影响氧化镁团簇胃肠道消化酶命运的因素：硅表征。

IF 2.3 3区化学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chemistry & Biodiversity Pub Date : 2025-06-06 DOI:10.1002/cbdv.202500157

Ghulam Haydar, Ataf Ali Altaf, Aqsa Iqbal, Uzma Hashmat, Samia Kausar

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引用次数: 0

摘要

最近，金属氧化物簇点已经进入医学和生物学领域。消化系统包含不同的pH值，这可能促进金属氧化物团簇的形成。这些团簇可能进一步与消化系统酶相互作用，产生金属团簇-酶蛋白复合物。本研究利用分子对接技术研究了这50种配合物的结构。设计并优化了5种氧化镁簇——mg4o4、Mg5O5、Mg6O6、Mg7O7和mg8o8，并与10种人体消化系统相关的金属酶（3P95、4A94、2V77、2JBK、1PJP、1N1M、1X0V、1BSI、1C8Q、1ZLI）进行对接。这些配合物是通过分子对接模拟生成的。结果表明，氧化镁簇点（MgO-CDs）与不同的酶表现出非键相互作用。氧化镁簇与酶的结合亲和力在-8.8 ~ -2.9 kcal/mol之间。羧基肽酶B （Protein Data Bank [PDB] ID: 1ZLI）与Mg8O8在-8.8 kcal/mol和Ki 0.35µM时相互作用最显著。这种相互作用有助于了解高镁血症症状中的羧肽酶B （IZLI）酶活性，这导致不可降解蛋白质的积累。

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Factors Impacting the Gastrointestinal Digestive Enzymes Fate of Magnesium Oxide Clusters: In Silico Characterization.

Recently, metal oxide cluster dots have moved into medicinal and biological contemplations. Digestive system comprises different pH levels that may facilitate the formation of metal oxide clusters hypothetically. Those clusters may further interact with digestive system enzymes and generate metal cluster-enzyme protein complexes. The present study investigated the profiles of such 50 complexes using molecular docking techniques. A total of five magnesium oxide clusters-Mg₄O₄, Mg₅O₅, Mg₆O₆, Mg₇O₇, and Mg₈O₈-were designed, optimized, and docked with 10 human digestive system-related metalloenzymes (3P95, 4A94, 2V77, 2JBK, 1PJP, 1N1M, 1X0V, 1BSI, 1C8Q, 1ZLI). The complexes were produced using molecular docking simulations. The results revealed that the magnesium oxide cluster dots (MgO-CDs) show nonbonding interactions with different enzymes. The binding affinities of MgO clusters with enzymes ranged from -8.8 to -2.9 kcal/mol. The carboxypeptidase B (Protein Data Bank [PDB] ID: 1ZLI) and Mg₈O₈ exhibited most significant interactions with -8.8 kcal/mol and Ki 0.35 µM. Such interactions are helpful to understand the carboxypeptidase B (IZLI) enzymatic activity in hypermagnesemia symptoms, which leads to build up of non-degraded proteins.

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来源期刊

Chemistry & Biodiversity 环境科学-化学综合

CiteScore

3.40

自引率

10.30%

发文量

475

审稿时长

2.6 months

期刊介绍： Chemistry & Biodiversity serves as a high-quality publishing forum covering a wide range of biorelevant topics for a truly international audience. This journal publishes both field-specific and interdisciplinary contributions on all aspects of biologically relevant chemistry research in the form of full-length original papers, short communications, invited reviews, and commentaries. It covers all research fields straddling the border between the chemical and biological sciences, with the ultimate goal of broadening our understanding of how nature works at a molecular level. Since 2017, Chemistry & Biodiversity is published in an online-only format.