Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers

Mironov, Vladimir; Shchugoreva, Irina A.; Artyushenko, P. V.; Morozov, Dmitry; Borbone, Nicola; Oliviero, Giorgia; Zamay, Tatiana N.; Moryachkov, Roman V.; Kolovskaya, Olga S.; Lukyanenko, Kirill A.; Song, Yangling; Merkuleva, Iuliia A.; Zabluda, V. N.; Peters, G. S.; Королева, Л. С.; Veprintsev, Dmitry V.; Glazyrin, Yury E.; Volosnikova, Ekaterina A.; Belenkaya, S. V.; Есина, Т. И.; Исаева, А. А.; Nesmeyanova, Valentina S.; Shanshin, Daniil V.; Berlina, Anna N.; Komova, Nadezhda S.; Светличный, В. А.; Silnikov, Vladimir N.; Щербаков, Д. Н.; Zamay, Galina S.; Zamay, Sergey S.; Smolyarova, T. E.; Тихонова, Е. П.; Chen, Kelvin H.‐C.; Jeng, U‐Ser; Condorelli, Gerolama; Franciscis, Vittorio de; Groenhof, Gerrit; Yang, Chaoyong; Moskovsky, Alexander; Fedorov, Dmitri G.; Tomilin, Felix N.; Tan, Weihong; Alexeev, Yuri; Berezovski, Maxim V.; Kichkailo, Anna S.

doi:10.1002/chem.202104481

Cited by 11 publications

(4 citation statements)

References 87 publications

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“…The partition analysis (PA), as implemented in GAMESS, allows us to circumvent this “inconvenience” by allowing arbitrary monomer definitions (called segments in PA to differentiate them from fragments). − The FMO method, in its many flavors, was successfully used to gain insight into complex biomolecular systems. − The choice of DFTB in our work is motivated by the availability of PA only in combination with this self-consistent field (SCF) method. Nevertheless, as recent works show, it may be an appropriate tool for our needs. , Unless indicated differently, all data discussed in this work is from PA based on FMO2-DFTB3/PCM/D3(BJ)/3ob calculations.…”

Section: Methodsmentioning

confidence: 99%

How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions

Sládek

Šmak

Tvaroŝka

2023

J. Chem. Inf. Model.

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Selectins and their ability to interact with specific ligands are a cornerstone in cell communication. Over the last three decades, a considerable wealth of experimental and molecular modeling insights into their structure and modus operandi were gathered. Nonetheless, explaining the role of individual selectin residues on a quantitative level remained elusive, despite its importance in understanding the structure–function relationship in these molecules and designing their inhibitors. This work explores essential interactions of selectin–ligand binding, employing a multiscale approach that combines molecular dynamics, quantum-chemical calculations, and residue interaction network models. Such an approach successfully reproduces most of the experimental findings. It proves to be helpful, with the potential for becoming an established tool for quantitative predictions of residue contribution to the binding of biomolecular complexes. The results empower us to quantify the importance of particular residues and functional groups in the protein–ligand interface and to pinpoint differences in molecular recognition by the three selectins. We show that mutations in the E-, L-, and P-selectins, e.g., different residues in positions 46, 85, 97, and 107, present a crucial difference in how the ligand is engaged. We assess the role of sulfation of tyrosine residues in PSGL-1 and suggest that TyrSO3 – in position 51 interacting with Arg85 in P-selectin is a significant factor in the increased affinity of P-selectin to PSGL-1 compared to E- and L-selectins. We propose an original pharmacophore targeting five essential PSGL-binding sites based on the analysis of the selectin···PSGL-1 interactions.

