Your search keyword '"Daniel W. Kneller"' showing total 39 results

1. Insights into the mechanism of SARS-CoV-2 main protease autocatalytic maturation from model precursors

Author

Annie Aniana, Nashaat T. Nashed, Rodolfo Ghirlando, Leighton Coates, Daniel W. Kneller, Andrey Kovalevsky, and John M. Louis

Subjects

Biology (General), QH301-705.5

Abstract

Abstract A critical step for SARS-CoV-2 assembly and maturation involves the autoactivation of the main protease (MProWT) from precursor polyproteins. Upon expression, a model precursor of MProWT mediates its own release at its termini rapidly to yield a mature dimer. A construct with an E290A mutation within MPro exhibits time dependent autoprocessing of the accumulated precursor at the N-terminal nsp4/nsp5 site followed by the C-terminal nsp5/nsp6 cleavage. In contrast, a precursor containing E290A and R298A mutations (MProM) displays cleavage only at the nsp4/nsp5 site to yield an intermediate monomeric product, which is cleaved at the nsp5/nsp6 site only by MProWT. MProM and the catalytic domain (MPro1-199) fused to the truncated nsp4 region also show time-dependent conversion in vitro to produce MProM and MPro1-199, respectively. The reactions follow first-order kinetics indicating that the nsp4/nsp5 cleavage occurs via an intramolecular mechanism. These results support a mechanism involving an N-terminal intramolecular cleavage leading to an increase in the dimer population and followed by an intermolecular cleavage at the C-terminus. Thus, targeting the predominantly monomeric MPro precursor for inhibition may lead to the identification of potent drugs for treatment.

Published

2023

2. Autoprocessing and oxyanion loop reorganization upon GC373 and nirmatrelvir binding of monomeric SARS-CoV-2 main protease catalytic domain

Author

Nashaat T. Nashed, Daniel W. Kneller, Leighton Coates, Rodolfo Ghirlando, Annie Aniana, Andrey Kovalevsky, and John M. Louis

Subjects

Biology (General), QH301-705.5

Abstract

Structural characterization and catalytic activity of SARS-CoV-2 main protease reveal minimal interface regions enabling dimer formation driven by inhibitor-induced conformational changes of the oxyanion loop.

Published

2022

3. Structural and functional characterization of NEMO cleavage by SARS-CoV-2 3CLpro

Author

Mikhail A. Hameedi, Erica T. Prates, Michael R. Garvin, Irimpan I. Mathews, B. Kirtley Amos, Omar Demerdash, Mark Bechthold, Mamta Iyer, Simin Rahighi, Daniel W. Kneller, Andrey Kovalevsky, Stephan Irle, Van-Quan Vuong, Julie C. Mitchell, Audrey Labbe, Stephanie Galanie, Soichi Wakatsuki, and Daniel Jacobson

Subjects

Science

Abstract

The authors report crystallographic and computational studies that detail how SARS-CoV-2 3CLpro cleaves the host NF-κB Essential Modulator in addition to its canonical viral substrates. The association with the high fitness of SARS-CoV-2 in humans is discussed.

Published

2022

4. Covalent narlaprevir- and boceprevir-derived hybrid inhibitors of SARS-CoV-2 main protease

Author

Daniel W. Kneller, Hui Li, Gwyndalyn Phillips, Kevin L. Weiss, Qiu Zhang, Mark A. Arnould, Colleen B. Jonsson, Surekha Surendranathan, Jyothi Parvathareddy, Matthew P. Blakeley, Leighton Coates, John M. Louis, Peter V. Bonnesen, and Andrey Kovalevsky

Subjects

Science

Abstract

Three covalent hybrid inhibitors of SARS-CoV-2 main protease (Mpro) have been designed and compared to Pfizer’s nirmatrelvir (PF-07321332), providing atomic and thermodynamic details of their binding to the enzyme, and antiviral potency.

Published

2022

5. Michaelis-like complex of SARS-CoV-2 main protease visualized by room-temperature X-ray crystallography

Author

Daniel W. Kneller, Qiu Zhang, Leighton Coates, John M. Louis, and Andrey Kovalevsky

Subjects

sars-cov-2, 3cl protease, main protease, catalytic mechanism, c145a mutant, enzyme–substrate complex, room-temperature x-ray crystallography, Crystallography, QD901-999

Abstract

SARS-CoV-2 emerged at the end of 2019 to cause an unprecedented pandemic of the deadly respiratory disease COVID-19 that continues to date. The viral main protease (Mpro) is essential for SARS-CoV-2 replication and is therefore an important drug target. Understanding the catalytic mechanism of Mpro, a cysteine protease with a catalytic site comprising the noncanonical Cys145–His41 dyad, can help in guiding drug design. Here, a 2.0 Å resolution room-temperature X-ray crystal structure is reported of a Michaelis-like complex of Mpro harboring a single inactivating mutation C145A bound to the octapeptide Ac-SAVLQSGF-CONH2 corresponding to the nsp4/nsp5 autocleavage site. The peptide substrate is unambiguously defined in subsites S5 to S3′ by strong electron density. Superposition of the Michaelis-like complex with the neutron structure of substrate-free Mpro demonstrates that the catalytic site is inherently pre-organized for catalysis prior to substrate binding. Induced fit to the substrate is driven by P1 Gln binding in the predetermined subsite S1 and rearrangement of subsite S2 to accommodate P2 Leu. The Michaelis-like complex structure is ideal for in silico modeling of the SARS-CoV-2 Mpro catalytic mechanism.

