Your search keyword '"Malla, Tika R."' showing total 28 results

1. Accelerating Inhibitor Discovery With A Deep Generative Foundation Model: Validation for SARS-CoV-2 Drug Targets

Author

Chenthamarakshan, Vijil, Hoffman, Samuel C., Owen, C. David, Lukacik, Petra, Strain-Damerell, Claire, Fearon, Daren, Malla, Tika R., Tumber, Anthony, Schofield, Christopher J., Duyvesteyn, Helen M. E., Dejnirattisai, Wanwisa, Carrique, Loic, Walter, Thomas S., Screaton, Gavin R., Matviiuk, Tetiana, Mojsilovic, Aleksandra, Crain, Jason, Walsh, Martin A., Stuart, David I., and Das, Payel

Subjects

Quantitative Biology - Quantitative Methods, Computer Science - Machine Learning, Quantitative Biology - Biomolecules, Statistics - Machine Learning

Abstract

The discovery of novel inhibitor molecules for emerging drug-target proteins is widely acknowledged as a challenging inverse design problem: Exhaustive exploration of the vast chemical search space is impractical, especially when the target structure or active molecules are unknown. Here we validate experimentally the broad utility of a deep generative framework trained at-scale on protein sequences, small molecules, and their mutual interactions -- that is unbiased toward any specific target. As demonstrators, we consider two dissimilar and relevant SARS-CoV-2 targets: the main protease and the spike protein (receptor binding domain, RBD). To perform target-aware design of novel inhibitor molecules, a protein sequence-conditioned sampling on the generative foundation model is performed. Despite using only the target sequence information, and without performing any target-specific adaptation of the generative model, micromolar-level inhibition was observed in in vitro experiments for two candidates out of only four synthesized for each target. The most potent spike RBD inhibitor also exhibited activity against several variants in live virus neutralization assays. These results therefore establish that a single, broadly deployable generative foundation model for accelerated hit discovery is effective and efficient, even in the most general case where neither target structure nor binder information is available., Comment: Revised title, abstract, and text; additional figures

Published

2022

2. In vitro selection of macrocyclic peptide inhibitors containing cyclic γ2,4-amino acids targeting the SARS-CoV-2 main protease

Author

Miura, Takashi, Malla, Tika R., Owen, C. David, Tumber, Anthony, Brewitz, Lennart, McDonough, Michael A., Salah, Eidarus, Terasaka, Naohiro, Katoh, Takayuki, Lukacik, Petra, Strain-Damerell, Claire, Mikolajek, Halina, Walsh, Martin A., Kawamura, Akane, Schofield, Christopher J., and Suga, Hiroaki

Published

2023

3. Faropenem reacts with serine and metallo-β-lactamases to give multiple products

Author

Lucic, Anka, Hinchliffe, Philip, Malla, Tika R., Tooke, Catherine L., Brem, Jürgen, Calvopiña, Karina, Lohans, Christopher T., Rabe, Patrick, McDonough, Michael A., Armistead, Timothy, Orville, Allen M., Spencer, James, and Schofield, Christopher J.

Published

2021

4. Cyclic β2,3-amino acids improve the serum stability of macrocyclic peptide inhibitors targeting the SARS-CoV-2 main protease

Author

Miura, Takashi, primary, Malla, Tika R, additional, Brewitz, Lennart, additional, Tumber, Anthony, additional, Salah, Eidarus, additional, Lee, Kang Ju, additional, Terasaka, Naohiro, additional, Owen, C David, additional, Strain-Damerell, Claire, additional, Lukacik, Petra, additional, Walsh, Martin A, additional, Kawamura, Akane, additional, Schofield, Christopher J, additional, Katoh, Takayuki, additional, and Suga, Hiroaki, additional

Published

2024

5. Publisher Correction: Bispecific repurposed medicines targeting the viral and immunological arms of COVID-19

Author

Redhead, Martin A., Owen, C. David, Brewitz, Lennart, Collette, Amelia H., Lukacik, Petra, Strain-Damerell, Claire, Robinson, Sean W., Collins, Patrick M., Schäfer, Philipp, Swindells, Mark, Radoux, Chris J., Hopkins, Iva Navratilova, Fearon, Daren, Douangamath, Alice, von Delft, Frank, Malla, Tika R., Vangeel, Laura, Vercruysse, Thomas, Thibaut, Jan, Leyssen, Pieter, Nguyen, Tu-Trinh, Hull, Mitchell, Tumber, Anthony, Hallett, David J., Schofield, Christopher J., Stuart, David I., Hopkins, Andrew L., and Walsh, Martin A.

