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Ion channel structure and function of the MERS coronavirus E protein

Iva Sučec, Bingqing Xia, Noah H. Somberg, Yi Wang, Hyunil Jo, Shuangqu Li, Barbara Perrone, Zhaobing Gao, Mei Hong

2025Science Advances10 citationsDOIOpen Access PDF

Abstract

Coronavirus envelope (E) proteins form drug-targeted ion channels that cause virulence to infected cells. The Middle East respiratory syndrome (MERS) virus has high mortality rates, but its E structure and function are unknown. We report the single-channel conductance and structure of membrane-bound MERS E protein. MERS E conducts K + ions with a unitary conductance of 113 picosiemens, fivefold larger than the conductance of severe acute respiratory syndrome coronavirus 2 E. Solid-state nuclear magnetic resonance data indicate that the MERS E transmembrane domain forms a five-helix bundle that spans the lipid bilayer. The amino-terminal helical interface features multiple interacting phenylalanine (Phe) residues and an asparagine (Asn), whereas the carboxyl-terminal channel pore contains Phe 33 . Mutation of Phe 17 abolished K + conductance, whereas mutations of Phe 33 and Asn 15 suppressed most channel activity. These results indicate that MERS E contains two Phe-centered ion-conduction apparatuses, which likely permeate ions through cation-π interactions, providing the structural basis for developing antiviral drugs to inhibit this pathogenic viroporin.

Topics & Concepts

CoronavirusIon channelCoronavirus disease 2019 (COVID-19)Middle East respiratory syndrome coronavirusFunction (biology)Computational biologyVirologyBiologyComputer scienceChemistryCell biologyMedicineGeneticsInfectious disease (medical specialty)DiseasePathologyReceptorSARS-CoV-2 and COVID-19 ResearchAnimal Virus Infections StudiesLipid Membrane Structure and Behavior
Ion channel structure and function of the MERS coronavirus E protein | Litcius