Improved Expression of SARS-CoV-2 Spike RBD Using the Insect Cell-Baculovirus System.

Insect cell-baculovirus expression vector system is one of the most established platforms to produce biological products, and it plays a fundamental role in the context of COVID-19 emergency, providing recombinant proteins for treatment, diagnosis, and prevention. SARS-CoV-2 infection is mediated by the interaction of the spike glycoprotein trimer via its receptor-binding domain (RBD) with the host's cellular receptor. As RBD is required for many applications, in the context of pandemic it is important to meet the challenge of producing a high amount of recombinant RBD (rRBD). For this reason, in the present study, we developed a process based on Sf9 insect cells to improve rRBD yield. rRBD was recovered from the supernatant of infected cells and easily purified by metal ion affinity chromatography, with a yield of 82% and purity higher than 95%. Expressed under a novel chimeric promoter (polh-pSeL), the yield of rRBD after purification was 21.1 ± 3.7 mg/L, which is the highest performance described in Sf9 cell lines. Finally, rRBD was successfully used in an assay to detect specific antibodies in COVID-19 serum samples. The efficient strategy herein described has the potential to produce high-quality rRBD in Sf9 cell line for diagnostic purpose.

Topology Dictates Evolution of Regulatory Cysteines in a Family of Viral Oncoproteins.

Redox regulation in biology is largely operated by cysteine chemistry in response to a variety of cell environmental and intracellular stimuli. The high chemical reactivity of cysteines determines their conservation in functional roles, but their presence can also result in harmful oxidation limiting their general use by proteins. Papillomaviruses constitute a unique system for studying protein sequence evolution since there are hundreds of anciently evolved stable genomes. E7, the viral transforming factor, is a dimeric, cysteine-rich oncoprotein that shows both conserved structural and variable regulatory cysteines constituting an excellent model for uncovering the mechanism that drives the acquisition of redox-sensitive groups. By analyzing over 300 E7 sequences, we found that although noncanonical cysteines show no obvious sequence conservation pattern, they are nonrandomly distributed based on topological constrains. Regulatory residues are strictly excluded from six positions stabilizing the hydrophobic core while they are enriched in key positions located at the dimerization interface or around the Zn+2 ion. Oxidation of regulatory cysteines is linked to dimer dissociation, acting as a reversible redox-sensing mechanism that triggers a conformational switch. Based on comparative sequence analysis, molecular dynamics simulations and biophysical analysis, we propose a model in which the occurrence of cysteine-rich positions is dictated by topological constrains, providing an explanation to why a degenerate pattern of cysteines can be achieved in a family of homologs. Thus, topological principles should enable the possibility to identify hidden regulatory cysteines that are not accurately detected using sequence based methodology.