Nucleic acid aptamers specific to S-protein and its receptor binding domain (RBD) of SARS-CoV-2 (severe acute respiratory syndrome-related coronavirus 2) virions are of high interest as potential inhibitors of viral infection and recognizing elements in biosensors. Development of specific therapy and biosensors is complicated by an emergence of new viral strains bearing amino acid substitutions and probable differences in glycosylation sites. Here, we studied affinity of a set of aptamers to two Wuhan-type RBD of S-protein expressed in Chinese hamster ovary cell line and Pichia pastoris that differ in glycosylation patterns. The expression system for the RBD protein has significant effects, both on values of dissociation constants and relative efficacy of the aptamer binding. We propose glycosylation of the RBD as the main force for observed differences. Moreover, affinity of a several aptamers was affected by a site of biotinylation. Thus, the robustness of modified aptamers toward new virus variants should be carefully tested.
The recent severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection has posed a great challenge for the development of ultra-fast methods for virus identification based on sensor principles. We created a structure modeling surface and size of the SARS-CoV-2 virus and used it in comparison with the standard antigen SARS-CoV-2—the receptor-binding domain (RBD) of the S-protein of the envelope of the SARS-CoV-2 virus from the Wuhan strain—for the development of detection of coronaviruses using a DNA-modified, surface-enhanced Raman scattering (SERS)-based aptasensor in sandwich mode: a primary aptamer attached to the plasmonic surface—RBD-covered Ag nanoparticle—the Cy3-labeled secondary aptamer. Fabricated novel hybrid plasmonic structures based on “Ag mirror-SiO2-nanostructured Ag” demonstrate sensitivity for the detection of investigated analytes due to the combination of localized surface plasmons in nanostructured silver surface and the gap surface plasmons in a thin dielectric layer of SiO2 between silver layers. A specific SERS signal has been obtained from SERS-active compounds with RBD-specific DNA aptamers that selectively bind to the S protein of synthetic virion (dissociation constants of DNA-aptamer complexes with protein in the range of 10 nM). The purpose of the study is to systematically analyze the combination of components in an aptamer-based sandwich system. A developed virus size simulating silver particles adsorbed on an aptamer-coated sensor provided a signal different from free RBD. The data obtained are consistent with the theory of signal amplification depending on the distance of the active compound from the amplifying surface and the nature of such a compound. The ability to detect the target virus due to specific interaction with such DNA is quantitatively controlled by the degree of the quenching SERS signal from the labeled compound. Developed indicator sandwich-type systems demonstrate high stability. Such a platform does not require special permissions to work with viruses. Therefore, our approach creates the promising basis for fostering the practical application of ultra-fast, amplification-free methods for detecting coronaviruses based on SARS-CoV-2.
Organic–inorganic nanocomposites with the structure of interpenetrating or semi‐interpenetrating networks are considered as advanced materials, since they have improved thermal and mechanical properties. An alternative approach to the preparation of such hybrid systems is proposed. It is based on the synthesis of silica from the precursor of hyperbranched polyethoxysiloxane by the hydrolytic condensation reaction in the volume of pores of a polymer matrix (bulk porosity is 40 vol%) stretched via the environmental crazing mechanism. Polyethylene–silica nanocomposites with the structure of semi‐interpenetrating networks when the content of silica is not less than 20–25 wt% are obtained. These composites can undergo an additional phase separation at a temperature of 160 °C (above the melting point of polyethylene), which is accompanied by an increase in the size of the polymer phase with the formation of macrophases. At the same time, the environment (orthophosphoric acid), in which the composite is heated, fills the pores that have appeared. As a result, the content of the third component with the new functionality increases up to 50 wt%, which allowed us to impart proton‐conducting properties to the composite material and preserve its shape stability.
DNA aptamers are oligonucleotides specifically bound to target molecules that can serve as antibodies of nucleic acid nature. For diagnosing the infection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV2), methods using antibodies specific to antigens on the virus are broadly used. We generated by classical SELEX a number of aptamers, interacting with the receptor-binding domain of SARS-CoV2 spike protein (SARS-CoV2 Spike RBD) from Wuhan-Hu-1 strain. The sequence identification was performed using a novel methodology based on the nanopore sequencing. For sequence identification of selected aptamers, we created the novel protocol for aptamer identification based on nanopore sequencing. We identified the best aptamer candidate named MEZ. It was chemically synthesized and tested for binding with SARS CoV2 Spike RBD domain of the S-protein from different strains. Kd of the complex is 6.5 nM being comparable with known aptamers. Virus neutralization tests demonstrate similar results for already known and MEZ aptamers. We identified differences for aptamers binding to SARS-CoV-2 Spike RBD from Wuhan-Hu-1 and Omicron strains. MD simulations reveal that the number of hydrogen bonds between the protein and aptamer is higher for the more stable complex. Moreover, dynamic network analysis show that the motions of the aptamer and protein are correlated to a higher extent in a more stable complex. Based on the experimental data and computational results we can conclude that the authentic RBD-aptamer complex has two specific points for interaction and the 3'-end of aptamer is responsible for strain identification. Therefore, the selected aptamer based on experimental data can be an alternative biological element for the development of SARS-CoV-2 diagnostic testing with strain specificity and cost efficiency due to the short length of aptamer being 31 nucleotides.
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