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17 results on '"Merkuleva, Iuliia A."'

1. Natural Antibodies Produced in Vaccinated Patients and COVID-19 Convalescents Hydrolyze Recombinant RBD and Nucleocapsid (N) Proteins.

Author: Timofeeva, Anna M., Shayakhmetova, Liliya Sh., Nikitin, Artem O., Sedykh, Tatyana A., Matveev, Andrey L., Shanshin, Daniil V., Volosnikova, Ekaterina A., Merkuleva, Iuliia A., Shcherbakov, Dmitriy N., Tikunova, Nina V., Sedykh, Sergey E., and Nevinsky, Georgy A.
Subjects: COVID-19, CYTOSKELETAL proteins, RECOMBINANT proteins, IMMUNOGLOBULINS, SARS-CoV-2
Abstract: Antibodies are protein molecules whose primary function is to recognize antigens. However, recent studies have demonstrated their ability to hydrolyze specific substrates, such as proteins, oligopeptides, and nucleic acids. In 2023, two separate teams of researchers demonstrated the proteolytic activity of natural plasma antibodies from COVID-19 convalescents. These antibodies were found to hydrolyze the S-protein and corresponding oligopeptides. Our study shows that for antibodies with affinity to recombinant structural proteins of the SARS-CoV-2: S-protein, its fragment RBD and N-protein can only hydrolyze the corresponding protein substrates and are not cross-reactive. By using strict criteria, we have confirmed that this proteolytic activity is an intrinsic property of antibodies and is not caused by impurities co-eluting with them. This discovery suggests that natural proteolytic antibodies that hydrolyze proteins of the SARS-CoV-2 virus may have a positive impact on disease pathogenesis. It is also possible for these antibodies to work in combination with other antibodies that bind specific epitopes to enhance the process of virus neutralization. [ABSTRACT FROM AUTHOR]
Published: 2024
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2. Pre-Pandemic Cross-Reactive Immunity against SARS-CoV-2 among Siberian Populations

Author: Shaprova, Olga N., primary, Shanshin, Daniil V., additional, Kolosova, Evgeniia A., additional, Borisevich, Sophia S., additional, Soroka, Artem A., additional, Merkuleva, Iuliia A., additional, Nikitin, Artem O., additional, Volosnikova, Ekaterina A., additional, Ushkalenko, Nikita D., additional, Zaykovskaya, Anna V., additional, Pyankov, Oleg V., additional, Elchaninova, Svetlana A., additional, Shcherbakov, Dmitry N., additional, and Ilyicheva, Tatiana N., additional
Published: 2023
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3. Corrigendum: The main protease 3CLpro of the SARS-CoV-2 virus: how to turn an enemy into a helper

Author: Belenkaya, Svetlana V., primary, Merkuleva, Iuliia A., additional, Yarovaya, Olga I., additional, Chirkova, Varvara Yu, additional, Sharlaeva, Elena A., additional, Shanshin, Daniil V., additional, Volosnikova, Ekaterina A., additional, Vatsadze, Sergey Z., additional, Khvostov, Mikhail V., additional, Salakhutdinov, Nariman F., additional, and Shcherbakov, Dmitriy, additional
Published: 2023
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4. The main protease 3CLpro of the SARS-CoV-2 virus: how to turn an enemy into a helper

Author: Belenkaya, Svetlana V., primary, Merkuleva, Iuliia A., additional, Yarovaya, Olga I., additional, Chirkova, Varvara Yu., additional, Sharlaeva, Elena A., additional, Shanshin, Daniil V., additional, Volosnikova, Ekaterina A., additional, Vatsadze, Sergey Z., additional, Khvostov, Mikhail V., additional, Salakhutdinov, Nariman F., additional, and Shcherbakov, Dmitriy N., additional
Published: 2023
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5. SARS-CoV-2 RBD Conjugated to Polyglucin, Spermidine, and dsRNA Elicits a Strong Immune Response in Mice

Author: Volosnikova, Ekaterina A., primary, Merkuleva, Iuliia A., additional, Esina, Tatiana I., additional, Shcherbakov, Dmitry N., additional, Borgoyakova, Mariya B., additional, Isaeva, Anastasiya A., additional, Nesmeyanova, Valentina S., additional, Volkova, Natalia V., additional, Belenkaya, Svetlana V., additional, Zaykovskaya, Anna V., additional, Pyankov, Oleg V., additional, Starostina, Ekaterina V., additional, Zadorozhny, Alexey M., additional, Zaitsev, Boris N., additional, Karpenko, Larisa I., additional, Ilyichev, Alexander A., additional, and Danilenko, Elena D., additional
Published: 2023
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6. Natural IgG against S-Protein and RBD of SARS-CoV-2 Do Not Bind and Hydrolyze DNA and Are Not Autoimmune

