Conformation Prediction of Human Plasmin and Docking on Gold Nanoparticle
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33122
Conformation Prediction of Human Plasmin and Docking on Gold Nanoparticle

Authors: Wen-Shyong Tzou, Chih-Ching Huang, Chin-Hwa Hu, Ying-Tsang Lo, Tun-Wen Pai, Chia-Yin Chiang, Chung-Hao Li, Hong-Jyuan Jian

Abstract:

Plasmin plays an important role in the human circulatory system owing to its catalytic ability of fibrinolysis. The immediate injection of plasmin in patients of strokes has intrigued many scientists to design vectors that can transport plasmin to the desired location in human body. Here we predict the structure of human plasmin and investigate the interaction of plasmin with the gold-nanoparticle. Because the crystal structure of plasminogen has been solved, we deleted N-terminal domain (Pan-apple domain) of plasminogen and generate a mimic of the active form of this enzyme (plasmin). We conducted a simulated annealing process on plasmin and discovered a very large conformation occurs. Kringle domains 1, 4 and 5 had been observed to leave its original location relative to the main body of the enzyme and the original doughnut shape of this enzyme has been transformed to a V-shaped by opening its two arms. This observation of conformational change is consistent with the experimental results of neutron scattering and centrifugation. We subsequently docked the plasmin on the simulated gold surface to predict their interaction. The V-shaped plasmin could utilize its Kringle domain and catalytic domain to contact the gold surface. Our findings not only reveal the flexibility of plasmin structure but also provide a guide for the design of a plasmin-gold nanoparticle.

Keywords: Docking, gold nanoparticle, molecular simulation, plasmin.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1106873

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2437

References:


[1] Ramakrishnan V, Patthy L, Mangel WF. Conformation of Lys-plasminogen and the kringle 1-3 fragment of plasminogen analyzed by small-angle neutron scattering. Biochemistry. 1991; 30:3963-9.
[2] Law RHP, Caradoc-Davies T, Cowieson N, Horvath AJ, Quek AJ, Encarnacao JA, et al. The X-ray Crystal Structure of Full-Length Human Plasminogen. Cell reports. 2012; 1:185-90.
[3] Xue Y, Bodin C, Olsson K. Crystal structure of the native plasminogen reveals an activation-resistant compact conformation. Journal of thrombosis and haemostasis: JTH. 2012; 10:1385-96.
[4] Pronk S, Pall S, Schulz R, Larsson P, Bjelkmar P, Apostolov R, et al. GROMACS 4.5: a high-throughput and highly parallel open source molecular simulation toolkit. Bioinformatics. 2013; 29:845-54.
[5] Brancolini G, Kokh DB, Calzolai L, Wade RC, Corni S. Docking of ubiquitin to gold nanoparticles. ACS nano. 2012; 6:9863-78.
[6] Hoefling M, Monti S, Corni S, Gottschalk KE. Interaction of beta-sheet folds with a gold surface. PLoS One. 2011; 6:e20925.
[7] Stueker O, Ortega VA, Goss GG, Stepanova M. Understanding interactions of functionalized nanoparticles with proteins: a case study on lactate dehydrogenase. Small. 2014; 10:2006-21.
[8] Gabdoulline RR, Wade RC. Simulation of the diffusional association of barnase and barstar. Biophys J. 1997; 72:1917-29.
[9] Gabdoulline RR, Wade RC. Brownian dynamics simulation of protein-protein diffusional encounter. Methods. 1998; 14:329-41.