Published

2021

6. Room-temperature X-ray crystallography reveals the oxidation and reactivity of cysteine residues in SARS-CoV-2 3CL Mpro: insights into enzyme mechanism and drug design

Author

Daniel W. Kneller, Gwyndalyn Phillips, Hugh M. O'Neill, Kemin Tan, Andrzej Joachimiak, Leighton Coates, and Andrey Kovalevsky

Subjects

room-temperature x-ray crystallography, sars-cov-2, 3cl main protease, 3cl mpro, cysteine oxidation, protonation state, enzyme mechanism, drug design, Crystallography, QD901-999

Abstract

The emergence of the novel coronavirus SARS-CoV-2 has resulted in a worldwide pandemic not seen in generations. Creating treatments and vaccines to battle COVID-19, the disease caused by the virus, is of paramount importance in order to stop its spread and save lives. The viral main protease, 3CL Mpro, is indispensable for the replication of SARS-CoV-2 and is therefore an important target for the design of specific protease inhibitors. Detailed knowledge of the structure and function of 3CL Mpro is crucial to guide structure-aided and computational drug-design efforts. Here, the oxidation and reactivity of the cysteine residues of the protease are reported using room-temperature X-ray crystallography, revealing that the catalytic Cys145 can be trapped in the peroxysulfenic acid oxidation state at physiological pH, while the other surface cysteines remain reduced. Only Cys145 and Cys156 react with the alkylating agent N-ethylmaleimide. It is suggested that the zwitterionic Cys145–His45 catalytic dyad is the reactive species that initiates catalysis, rather than Cys145-to-His41 proton transfer via the general acid–base mechanism upon substrate binding. The structures also provide insight into the design of improved 3CL Mpro inhibitors.

Published

2020

7. Structural plasticity of SARS-CoV-2 3CL Mpro active site cavity revealed by room temperature X-ray crystallography

Author

Daniel W. Kneller, Gwyndalyn Phillips, Hugh M. O’Neill, Robert Jedrzejczak, Lucy Stols, Paul Langan, Andrzej Joachimiak, Leighton Coates, and Andrey Kovalevsky

Subjects

Science

Abstract

The SARS-CoV-2 3CL main protease (3CL Mpro) is a chymotrypsin-like protease that facilitates the production of non-structural proteins, which are essential for viral replication and is therefore of great interest as a drug target. Here, the authors present the 2.30 Å room temperature crystal structure of ligand-free 3CL Mpro and compare it with the earlier determined low-temperature ligand-free and inhibitor-bound crystal structures.

Published

2020

8. Highly Drug-Resistant HIV‑1 Protease Mutant PRS17 Shows Enhanced Binding to Substrate Analogues

Author

Johnson Agniswamy, Daniel W. Kneller, Rowan Brothers, Yuan-Fang Wang, Robert W. Harrison, and Irene T. Weber

Subjects

Chemistry, QD1-999

Published

2019

9. AI-Accelerated Design of Targeted Covalent Inhibitors for SARS-CoV-2.

Author

Rajendra P. Joshi, Katherine J. Schultz, Jesse William Wilson, Agustin Kruel, Rohith Anand Varikoti, Chathuri J. Kombala, Daniel W. Kneller, Stephanie Galanie, Gwyndalyn Phillips, Qiu Zhang, Leighton Coates, Jyothi Parvathareddy, Surekha Surendranathan, Ying Kong, Austin Clyde, Arvind Ramanathan, Colleen B. Jonsson, Kristoffer R. Brandvold, Mowei Zhou, Martha S. Head, Andrey Kovalevsky, and Neeraj Kumar

Published

2023

10. High-Throughput Virtual Screening and Validation of a SARS-CoV-2 Main Protease Noncovalent Inhibitor.

Author

Austin Clyde, Stephanie Galanie, Daniel W. Kneller, Heng Ma, Yadu N. Babuji, Ben Blaiszik, Alexander Brace, Thomas S. Brettin, Kyle Chard, Ryan Chard, Leighton Coates, Ian T. Foster, Darin Hauner, Vilmos Kertesz, Neeraj Kumar, Hyungro Lee, Zhuozhao Li, André Merzky, Jurgen G. Schmidt, Li Tan, Mikhail Titov, Anda Trifan, Matteo Turilli, Hubertus Van Dam, Srinivas C. Chennubhotla, Shantenu Jha, Andrey Kovalevsky, Arvind Ramanathan, Martha S. Head, and Rick Stevens

Published

2022

11. Supercomputer-Based Ensemble Docking Drug Discovery Pipeline with Application to Covid-19.

Author

Atanu Acharya, Rupesh Agarwal, Matthew B. Baker, Jérôme Baudry, Debsindhu Bhowmik, Swen Böhm, Kendall G. Byler, Sam Yen-Chi Chen, Leighton Coates, Connor J. Cooper, Omar Demerdash, Isabella Daidone, John D. Eblen, Sally R. Ellingson, Stefano Forli, Jens Glaser, James C. Gumbart, John Gunnels, Oscar R. Hernandez, Stephan Irle, Daniel W. Kneller, Andrey Kovalevsky, Jeffrey M. Larkin, Travis J. Lawrence, Scott LeGrand, Shih-Hsien Liu, Julie C. Mitchell, Gilchan Park, Jerry M. Parks, Anna Pavlova, Loukas Petridis, Duncan Poole, Line Pouchard, Arvind Ramanathan, David M. Rogers, Diogo Santos-Martins, Aaron Scheinberg, Ada Sedova, Yue Shen, Jeremy C. Smith, Micholas Dean Smith, Carlos Soto 0003, Aristides Tsaris, Mathialakan Thavappiragasam, Andreas F. Tillack, Josh Vincent Vermaas, Van Quan Vuong, Junqi Yin, Shinjae Yoo, Mai Zahran, and Laura Zanetti Polzi

Published

2020

12. High-Throughput Virtual Screening and Validation of a SARS-CoV-2 Main Protease Noncovalent Inhibitor

Author

Andre Merzky, Ryan Chard, Jurgen G. Schmidt, Zhuozhao Li, Srinivas C. Chennubhotla, Heng Ma, Li Tan, Mikhail Titov, Vlimos Kertesz, Austin Clyde, Daniel W. Kneller, Hyungro Lee, Alexander Brace, Rick Stevens, Darin Hauner, Leighton Coates, Shantenu Jha, Kyle Chard, Andrey Kovalevsky, Arvind Ramanathan, Thomas Brettin, Neeraj Kumar, Ben Blaiszik, Stephanie Galanie, Hubertus J. J. van Dam, Matteo Turilli, Martha S Head, Yadu Babuji, Ian Foster, and Anda Trifan

