SARS-CoV-2 envelope protein topology in eukaryotic membranes

Coronavirus E protein is a small membrane protein found in the virus envelope. Different coronavirus E proteins share striking biochemical and functional similarities, but sequence conservation is limited. In this report, we studied the E protein topology from the new SARS-CoV-2 virus both in microsomal membranes and in mammalian cells. Experimental data reveal that E protein is a single-spanning membrane protein with the N-terminus being translocated across the membrane, while the C-terminus is exposed to the cytoplasmic side (Nt lum /Ct cyt ). The defined membrane protein topology of SARS-CoV-2 E protein may provide a useful framework to understand its interaction with other viral and host components and contribute to establish the basis to tackle the pathogenesis of SARS-CoV-2.

SARS-CoV-2 envelope protein topology in eukaryotic membranes

ABSTRACTCoronavirus E protein is a small membrane protein found in the virus envelope. Different coronavirus E proteins share striking biochemical and functional similarities, but sequence conservation is limited. In this report, we studied the E protein topology from the new SARS-CoV-2 virus both in microsomal membranes and in mammalian cells. Experimental data reveal that E protein is a single-spanning membrane protein with the N-terminus being translocated across the membrane, while the C-terminus is exposed to the cytoplasmic side (Ntlum/Ctcyt). The defined membrane protein topology of SARS-CoV-2 E protein may provide a useful framework to understand its interaction with other viral and host components and establish the basis to tackle the pathogenesis of SARS-CoV-2.

Dynamic membrane topology in an unassembled membrane protein

Helical membrane proteins constitute roughly a quarter of all proteomes and perform diverse biological functions. To avoid aggregation, they undergo cotranslational membrane insertion and are typically assumed to attain stable transmembrane topologies immediately upon insertion. To what extent post-translational changes in topology are possible in-vivo and how they may affect biogenesis is incompletely understood. Here, we show that monomeric forms of Small Multidrug Resistance (SMR) proteins display topological dynamics, where the N-terminal transmembrane helix equilibrates between membrane-inserted and non-inserted states. We characterize the kinetics of the process and show how the composition of the helix regulates the topological dynamics. We further show that topological dynamics is a property of the unassembled monomeric protein, as the N-terminal helix becomes fixed in a transmembrane disposition upon dimerization. Membrane protein topology can thus remain dynamic long after cotranslational membrane insertion, and can be regulated by later assembly processes.

Insights into the key determinants of membrane protein topology enable the identification of new monotopic folds

Monotopic membrane proteins integrate into the lipid bilayer via reentrant hydrophobic domains that enter and exit on a single face of the membrane. Whereas many membrane-spanning proteins have been structurally characterized and transmembrane topologies can be predicted computationally, relatively little is known about the determinants of membrane topology in monotopic proteins. Recently, we reported the X-ray structure determination of PglC, a full-length monotopic membrane protein with phosphoglycosyl transferase (PGT) activity. The definition of this unique structure has prompted in vivo, biochemical, and computational analyses to understand and define key motifs that contribute to the membrane topology and to provide insight into the dynamics of the enzyme in a lipid bilayer environment. Using the new information gained from studies on the PGT superfamily we demonstrate that two motifs exemplify principles of topology determination that can be applied to the identification of reentrant domains among diverse monotopic proteins of interest.