人和小鼠e -选择素与Sialyl-Lewisx结合的比较

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology BMC Structural Biology Pub Date : 2016-07-02 DOI:10.1186/s12900-016-0060-x
Anne D. Rocheleau, Thong M. Cao, Tait Takitani, Michael R. King
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引用次数: 6

摘要

在炎症期间,白细胞被血管内壁粘附受体的选择素家族捕获,以促进其从血流中排出。e -选择素在受刺激的内皮细胞上表达上调,并与白细胞表面的几种配体结合。选择素:配体相互作用部分是由凝集素结构域和Sialyl-Lewis x (sLex)之间的相互作用介导的,sLex是选择素配体共同的四糖。在不同物种的选择之间有高度的同源性:约为72和60?%分别在凝集素和EGF结构域。本研究采用分子动力学、对接和定向分子动力学模拟来比较sLex与小鼠和人e -选择素的结合和解离机制。首先,以人类e -选择素晶体结构为模板,构建小鼠e -选择素同源性模型。小鼠e -选择素被发现具有更大的域间角度,这与先前的研究表明选择素之间的结合更强有关。将sLex与人和小鼠E-selectin结合,发现小鼠复合物具有较高的自由结合能和较低的解离常数,表明其结合更强。小鼠复合物在几个关键残基上具有更高的灵活性。最后,采用定向分子动力学方法在2000-5000 μ m/ps2的力加载速率下解离配合物。在每种力加载速率下,小鼠复合物的解离时间都更长,在3000 μ m/ps2时差异具有统计学意义。当slex包被的微球通过包被人或小鼠e -选择素的微管灌注时,颗粒在小鼠e -选择素上滚动的速度更慢。分子动力学模拟和微球粘附实验表明,小鼠e -选择素蛋白与唾液Lewis x配体的结合比人类e -选择素更强。这种差异可以解释为小鼠e -选择素的域间角度更大,关键残基的灵活性更大。未来的工作可能会在人类e -选择素序列中引入类似的氨基酸取代,以进一步调节粘附行为。
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Comparison of human and mouse E-selectin binding to Sialyl-Lewisx

During inflammation, leukocytes are captured by the selectin family of adhesion receptors lining blood vessels to facilitate exit from the bloodstream. E-selectin is upregulated on stimulated endothelial cells and binds to several ligands on the surface of leukocytes. Selectin:ligand interactions are mediated in part by the interaction between the lectin domain and Sialyl-Lewis x (sLex), a tetrasaccharide common to selectin ligands. There is a high degree of homology between selectins of various species: about 72 and 60?% in the lectin and EGF domains, respectively. In this study, molecular dynamics, docking, and steered molecular dynamics simulations were used to compare the binding and dissociation mechanisms of sLex with mouse and human E-selectin. First, a mouse E-selectin homology model was generated using the human E-selectin crystal structure as a template.

Mouse E-selectin was found to have a greater interdomain angle, which has been previously shown to correlate with stronger binding among selectins. sLex was docked onto human and mouse E-selectin, and the mouse complex was found to have a higher free energy of binding and a lower dissociation constant, suggesting stronger binding. The mouse complex had higher flexibility in a few key residues. Finally, steered molecular dynamics was used to dissociate the complexes at force loading rates of 2000–5000?pm/ps2. The mouse complex took longer to dissociate at every force loading rate and the difference was statistically significant at 3000?pm/ps2. When sLex-coated microspheres were perfused through microtubes coated with human or mouse E-selectin, the particles rolled more slowly on mouse E-selectin.

Both molecular dynamics simulations and microsphere adhesion experiments show that mouse E-selectin protein binds more strongly to sialyl Lewis x ligand than human E-selectin. This difference was explained by a greater interdomain angle for mouse E-selectin, and greater flexibility in key residues. Future work could introduce similar amino acid substitutions into the human E-selectin sequence to further modulate adhesion behavior.

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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
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0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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