Subjects

General Chemical Engineering, medicine.medical_treatment, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Context (language use), Computational biology, Molecular Dynamics Simulation, Library and Information Sciences, medicine.disease_cause, Antiviral Agents, Article, Piperazines, medicine, Humans, Protease Inhibitors, Binding site, Coronavirus 3C Proteases, Coronavirus, Orotic Acid, Virtual screening, Protease, SARS-CoV-2, Chemistry, COVID-19, General Chemistry, Ligand (biochemistry), Computer Science Applications, Molecular Docking Simulation, Docking (molecular)

Abstract

Despite the recent availability of vaccines against the acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the search for inhibitory therapeutic agents has assumed importance especially in the context of emerging new viral variants. In this paper, we describe the discovery of a novel noncovalent small-molecule inhibitor, MCULE-5948770040, that binds to and inhibits the SARS-Cov-2 main protease (Mpro) by employing a scalable high-throughput virtual screening (HTVS) framework and a targeted compound library of over 6.5 million molecules that could be readily ordered and purchased. Our HTVS framework leverages the U.S. supercomputing infrastructure achieving nearly 91% resource utilization and nearly 126 million docking calculations per hour. Downstream biochemical assays validate this Mpro inhibitor with an inhibition constant (Ki) of 2.9 μM (95% CI 2.2, 4.0). Furthermore, using room-temperature X-ray crystallography, we show that MCULE-5948770040 binds to a cleft in the primary binding site of Mpro forming stable hydrogen bond and hydrophobic interactions. We then used multiple μs-time scale molecular dynamics (MD) simulations and machine learning (ML) techniques to elucidate how the bound ligand alters the conformational states accessed by Mpro, involving motions both proximal and distal to the binding site. Together, our results demonstrate how MCULE-5948770040 inhibits Mpro and offers a springboard for further therapeutic design.

Published

2021

13. Michaelis-like complex of SARS-CoV-2 main protease visualized by room-temperature X-ray crystallography

Author

Leighton Coates, Daniel W. Kneller, Qiu Zhang, Andrey Kovalevsky, and John M. Louis

Subjects

Stereochemistry, medicine.medical_treatment, In silico, Crystal structure, catalytic mechanism, medicine.disease_cause, Biochemistry, c145a mutant, 3cl protease, medicine, General Materials Science, Enzyme substrate complex, Mutation, Protease, Crystallography, Chemistry, enzyme–substrate complex, room-temperature x-ray crystallography, Substrate (chemistry), General Chemistry, Condensed Matter Physics, Cysteine protease, Research Papers, sars-cov-2, main protease, QD901-999, X-ray crystallography

Abstract

Understanding the catalytic mechanism of SARS-CoV-2 main protease (Mpro) can help in guiding drug design of specific small-molecule antivirals. A 2.0 Å resolution room-temperature X-ray crystal structure of inactive C145A mutant Mpro in complex with the octapeptide Ac-SAVLQSGF-CONH2 that resembles a Michaelis complex is reported., SARS-CoV-2 emerged at the end of 2019 to cause an unprecedented pandemic of the deadly respiratory disease COVID-19 that continues to date. The viral main protease (Mpro) is essential for SARS-CoV-2 replication and is therefore an important drug target. Understanding the catalytic mechanism of Mpro, a cysteine protease with a catalytic site comprising the noncanonical Cys145–His41 dyad, can help in guiding drug design. Here, a 2.0 Å resolution room-temperature X-ray crystal structure is reported of a Michaelis-like complex of Mpro harboring a single inactivating mutation C145A bound to the octapeptide Ac-SAVLQSGF-CONH2 corresponding to the nsp4/nsp5 autocleavage site. The peptide substrate is unambiguously defined in subsites S5 to S3′ by strong electron density. Superposition of the Michaelis-like complex with the neutron structure of substrate-free Mpro demonstrates that the catalytic site is inherently pre-organized for catalysis prior to substrate binding. Induced fit to the substrate is driven by P1 Gln binding in the predetermined subsite S1 and rearrangement of subsite S2 to accommodate P2 Leu. The Michaelis-like complex structure is ideal for in silico modeling of the SARS-CoV-2 Mpro catalytic mechanism.

Published

2021

14. Novel HIV PR inhibitors with C4-substituted bis-THF and bis-fluoro-benzyl target the two active site mutations of highly drug resistant mutant PRS17

Author

Johnson Agniswamy, Irene T. Weber, Arun K. Ghosh, and Daniel W. Kneller

Subjects

Models, Molecular, 0301 basic medicine, Proteases, medicine.medical_treatment, Biophysics, HIV Infections, medicine.disease_cause, Biochemistry, Article, 03 medical and health sciences, Amprenavir, 0302 clinical medicine, HIV Protease, Catalytic Domain, Drug Resistance, Viral, medicine, Humans, Point Mutation, Protease inhibitor (pharmacology), Molecular Biology, Darunavir, Mutation, Protease, biology, Chemistry, Active site, HIV Protease Inhibitors, Cell Biology, Molecular biology, Multiple drug resistance, 030104 developmental biology, 030220 oncology & carcinogenesis, HIV-1, biology.protein, medicine.drug

Abstract

The emergence of multidrug resistant (MDR) HIV strains severely reduces the effectiveness of antiretroviral therapy. Clinical inhibitor darunavir (1) has picomolar binding affinity for HIV-1 protease (PR), however, drug resistant variants like PR(S17) show poor inhibition by 1, despite the presence of only two mutated residues in the inhibitor-binding site. Antiviral inhibitors that target MDR proteases like PR(S17) would be valuable as therapeutic agents. Inhibitors 2 and 3 derived from 1 through substitutions at P1, P2 and P2ʹ positions exhibit 3.4- to 500-fold better inhibition than clinical inhibitors for PR(S17) with the exception of amprenavir. Crystal structures of PR(S17)/2 and PR(S17)/3 reveal how these inhibitors target the two active site mutations of PR(S17). The substituted methoxy P2 group of 2 forms new interactions with G48V mutation, while the modified bis-fluoro-benzyl P1 group of 3 forms a halogen interaction with V82S mutation, contributing to improved inhibition of PR(S17).

