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曲酸衍生物作为一种选择性杀死肿瘤细胞的抗有丝分裂剂。

Kojic Acid Derivative as an Antimitotic Agent That Selectively Kills Tumour Cells.

作者信息

Pichiri Giuseppina, Piludu Marco, Congiu Terenzio, Grandi Nicole, Coni Pierpaolo, Piras Monica, Jaremko Mariusz, Lachowicz Joanna Izabela

机构信息

Department of Medical Sciences and Public Health, University of Cagliari, Cittadella Universitaria, 09042 Monserrato, Italy.

Department of Biomedical Sciences, University of Cagliari, Cittadella Universitaria, 09042 Monserrato, Italy.

出版信息

Pharmaceuticals (Basel). 2024 Dec 25;18(1):11. doi: 10.3390/ph18010011.

DOI:10.3390/ph18010011
PMID:39861074
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11768441/
Abstract

The primary method used to pharmacologically arrest cancer development and its metastasis is to disrupt the cell division process. There are a few approaches that may be used to meet this objective, mainly through inhibiting DNA replication or mitosis. Despite intensive studies on new chemotherapeutics, the biggest problem remains the side effects associated with the inhibition of cell division in non-tumoural host cells. The efficacy and selectivity of the kojic acid derivative (L1) was studied in vitro with the use of tumoural (Caco2, SW480, HT29, T98G) and non- tumoural (HEK293T, RAW) cell lines. Light and electron microscopy observations were supported by the next generation sequencing (NGS), cytoflow, and spectroscopy analysis of mRNA and biomolecules, respectively. The light and electron microscopy observations showed that L1 treatment leads to significant morphological changes in Caco2 cells, which are characteristic of mitosis arrest. Moreover, the fluorescent tubulin staining revealed the formation of tubulin ring structure associated with the apoptotic stage. Mitotic exit into apoptosis was further conformed by the cytoflow of early/late apoptosis stages and caspase-3 analysis. NGS investigation showed differentiated expressions of genes involved in mitosis and apoptosis processes. The observed IC50 in tumoural cell lines were as follows: Caco2 (IC50 = 68.2 mM), SW480 (IC50 = 15.5 mM), and HT29 (IC50 = 4.7 mM). The findings presented here suggest that L1 could be a valid candidate for oral prevention and/or chemotherapy in colorectal cancer. Considering high selectivity of L1 versus tumoural cell lines, more in-depth mechanistic studies could reveal unknown stages in carcinogenesis.

摘要

药理学上阻止癌症发展及其转移的主要方法是破坏细胞分裂过程。有几种方法可用于实现这一目标,主要是通过抑制DNA复制或有丝分裂。尽管对新型化疗药物进行了深入研究,但最大的问题仍然是抑制非肿瘤宿主细胞中的细胞分裂所带来的副作用。利用肿瘤细胞系(Caco2、SW480、HT29、T98G)和非肿瘤细胞系(HEK293T、RAW)在体外研究了曲酸衍生物(L1)的疗效和选择性。光镜和电镜观察分别得到了下一代测序(NGS)、细胞流式分析以及mRNA和生物分子光谱分析的支持。光镜和电镜观察表明,L1处理导致Caco2细胞发生显著的形态变化,这是有丝分裂停滞的特征。此外,荧光微管蛋白染色显示了与凋亡阶段相关的微管蛋白环结构的形成。早期/晚期凋亡阶段的细胞流式分析和caspase-3分析进一步证实了有丝分裂向凋亡的转变。NGS研究显示了参与有丝分裂和凋亡过程的基因的差异表达。在肿瘤细胞系中观察到的IC50如下:Caco2(IC50 = 68.2 mM)、SW480(IC50 = 15.5 mM)和HT29(IC50 = 4.7 mM)。本文的研究结果表明,L1可能是结直肠癌口服预防和/或化疗的有效候选药物。考虑到L1对肿瘤细胞系的高选择性,更深入的机制研究可能会揭示致癌过程中未知的阶段。

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Study of the DNA binding mechanism and activity against cancer cells of iron(III) and aluminium(III) kojic acid derivative complexes.铁(III)和铝(III)曲酸衍生物配合物的DNA结合机制及其对癌细胞活性的研究。
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From Toxicity to Selectivity: Coculture of the Fluorescent Tumor and Non-Tumor Lung Cells and High-Throughput Screening of Anticancer Compounds.从毒性到选择性:荧光肿瘤与非肿瘤肺细胞的共培养及抗癌化合物的高通量筛选
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