, Technical University of Denmark, Kongens Lyngby, Denmark.
Department of Biology and Biological Engineering, Division of Systems and Synthetic Biology, Chalmers University of Technology, Sweden.
Mater Today Bio. 2024 Feb 11;25:100997. doi: 10.1016/j.mtbio.2024.100997. eCollection 2024 Apr.
Lung cancer is one of the most commonly occurring cancer types that accounts for almost 2 million cases per year. Its resistance to anticancer drugs, failure of new molecules in clinical trials, severe side-effects of current treatments, and its recurrence limit the success of anticancer therapies. Nanotherapeutic agents offer several advantages over conventional anticancer therapies, including improved retention in tumors, specificity, and anticancer effects at lower concentrations, hence reducing the side-effects. Here, we have explored the anticancer activity of silver nanoparticles synthesized in sp. enriched culture medium for the first time. Such green nanoparticles, synthesized by biological systems, are superior to chemically synthesized ones in terms of their environmental footprint and production cost, and have one crucial advantage of excellent stability owing to their biological corona. To assess anticancer activity of these nanoparticles, we used conventional 2D cultured A549 cells as well as 3D spheroids of A549 cells. In both models of lung cancer, our silver nanoparticles diminished cell proliferation, arrested DNA synthesis, and showed a dose dependent cytotoxic effect. The nanoparticles damaged the DNA and mitochondrial structures in both A549 cells and A549 spheroids, leading to mitochondrial depolarization and increased cell permeability. Low lethal median doses (LD50) for 2D cultured A549 cells (1 μg/ml) and for A549 spheroids (13 μg/ml) suggest that our nanoparticles are potent anticancer agents. We also developed tumor progression model and tumor size model using 3D spheroids to test anticancer potential of our nanoparticles which otherwise would require longer experimental duration along with large number of animals and trained personnel. In these models, our nanoparticles showed strong dose dependent anticancer activity. In case of tumor progression model, the A549 cells failed to form tight spheroidal mass and showed increased dead cell fraction since day 1 as compared to control. On the other hand, in case of tumor size model, the 4 and 8 μg/ml nanoparticle treatment led to reduction in spheroid size from 615 ± 53 μm to 440 ± 45 μm and 612 ± 44 μm to 368 ± 62 μm respectively, within the time span of 3 days post treatment. We believe that use of such novel experimental models offers excellent and fast alternative to studies, and to the best of our knowledge, this is the first report that gives proof-of-concept for use of such novel cancer models to test anticancer agents such as culture derived silver nanoparticles. Based on our results, we propose that these nanoparticles offer an interesting alternative for anticancer therapies, especially if they can be combined with classical anticancer drugs.
肺癌是最常见的癌症类型之一,每年新增病例近200万。其对抗癌药物的耐药性、临床试验中新分子的失败、现有治疗方法的严重副作用以及复发情况,限制了抗癌治疗的成效。纳米治疗剂相较于传统抗癌疗法具有诸多优势,包括在肿瘤中的保留时间延长、特异性增强以及在较低浓度下即具有抗癌效果,从而减少副作用。在此,我们首次探索了在特定富集培养基中合成的银纳米颗粒的抗癌活性。这种由生物系统合成的绿色纳米颗粒,在环境影响和生产成本方面优于化学合成的纳米颗粒,并且由于其生物冠层而具有出色稳定性这一关键优势。为评估这些纳米颗粒的抗癌活性,我们使用了传统的二维培养A549细胞以及A549细胞的三维球体。在这两种肺癌模型中,我们的银纳米颗粒均能抑制细胞增殖、阻止DNA合成,并呈现出剂量依赖性细胞毒性作用。这些纳米颗粒破坏了A549细胞和A549球体中的DNA和线粒体结构,导致线粒体去极化并增加细胞通透性。二维培养A549细胞(1μg/ml)和A549球体(13μg/ml)的低半数致死剂量表明我们的纳米颗粒是有效的抗癌剂。我们还使用三维球体开发了肿瘤进展模型和肿瘤大小模型,以测试我们纳米颗粒的抗癌潜力,否则这将需要更长的实验时间以及大量动物和专业人员。在这些模型中,我们的纳米颗粒呈现出强烈的剂量依赖性抗癌活性。在肿瘤进展模型中,与对照组相比,A549细胞从第1天起就无法形成紧密的球体团块,且死细胞比例增加。另一方面,在肿瘤大小模型中,4μg/ml和8μg/ml的纳米颗粒处理分别在处理后3天内使球体大小从615±53μm减小至440±45μm以及从612±44μm减小至368±62μm。我们认为,使用这种新型实验模型为相关研究提供了出色且快速的替代方法,据我们所知,这是第一份为使用此类新型癌症模型测试抗癌剂(如特定培养来源的银纳米颗粒)提供概念验证的报告。基于我们的研究结果,我们提出这些纳米颗粒为抗癌治疗提供了一种有趣的替代方案,特别是如果它们能够与经典抗癌药物联合使用的话。