Published

2021

15. HIV-1 protease with 10 lopinavir and darunavir resistance mutations exhibits altered inhibition, structural rearrangements and extreme dynamics

Author

Andres Wong-Sam, Yuan-Fang Wang, Daniel W. Kneller, Andrey Y. Kovalevsky, Arun K. Ghosh, Robert W. Harrison, and Irene T. Weber

Subjects

HIV Protease, Drug Resistance, Viral, Mutation, Materials Chemistry, Humans, HIV Protease Inhibitors, Physical and Theoretical Chemistry, Molecular Dynamics Simulation, Crystallography, X-Ray, Computer Graphics and Computer-Aided Design, Spectroscopy, Lopinavir, Darunavir

Abstract

Antiretroviral drug resistance is a therapeutic obstacle for people with HIV. HIV protease inhibitors darunavir and lopinavir are recommended for resistant infections. We characterized a protease mutant (PR10x) derived from a highly resistant clinical isolate including 10 mutations associated with resistance to lopinavir and darunavir. Compared to the wild-type protease, PR10x exhibits ∼3-fold decrease in catalytic efficiency and K

Published

2022

16. Room-temperature X-ray crystallography reveals the oxidation and reactivity of cysteine residues in SARS-CoV-2 3CL Mpro: insights into enzyme mechanism and drug design

Author

Gwyndalyn Phillips, Hugh O'Neill, Leighton Coates, Kemin Tan, Andrey Kovalevsky, Andrzej Joachimiak, and Daniel W. Kneller

Subjects

Drug, Stereochemistry, drug design, medicine.medical_treatment, media_common.quotation_subject, protonation state, medicine.disease_cause, 01 natural sciences, Biochemistry, Catalysis, 03 medical and health sciences, medicine, General Materials Science, Reactivity (chemistry), enzyme mechanism, lcsh:Science, 030304 developmental biology, media_common, Coronavirus, chemistry.chemical_classification, 0303 health sciences, Protease, 010405 organic chemistry, Chemistry, room-temperature x-ray crystallography, Substrate (chemistry), General Chemistry, Condensed Matter Physics, Research Papers, 3cl main protease, 0104 chemical sciences, sars-cov-2, Enzyme, lcsh:Q, 3cl mpro, cysteine oxidation, Cysteine

Abstract

The viral main protease is indispensable for SARS-CoV-2 replication, and detailed knowledge of its structure and function is crucial to guide structure-aided and computational drug-design efforts. X-ray crystallography is used to reveal the oxidation and reactivity of the cysteine residues of the protease, providing insights into the enzyme mechanism and drug design., The emergence of the novel coronavirus SARS-CoV-2 has resulted in a worldwide pandemic not seen in generations. Creating treatments and vaccines to battle COVID-19, the disease caused by the virus, is of paramount importance in order to stop its spread and save lives. The viral main protease, 3CL Mpro, is indispensable for the replication of SARS-CoV-2 and is therefore an important target for the design of specific protease inhibitors. Detailed knowledge of the structure and function of 3CL Mpro is crucial to guide structure-aided and computational drug-design efforts. Here, the oxidation and reactivity of the cysteine residues of the protease are reported using room-temperature X-ray crystallography, revealing that the catalytic Cys145 can be trapped in the peroxysulfenic acid oxidation state at physiological pH, while the other surface cysteines remain reduced. Only Cys145 and Cys156 react with the alkylating agent N-ethylmaleimide. It is suggested that the zwitterionic Cys145–His45 catalytic dyad is the reactive species that initiates catalysis, rather than Cys145-to-His41 proton transfer via the general acid–base mechanism upon substrate binding. The structures also provide insight into the design of improved 3CL Mpro inhibitors.

Published

2020

17. Hit Expansion of a Noncovalent SARS-CoV-2 Main Protease Inhibitor

Author

Jens Glaser, Ada Sedova, Stephanie Galanie, Daniel W. Kneller, Russell B. Davidson, Elvis Maradzike, Sara Del Galdo, Audrey Labbé, Darren J. Hsu, Rupesh Agarwal, Dmytro Bykov, Arnold Tharrington, Jerry M. Parks, Dayle M. A. Smith, Isabella Daidone, Leighton Coates, Andrey Kovalevsky, and Jeremy C. Smith

Subjects

Pharmacology, main protease inhibitor, SARS-CoV-2, antiviral therapeutics, drug discovery, hit expansion, Pharmacology (medical)

Abstract

Inhibition of the SARS-CoV-2 main protease (M

Published

2022

18. Joint neutron/molecular dynamics vibrational spectroscopy reveals softening of HIV-1 protease upon binding of a tight inhibitor

Author

Daniel W. Kneller, Oksana Gerlits, Luke L. Daemen, Anna Pavlova, James C. Gumbart, Yongqiang Cheng, and Andrey Kovalevsky

Subjects

Neutrons, HIV Protease, Spectrum Analysis, Physics::Atomic and Molecular Clusters, HIV-1, General Physics and Astronomy, Physics::Chemical Physics, Physical and Theoretical Chemistry, Molecular Dynamics Simulation, Vibration, Article

Abstract

Biomacromolecules are inherently dynamic, and their dynamics are interwoven into function. The fast collective vibrational dynamics in proteins occurs in the low picosecond timescale corresponding to frequencies of ~5–50 cm(−1). This sub-to-low THz frequency regime covers the low-amplitude collective breathing motions of a whole protein and vibrations of the constituent secondary structure elements, such as α-helices, β-sheets and loops. We have used inelastic neutron scattering experiments in combination with molecular dynamics simulations to demonstrate the vibrational dynamics softening of HIV-1 protease, a target of HIV/AIDS antivirals, upon binding of a tight clinical inhibitor darunavir. Changes in the vibrational density of states of matching structural elements in the two monomers of the homodimeric protein are not identical, indicating asymmetric effects of darunavir on the vibrational dynamics. Three of the 11 major secondary structure elements contribute over 40% to the overall changes in the vibrational density of states upon darunavir binding. Molecular dynamics simulations informed by experiments allowed us to estimate that the altered vibrational dynamics of the protease would contribute −3.6 kcal/mol at 300 K, or 25%, to the free energy of darunavir binding. As HIV-1 protease drug resistance remains a concern, our results open a new avenue to help establish a direct quantitative link between protein vibrational dynamics and drug resistance.