Published

2021

6. Bispecific repurposed medicines targeting the viral and immunological arms of COVID-19

Author

Redhead, Martin A., Owen, C. David, Brewitz, Lennart, Collette, Amelia H., Lukacik, Petra, Strain-Damerell, Claire, Robinson, Sean W., Collins, Patrick M., Schäfer, Philipp, Swindells, Mark, Radoux, Chris J., Hopkins, Iva Navratilova, Fearon, Daren, Douangamath, Alice, von Delft, Frank, Malla, Tika R., Vangeel, Laura, Vercruysse, Thomas, Thibaut, Jan, Leyssen, Pieter, Nguyen, Tu-Trinh, Hull, Mitchell, Tumber, Anthony, Hallett, David J., Schofield, Christopher J., Stuart, David I., Hopkins, Andrew L., and Walsh, Martin A.

Published

2021

7. Alkyne Derivatives of SARS-CoV-2 Main Protease Inhibitors Including Nirmatrelvir Inhibit by Reacting Covalently with the Nucleophilic Cysteine

Author

Brewitz, Lennart, primary, Dumjahn, Leo, additional, Zhao, Yilin, additional, Owen, C. David, additional, Laidlaw, Stephen M., additional, Malla, Tika R., additional, Nguyen, Dung, additional, Lukacik, Petra, additional, Salah, Eidarus, additional, Crawshaw, Adam D., additional, Warren, Anna J., additional, Trincao, Jose, additional, Strain-Damerell, Claire, additional, Carroll, Miles W., additional, Walsh, Martin A., additional, and Schofield, Christopher J., additional