Author: Timofeeva, Anna M., primary, Sedykh, Sergey E., additional, Ermakov, Evgeny A., additional, Matveev, Andrey L., additional, Odegova, Eva I., additional, Sedykh, Tatiana A., additional, Shcherbakov, Dmitry N., additional, Merkuleva, Iuliia A., additional, Volosnikova, Ekaterina A., additional, Nesmeyanova, Valentina S., additional, Tikunova, Nina V., additional, and Nevinsky, Georgy A., additional
Published: 2022
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7. Antibodies to the Spike Protein Receptor-Binding Domain of SARS-CoV-2 at 4–13 Months after COVID-19

Author: Kolosova, Evgeniia A., primary, Shaprova, Olga N., additional, Shanshin, Daniil V., additional, Nesmeyanova, Valentina S., additional, Merkuleva, Iuliia A., additional, Belenkaya, Svetlana V., additional, Isaeva, Anastasiya A., additional, Nikitin, Artem O., additional, Volosnikova, Ekaterina A., additional, Nikulina, Yuliya A., additional, Nikonorova, Marina A., additional, Shcherbakov, Dmitry N., additional, and Elchaninova, Svetlana A., additional
Published: 2022
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8. Detection of Viral Particles Using a Biosensor

Author: Cheremiskina, Anastasia A., primary, Generalov, Vladimir M., additional, Merkuleva, Iuliia A., additional, Shcherbakov, Dmitriy N., additional, Safarov, Aleksander S., additional, and Buryak, Galina A., additional
Published: 2022
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9. Are Hamsters a Suitable Model for Evaluating the Immunogenicity of RBD-Based Anti-COVID-19 Subunit Vaccines?

Author: Merkuleva, Iuliia A., primary, Shcherbakov, Dmitry N., additional, Borgoyakova, Mariya B., additional, Isaeva, Anastasiya A., additional, Nesmeyanova, Valentina S., additional, Volkova, Natalia V., additional, Aripov, Vazirbek S., additional, Shanshin, Daniil V., additional, Karpenko, Larisa I., additional, Belenkaya, Svetlana V., additional, Kazachinskaia, Elena I., additional, Volosnikova, Ekaterina A., additional, Esina, Tatiana I., additional, Sergeev, Alexandr A., additional, Titova, Kseniia A., additional, Konyakhina, Yulia V., additional, Zaykovskaya, Anna V., additional, Pyankov, Oleg V., additional, Kolosova, Evgeniia A., additional, Viktorina, Olesya E., additional, Shelemba, Arseniya A., additional, Rudometov, Andrey P., additional, and Ilyichev, Alexander A., additional
Published: 2022
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10. Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers

Author: Mironov, Vladimir, primary, Shchugoreva, Irina A., additional, Artyushenko, Polina V., additional, Morozov, Dmitry, additional, Borbone, Nicola, additional, Oliviero, Giorgia, additional, Zamay, Tatiana N., additional, Moryachkov, Roman V., additional, Kolovskaya, Olga S., additional, Lukyanenko, Kirill A., additional, Song, Yanling, additional, Merkuleva, Iuliia A., additional, Zabluda, Vladimir N., additional, Peters, Georgy, additional, Koroleva, Lyudmila S., additional, Veprintsev, Dmitry V., additional, Glazyrin, Yury E., additional, Volosnikova, Ekaterina A., additional, Belenkaya, Svetlana V., additional, Esina, Tatiana I., additional, Isaeva, Anastasiya A., additional, Nesmeyanova, Valentina S., additional, Shanshin, Daniil V., additional, Berlina, Anna N., additional, Komova, Nadezhda S., additional, Svetlichnyi, Valery A., additional, Silnikov, Vladimir N., additional, Shcherbakov, Dmitriy N., additional, Zamay, Galina S., additional, Zamay, Sergey S., additional, Smolyarova, Tatyana, additional, Tikhonova, Elena P., additional, Chen, Kelvin H.‐C., additional, Jeng, U‐Ser, additional, Condorelli, Gerolama, additional, Franciscis, Vittorio, additional, Groenhof, Gerrit, additional, Yang, Chaoyong, additional, Moskovsky, Alexander A., additional, Fedorov, Dmitri G., additional, Tomilin, Felix N., additional, Tan, Weihong, additional, Alexeev, Yuri, additional, Berezovski, Maxim V., additional, and Kichkailo, Anna S., additional
Published: 2022
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11. Self-Assembled Particles Combining SARS-CoV-2 RBD Protein and RBD DNA Vaccine Induce Synergistic Enhancement of the Humoral Response in Mice