Published

2022

19. The mechanisms of catalysis and ligand binding for the SARS-CoV-2 NSP3 macrodomain from neutron and X-ray diffraction at room temperature

Author

Galen J. Correy, Daniel W. Kneller, Gwyndalyn Phillips, Swati Pant, Silvia Russi, Aina E. Cohen, George Meigs, James M. Holton, Stefan Gahbauer, Michael C. Thompson, Alan Ashworth, Leighton Coates, Andrey Kovalevsky, Flora Meilleur, and James S. Fraser

Subjects

Vaccine Related, Multidisciplinary, Emerging Infectious Diseases, Infectious Diseases, 5.1 Pharmaceuticals, viruses, Prevention, Pneumonia & Influenza, Pneumonia, Development of treatments and therapeutic interventions, Lung, Article

Abstract

The nonstructural protein 3 (NSP3) macrodomain of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (Mac1) removes adenosine diphosphate (ADP) ribosylation posttranslational modifications, playing a key role in the immune evasion capabilities of the virus responsible for the coronavirus disease 2019 pandemic. Here, we determined neutron and x-ray crystal structures of the SARS-CoV-2 NSP3 macrodomain using multiple crystal forms, temperatures, and pHs, across the apo and ADP-ribose–bound states. We characterize extensive solvation in the Mac1 active site and visualize how water networks reorganize upon binding of ADP-ribose and non-native ligands, inspiring strategies for displacing waters to increase the potency of Mac1 inhibitors. Determining the precise orientations of active site water molecules and the protonation states of key catalytic site residues by neutron crystallography suggests a catalytic mechanism for coronavirus macrodomains distinct from the substrate-assisted mechanism proposed for human MacroD2. These data provoke a reevaluation of macrodomain catalytic mechanisms and will guide the optimization of Mac1 inhibitors.

Published

2022

20. Room-temperature neutron and X-ray data collection of 3CL Mprofrom SARS-CoV-2

Author

Gwyndalyn Phillips, Leighton Coates, Daniel W. Kneller, and Andrey Kovalevsky

Subjects

chemistry.chemical_classification, 0303 health sciences, Polyproteins, biology, Chemistry, Stereochemistry, 030302 biochemistry & molecular biology, Biophysics, Active site, Protonation, Condensed Matter Physics, Cleavage (embryo), Biochemistry, Cysteine protease, 03 medical and health sciences, Protein structure, Enzyme, Structural Biology, Genetics, biology.protein, Molecule, 030304 developmental biology

Abstract

The replication of SARS-CoV-2 produces two large polyproteins, pp1a and pp1ab, that are inactive until cleavage by the viral chymotrypsin-like cysteine protease enzyme (3CL Mpro) into a series of smaller functional proteins. At the heart of 3CL Mprois an unusual catalytic dyad formed by the side chains of His41 and Cys145 and a coordinated water molecule. The catalytic mechanism by which the enzyme operates is still unknown, as crucial information on the protonation states within the active site is unclear. To experimentally determine the protonation states of the catalytic site and of the other residues in the substrate-binding cavity, and to visualize the hydrogen-bonding networks throughout the enzyme, room-temperature neutron and X-ray data were collected from a large H/D-exchanged crystal of ligand-free (apo) 3CL Mpro.

Published

2020

21. Highly drug‐resistant HIV‐1 protease reveals decreased intra‐subunit interactions due to clusters of mutations

Author

Irene T. Weber, Johnson Agniswamy, Daniel W. Kneller, and Robert W. Harrison

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, medicine.medical_treatment, Protein subunit, Mutant, Molecular Dynamics Simulation, Crystallography, X-Ray, medicine.disease_cause, Biochemistry, Article, 03 medical and health sciences, Amprenavir, 0302 clinical medicine, HIV Protease, HIV-1 protease, Catalytic Domain, Drug Resistance, Viral, medicine, Humans, Binding site, Molecular Biology, Darunavir, Mutation, Binding Sites, Protease, biology, Chemistry, HIV Protease Inhibitors, Cell Biology, Molecular biology, 030104 developmental biology, 030220 oncology & carcinogenesis, biology.protein, medicine.drug

Abstract

Drug-resistance is a serious problem for treatment of the HIV/AIDS pandemic. Potent clinical inhibitors of HIV-1 protease show several orders of magnitude worse inhibition of highly drug-resistant variants. Hence, the structure and enzyme activities were analyzed for HIV protease mutant HIV-1 protease (EC 3.4.23.16) (PR) with 22 mutations (PRS5B) from a clinical isolate that was selected by machine learning to represent high-level drug-resistance. PRS5B has 22 mutations including only one (I84V) in the inhibitor binding site; however, clinical inhibitors had poor inhibition of PRS5B activity with kinetic inhibition value (Ki ) values of 4-1000 nm or 18- to 8000-fold worse than for wild-type PR. High-resolution crystal structures of PRS5B complexes with the best inhibitors, amprenavir (APV) and darunavir (DRV) (Ki ~ 4 nm), revealed only minor changes in protease-inhibitor interactions. Instead, two distinct clusters of mutations in distal regions induce coordinated conformational changes that decrease favorable internal interactions across the entire protein subunit. The largest structural rearrangements are described and compared to other characterized resistant mutants. In the protease hinge region, the N83D mutation eliminates a hydrogen bond connecting the hinge and core of the protease and increases disorder compared to highly resistant mutants PR with 17 mutations and PR with 20 mutations with similar hinge mutations. In a distal β-sheet, mutations G73T and A71V coordinate with accessory mutations to bring about shifts that propagate throughout the subunit. Molecular dynamics simulations of ligand-free dimers show differences consistent with loss of interactions in mutant compared to wild-type PR. Clusters of mutations exhibit both coordinated and antagonistic effects, suggesting PRS5B may represent an intermediate stage in the evolution of more highly resistant variants. DATABASES: Structural data are available in Protein Data Bank under the accession codes 6P9A and 6P9B for PRS5B/DRV and PRS5B/APV, respectively.