Published

2023

8. SARS-CoV-2 infects the human kidney and drives fibrosis in kidney organoids

Author

Achdout, Hagit, Aimon, Anthony, Bar-David, Elad, Barr, Haim, Ben-Shmuel, Amir, Bennett, James, Boby, Melissa L., Borden, Bruce, Bowman, Gregory R., Brun, Juliane, BVNBS, Sarma, Calmiano, Mark, Carbery, Anna, Cattermole, Emma, Chernychenko, Eugene, Choder, John D., Clyde, Austin, Coffland, Joseph E., Cohen, Galit, Cole, Jason, Contini, Alessandro, Cox, Lisa, Cvitkovic, Milan, Dias, Alex, Donckers, Kim, Dotson, David L., Douangamath, Alica, Duberstein, Shirly, Dudgeon, Tim, Dunnett, Louise, Eastman, Peter K., Erez, Noam, Eyermann, Charles J., Fairhead, Mike, Fate, Gwen, Fearon, Daren, Federov, Oleg, Ferla, Matteo, Fernandes, Rafaela S., Ferrins, Lori, Foster, Richard, Foster, Holly, Gabizon, Ronen, Garcia-Sastre, Adolfo, Gawriljuk, Victor O., Gehrtz, Paul, Gileadi, Carina, Giroud, Charline, Glass, William G., Glen, Robert, Itai glinert, Godoy, Andre S., Gorichko, Marian, Gorrie-Stone, Tyler, Griffen, Ed J., Hart, Storm Hassell, Heer, Jag, Henry, Micheal, Hill, Michelle, Horrell, Sam, Hurley, Matthew F.D., Israely, Tomer, Jajack, Andrew, Jnoff, Eric, Jochmans, Dirk, John, Tobias, De Jonghe, Steven, Kantsadi, Anastassia L., Kenny, Peter W., Kiappes, J.L., Koekemoer, Lizbe, Kovar, Boris, Krojer, Tobias, Lee, Alpha A., Lefker, Bruce A., Levy, Haim, London, Nir, Lukacik, Petra, Macdonald, Hannah Bruce, Maclean, Beth, Malla, Tika R., Matviiuk, Tatiana, McCorkindale, Willam, McGovern, Briana L., Melamed, Sharon, Michurin, Oleg, Mikolajek, Halina, Milne, Bruce F., Morris, Aaron, Morris, Garret M., Morwitzer, Melody Jane, Moustakas, Demetri, Nakamura, Aline M., Neto, Jose Brandao, Neyts, Johan, Nguyen, Luong, Noske, Gabriela D., Oleinikovas, Vladas, Oliva, Glaucius, Overheul, Gijs J., Owen, David, Psenak, Vladimir, Pai, Ruby, Pan, Jin, Paran, Nir, Perry, Benjamin, Pingle, Maneesh, Pinjari, Jakir, Politi, Boaz, Powell, Ailsa, Puni, Reut, Rangel, Victor L., Reddi, Ranbabu N., Reid, St Patrick, Resnick, Efrat, Ripka, Emily Grace, Robinson, Matthew C., Robinson, Ralph P., Rodriguez-Guerra, Jaime, Rosales, Romel, Rufa, Dominic, Schofield, Chris, Shafeev, Mikhail, Shaikh, Aarif, Shi, Jiye, Shurrush, Khriesto, Sing, Sukrit, Sittner, Assa, Skyner, Rachael, Smalley, Adam, Smilova, Mihaela D., Solmesky, Leonardo J., Spencer, John, Strain-Damarell, Claire, Swamy, Vishwanath, Tamir, Hadas, Tennant, Rachael, Thompson, Warren, Thompson, Andrew, Tomasia, Susana, Tumber, Anthony, Vakonakis, Ioannis, van Rij, Ronald P., van Geel, Laura, Varghese, Finny S., Vaschetto, Mariana, Vitner, Einat B., Voelz, Vincent, Volkamer, Andra, von Delft, Frank, von Delft, Annette, Walsh, Martin, Ward, Walter, Weatherall, Charlie, Weiss, Shay, White, Kris M., Wild, Conor Francis, Wittmann, Matthew, Wright, Nathan, Yahalom-Ronen, Yfat, Zaidmann, Daniel, Zidane, Hadeer, Zitzmann, Nicole, Jansen, Jitske, Reimer, Katharina C., Nagai, James S., de Beer, Marit, Roverts, Rona, Daviran, Deniz, Fermin, Liline A.S., Willemsen, Brigith, Beukenboom, Marcel, Djudjaj, Sonja, von Stillfried, Saskia, van Eijk, Larissa E., Mastik, Mirjam, Bulthuis, Marian, Dunnen, Wilfred den, van Goor, Harry, Hillebrands, Jan-Luuk, Triana, Sergio H., Alexandrov, Theodore, Timm, Marie-Cherelle, van den Berge, Bartholomeus T., van den Broek, Martijn, Nlandu, Quincy, Heijnert, Joelle, Bindels, Eric M.J., Hoogenboezem, Remco M., Mooren, Fieke, Kuppe, Christoph, Miesen, Pascal, Grünberg, Katrien, Ijzermans, Ties, Steenbergen, Eric J., Czogalla, Jan, Schreuder, Michiel F., Sommerdijk, Nico, Akiva, Anat, Boor, Peter, Puelles, Victor G., Floege, Jürgen, Huber, Tobias B., Costa, Ivan G., Schneider, Rebekka K., Smeets, Bart, and Kramann, Rafael

Published

2022

9. Penicillin Derivatives Inhibit the SARS-CoV-2 Main Protease by Reaction with Its Nucleophilic Cysteine

Author

Malla, Tika R., primary, Brewitz, Lennart, additional, Muntean, Dorian-Gabriel, additional, Aslam, Hiba, additional, Owen, C. David, additional, Salah, Eidarus, additional, Tumber, Anthony, additional, Lukacik, Petra, additional, Strain-Damerell, Claire, additional, Mikolajek, Halina, additional, Walsh, Martin A., additional, and Schofield, Christopher J., additional