Author: Borgoyakova, Mariya B., primary, Karpenko, Larisa I., additional, Rudometov, Andrey P., additional, Volosnikova, Ekaterina A., additional, Merkuleva, Iuliia A., additional, Starostina, Ekaterina V., additional, Zadorozhny, Alexey M., additional, Isaeva, Anastasiya A., additional, Nesmeyanova, Valentina S., additional, Shanshin, Daniil V., additional, Baranov, Konstantin O., additional, Volkova, Natalya V., additional, Zaitsev, Boris N., additional, Orlova, Lyubov A., additional, Zaykovskaya, Anna V., additional, Pyankov, Oleg V., additional, Danilenko, Elena D., additional, Bazhan, Sergei I., additional, Shcherbakov, Dmitry N., additional, Taranin, Alexander V., additional, and Ilyichev, Alexander A., additional
Published: 2022
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12. Comparative Immunogenicity of the Recombinant Receptor-Binding Domain of Protein S SARS-CoV-2 Obtained in Prokaryotic and Mammalian Expression Systems

Author: Merkuleva, Iuliia A., primary, Shcherbakov, Dmitry N., additional, Borgoyakova, Mariya B., additional, Shanshin, Daniil V., additional, Rudometov, Andrey P., additional, Karpenko, Larisa I., additional, Belenkaya, Svetlana V., additional, Isaeva, Anastasiya A., additional, Nesmeyanova, Valentina S., additional, Kazachinskaia, Elena I., additional, Volosnikova, Ekaterina A., additional, Esina, Tatiana I., additional, Zaykovskaya, Anna V., additional, Pyankov, Oleg V., additional, Borisevich, Sophia S., additional, Shelemba, Arseniya A., additional, Chikaev, Anton N., additional, and Ilyichev, Alexander A., additional
Published: 2022
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13. Laboratory Preparation of Biosensor Based on Silicon Nanowire Field-Effect Transistor for Virus Indication

Author: Cheremiskina, Anastasia, primary, Generalov, Vladimir, additional, Safarov, Aleksander, additional, Shcherbakov, Dmitriy, additional, Merkuleva, Iuliia, additional, and Buryak, Galina, additional
Published: 2021
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14. Indication of the Coronavirus Model Using a Nanowire Biosensor

Author: Generalov, Vladimir, primary, Naumova, Olga, additional, Shcherbakov, Dmitry, additional, Safatov, Alexander, additional, Zaitsev, Boris, additional, Zaitseva, Elza, additional, Buryak, Galina, additional, Shcheglov, Dmitry, additional, Cheremiskina, Anastasiya, additional, Merkuleva, Iuliia, additional, and Aseyev, Alexander, additional
Published: 2020
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15. Cover Feature: Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers (Chem. Eur. J. 12/2022).

Author: Mironov, Vladimir, Shchugoreva, Irina A., Artyushenko, Polina V., Morozov, Dmitry, Borbone, Nicola, Oliviero, Giorgia, Zamay, Tatiana N., Moryachkov, Roman V., Kolovskaya, Olga S., Lukyanenko, Kirill A., Song, Yanling, Merkuleva, Iuliia A., Zabluda, Vladimir N., Peters, Georgy, Koroleva, Lyudmila S., Veprintsev, Dmitry V., Glazyrin, Yury E., Volosnikova, Ekaterina A., Belenkaya, Svetlana V., and Esina, Tatiana I.
Subjects: MOLECULAR orbitals, MOLECULAR dynamics, APTAMERS, SMALL-angle X-ray scattering
Abstract: Keywords: aptamers; fragment molecular orbitals method; molecular dynamics; SARS-CoV-2; SAXS EN aptamers fragment molecular orbitals method molecular dynamics SARS-CoV-2 SAXS 1 1 1 02/28/22 20220224 NES 220224 B Digital drug design reveals DNA aptamers binding SARS-CoV-2 b : A hybrid in silico et vitro approach, structure and interaction-based drug design, has been developed to create highly specific DNA aptamers for the receptor-binding domain of the SARS-CoV-2 spike protein. The structure and binding affinity of the aptamers were validated by small-angle X-ray scattering, flow cytometry, and fluorescence polarization. Cover Feature: Structure- and Interaction-Based Design of Anti-SARS-CoV-2 Aptamers (Chem. Eur. J. 12/2022). [Extracted from the article]
Published: 2022
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16. Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers

