Elmezzi Graduate School of Molecular Medicine, Northwell Health, 350 Community Drive, Manhasset, 11030, New York, United States.
Institute of Molecular Medicine, Feinstein Institutes for Medical Research, Northwell Health, 350 Community Drive, Manhasset, 11030, New York, United States.
Magnes Res. 2020 Aug 1;33(3):68-85. doi: 10.1684/mrh.2020.0470.
Magnesium (Mg) plays important roles in maintaining genomic stability and cellular redox. Mg also serves as nature's physiological calcium (Ca) channel antagonist, controlling intracellular Ca entry. Because Ca is the most important second messenger, its intracellular concentration is tightly regulated. Excess intracellular Ca can activate aberrant signaling pathways leading to the acquisition of pathological characteristics and cell injury. Several epidemiological studies have linked Mg deficiency (MgD) and increased Ca:Mg ratios with higher incidences of colon cancer and increased mortality. While it is estimated that less than 50% of the US population consumes the recommended daily allowance for Mg, Ca supplementation is widespread. Therefore, we studied the effect of MgD, with variable Ca:Mg ratios on cellular oxidative stress, cell migration, calpain activity, and associated signaling pathways using the CT26 colon cancer cell line. MgD (with Ca:Mg ratios >1) elevated intracellular Ca levels, calpain activity and TRPM7 expression, as well as oxidative stress and cell migration, consistent with observed degradation of full-length E-cadherin, β-catenin, and N-terminal FAK. MgD was accompanied by enhanced degradation of IκBα and the transactivation domain containing the C-terminus of NF-κB p65 (RelA). MgD-exposed CT26 cells exhibited increased p53 degradation and aneuploidy, markers of genomic instability. By contrast, these pathological changes were not observed when CT26 were cultured under MgD conditions where the Ca:Mg ratio was kept at 1. Together, these data support that exposure of colon cancer cells to MgD with physiological Ca concentrations (or increasing Ca:Mg ratios) leads to the acquisition of a more aggressive, metastatic phenotype.
镁(Mg)在维持基因组稳定性和细胞氧化还原方面发挥着重要作用。Mg 还是天然的钙(Ca)通道拮抗剂,控制细胞内 Ca 内流。由于 Ca 是最重要的第二信使,其细胞内浓度受到严格调节。过量的细胞内 Ca 可以激活异常信号通路,导致获得病理性特征和细胞损伤。几项流行病学研究表明,镁缺乏症(MgD)和 Ca:Mg 比值升高与结肠癌发病率增加和死亡率升高有关。虽然估计只有不到 50%的美国人口摄入了推荐的镁日摄入量,但钙补充剂却很普遍。因此,我们使用 CT26 结肠癌细胞系研究了 MgD(伴有不同 Ca:Mg 比值)对细胞氧化应激、细胞迁移、钙蛋白酶活性以及相关信号通路的影响。MgD(伴有 Ca:Mg 比值>1)会升高细胞内 Ca 水平、钙蛋白酶活性和 TRPM7 表达,以及氧化应激和细胞迁移,这与观察到的全长 E-钙黏蛋白、β-连环蛋白和 FAK 的 N 端降解一致。MgD 伴随着 IκBα和包含 NF-κB p65(RelA)C 端的转录激活域的降解增强。MgD 暴露的 CT26 细胞表现出 p53 降解增加和非整倍体,这是基因组不稳定性的标志物。相比之下,当 CT26 在 MgD 条件下培养时,Ca:Mg 比值保持在 1,这些病理变化没有观察到。这些数据共同表明,暴露于具有生理 Ca 浓度的 MgD(或增加 Ca:Mg 比值)的结肠癌细胞会获得更具侵袭性、转移性的表型。