Published

2022

10. Studies on the Reactions of Biapenem with VIM Metallo β-Lactamases and the Serine β-Lactamase KPC-2

Author

Lucic, Anka, primary, Malla, Tika R., additional, Calvopiña, Karina, additional, Tooke, Catherine L., additional, Brem, Jürgen, additional, McDonough, Michael A., additional, Spencer, James, additional, and Schofield, Christopher J., additional

Published

2022

11. Mass Spectrometric Assays Reveal Discrepancies in Inhibition Profiles for the SARS‐CoV‐2 Papain‐Like Protease

Author

Brewitz, Lennart, primary, Kamps, Jos J. A. G., additional, Lukacik, Petra, additional, Strain‐Damerell, Claire, additional, Zhao, Yilin, additional, Tumber, Anthony, additional, Malla, Tika R., additional, Orville, Allen M., additional, Walsh, Martin A., additional, and Schofield, Christopher J., additional

Published

2022

12. Structure‐Activity Studies Reveal Scope for Optimisation of Ebselen‐Type Inhibition of SARS‐CoV‐2 Main Protease

Author

Thun‐Hohenstein, Siegfried T. D., primary, Suits, Timothy F., additional, Malla, Tika R., additional, Tumber, Anthony, additional, Brewitz, Lennart, additional, Choudhry, Hani, additional, Salah, Eidarus, additional, and Schofield, Christopher J., additional

Published

2021

13. Targeting the Mycobacterium tuberculosis transpeptidase LdtMt2 with cysteine-reactive inhibitors including ebselen† †Electronic supplementary information (ESI) available: Experimental details, IC50 curves, mass spectra, electron density maps. See DOI: 10.1039/c9cc04145a

Author

de Munnik, Mariska, Lohans, Christopher T., Lang, Pauline A., Langley, Gareth W., Malla, Tika R., Tumber, Anthony, Schofield, Christopher J., and Brem, Jürgen

Subjects

Azoles, Molecular Docking Simulation, Chemistry, Organoselenium Compounds, Peptidyl Transferases, Antitubercular Agents, Benzene Derivatives, Humans, Tuberculosis, Cysteine, Mycobacterium tuberculosis, Enzyme Inhibitors, Isoindoles

Abstract

Inhibitors targeting the conserved nucleophilic cysteine of the mycobacterial l,d-transpeptidases are a potential strategy for the treatment of tuberculosis., The l,d-transpeptidases (Ldts) are promising antibiotic targets for treating tuberculosis. We report screening of cysteine-reactive inhibitors against LdtMt2 from Mycobacterium tuberculosis. Structural studies on LdtMt2 with potent inhibitor ebselen reveal opening of the benzisoselenazolone ring by a nucleophilic cysteine, forming a complex involving extensive hydrophobic interactions with a substrate-binding loop.

Published

2019

14. Discovery of SARS-CoV-2 Mpro Peptide Inhibitors from Modelling Substrate and Ligand Binding

Author

Chan, H. T. Henry, primary, Moesser, Marc A., additional, Walters, Rebecca K., additional, Malla, Tika R., additional, Twidale, Rebecca M., additional, John, Tobias, additional, Deeks, Helen M., additional, Johnston-Wood, Tristan, additional, Mikhailov, Victor, additional, Sessions, Richard B., additional, Dawson, William, additional, Salah, Eidarus, additional, Lukacik, Petra, additional, Strain-Damerell, Claire, additional, Owen, C. David, additional, Nakajima, Takahito, additional, Świderek, Katarzyna, additional, Lodola, Alessio, additional, Moliner, Vicent, additional, Glowacki, David R., additional, Walsh, Martin A., additional, Schofield, Christopher J., additional, Genovese, Luigi, additional, Shoemark, Deborah K., additional, Mulholland, Adrian J., additional, Duarte, Fernanda, additional, and Morris, Garrett M., additional

Published

2021

15. Mass spectrometry reveals potential of β-lactams as SARS-CoV-2 Mpro inhibitors

Author

Malla, Tika R., primary, Tumber, Anthony, additional, John, Tobias, additional, Brewitz, Lennart, additional, Strain-Damerell, Claire, additional, Owen, C David, additional, Lukacik, Petra, additional, Chan, H. T. Henry, additional, Maheswaran, Pratheesh, additional, Salah, Eidarus, additional, Duarte, Fernanda, additional, Yang, Haitao, additional, Rao, Zihe, additional, Walsh, Martin A., additional, and Schofield, Christopher J., additional

