Dielectrometry of hydration of fl avin mononucleotide and DNA

V. Kashpur, O. Khorunzhaya, D. Pesina
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Abstract

Subject and Purpose. The elucidation of the molecular mechanisms of action of biomolecules is necessary for the development of state-of-the-art means of diagnosing and treatment. Dielectric studies in the millimeter wave range are effective for puzzling out the nature of the interaction of biomolecules with a surrounding aqueous solvent. Flavin mononucleotide (FMN), which can kill microorganisms and destroy cancer cells, is of particular interest. The aim of the work is to recognize hydration effects (changes in the state of water molecules) in FMN solutions. Methods and Methodology. The complex dielectric permittivity (CDP) is measured in the EHF range. Knowing the difference between the CDP of FMN solution and the CDP of water we find the difference, D es , between the effective dielectric permittivities in terms of the Debye theory of polar liquids. Since the relaxation time of dipoles of bound water is one or two orders of magnitude longer than that of free water, the amount of the difference D es characterizes the hydration of biomolecules. At low concentrations, this difference is proportional to the number of bound water molecules. Results. It has been shown that approximately18 water molecules are bound to the FMN molecule. Groups of atoms as the most probable hydration centers (primarily due to the hydrogen bonds) have been indicated. As the pH decreases, the number of water molecules bound to the Flavin mononucleotide increases to 21. The study of the FMN–DNA solution has shown that one nucleotide accounts for 25–26 bound water molecules in total. However, composing hydration numbers assumes a quantity of components less than 20. An assumption is made that the additional components are due to the cooperative nature of the hydration, leading to the fact that even if some solvent molecules do not come into a direct contact with hydration centers, they are under the influence of biomolecules all the same. Conclusion. Extremely-high-frequency dielectrometry is an effective method of research into the interaction of biomolecules with a water-ionic solvent. A FMN hydration model has been proposed, which indicates probable hydration centers and tells a measure of their effect on the solvent. It has been found that the FMN with DNA interaction increases the number of bound water molecules per one nucleotide of the DNA. The obtained results have been compared to the existing models of the DNA with FMN interaction.
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黄嘌呤单核苷酸与DNA水合作用的介电测定
主题和目的。阐明生物分子作用的分子机制对于发展最先进的诊断和治疗手段是必要的。毫米波范围内的介电介质研究对于弄清生物分子与周围水溶液相互作用的性质是有效的。黄素单核苷酸(FMN),可以杀死微生物和破坏癌细胞,是特别感兴趣的。这项工作的目的是识别水合作用(水分子状态的变化)在FMN溶液中。方法和方法论。在EHF范围内测量复介电常数(CDP)。了解了FMN溶液的CDP和水的CDP之间的差异,我们发现,根据极性液体的德拜理论,有效介电常数之间的差异,des。由于束缚水的偶极子弛豫时间比自由水的偶极子弛豫时间长一到两个数量级,因此差值的大小表征了生物分子的水合作用。在低浓度下,这种差异与结合水分子的数量成正比。结果。研究表明,大约有18个水分子与FMN分子结合。原子群作为最可能的水化中心(主要是由于氢键)已被指出。随着pH值的降低,与黄素单核苷酸结合的水分子数量增加到21个。对FMN-DNA溶液的研究表明,一个核苷酸总共占25-26个结合水分子。然而,组合水化数假设组分的数量小于20。假设额外的成分是由于水化的合作性质,导致即使一些溶剂分子不与水化中心直接接触,它们也会受到生物分子的影响。结论。超高频电介质测量是研究生物分子与水离子溶剂相互作用的有效方法。提出了一个FMN水化模型,该模型指出了可能的水化中心,并说明了它们对溶剂的影响。已经发现,与DNA相互作用的FMN增加了DNA的每一个核苷酸的结合水分子的数量。所得结果已与现有的DNA与FMN相互作用模型进行了比较。
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