Endonuclease-based genotyping of the RBM, a first-line method for the surveillance of emergence or evolution of SARS-CoV-2 Variants (preprint)

Since the beginning of the Covid-19 pandemics, variants have emerged. Whereas most of them have no to limited selective advantage, some display increased transmissibility and/or resistance to immune response. To date, most of the mutations involved in the functional adaptation are found in the Receptor Binding Module (RBM), close to the interface with the human receptor ACE2. In this study, we thus developed and validated a fast and simple molecular assay allowing the detection and partial identification of the mutations in the RBM coding sequence. After the amplification of the region of interest, the amplicon is heat-denatured and hybridized with an amplicon of reference. The presence of a mutation in the heteroduplex can be cleaved by a mismatch-specific endonuclease and the cleavage pattern is analysed by capillary electrophoresis. The approach was first validated on viral RNA purified different SARS-CoV-2 variants produced in the lab before being implemented for clinical samples. The results highlighted the performance of the assay for the detection of mutations in the RBM from clinical samples. The procedure can be easily set up for high throughput identification of the presence of mutations and serve as a first-line screening to select the samples for full genome sequencing.

Label-Free Plasmonic Biosensor for Rapid, Quantitative, and Highly Sensitive COVID-19 Serology: Implementation and Clinical Validation (preprint)

Serological tests are essential for the control and management of COVID-19 pandemic, not only for current and historical diagnostics but especially for surveillance, epidemiological, and acquired immunity studies. Clinical COVID-19 serology is routinely performed by enzymatic or chemiluminescence immunoassays (i.e., ELISA or CLIA), which provide good sensitivities at the expense of relatively long turnaround times and specialized laboratory settings. Rapid serological tests, based on lateral flow assays, have also been developed and widely commercialized, but they suffer from limited reliability due to relatively low sensitivity and specificity. We have developed and validated a direct serological biosensor assay employing proprietary technology based on Surface Plasmon Resonance (SPR). The biosensor offers a rapid -less than 15 min- identification and quantification of SARS-CoV-2 antibodies directly in clinical samples, without the need of any signal amplification. The portable plasmonic biosensor device employs a custom-designed multi-antigen sensor biochip, combining the two main viral antigens (RBD peptide and N protein), for simultaneous detection of human antibodies targeting both antigens. The SPR serology assay reaches detection limits in the low ng mL-1 range employing polyclonal antibodies as standard, which are well below the commonly detected antibody levels in COVID-19 patients. The assay has also been implemented employing the first WHO approved anti-SARS-CoV-2 immunoglobulin standard. We have carried out a clinical validation with COVID-19 positive and negative samples (n=120) that demonstrates the excellent diagnostic sensitivity (99%) and specificity (100%). This positions our biosensor device as an accurate, robust, and easy-to-use diagnostics tool for rapid and reliable COVID-19 serology to be employed both at laboratory and decentralized settings for the management of COVID-19 patients and for the evaluation of immunological status during vaccination, treatment or in front of emerging variants.