Your search keyword '"Danmei Yao"' showing total 3 results

1. NKG2D discriminates diverse ligands through selectively mechano‐regulated ligand conformational changes

Author

Juan Fan, Jiawei Shi, Yong Zhang, Junwei Liu, Chenyi An, Huaying Zhu, Peng Wu, Wei Hu, Rui Qin, Danmei Yao, Xin Shou, Yibing Xu, Zhou Tong, Xue Wen, Jianpo Xu, Jin Zhang, Weijia Fang, Jizhong Lou, Weiwei Yin, and Wei Chen

Subjects

Binding Sites, General Immunology and Microbiology, ligand discrimination, General Neuroscience, Immunology, Histocompatibility Antigens Class I, chemical and pharmacologic phenomena, Articles, Molecular Dynamics Simulation, Ligands, Article, Single Molecule Imaging, General Biochemistry, Genetics and Molecular Biology, NKG2D, mechanical regulation, NK Cell Lectin-Like Receptor Subfamily K, Humans, conformational changes, Cell Adhesion, Polarity & Cytoskeleton, K562 Cells, Molecular Biology, Cells, Cultured, Signal Transduction, Mechanical Phenomena, Protein Binding

Abstract

Stimulatory immune receptor NKG2D binds diverse ligands to elicit differential anti‐tumor and anti‐virus immune responses. Two conflicting degeneracy recognition models based on static crystal structures and in‐solution binding affinities have been considered for almost two decades. Whether and how NKG2D recognizes and discriminates diverse ligands still remain unclear. Using live‐cell‐based single‐molecule biomechanical assay, we characterized the in situ binding kinetics of NKG2D interacting with different ligands in the absence or presence of mechanical force. We found that mechanical force application selectively prolonged NKG2D interaction lifetimes with the ligands MICA and MICB, but not with ULBPs, and that force‐strengthened binding is much more pronounced for MICA than for other ligands. We also integrated steered molecular dynamics simulations and mutagenesis to reveal force‐induced rotational conformational changes of MICA, involving formation of additional hydrogen bonds on its binding interface with NKG2D, impeding MICA dissociation under force. We further provided a kinetic triggering model to reveal that force‐dependent affinity determines NKG2D ligand discrimination and its downstream NK cell activation. Together, our results demonstrate that NKG2D has a discrimination power to recognize different ligands, which depends on selective mechanical force‐induced ligand conformational changes., Force‐induced alterations of ligand affinity and conformation allow immune receptor NKG2D to recognize different ligands and trigger distinct signaling responses for downstream natural killer cell activation.

Published

2021

2. Mechanical activation of spike fosters SARS-CoV-2 viral infection

Author

Chuxuan Xiao, Wei Hu, Jizhong Lou, Yufei Gao, Yang Ye, Jia Liu, Danmei Yao, Wei Chen, Jing Zhang, Tenny Mudianto, Jun Wang, Qiao Lu, Zhenhai Li, Xinrui Zhang, Pei-Hui Wang, Qiming Sun, Tongtong Zhang, Yong Zhang, Panyu Fei, Qi Xie, and Hui Chen

Subjects

Protein subunit, Mutant, Plasma protein binding, Biology, Molecular Dynamics Simulation, Article, Protein Domains, Viral entry, Tensile Strength, Humans, Binding site, Receptor, Molecular Biology, COVID-19 Serotherapy, Host cell membrane, Binding Sites, SARS-CoV-2, Immunization, Passive, COVID-19, Cell Biology, Hydrogen-Ion Concentration, Virus Internalization, Antibodies, Neutralizing, Cell biology, Protein Subunits, Spike Glycoprotein, Coronavirus, Spike (software development), Angiotensin-Converting Enzyme 2, Structural biology, Protein Binding

Abstract

The outbreak of SARS-CoV-2 (SARS2) has caused a global COVID-19 pandemic. The spike protein of SARS2 (SARS2-S) recognizes host receptors, including ACE2, to initiate viral entry in a complex biomechanical environment. Here, we reveal that tensile force, generated by bending of the host cell membrane, strengthens spike recognition of ACE2 and accelerates the detachment of spike’s S1 subunit from the S2 subunit to rapidly prime the viral fusion machinery. Mechanistically, such mechano-activation is fulfilled by force-induced opening and rotation of spike’s receptor-binding domain to prolong the bond lifetime of spike/ACE2 binding, up to 4 times longer than that of SARS-S binding with ACE2 under 10 pN force application, and subsequently by force-accelerated S1/S2 detachment which is up to ~103 times faster than that in the no-force condition. Interestingly, the SARS2-S D614G mutant, a more infectious variant, shows 3-time stronger force-dependent ACE2 binding and 35-time faster force-induced S1/S2 detachment. We also reveal that an anti-S1/S2 non-RBD-blocking antibody that was derived from convalescent COVID-19 patients with potent neutralizing capability can reduce S1/S2 detachment by 3 × 106 times under force. Our study sheds light on the mechano-chemistry of spike activation and on developing a non-RBD-blocking but S1/S2-locking therapeutic strategy to prevent SARS2 invasion.

Published

2020

3. Mechano-regulation of Peptide-MHC Class I Conformations Determines TCR Antigen Recognition

Author

Wei Chen, Cheng Zhu, Jizhong Lou, Baoyu Liu, Huaying Zhu, Brian D. Evavold, An Chenyi, Junwei Liu, Jie Sun, Chenqi Xu, Danmei Yao, Tongtong Zhang, Yong Zhang, Juan Fan, Chun Zhou, Rui Qin, Xun Zeng, Weiwei Yin, Jianan Wang, Jiawei Shi, Peng Wu, Ryan J. Martinez, Panyu Fei, Wei Hu, and Lei Cui

Subjects

Conformational change, Protein Conformation, T-Lymphocytes, Receptors, Antigen, T-Cell, Mice, Transgenic, chemical and pharmacologic phenomena, Human leukocyte antigen, Adaptive Immunity, Molecular Dynamics Simulation, Biology, Mechanotransduction, Cellular, Article, Structure-Activity Relationship, 03 medical and health sciences, Molecular dynamics, 0302 clinical medicine, HLA-A2 Antigen, Animals, Humans, Molecular Biology, 030304 developmental biology, 0303 health sciences, Hybridomas, Mechano regulation, T-cell receptor, Cell Biology, Antigen recognition, Acquired immune system, Single Molecule Imaging, Mice, Inbred C57BL, HEK293 Cells, Mutation, Biophysics, Peptide-MHC, 030217 neurology & neurosurgery, Protein Binding

Abstract

Summary TCRs recognize cognate pMHCs to initiate T cell signaling and adaptive immunity. Mechanical force strengthens TCR-pMHC interactions to elicit agonist-specific catch bonds to trigger TCR signaling, but the underlying dynamic structural mechanism is unclear. We combined steered molecular dynamics (SMD) simulation, single-molecule biophysical approaches, and functional assays to collectively demonstrate that mechanical force induces conformational changes in pMHCs to enhance pre-existing contacts and activates new interactions at the TCR-pMHC binding interface to resist bond dissociation under force, resulting in TCR-pMHC catch bonds and T cell activation. Intriguingly, cancer-associated somatic mutations in HLA-A2 that may restrict these conformational changes suppressed TCR-pMHC catch bonds. Structural analysis also indicated that HLA polymorphism might alter the equilibrium of these conformational changes. Our findings not only reveal critical roles of force-induced conformational changes in pMHCs for activating TCR-pMHC catch bonds but also have implications for T cell-based immunotherapy.

Published

2019