Viral protein biogenesis underpins every viral life cycle stage, and elucidating these processes could reveal fundamental principles of virus–host interaction, and vulnerabilities amenable to therapeutic targeting. Here we apply biophysical, molecular, and cell biology techniques to investigate the insertion, folding, and oligomerization of the SARS-CoV-2 M protein. We describe the sequential co-translational insertion of the hydrophobic core, and demonstrate that the cytosolic C-terminal domain undergoes slower adoption of its tertiary structure. Additionally, we characterize how the transmembrane domain bundle facilitates M-protein oligomerization. Our results reveal a hydrophobic residue cluster that is essential for protein folding and co-translational dimerization. Additionally, we identify the cellular machinery responsible for targeting and inserting the M protein into the ER membrane, and chaperones and cofactors that may contribute to proper folding.
Arantza Muguruza-Montero, Jack Robert Tait, Sara Alicante, Ane Metola, Eider Núñez, Janire Urrutia, Vanda Šunderlíková, Alexandros Katranidis, Gunnar Von Heijne, Sander J. Tans, Álvaro Villarroel
Arantza Muguruza‐Montero, Jonathan Tait, Sara M‐Alicante, Ane Metola, Eider Núñez, Janire Urrutia, Vanda Šunderlíková, Alexandros Katranidis, Gunnar Von Heijne, Sander J. Tans, Álvaro Villarroel
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