ABSTRACT
SARS-CoV-2 extensively N-glycosylates its spike proteins, which are necessary for host cell invasion and the target of both vaccines and immunotherapies. These sugars are predicted to help mediate spike binding to the host receptor by stabilizing its open conformation and evading host immunity. Here, we investigated both the essentiality of the host N-glycosylation pathway and SARS-CoV-2 N-glycans for infection. Inhibition of host N-glycosylation using RNAi or FDA-approved drugs reduced virus infectivity, including that of several variants. Under these conditions, cells produced less virions and some completely lost their infectivity. Furthermore, partial deglycosylation of intact virions showed that surface-exposed N-glycans are critical for cell invasion. Altogether, spike N-glycosylation is a targetable pathway with clinical potential for treatment or prevention of COVID-19.
ABSTRACT
The scientific community has responded to the COVID-19 pandemic by rapidly undertaking research to find effective strategies to reduce the burden of this disease. Encouragingly, researchers from a diverse array of fields are collectively working towards this goal. Research with infectious SARS-CoV-2 is undertaken in high containment laboratories, however, it is often desirable to work with samples at lower containment levels. To facilitate the transfer of infectious samples from high containment laboratories, we have tested methods commonly used to inactivate virus and prepare the sample for additional experiments. Incubation at 80{degrees}C, and a range of detergents and UV energies were successful at inactivating a high titre of SARS-CoV-2. These protocols can provide a framework for in house inactivation of SARS-CoV-2 in other laboratories, ensuring the safe use of samples in lower containment levels.
