Therapeutic influence of simvastatin on MCF-7 and MDA-MB-231 breast cancer cells via mitochondrial depletion and improvement in chemosensitivity of cytotoxic drugs

IF 2 Q3 ONCOLOGY
Versha Tripathi , Pooja Jaiswal , Ruchi Verma , Khageswar Sahu , Shovan Kumar Majumder , Sourabrata Chakraborty , Hem Chandra Jha , Hamendra Singh Parmar
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引用次数: 0

Abstract

Background

Breast cancer is the most commonly diagnosed cancer worldwide with 2.26 million cases in 2020. Cancer heterogeneity is the major challenge before existing therapeutic modalities due to metabolic variability of the cells as Warburg and anti-Warburg both type of metabolic phenotypes has been reported as a major contributing factors for cancer progression, invasion, metastasis and relapse. Also, this metabolic variability is associated with chemo and radio-resistance and poor therapeutic outcomes. Therefore, in present study we put an attempt to understand how simvastatin exert its effects on two metabolically different cell types and second how this drug can affect mitochondrial biomass, mt-DNA and glycolysis in both the cell types.

Methods

We have observed effects of simvastatin on MCF-7 (dependent more on OXPHOS) and MDA-MB-231 (TNBC; more glycolytic with defected mitochondria) cells alone and after simvastatin pre-treatment followed by cytotoxic drugs including cisplatin, doxorubicin, gemcitabine, vincristine. We have conducted MTT assay for viability, cell death detection assay, apoptotic morphology study, scratch assay, transwell migration assay, lactate estimation in media (glycolysis parameter), mt-DNA to n-DNA ratio, mitotracker red (for mitochondrial membrane potential) and mitotracker green staining (for mitochondrial biomass) and qPCR to study expression of mitochondrial transcription factors and apoptotic genes including PGC-1α, NRF-1, NRF-2, TFAM, Bcl-2 and Bax.

Results

We observed that 20 μM simvastatin (SIM) was most efficient dose for MCF-7, whereas 12.5 μM for MDA-MB-231 cells. Simvastatin itself caused a significant decrease in viability, increased cell death, and diminished wound closure in scratch assay as well as inhibited transwell migration. Also, the cells pre-treated with simvastatin for 72 h followed by treatment with cytotoxic drugs for 48 h increased chemo-sensitivity of cisplatin (CIS), doxorubicin (DOX), gemcitabine (GEM) and vincristine (VIN). SIM alone and in pre-treatment followed by cytotoxic drug treatment studies, there was a significant decrease in mitochondrial biomass and mitochondrial membrane potential (MMP), but also decreased glycolysis as evidenced by decrease in lactate levels in culture media. For inhibition of migratory potential, it was in the following order: CIS ˃ VIN ˃DOX˃ GEM, which was in the same order to diminish mitochondrial functionality (mt-DNA/n-DNA ratio, mitotracker green staining and a significant decrease in the expression of transcriptional factors of mitochondrial biogenesis). Contrastingly a decrease in the same order was observed in lactate concentration independent to the mitochondrial loss, but probably via inherent ability of the drugs to reduce lactate and glycolysis. However, for cell death, apoptotic phenotype, diminished expression of Bcl-2 along with increase in Bax and loss of viability, the efficiency of simvastatin alone and in pre-treatment studies was in the following order: VIN ˃ DOX˃GEM˃CIS, which was supported by loss of fluorescence of mitotracker red, suggested decrease in MMP; marker of cell death.

Conclusion

We conclude that by using different doses simvastatin can target different metabolic phenotypes of breast cancer cells and can also increase the chemo-sensitivity of cytotoxic drugs, so that they can work efficiently at lower doses which will ultimately diminish the cost and toxicity issues.

Abstract Image

辛伐他汀对MCF-7和MDA-MB-231乳腺癌细胞的治疗影响通过线粒体耗竭和改善细胞毒性药物的化疗敏感性
乳腺癌是世界上最常见的癌症,到2020年有226万例。由于细胞的代谢变异性,癌症异质性是现有治疗模式面临的主要挑战,因为Warburg和anti-Warburg两种类型的代谢表型已被报道为癌症进展、侵袭、转移和复发的主要因素。此外,这种代谢变异性与化疗和放射耐药以及不良的治疗结果有关。因此,在本研究中,我们试图了解辛伐他汀如何对两种代谢不同的细胞类型发挥作用,以及这种药物如何影响这两种细胞类型的线粒体生物量、mt-DNA和糖酵解。方法观察辛伐他汀对MCF-7(更多依赖于OXPHOS)和MDA-MB-231 (TNBC;单独和辛伐他汀预处理后,细胞毒性药物包括顺铂、阿霉素、吉西他滨、长春新碱后,线粒体缺陷细胞糖酵解更多。我们进行了MTT法测定细胞活力、细胞死亡检测、凋亡形态学研究、划痕试验、transwell迁移试验、培养基乳酸估计(糖酵解参数)、mt-DNA与n-DNA比值、丝裂跟踪器红色(用于线粒体膜电位)和丝裂跟踪器绿色染色(用于线粒体生物量)以及qPCR研究线粒体转录因子和凋亡基因的表达,包括PGC-1α、NRF-1、NRF-2、TFAM、Bcl-2和Bax。结果20 μM辛伐他汀(SIM)对MCF-7细胞有效,12.5 μM辛伐他汀对MDA-MB-231细胞有效。辛伐他汀本身在划痕试验中导致存活能力显著下降,细胞死亡增加,伤口愈合减少,并抑制跨井迁移。此外,用辛伐他汀预处理72小时后再用细胞毒性药物治疗48小时,细胞对顺铂(CIS)、阿霉素(DOX)、吉西他滨(GEM)和长春新碱(VIN)的化学敏感性增加。单独使用SIM以及在细胞毒性药物治疗后进行的预处理研究中,线粒体生物量和线粒体膜电位(MMP)显著降低,培养基中乳酸水平降低也证明了糖酵解减少。抑制迁徙的潜力,这是按照以下顺序:独联体˃VIN˃阿霉素˃宝石,在同一订单减少线粒体功能(线粒体基因/ n-DNA比率,mitotracker绿色染色和显著降低线粒体生物起源的转录因子的表达)。相比之下,乳酸浓度的下降顺序与线粒体损失无关,但可能是通过药物固有的减少乳酸和糖酵解的能力。然而,对于细胞死亡、凋亡表型、Bcl-2表达降低、Bax增加和活力丧失,辛伐他汀单独和预处理研究的效率依次为:VIN - DOX - GEM - CIS,有丝分裂跟踪器红色荧光丧失支持,提示MMP降低;细胞死亡的标志。结论不同剂量的辛伐他汀可以针对不同代谢表型的乳腺癌细胞,增加细胞毒性药物的化学敏感性,从而使其在低剂量下有效发挥作用,最终减少成本和毒性问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advances in cancer biology - metastasis
Advances in cancer biology - metastasis Cancer Research, Oncology
CiteScore
2.40
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