Published

2021

16. Allosteric Inhibition of the SARS‐CoV‐2 Main Protease: Insights from Mass Spectrometry Based Assays**

Author

El‐Baba, Tarick J., primary, Lutomski, Corinne A., additional, Kantsadi, Anastassia L., additional, Malla, Tika R., additional, John, Tobias, additional, Mikhailov, Victor, additional, Bolla, Jani R., additional, Schofield, Christopher J., additional, Zitzmann, Nicole, additional, Vakonakis, Ioannis, additional, and Robinson, Carol V., additional

Published

2020

17. Allosteric inhibition of the SARS-CoV-2 main protease – insights from mass spectrometry-based assays

Author

El-Baba, Tarick J., primary, Lutomski, Corinne A., additional, Kantsadi, Anastassia L., additional, Malla, Tika R., additional, John, Tobias, additional, Mikhailov, Victor, additional, Bolla, Jani R., additional, Schofield, Christopher J., additional, Zitzmann, Nicole, additional, Vakonakis, Ioannis, additional, and Robinson, Carol V., additional

Published

2020

18. Expanding the Repertoire of Low‐Molecular‐Weight Pentafluorosulfanyl‐Substituted Scaffolds.

Author

Jose, Arathy, Guest, Daniel, LeGay, Remi, Tizzard, Graham J., Coles, Simon J., Derveni, Mariliza, Wright, Edward, Marrison, Lester, Lee, Alpha A., Morris, Aaron, Robinson, Matt, von Delft, Frank, Fearon, Daren, Koekemoer, Lizbé, Matviuk, Tetiana, Aimon, Anthony, Schofield, Christopher J., Malla, Tika R., London, Nir, and Greenland, Barnaby W.

Published

2022

19. Structure‐Activity Studies Reveal Scope for Optimisation of Ebselen‐Type Inhibition of SARS‐CoV‐2 Main Protease.

Author

Thun‐Hohenstein, Siegfried T. D., Suits, Timothy F., Malla, Tika R., Tumber, Anthony, Brewitz, Lennart, Choudhry, Hani, Salah, Eidarus, and Schofield, Christopher J.

Published

2022

20. Discovery of SARS-CoV-2 Mpro peptide inhibitors from modelling substrate and ligand binding.

Author

Chan, H. T. Henry, Moesser, Marc A., Walters, Rebecca K., Malla, Tika R., Twidale, Rebecca M., John, Tobias, Deeks, Helen M., Johnston-Wood, Tristan, Mikhailov, Victor, Sessions, Richard B., Dawson, William, Salah, Eidarus, Lukacik, Petra, Strain-Damerell, Claire, Owen, C. David, Nakajima, Takahito, Świderek, Katarzyna, Lodola, Alessio, Moliner, Vicent, and Glowacki, David R.

Published

2021

21. Non-Hydrolytic β-Lactam Antibiotic Fragmentation byl,d-Transpeptidases and Serine β-Lactamase Cysteine Variants

Author

Lohans, Christopher T., primary, Chan, H. T. Henry, additional, Malla, Tika R., additional, Kumar, Kiran, additional, Kamps, Jos J. A. G., additional, McArdle, Darius J. B., additional, van Groesen, Emma, additional, de Munnik, Mariska, additional, Tooke, Catherine L., additional, Spencer, James, additional, Paton, Robert S., additional, Brem, Jürgen, additional, and Schofield, Christopher J., additional

Published

2019

22. Mass spectrometry reveals potential of β-lactams as SARS-CoV-2 Mpro inhibitors.

Author

Malla, Tika R., Tumber, Anthony, John, Tobias, Brewitz, Lennart, Strain-Damerell, Claire, Owen, C David, Lukacik, Petra, Chan, H. T. Henry, Maheswaran, Pratheesh, Salah, Eidarus, Duarte, Fernanda, Yang, Haitao, Rao, Zihe, Walsh, Martin A., and Schofield, Christopher J.