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Section: Methodsmentioning

confidence: 99%

How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions

Sládek

Šmak

Tvaroŝka

2023

J. Chem. Inf. Model.

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“…The rapid and ultrasensitive technique has recently gained considerable momentum with regard to the detection of respiratory viruses for the purpose of point-of-care testing, especially after the COVID-19 pandemic. When combined with the specificity and versatility (here, Raman-active labeling) of nucleic acid aptamers, the technique was able to reach low limits of detection (that could challenge the limits of PCR techniques) as shown for SARS-CoV-2 [163,164] as well as the influenza A virus [165,166]. SERS was also applied recently for the sensitive detection of cancer biomarkers, such as carcinoembryonic antigen (CEA) [167].…”

Section: Optical Aptasensorsmentioning

confidence: 99%

Aptamers Targeting Membrane Proteins for Sensor and Diagnostic Applications

et al. 2023

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Many biological processes (physiological or pathological) are relevant to membrane proteins (MPs), which account for almost 30% of the total of human proteins. As such, MPs can serve as predictive molecular biomarkers for disease diagnosis and prognosis. Indeed, cell surface MPs are an important class of attractive targets of the currently prescribed therapeutic drugs and diagnostic molecules used in disease detection. The oligonucleotides known as aptamers can be selected against a particular target with high affinity and selectivity by iterative rounds of in vitro library evolution, known as Systematic Evolution of Ligands by EXponential Enrichment (SELEX). As an alternative to antibodies, aptamers offer unique features like thermal stability, low-cost, reuse, ease of chemical modification, and compatibility with various detection techniques. Particularly, immobilized-aptamer sensing platforms have been under investigation for diagnostics and have demonstrated significant value compared to other analytical techniques. These “aptasensors” can be classified into several types based on their working principle, which are commonly electrochemical, optical, or mass-sensitive. In this review, we review the studies on aptamer-based MP-sensing technologies for diagnostic applications and have included new methodological variations undertaken in recent years.

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“…Aptamers have high specificity, selectivity, and binding affinity for their related targets (metal ions, chemical compounds, proteins, cells, and whole micro-organisms) with the equilibrium dissociation constants (KD) ranging from the nanomolar to picomolar range [ 52 , 53 ]. They can also form multiple three-dimensional (3D) structures, due to which aptamers can match a given protein target [ 54 ]. SELEX (Systematic Evolution of Ligands by EXponential Enrichment) technology can be used to find an aptamer for a target that does not yet have antibodies, or, if the antigen is toxic to the host animal, the aptamer can be created in vitro ( Figure 2 ) [ 55 ].…”

Section: Aptamersmentioning

confidence: 99%

Aptamers Enhance Oncolytic Viruses’ Antitumor Efficacy

et al. 2022

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Oncolytic viruses are highly promising for cancer treatment because they target and lyse tumor cells. These genetically engineered vectors introduce therapeutic or immunostimulatory genes into the tumor. However, viral therapy is not always safe and effective. Several problems are related to oncolytic viruses’ targeted delivery to the tumor and immune system neutralization in the bloodstream. Cryoprotection and preventing viral particles from aggregating during storage are other critical issues. Aptamers, short RNA, or DNA oligonucleotides may help to crawl through this bottleneck. They are not immunogenic, are easily synthesized, can be chemically modified, and are not very demanding in storage conditions. It is possible to select an aptamer that specifically binds to any target cell, oncolytic virus, or molecule using the SELEX technology. This review comprehensively highlights the most important research and methodological approaches related to oncolytic viruses and nucleic acid aptamers. Here, we also analyze possible future research directions for combining these two methodologies to improve the effectiveness of cancer virotherapy.

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Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers

Cited by 11 publications

References 87 publications

How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions

How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions

Aptamers Targeting Membrane Proteins for Sensor and Diagnostic Applications

Aptamers Enhance Oncolytic Viruses’ Antitumor Efficacy

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Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers

Cited by 11 publications

References 87 publications

How E-, L-, and P-Selectins Bind to sLex and PSGL-1: A Quantification of Critical Residue Interactions

How E-, L-, and P-Selectins Bind to sLex and PSGL-1: A Quantification of Critical Residue Interactions

Aptamers Targeting Membrane Proteins for Sensor and Diagnostic Applications

Aptamers Enhance Oncolytic Viruses’ Antitumor Efficacy

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Product

Resources

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How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions

How E-, L-, and P-Selectins Bind to sLe^x and PSGL-1: A Quantification of Critical Residue Interactions