微囊藻毒素- lr的分离及其离子载体的潜在功能

IF 0.4 Q4 BIOCHEMICAL RESEARCH METHODS Journal of the Korean magnetic resonance society Pub Date : 2015-10-10 DOI:10.6564/JKMRS.2015.19.2.067
Gilhoon Kim, S. Han, Hoshik Won
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引用次数: 0

摘要

微囊藻毒素是一种环七肽,来自于菌胞属蓝藻的代谢物,是富营养化的结果。众所周知,微囊藻毒素lr是蛋白磷酸酶-1 (PP-1)催化亚基的有效抑制剂,也是强大的肿瘤启动子。微囊藻毒素的活性位点实际上有两个金属离子fe2 + / zn2 +靠近pp -1-微囊藻毒素复合物的亲核部分。我们报道了从韩国忠清岛大兴大坝的蓝藻(蓝绿藻)中分离和纯化这种微囊藻毒素lr。用CN滤筒从固相萃取(SPE)样品制备中提取微囊藻毒素lr。采用高效液相色谱法纯化蓝藻提取物,得到微囊藻毒素lr,并采用液相色谱/质谱法进行鉴定。利用分子动力学方法对其进行了详细的结构研究,以阐明单价和二价金属离子在pp -1-微囊藻毒素络合中的可能作用。采用分子计算和平均力势(PMF)方法,利用自由能摄动法监测金属与配体结合过程中的构象变化。微囊藻毒素-金属结合PMF模拟结果表明,微囊藻毒素采用广义几何分布为0.5~4.5 Å的mg2 +离子,其结合自由能非常稳定,为-10.95 kcal/mol,且与其他一价碱金属离子相比,K +离子可以形成稳定的金属配合物。
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Isolation of Microcystin-LR and Its Potential Function of Ionophore
The microcystin is a cyclic heptapeptide from metabolites of cyanobacteria in the genera mycrocystis, anabaeba as a result of eutrophication. It has been known that microcystin-LR is a potent inhibitor of the catalytic subunits of protein phosphatase-1 (PP-1) as well as powerful tumor promoter. The active site of microcystin actually has two metal ions Fe 2+ /Zn 2+ close to the nucleophilic portion of PP-1-microcystin complex. We report the isolation and purification of this microcystin-LR from cyanobacteria (blue-green algae) obtained from Daechung Dam in Chung-cheong Do, Korea. Microcystin-LR was extracted from solid-phase extraction (SPE) sample preparation using a CN cartridge. The cyanobacteria extract was purified to obtain microcystin-LR by HPLC method and identified by LC/MS. The detail structural studies that can elucidate the possible role of monovalent and divalent metal ions in PP-1-microcystin complexation were carried out by utilizing molecular dynamics. Conformational changes in metal binding for ligands were monitored by molecular computation and potential of mean force (PMF) using the method of the free energy perturbation. The microcystin-metal binding PMF simulation results exhibit that microcystin can have very stable binding free energy of -10.95 kcal/mol by adopting the Mg 2+ ion at broad geometrical distribution of 0.5~4.5 Å , and show that the K + ion can form a stable metal complex rather than other monovalent alkali metal ions.
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Journal of the Korean magnetic resonance society
Journal of the Korean magnetic resonance society BIOCHEMICAL RESEARCH METHODS-
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