Published

2020

22. Potent antiviral HIV-1 protease inhibitor combats highly drug resistant mutant PR20

Author

Arun K. Ghosh, Johnson Agniswamy, Irene T. Weber, and Daniel W. Kneller

Subjects

Models, Molecular, 0301 basic medicine, medicine.medical_treatment, Dimer, Mutant, Molecular Conformation, Biophysics, Drug resistance, Pharmacology, Crystallography, X-Ray, Antiviral Agents, Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, HIV Protease, HIV-1 protease, Drug Resistance, Viral, medicine, Humans, Molecular Biology, Darunavir, chemistry.chemical_classification, Protease, biology, Chemistry, HIV Protease Inhibitors, Cell Biology, Ligand (biochemistry), Kinetics, 030104 developmental biology, 030220 oncology & carcinogenesis, Mutation, HIV-1, biology.protein, Tricyclic, medicine.drug

Abstract

Drug-resistance threatens effective treatment of HIV/AIDS. Clinical inhibitors, including darunavir (1), are ineffective for highly resistant protease mutant PR20, however, antiviral compound 2 derived from 1 with fused tricyclic group at P2, extended amino-benzothiazole P2’ ligand and two fluorine atoms on P1 shows 16-fold better inhibition of PR20 enzyme activity. Crystal structures of PR20 and wild-type PR complexes reveal how the extra groups of 2 counteract the expanded ligand-binding pocket, dynamic flaps, and faster dimer dissociation of PR20.

Published

2019

23. Structural and functional characterization of NEMO cleavage by SARS-CoV-2 3CLpro

Author

Soichi Wakatsuki, Stephanie Galanie, B Kirtley Amos, Daniel Jacobson, Stephan Irle, Audrey Labbe, M. A. Hameedi, O. Demerdash, Michael R. Garvin, J. C. Mitchell, Irimpan I. Mathews, Daniel W. Kneller, Erica T. Prates, Van Quan Vuong, M. Iyer, Andrey Kovalevsky, Simin Rahighi, and M. Bechthold

Subjects

2019-20 coronavirus outbreak, Multidisciplinary, Protease, Immune signaling, Coronavirus disease 2019 (COVID-19), SARS-CoV-2, Hydrogen bond, Chemistry, medicine.medical_treatment, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), General Physics and Astronomy, COVID-19, Proteins, General Chemistry, Cleavage (embryo), Antiviral Agents, General Biochemistry, Genetics and Molecular Biology, Article, Cell biology, Cysteine Endopeptidases, Cleave, medicine, Humans, skin and connective tissue diseases, Peptide Hydrolases

Abstract

In addition to its essential role in viral polyprotein processing, the SARS-CoV-2 3C-like (3CLpro) protease can cleave human immune signaling proteins, like NF-κB Essential Modulator (NEMO) and deregulate the host immune response. Here, in vitro assays show that SARS-CoV-2 3CLpro cleaves NEMO with fine-tuned efficiency. Analysis of the 2.14 Å resolution crystal structure of 3CLpro C145S bound to NEMO226-235 reveals subsites that tolerate a range of viral and host substrates through main chain hydrogen bonds while also enforcing specificity using side chain hydrogen bonds and hydrophobic contacts. Machine learning- and physics-based computational methods predict that variation in key binding residues of 3CLpro- NEMO helps explain the high fitness of SARS-CoV-2 in humans. We posit that cleavage of NEMO is an important piece of information to be accounted for in the pathology of COVID-19.

Published

2021

24. Structural, Electronic, and Electrostatic Determinants for Inhibitor Binding to Subsites S1 and S2 in SARS-CoV-2 Main Protease

Author

Gwyndalyn Phillips, John M. Louis, Colleen B. Jonsson, Stephanie Galanie, Martha S Head, Audrey Labbe, Arvind Ramanathan, Kevin L Weiss, Mark A Arnould, Heng Ma, Qiu Zhang, Andrey Kovalevsky, Hui Li, Peter V. Bonnesen, Daniel W. Kneller, Austin Clyde, and Leighton Coates

Subjects

chemistry.chemical_classification, Orotic Acid, Protease, Coronavirus disease 2019 (COVID-19), Chemistry, Hydrogen bond, Stereochemistry, Protein Conformation, medicine.medical_treatment, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Static Electricity, Protonation, In vitro, Article, Piperazines, Enzyme, Drug Discovery, medicine, Molecular Medicine, Protease Inhibitors, Linker, Coronavirus 3C Proteases

Abstract

Creating small-molecule antivirals specific for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) proteins is crucial to battle coronavirus disease 2019 (COVID-19). SARS-CoV-2 main protease (Mpro) is an established drug target for the design of protease inhibitors. We performed a structure-activity relationship (SAR) study of noncovalent compounds that bind in the enzyme's substrate-binding subsites S1 and S2, revealing structural, electronic, and electrostatic determinants of these sites. The study was guided by the X-ray/neutron structure of Mpro complexed with Mcule-5948770040 (compound 1), in which protonation states were directly visualized. Virtual reality-assisted structure analysis and small-molecule building were employed to generate analogues of 1. In vitro enzyme inhibition assays and room-temperature X-ray structures demonstrated the effect of chemical modifications on Mpro inhibition, showing that (1) maintaining correct geometry of an inhibitor's P1 group is essential to preserve the hydrogen bond with the protonated His163; (2) a positively charged linker is preferred; and (3) subsite S2 prefers nonbulky modestly electronegative groups.