Author: Vladimir Mironov, Irina A. Shchugoreva, Polina V. Artyushenko, Dmitry Morozov, Nicola Borbone, Giorgia Oliviero, Tatiana N. Zamay, Roman V. Moryachkov, Olga S. Kolovskaya, Kirill A. Lukyanenko, Yanling Song, Iuliia A. Merkuleva, Vladimir N. Zabluda, Georgy Peters, Lyudmila S. Koroleva, Dmitry V. Veprintsev, Yury E. Glazyrin, Ekaterina A. Volosnikova, Svetlana V. Belenkaya, Tatiana I. Esina, Anastasiya A. Isaeva, Valentina S. Nesmeyanova, Daniil V. Shanshin, Anna N. Berlina, Nadezhda S. Komova, Valery A. Svetlichnyi, Vladimir N. Silnikov, Dmitriy N. Shcherbakov, Galina S. Zamay, Sergey S. Zamay, Tatyana Smolyarova, Elena P. Tikhonova, Kelvin H.‐C. Chen, U‐Ser Jeng, Gerolama Condorelli, Vittorio Franciscis, Gerrit Groenhof, Chaoyong Yang, Alexander A. Moskovsky, Dmitri G. Fedorov, Felix N. Tomilin, Weihong Tan, Yuri Alexeev, Maxim V. Berezovski, Anna S. Kichkailo, Mironov, Vladimir, Shchugoreva, Irina A., Artyushenko, Polina 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, Vladimir N., Peters, Georgy, Koroleva, Lyudmila S., Veprintsev, Dmitry V., Glazyrin, Yury E., Volosnikova, Ekaterina A., Belenkaya, Svetlana V., Esina, Tatiana I., Isaeva, Anastasiya A., Nesmeyanova, Valentina S., Shanshin, Daniil V., Berlina, Anna N., Komova, Nadezhda S., Svetlichnyi, Valery A., Silnikov, Vladimir N., Shcherbakov, Dmitriy N., Zamay, Galina S., Zamay, Sergey S., Smolyarova, Tatyana, Tikhonova, Elena P., Chen, Kelvin H. -C., Jeng, U-Ser, Condorelli, Gerolama, de Franciscis, Vittorio, Groenhof, Gerrit, Yang, Chaoyong, Moskovsky, Alexander A., Fedorov, Dmitri G., Tomilin, Felix N., Tan, Weihong, Alexeev, Yuri, Berezovski, Maxim V., and Kichkailo, Anna S
Subjects: oligonukleotidit, aptamers, fragment molecular orbitals method, molecular dynamics, SARS-CoV-2, SAXS, fragment molecular orbitals method, SARS-CoV-2, SELEX Aptamer Technique, Organic Chemistry, aptamers, SARS-CoV-2-virus, COVID-19, SAXS, General Chemistry, Aptamers, Nucleotide, Molecular Dynamics Simulation, laskennallinen kemia, molecular dynamics, Catalysis, lääkesuunnittelu, Molecular Docking Simulation, SARS-CoV-2, белки, Spike Glycoprotein, Coronavirus, Humans, дизайн аптамеров, molekyylidynamiikka, proteiinit
Abstract: Aptamer selection against novel infections is a complicated and time-consuming approach. Synergy can be achieved by using computational methods together with experimental procedures. This study aims to develop a reliable methodology for a rational aptamer in silico et vitro design. The new approach combines multiple steps: (1) Molecular design, based on screening in a DNA aptamer library and directed mutagenesis to fit the protein tertiary structure; (2) 3D molecular modeling of the target; (3) Molecular docking of an aptamer with the protein; (4) Molecular dynamics (MD) simulations of the complexes; (5) Quantum-mechanical (QM) evaluation of the interactions between aptamer and target with further analysis; (6) Experimental verification at each cycle for structure and binding affinity by using small-angle X-ray scattering, cytometry, and fluorescence polarization. By using a new iterative design procedure, structure- and interaction-based drug design (SIBDD), a highly specific aptamer to the receptor-binding domain of the SARS-CoV-2 spike protein, was developed and validated. The SIBDD approach enhances speed of the high-affinity aptamers development from scratch, using a target protein structure. The method could be used to improve existing aptamers for stronger binding. This approach brings to an advanced level the development of novel affinity probes, functional nucleic acids. It offers a blueprint for the straightforward design of targeting molecules for new pathogen agents and emerging variants.
Published: 2022
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17. Structure- and Interaction-Based Design of Anti-SARS-CoV-2 Aptamers.

