Insights into the dynamic nature of the dsRNA-bound TLR3 complex

Toll-like receptor 3 (TLR3), an endosomal receptor crucial for immune responses upon viral invasion. The TLR3 ectodomain (ECD) is responsible for double-stranded RNA (dsRNA) recognition and mutational analysis suggested that TLR3 ECD C-terminal dimerization is essential for dsRNA binding. Moreover,...

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Veröffentlicht in:	Scientific reports 2019-03, Vol.9 (1), p.3652-3652, Article 3652
Hauptverfasser:	Gosu, Vijayakumar, Son, Seungwoo, Shin, Donghyun, Song, Ki-Duk
Format:	Artikel
Sprache:	eng
Schlagworte:	119/118 45 631/114/2411 631/154/555 631/535/1267 Crystallography Dimerization Double-stranded RNA Herpes viruses Humanities and Social Sciences Hydrogen bonding Hydrogen bonds Immune response Kinases Monomers multidisciplinary Mutation Pattern recognition Polymorphism Principal components analysis Proteins Science Science (multidisciplinary) Signal transduction Simulation TLR3 protein Toll-like receptors Viral infections
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description	Toll-like receptor 3 (TLR3), an endosomal receptor crucial for immune responses upon viral invasion. The TLR3 ectodomain (ECD) is responsible for double-stranded RNA (dsRNA) recognition and mutational analysis suggested that TLR3 ECD C-terminal dimerization is essential for dsRNA binding. Moreover, the L412F polymorphism of TLR3 is associated with human diseases. Although the mouse structure of the TLR3-dsRNA complex provides valuable insights, the structural dynamic behavior of the TLR3-dsRNA complex in humans is not completely understood. Hence, in this study, we performed molecular dynamic simulations of human wild-type and mutant TLR3 complexes. Our results suggested that apoTLR3 ECD dimers are unlikely to be stable due to the distance between the monomers are largely varied during simulations. The observed interaction energies and hydrogen bonds in dsRNA-bound TLR3 wild-type and mutant complexes indicate the presence of a weak dimer interface at the TLR3 ECD C-terminal site, which is required for effective dsRNA binding. The L412F mutant exhibited similar dominant motion compared to wild-type. Additionally, we identified the distribution of crucial residues for signal propagation in TLR3-dsRNA complex through the evaluation of residue betweenness centrality (C B ). The results of this study extend our understanding of TLR3-dsRNA complex, which may assist in TLR3 therapeutics.
doi_str_mv	10.1038/s41598-019-39984-8
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The TLR3 ectodomain (ECD) is responsible for double-stranded RNA (dsRNA) recognition and mutational analysis suggested that TLR3 ECD C-terminal dimerization is essential for dsRNA binding. Moreover, the L412F polymorphism of TLR3 is associated with human diseases. Although the mouse structure of the TLR3-dsRNA complex provides valuable insights, the structural dynamic behavior of the TLR3-dsRNA complex in humans is not completely understood. Hence, in this study, we performed molecular dynamic simulations of human wild-type and mutant TLR3 complexes. Our results suggested that apoTLR3 ECD dimers are unlikely to be stable due to the distance between the monomers are largely varied during simulations. The observed interaction energies and hydrogen bonds in dsRNA-bound TLR3 wild-type and mutant complexes indicate the presence of a weak dimer interface at the TLR3 ECD C-terminal site, which is required for effective dsRNA binding. The L412F mutant exhibited similar dominant motion compared to wild-type. Additionally, we identified the distribution of crucial residues for signal propagation in TLR3-dsRNA complex through the evaluation of residue betweenness centrality (C B ). 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The TLR3 ectodomain (ECD) is responsible for double-stranded RNA (dsRNA) recognition and mutational analysis suggested that TLR3 ECD C-terminal dimerization is essential for dsRNA binding. Moreover, the L412F polymorphism of TLR3 is associated with human diseases. Although the mouse structure of the TLR3-dsRNA complex provides valuable insights, the structural dynamic behavior of the TLR3-dsRNA complex in humans is not completely understood. Hence, in this study, we performed molecular dynamic simulations of human wild-type and mutant TLR3 complexes. Our results suggested that apoTLR3 ECD dimers are unlikely to be stable due to the distance between the monomers are largely varied during simulations. The observed interaction energies and hydrogen bonds in dsRNA-bound TLR3 wild-type and mutant complexes indicate the presence of a weak dimer interface at the TLR3 ECD C-terminal site, which is required for effective dsRNA binding. The L412F mutant exhibited similar dominant motion compared to wild-type. Additionally, we identified the distribution of crucial residues for signal propagation in TLR3-dsRNA complex through the evaluation of residue betweenness centrality (C B ). The results of this study extend our understanding of TLR3-dsRNA complex, which may assist in TLR3 therapeutics.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>30842554</pmid><doi>10.1038/s41598-019-39984-8</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0003-2827-0873</orcidid><oa>free_for_read</oa></addata></record>
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subjects	119/118 45 631/114/2411 631/154/555 631/535/1267 Crystallography Dimerization Double-stranded RNA Herpes viruses Humanities and Social Sciences Hydrogen bonding Hydrogen bonds Immune response Kinases Monomers multidisciplinary Mutation Pattern recognition Polymorphism Principal components analysis Proteins Science Science (multidisciplinary) Signal transduction Simulation TLR3 protein Toll-like receptors Viral infections
title	Insights into the dynamic nature of the dsRNA-bound TLR3 complex
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