Subjects

*MASS spectrometry, *SARS-CoV-2, *SOLID phase extraction

Abstract

The main viral protease (Mpro) of SARS-CoV-2 is a nucleophilic cysteine hydrolase and a current target for anti-viral chemotherapy. We describe a high-throughput solid phase extraction coupled to mass spectrometry Mpro assay. The results reveal some β-lactams, including penicillin esters, are active site reacting Mpro inhibitors, thus highlighting the potential of acylating agents for Mpro inhibition. [ABSTRACT FROM AUTHOR]

Published

2021

23. Targeting the Mycobacterium tuberculosis transpeptidase LdtMt2 with cysteine-reactive inhibitors including ebselen.

Author

de Munnik, Mariska, Lohans, Christopher T., Lang, Pauline A., Langley, Gareth W., Malla, Tika R., Tumber, Anthony, Schofield, Christopher J., and Brem, Jürgen

Subjects

MYCOBACTERIUM tuberculosis, PEPTIDASE, HYDROPHOBIC interactions, TUBERCULOSIS, CYSTEINE, EBSELEN

Abstract

The L,D -transpeptidases (Ldts) are promising antibiotic targets for treating tuberculosis. We report screening of cysteine-reactive inhibitors against LdtMt2 from Mycobacterium tuberculosis. Structural studies on LdtMt2 with potent inhibitor ebselen reveal opening of the benzisoselenazolone ring by a nucleophilic cysteine, forming a complex involving extensive hydrophobic interactions with a substrate-binding loop. [ABSTRACT FROM AUTHOR]

Published

2019

24. Non‐Hydrolytic β‐Lactam Antibiotic Fragmentation by l,d‐Transpeptidases and Serine β‐Lactamase Cysteine Variants.

Author

Lohans, Christopher T., Chan, H. T. Henry, Malla, Tika R., Kumar, Kiran, Kamps, Jos J. A. G., McArdle, Darius J. B., van Groesen, Emma, de Munnik, Mariska, Tooke, Catherine L., Spencer, James, Paton, Robert S., Brem, Jürgen, and Schofield, Christopher J.

Subjects

CYSTEINE, BETA lactam antibiotics, NUCLEOPHILIC reactions, AMINO acid residues, INTERMEDIATES (Chemistry), REACTIVITY (Chemistry)

Abstract

Copyright of Angewandte Chemie is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

25. Accelerating drug target inhibitor discovery with a deep generative foundation model.

Author

Chenthamarakshan, Vijil, Hoffman, Samuel C., Owen, C. David, Lukacik, Petra, Strain-Damerell, Claire, Fearon, Daren, Malla, Tika R., Tumber, Anthony, Schofield, Christopher J., Duyvesteyn, Helen M. E., Dejnirattisai, Wanwisa, Carrique, Loic, Walter, Thomas S., Screaton, Gavin R., Matviiuk, Tetiana, Mojsilovic, Aleksandra, Crain, Jason, Walsh, Martin A., Stuart, David I., and Das, Payel

Subjects

*ACYL chlorides, *BORED piles, *SARS-CoV-2, *DRUG target, *FILTERS & filtration

Abstract

The article presents a study which explores about accelerating drug target inhibitor discovery with a deep generative foundation model. It mentions that results of a study establish that a single, broadly deployable generative foundation model for accelerated inhibitor discovery is effective and efficient, even in the absence of target structure or binder information.

Published

2023

26. Cyclic β 2,3 -amino acids improve the serum stability of macrocyclic peptide inhibitors targeting the SARS-CoV-2 main protease.

