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Structural Modeling and Molecular Dynamics of the Immune Checkpoint Molecule HLA-G

Thaís Arns, Dinler A. Antunes, Jayvee R. Abella, Maurício Rigo, Lydia E. Kavraki, Silvana Giuliatti, Eduardo Antônio Donadi

2020Frontiers in Immunology18 citationsDOIOpen Access PDF

Abstract

strategies to disclose the dynamic behavior of selected HLA-G forms, including the membrane-bound HLA-G1 molecule, soluble HLA-G1 dimer, and HLA-G5 isoform. Both the membrane-bound HLA-G1 molecule and the soluble HLA-G1 dimer were quite stable. Residues involved in the interaction with ILT2 and ILT4 receptors (α3 domain) were very close to the lipid bilayer in the complete HLA-G1 molecule, which might limit accessibility. On the other hand, these residues can be completely exposed in the soluble HLA-G1 dimer, due to the free rotation of the disulfide bridge (Cys42/Cys42). In fact, we speculate that this free rotation of each protomer (i.e., the chains composing the dimer) could enable alternative binding modes for ILT2/ILT4 receptors, which in turn could be associated with greater affinity of the soluble HLA-G1 dimer. Structural analysis of the HLA-G5 isoform demonstrated higher stability for the complex containing the peptide and coupled β2-microglobulin, while structures lacking such domains were significantly unstable. This study reports for the first time structural conformations for the HLA-G5 isoform and the dynamic behavior of HLA-G1 molecules under simulated biological conditions. All modeled structures were made available through GitHub (https://github.com/KavrakiLab/), enabling their use as templates for modeling other alleles and isoforms, as well as for other computational analyses to investigate key molecular interactions.

Topics & Concepts

DimerGene isoformChemistryHuman leukocyte antigenReceptorBiophysicsLigand (biochemistry)BiologyBiochemistryAntigenGeneImmunologyOrganic chemistryReproductive System and PregnancyReproductive Physiology in LivestockReproductive Biology and Fertility
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