Published

2021

25. Direct Observation of Protonation State Modulation in SARS-CoV-2 Main Protease upon Inhibitor Binding with Neutron Crystallography

Author

Daniel W. Kneller, Kevin L Weiss, Andrey Kovalevsky, Qiu Zhang, Leighton Coates, and Gwyndalyn Phillips

Subjects

Models, Molecular, Antagonists & inhibitors, Stereochemistry, Protein Conformation, medicine.medical_treatment, Drug design, Protonation, Cysteine Proteinase Inhibitors, Crystallography, X-Ray, 01 natural sciences, Article, 03 medical and health sciences, Protein structure, Drug Discovery, medicine, Binding site, Coronavirus 3C Proteases, 030304 developmental biology, Neutrons, 0303 health sciences, Protease, Binding Sites, Crystallography, biology, Chemistry, Active site, 0104 chemical sciences, 010404 medicinal & biomolecular chemistry, biology.protein, Molecular Medicine, Protons, Oligopeptides

Abstract

The main protease (3CL Mpro) from severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that causes COVID-19, is an essential enzyme for viral replication with no human counterpart, making it an attractive drug target. To date, no small-molecule clinical drugs are available that specifically inhibit SARS-CoV-2 Mpro. To aid rational drug design, we determined a neutron structure of Mpro in complex with the α-ketoamide inhibitor telaprevir at near-physiological (22 °C) temperature. We directly observed protonation states in the inhibitor complex and compared them with those in the ligand-free Mpro, revealing modulation of the active-site protonation states upon telaprevir binding. We suggest that binding of other α-ketoamide covalent inhibitors can lead to the same protonation state changes in the Mpro active site. Thus, by studying the protonation state changes induced by inhibitors, we provide crucial insights to help guide rational drug design, allowing precise tailoring of inhibitors to manipulate the electrostatic environment of SARS-CoV-2 Mpro.

Published

2021

26. Inhibitor Binding Modulates Protonation States in the Active Site of SARS-CoV-2 Main Protease

Author

Kevin L Weiss, Daniel W. Kneller, Andrey Kovalevsky, Qiu Zhang, Gwyndalyn Phillips, and Leighton Coates

Subjects

chemistry.chemical_classification, Proteases, Protease, biology, Stereochemistry, medicine.medical_treatment, Active site, Drug design, Protonation, Enzyme, chemistry, Viral replication, medicine, biology.protein, Histidine

Abstract

The main protease (3CL Mpro) from SARS-CoV-2, the virus that causes COVID-19, is an essential enzyme for viral replication with no human counterpart, making it an attractive drug target. Although drugs have been developed to inhibit the proteases from HIV, hepatitis C and other viruses, no such therapeutic is available to inhibit the main protease of SARS-CoV-2. To directly observe the protonation states in SARS-CoV-2 Mpro and to elucidate their importance in inhibitor binding, we determined the structure of the enzyme in complex with the α-ketoamide inhibitor telaprevir using neutron protein crystallography at near-physiological temperature. We compared protonation states in the inhibitor complex with those determined for a ligand-free neutron structure of Mpro. This comparison revealed that three active-site histidine residues (His41, His163 and His164) adapt to ligand binding, altering their protonation states to accommodate binding of telaprevir. We suggest that binding of other α-ketoamide inhibitors can lead to the same protonation state changes of the active site histidine residues. Thus, by studying the role of active site protonation changes induced by inhibitors we provide crucial insights to help guide rational drug design, allowing precise tailoring of inhibitors to manipulate the electrostatic environment of SARS-CoV-2 Mpro.

Published

2021

27. Inhibitor binding influences the protonation states of histidines in SARS-CoV-2 main protease

Author

Micholas Dean Smith, Jerry M. Parks, Daniel W. Kneller, Jeremy C. Smith, Andrei Golosov, Leighton Coates, Isabella Daidone, Camilo Velez-Vega, Atanu Acharya, Chris Chipot, Callum J. Dickson, Diane L. Lynch, Anna Pavlova, Yui Tik Pang, José S. Duca, James C. Gumbart, Josh V. Vermaas, Andrey Kovalevsky, and Laura Zanetti-Polzi

Subjects

Peptidomimetic, Stereochemistry, medicine.medical_treatment, viruses, Protonation, 010402 general chemistry, Cleavage (embryo), 01 natural sciences, Article, 03 medical and health sciences, 0103 physical sciences, medicine, Binding site, Histidine, 030304 developmental biology, 0303 health sciences, Protease, 010304 chemical physics, 010405 organic chemistry, Chemistry, Hydrogen bond, virus diseases, General Chemistry, Cysteine protease, 0104 chemical sciences

Abstract

The main protease (Mpro) of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is an attractive target for antiviral therapeutics. Recently, many high-resolution apo and inhibitor-bound structures of Mpro, a cysteine protease, have been determined, facilitating structure-based drug design. Mpro plays a central role in the viral life cycle by catalyzing the cleavage of SARS-CoV-2 polyproteins. In addition to the catalytic dyad His41-Cys145, Mpro contains multiple histidines including His163, His164, and His172. The protonation states of these histidines and the catalytic nu-cleophile Cys145 have been debated in previous studies of SARS-CoV Mpro, but have yet to be investigated for SARS-CoV-2. In this work we have used molecular dynamics simulations to determine the structural stability of SARS-CoV-2 Mpro as a function of the protonation assignments for these residues. We simulated both the apo and inhibitor-bound enzyme and found that the conformational stability of the binding site, bound inhibitors, and the hydrogen bond networks of Mpro are highly sensitive to these assignments. Additionally, the two inhibitors studied, the peptidomimetic N3 and an α-ketoamide, display distinct His41/His164 protonation-state-dependent stabilities. While the apo and the N3-bound systems favored Nδ (HD) and Nϵ (HE) protonation of His41 and His164, respectively, the α-ketoamide was not stably bound in this state. Our results illustrate the importance of using appropriate histidine protonation states to accurately model the structure and dynamics of SARS-CoV-2 Mpro in both the apo and inhibitor-bound states, a necessary prerequisite for drug-design efforts.

