Jessica M M Valadares, Pedro Azalim-Neto, Xiaofan Liu, Nathallia Cavalcanti Carrozza, George A O'Doherty, Luis Eduardo M Quintas, Leandro A Barbosa
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引用次数: 0
Abstract
Cancer is a leading cause of death worldwide and its treatment is hampered by the lack of specificity and side effects of current drugs. Cardiotonic steroids (CTS) interact with Na+/K+-ATPase (NKA) and induce antineoplastic effects, but their narrow therapeutic window is key limiting factor. The synthesis of digitoxigenin derivatives with glycosidic unit modifications is a promising approach to develop more selective and effective antitumor agents. This study aimed to compare the pharmacological properties as well as the cytotoxic effects of digitoxigenin-α-L-amiceto-pyranoside and digitoxigenin-α-L-rhamno-pyranoside and to evaluate the mechanism of these derivatives in oxidative conditions in HeLa cells. The rhamnose derivative increased the binding affinity and inhibitory effect of digitoxigenin by approximately 5-15 times, unlike the amicetose derivative. Despite this difference, both compounds similarly increased H2O2 levels, induced membrane lipid peroxidation, and reduced GSH levels and SOD activity at nanomolar concentrations. This study highlights the importance of the sugar moiety in CTS structure for NKA binding and demonstrates that a primary mechanism of cytotoxicity of digitoxigenin derivatives may involve cellular oxidative stress, underscoring their potential as therapeutic agents for cancer treatment.
癌症是世界范围内导致死亡的主要原因之一,其治疗受到目前药物缺乏特异性和副作用的阻碍。促心甾体(CTS)与Na+/K+- atp酶(NKA)相互作用并诱导抗肿瘤作用,但其狭窄的治疗窗口是关键的限制因素。糖苷基修饰的洋地黄苷衍生物的合成是开发更有选择性和更有效的抗肿瘤药物的一条很有前途的途径。本研究旨在比较洋地黄苷元-α- l -氨基吡喃苷和洋地黄苷元-α- l -鼠李糖吡喃苷的药理特性和细胞毒作用,并探讨其在HeLa细胞氧化条件下的作用机制。鼠李糖衍生物与氨基糖衍生物相比,其结合亲和力和抑制作用提高了约5-15倍。尽管存在这种差异,但两种化合物在纳米摩尔浓度下相似地增加H2O2水平,诱导膜脂过氧化,降低GSH水平和SOD活性。本研究强调了CTS结构中糖部分对NKA结合的重要性,并表明洋地黄苷元衍生物的细胞毒性的主要机制可能涉及细胞氧化应激,强调了它们作为癌症治疗药物的潜力。
期刊介绍:
The Journal of Membrane Biology is dedicated to publishing high-quality science related to membrane biology, biochemistry and biophysics. In particular, we welcome work that uses modern experimental or computational methods including but not limited to those with microscopy, diffraction, NMR, computer simulations, or biochemistry aimed at membrane associated or membrane embedded proteins or model membrane systems. These methods might be applied to study topics like membrane protein structure and function, membrane mediated or controlled signaling mechanisms, cell-cell communication via gap junctions, the behavior of proteins and lipids based on monolayer or bilayer systems, or genetic and regulatory mechanisms controlling membrane function.
Research articles, short communications and reviews are all welcome. We also encourage authors to consider publishing ''negative'' results where experiments or simulations were well performed, but resulted in unusual or unexpected outcomes without obvious explanations.
While we welcome connections to clinical studies, submissions that are primarily clinical in nature or that fail to make connections to the basic science issues of membrane structure, chemistry and function, are not appropriate for the journal. In a similar way, studies that are primarily descriptive and narratives of assays in a clinical or population study are best published in other journals. If you are not certain, it is entirely appropriate to write to us to inquire if your study is a good fit for the journal.
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