Author

Miura T, Malla TR, Brewitz L, Tumber A, Salah E, Lee KJ, Terasaka N, Owen CD, Strain-Damerell C, Lukacik P, Walsh MA, Kawamura A, Schofield CJ, Katoh T, and Suga H

Abstract

Due to their constrained conformations, cyclic β 2,3 -amino acids (cβAA) are key building blocks that can fold peptides into compact and rigid structures, improving peptidase resistance and binding affinity to target proteins, due to their constrained conformations. Although the translation efficiency of cβAAs is generally low, our engineered tRNA, referred to as tRNA Pro1E2 , enabled efficient incorporation of cβAAs into peptide libraries using the flexible in vitro translation (FIT) system. Here we report on the design and application of a macrocyclic peptide library incorporating 3 kinds of cβAAs: (1 R ,2 S )-2-aminocyclopentane carboxylic acid (β 1 ), (1 S ,2 S )-2-aminocyclohexane carboxylic acid (β 2 ), and (1 R ,2 R )-2-aminocyclopentane carboxylic acid. This library was applied to an in vitro selection against the SARS-CoV-2 main protease (M pro ). The resultant peptides, BM3 and BM7, bearing one β 2 and two β 1 , exhibited potent inhibitory activities with IC 50 values of 40 and 20 nM, respectively. BM3 and BM7 also showed remarkable serum stability with half-lives of 48 and >168 h, respectively. Notably, BM3A and BM7A, wherein the cβAAs were substituted with alanine, lost their inhibitory activities against M pro and displayed substantially shorter serum half-lives. This observation underscores the significant contribution of cβAA to the activity and stability of peptides. Overall, our results highlight the potential of cβAA in generating potent and highly stable macrocyclic peptides with drug-like properties., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Chemical Society of Japan.)

Published

2024

27. Open science discovery of potent noncovalent SARS-CoV-2 main protease inhibitors.

Author

Boby ML, Fearon D, Ferla M, Filep M, Koekemoer L, Robinson MC, Chodera JD, Lee AA, London N, von Delft A, von Delft F, Achdout H, Aimon A, Alonzi DS, Arbon R, Aschenbrenner JC, Balcomb BH, Bar-David E, Barr H, Ben-Shmuel A, Bennett J, Bilenko VA, Borden B, Boulet P, Bowman GR, Brewitz L, Brun J, Bvnbs S, Calmiano M, Carbery A, Carney DW, Cattermole E, Chang E, Chernyshenko E, Clyde A, Coffland JE, Cohen G, Cole JC, Contini A, Cox L, Croll TI, Cvitkovic M, De Jonghe S, Dias A, Donckers K, Dotson DL, Douangamath A, Duberstein S, Dudgeon T, Dunnett LE, Eastman P, Erez N, Eyermann CJ, Fairhead M, Fate G, Fedorov O, Fernandes RS, Ferrins L, Foster R, Foster H, Fraisse L, Gabizon R, García-Sastre A, Gawriljuk VO, Gehrtz P, Gileadi C, Giroud C, Glass WG, Glen RC, Glinert I, Godoy AS, Gorichko M, Gorrie-Stone T, Griffen EJ, Haneef A, Hassell Hart S, Heer J, Henry M, Hill M, Horrell S, Huang QYJ, Huliak VD, Hurley MFD, Israely T, Jajack A, Jansen J, Jnoff E, Jochmans D, John T, Kaminow B, Kang L, Kantsadi AL, Kenny PW, Kiappes JL, Kinakh SO, Kovar B, Krojer T, La VNT, Laghnimi-Hahn S, Lefker BA, Levy H, Lithgo RM, Logvinenko IG, Lukacik P, Macdonald HB, MacLean EM, Makower LL, Malla TR, Marples PG, Matviiuk T, McCorkindale W, McGovern BL, Melamed S, Melnykov KP, Michurin O, Miesen P, Mikolajek H, Milne BF, Minh D, Morris A, Morris GM, Morwitzer MJ, Moustakas D, Mowbray CE, Nakamura AM, Neto JB, Neyts J, Nguyen L, Noske GD, Oleinikovas V, Oliva G, Overheul GJ, Owen CD, Pai R, Pan J, Paran N, Payne AM, Perry B, Pingle M, Pinjari J, Politi B, Powell A, Pšenák V, Pulido I, Puni R, Rangel VL, Reddi RN, Rees P, Reid SP, Reid L, Resnick E, Ripka EG, Robinson RP, Rodriguez-Guerra J, Rosales R, Rufa DA, Saar K, Saikatendu KS, Salah E, Schaller D, Scheen J, Schiffer CA, Schofield CJ, Shafeev M, Shaikh A, Shaqra AM, Shi J, Shurrush K, Singh S, Sittner A, Sjö P, Skyner R, Smalley A, Smeets B, Smilova MD, Solmesky LJ, Spencer J, Strain-Damerell C, Swamy V, Tamir H, Taylor JC, Tennant RE, Thompson W, Thompson A, Tomásio S, Tomlinson CWE, Tsurupa IS, Tumber A, Vakonakis I, van Rij RP, Vangeel L, Varghese FS, Vaschetto M, Vitner EB, Voelz V, Volkamer A, Walsh MA, Ward W, Weatherall C, Weiss S, White KM, Wild CF, Witt KD, Wittmann M, Wright N, Yahalom-Ronen Y, Yilmaz NK, Zaidmann D, Zhang I, Zidane H, Zitzmann N, and Zvornicanin SN