Author: Mironov V, Shchugoreva IA, Artyushenko PV, Morozov D, Borbone N, Oliviero G, Zamay TN, Moryachkov RV, Kolovskaya OS, Lukyanenko KA, Song Y, Merkuleva IA, Zabluda VN, Peters G, Koroleva LS, Veprintsev DV, Glazyrin YE, Volosnikova EA, Belenkaya SV, Esina TI, Isaeva AA, Nesmeyanova VS, Shanshin DV, Berlina AN, Komova NS, Svetlichnyi VA, Silnikov VN, Shcherbakov DN, Zamay GS, Zamay SS, Smolyarova T, Tikhonova EP, Chen KH, Jeng US, Condorelli G, de Franciscis V, Groenhof G, Yang C, Moskovsky AA, Fedorov DG, Tomilin FN, Tan W, Alexeev Y, Berezovski MV, and Kichkailo AS
Subjects: Humans, Molecular Docking Simulation, Molecular Dynamics Simulation, SARS-CoV-2, SELEX Aptamer Technique, Spike Glycoprotein, Coronavirus, Aptamers, Nucleotide chemistry, COVID-19
Abstract: Aptamer selection against novel infections is a complicated and time-consuming approach. Synergy can be achieved by using computational methods together with experimental procedures. This study aims to develop a reliable methodology for a rational aptamer in silico et vitro design. The new approach combines multiple steps: (1) Molecular design, based on screening in a DNA aptamer library and directed mutagenesis to fit the protein tertiary structure; (2) 3D molecular modeling of the target; (3) Molecular docking of an aptamer with the protein; (4) Molecular dynamics (MD) simulations of the complexes; (5) Quantum-mechanical (QM) evaluation of the interactions between aptamer and target with further analysis; (6) Experimental verification at each cycle for structure and binding affinity by using small-angle X-ray scattering, cytometry, and fluorescence polarization. By using a new iterative design procedure, structure- and interaction-based drug design (SIBDD), a highly specific aptamer to the receptor-binding domain of the SARS-CoV-2 spike protein, was developed and validated. The SIBDD approach enhances speed of the high-affinity aptamers development from scratch, using a target protein structure. The method could be used to improve existing aptamers for stronger binding. This approach brings to an advanced level the development of novel affinity probes, functional nucleic acids. It offers a blueprint for the straightforward design of targeting molecules for new pathogen agents and emerging variants., (© 2022 Wiley-VCH GmbH.)
Published: 2022
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17 results on '"Merkuleva, Iuliia A."'

1. Natural Antibodies Produced in Vaccinated Patients and COVID-19 Convalescents Hydrolyze Recombinant RBD and Nucleocapsid (N) Proteins.

2. Pre-Pandemic Cross-Reactive Immunity against SARS-CoV-2 among Siberian Populations

3. Corrigendum: The main protease 3CLpro of the SARS-CoV-2 virus: how to turn an enemy into a helper

4. The main protease 3CLpro of the SARS-CoV-2 virus: how to turn an enemy into a helper

5. SARS-CoV-2 RBD Conjugated to Polyglucin, Spermidine, and dsRNA Elicits a Strong Immune Response in Mice

6. Natural IgG against S-Protein and RBD of SARS-CoV-2 Do Not Bind and Hydrolyze DNA and Are Not Autoimmune

7. Antibodies to the Spike Protein Receptor-Binding Domain of SARS-CoV-2 at 4–13 Months after COVID-19

8. Detection of Viral Particles Using a Biosensor

9. Are Hamsters a Suitable Model for Evaluating the Immunogenicity of RBD-Based Anti-COVID-19 Subunit Vaccines?

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

11. Self-Assembled Particles Combining SARS-CoV-2 RBD Protein and RBD DNA Vaccine Induce Synergistic Enhancement of the Humoral Response in Mice

12. Comparative Immunogenicity of the Recombinant Receptor-Binding Domain of Protein S SARS-CoV-2 Obtained in Prokaryotic and Mammalian Expression Systems

13. Laboratory Preparation of Biosensor Based on Silicon Nanowire Field-Effect Transistor for Virus Indication

14. Indication of the Coronavirus Model Using a Nanowire Biosensor

15. Cover Feature: Structure‐ and Interaction‐Based Design of Anti‐SARS‐CoV‐2 Aptamers (Chem. Eur. J. 12/2022).

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

17. Structure- and Interaction-Based Design of Anti-SARS-CoV-2 Aptamers.

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