突变和二硫键形成对单体细胞红蛋白催化位点的影响:分子水平的洞察

Q3 Physics and Astronomy

Plasma Medicine Pub Date : 2021-01-01 DOI:10.1615/plasmamed.2021041420

Jamoliddin Razzokov, Sunnatullo Fazliev, M. Yusupov, A. Sharipov, Zukhriddin Ruziev, Sh. I. Mamatkulov

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引用次数: 3

摘要

细胞珠蛋白(Cygb)是最近发现的珠蛋白家族成员。Cygb保持一个大的极性腔，其中有血红素群。Cygb的主要催化活性发生在这个血红素基团周围，它也被认为是一个配体对接站。生化实验表明，Cygb可以清除活性氧和活性氮，如过氧化氢、一氧化氮和过氧化物，保护细胞免受氧化和亚硝化应激。然而，突变及其与氧化的协同作用对Cygb清除活性的影响尚未得到详细研究。因此，在本研究中，我们通过分子动力学和对接模拟来研究突变和氧化对Cygb催化功能的影响。我们的模拟结果表明，Cygb中赖氨酸80残基向丙氨酸的突变导致血红素基团的通路打开，从而增强其清除功能。此外，这种突变(即Cygb (L80A))与氧化[即Cygb(即Cygb S-S)中的二硫键形成]的结合诱导了其结构的复杂构象变化。因此，这些变化导致进入血红素基团的通道更加开放，这反过来又在更大程度上增强了Cygb的清除活性。后者可以是修饰Cygb(即Cygb (L80A)和Cygb S-S)的酶促功能增强的标志。

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Effect of mutation and disulfide bond formation on the catalytic site of monomeric cytoglobin: a molecular level insight

: Cytoglobin (Cygb) is a recently discovered member of the globin family. Cygb maintains a large apolar cavity with the heme group located in it. The main catalytic activity of Cygb takes place around this heme group, which is also considered as a ligand docking station. Biochemical experiments revealed that Cygb can scavenge reactive oxygen and nitrogen species, such as hydrogen peroxide, nitric oxide, and peroxinitrite, protecting the cell against oxidative and nitrosative stress. However, the effect of mutation, as well as its synergistic effect together with oxidation on scavenging activity of the Cygb, has not yet been studied in detail. Thus, in this research we perform molecular dynamics and docking simulations to study the impact of mutation and oxidation on the Cygb catalytic function. Our simulation results show that the mutation of lysine 80 residue to alanine in Cygb results in an opening of the access to the heme group, thereby increasing its scavenging function. Moreover, the combination of this mutation (i.e., Cygb (L80A) ) with the oxidation [namely, the disulfide bond formation in Cygb (i.e., Cygb S-S )] induces the complex conformational changes in its structure. As a result, these changes lead to even more opening of the access to the heme group, which in turn enhances the scavenging activity of Cygb to a more extent. The latter can be a hallmark of enhanced enzymatic function of the modified Cygb (i.e., Cygb (L80A) and Cygb S-S ).

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来源期刊

Plasma Medicine Physics and Astronomy-Physics and Astronomy (all)

CiteScore

1.40

自引率

0.00%

发文量

期刊介绍： Technology has always played an important role in medicine and there are many journals today devoted to medical applications of ionizing radiation, lasers, ultrasound, magnetic resonance and others. Plasma technology is a relative newcomer to the field of medicine. Experimental work conducted at several major universities, research centers and companies around the world over the recent decade demonstrates that plasma can be used in variety of medical applications. It is already widely used surgeries and endoscopic procedures. It has been shown to control properties of cellular and tissue matrices, including biocompatibility of various substrates. Non-thermal plasma has been demonstrated to deactivate dangerous pathogens and to stop bleeding without damaging healthy tissue. It can be used to promote wound healing and to treat cancer. Understanding of various mechanisms by which plasma can interact with living systems, including effects of reactive oxygen species, reactive nitrogen species and charges, has begun to emerge recently. The aim of the Plasma Medicine journal will be to provide a forum where the above topics as well as topics closely related to them can be presented and discussed. Existing journals on plasma science and technology are aimed for audiences with primarily engineering and science background. The field of Plasma Medicine, on the other hand, is highly interdisciplinary. Some of prospective readers and contributors of the Plasma Medicine journal are expected to have background in medicine and biology. Others might be more familiar with plasma science. The goal of the proposed Plasma Medicine journal is to bridge the gap between audiences with such different backgrounds, without sacrificing the quality of the papers be their emphasis on medicine, biology or plasma science and technology.