Subjects

Humans, Molecular Docking Simulation, Structure-Activity Relationship, Crystallography, X-Ray, Coronavirus 3C Proteases antagonists & inhibitors, Coronavirus 3C Proteases chemistry, SARS-CoV-2, Drug Discovery, Coronavirus Protease Inhibitors chemical synthesis, Coronavirus Protease Inhibitors chemistry, Coronavirus Protease Inhibitors pharmacology, COVID-19 Drug Treatment

Abstract

We report the results of the COVID Moonshot, a fully open-science, crowdsourced, and structure-enabled drug discovery campaign targeting the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) main protease. We discovered a noncovalent, nonpeptidic inhibitor scaffold with lead-like properties that is differentiated from current main protease inhibitors. Our approach leveraged crowdsourcing, machine learning, exascale molecular simulations, and high-throughput structural biology and chemistry. We generated a detailed map of the structural plasticity of the SARS-CoV-2 main protease, extensive structure-activity relationships for multiple chemotypes, and a wealth of biochemical activity data. All compound designs (>18,000 designs), crystallographic data (>490 ligand-bound x-ray structures), assay data (>10,000 measurements), and synthesized molecules (>2400 compounds) for this campaign were shared rapidly and openly, creating a rich, open, and intellectual property-free knowledge base for future anticoronavirus drug discovery.

Published

2023

28. Discovery of SARS-CoV-2 M pro peptide inhibitors from modelling substrate and ligand binding.

Author

Chan HTH, Moesser MA, Walters RK, Malla TR, Twidale RM, John T, Deeks HM, Johnston-Wood T, Mikhailov V, Sessions RB, Dawson W, Salah E, Lukacik P, Strain-Damerell C, Owen CD, Nakajima T, Świderek K, Lodola A, Moliner V, Glowacki DR, Spencer J, Walsh MA, Schofield CJ, Genovese L, Shoemark DK, Mulholland AJ, Duarte F, and Morris GM

Abstract

The main protease (M pro ) of SARS-CoV-2 is central to viral maturation and is a promising drug target, but little is known about structural aspects of how it binds to its 11 natural cleavage sites. We used biophysical and crystallographic data and an array of biomolecular simulation techniques, including automated docking, molecular dynamics (MD) and interactive MD in virtual reality, QM/MM, and linear-scaling DFT, to investigate the molecular features underlying recognition of the natural M pro substrates. We extensively analysed the subsite interactions of modelled 11-residue cleavage site peptides, crystallographic ligands, and docked COVID Moonshot-designed covalent inhibitors. Our modelling studies reveal remarkable consistency in the hydrogen bonding patterns of the natural M pro substrates, particularly on the N-terminal side of the scissile bond. They highlight the critical role of interactions beyond the immediate active site in recognition and catalysis, in particular plasticity at the S2 site. Building on our initial M pro -substrate models, we used predictive saturation variation scanning (PreSaVS) to design peptides with improved affinity. Non-denaturing mass spectrometry and other biophysical analyses confirm these new and effective 'peptibitors' inhibit M pro competitively. Our combined results provide new insights and highlight opportunities for the development of M pro inhibitors as anti-COVID-19 drugs., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021