Published

2021

28. Unusual zwitterionic catalytic site of SARS–CoV-2 main protease revealed by neutron crystallography

Author

Leighton Coates, Gwyndalyn Phillips, Qiu Zhang, Daniel W. Kneller, Andrey Kovalevsky, Kevin L Weiss, Hugh O'Neill, and Swati Pant

Subjects

0301 basic medicine, Models, Molecular, SARS–CoV-2, drug design, medicine.medical_treatment, Dimer, protonation state, Neutron diffraction, Protonation, joint neutron, Crystallography, X-Ray, Biochemistry, SARS–CoV-2 3CL main protease, Catalysis, 03 medical and health sciences, chemistry.chemical_compound, neutron diffraction, Catalytic Domain, medicine, Neutron, enzyme mechanism, Molecular Biology, Coronavirus 3C Proteases, X-ray crystallography, Neutrons, hydrogen bond, Protease, 030102 biochemistry & molecular biology, Hydrogen bond, SARS-CoV-2, Molecular Bases of Disease, viral protease, Hydrogen atom, Cell Biology, 3CL Mpro, Crystallography, 030104 developmental biology, chemistry, 3CL main protease, Enzymology, room temperature

Abstract

The main protease (3CL Mpro) from SARS–CoV-2, the etiological agent of COVID-19, is an essential enzyme for viral replication. 3CL Mpro possesses an unusual catalytic dyad composed of Cys145 and His41 residues. A critical question in the field has been what the protonation states of the ionizable residues in the substrate-binding active-site cavity are; resolving this point would help understand the catalytic details of the enzyme and inform rational drug development against this pernicious virus. Here, we present the room-temperature neutron structure of 3CL Mpro, which allowed direct determination of hydrogen atom positions and, hence, protonation states in the protease. We observe that the catalytic site natively adopts a zwitterionic reactive form in which Cys145 is in the negatively charged thiolate state and His41 is doubly protonated and positively charged, instead of the neutral unreactive state usually envisaged. The neutron structure also identified the protonation states, and thus electrical charges, of all other amino acid residues and revealed intricate hydrogen-bonding networks in the active-site cavity and at the dimer interface. The fine atomic details present in this structure were made possible by the unique scattering properties of the neutron, which is an ideal probe for locating hydrogen positions and experimentally determining protonation states at near-physiological temperature. Our observations provide critical information for structure-assisted and computational drug design, allowing precise tailoring of inhibitors to the enzyme's electrostatic environment.

Published

2020

29. Protonation states in SARS-CoV-2 main protease mapped by neutron crystallography

Author

Leighton Coates, Qiu Zhang, Kevin L Weiss, Andrey Kovalevsky, Gwyndalyn Phillips, Swati Pant, and Daniel W. Kneller

Subjects

chemistry.chemical_compound, Crystallography, chemistry, biology, Hydrogen bond, Dimer, X-ray crystallography, biology.protein, Active site, Neutron, Protonation, Hydrogen atom, Catalysis

Abstract

The main protease (3CL Mpro) from SARS-CoV-2, the etiological agent of COVID-19, is an essential enzyme for viral replication, possessing an unusual catalytic dyad composed of His41 and Cys145. A long-standing question in the field has been what the protonation states of the ionizable residues in the substrate-binding active site cavity are. Here, we present the room-temperature neutron structure of 3CL Mpro from SARS-CoV-2, which allows direct determination of hydrogen atom positions and, hence, protonation states. The catalytic site natively adopts a zwitterionic reactive state where His41 is doubly protonated and positively charged, and Cys145 is in the negatively charged thiolate state. The neutron structure also identified the protonation states of other amino acid residues, mapping electrical charges and intricate hydrogen bonding networks in the SARS-CoV-2 3CL Mpro active site cavity and dimer interface. This structure highlights the ability of neutron protein crystallography for experimentally determining protonation states at near-physiological temperature – the critical information for structure-assisted and computational drug design.

Published

2020

30. Room-temperature neutron and X-ray data collection of 3CL M

Author

Daniel W, Kneller, Gwyndalyn, Phillips, Andrey, Kovalevsky, and Leighton, Coates

Subjects

Models, Molecular, Protein Conformation, SARS-CoV-2, Pneumonia, Viral, Temperature, COVID-19, Viral Nonstructural Proteins, 3CL Mpro, Crystallography, X-Ray, Recombinant Proteins, SARS‐CoV‐2, Research Communications, Betacoronavirus, Cysteine Endopeptidases, Neutron Diffraction, Catalytic Domain, Humans, X‐ray diffraction, Coronavirus Infections, Pandemics, Coronavirus 3C Proteases

Abstract

The replication of SARS‐CoV‐2 produces two large polyproteins, pp1a and pp1ab, that are inactive until cleavage by the viral chymotrypsin‐like cysteine protease enzyme (3CL Mpro) into a series of smaller functional proteins. At the heart of 3CL Mpro is an unusual catalytic dyad formed by the side chains of His41 and Cys145 and a coordinated water molecule. The catalytic mechanism by which the enzyme operates is still unknown, as crucial information on the protonation states within the active site is unclear. To experimentally determine the protonation states of the catalytic site and of the other residues in the substrate‐binding cavity, and to visualize the hydrogen‐bonding networks throughout the enzyme, room‐temperature neutron and X‐ray data were collected from a large H/D‐exchanged crystal of ligand‐free (apo) 3CL Mpro., Protein crystallization of 3CL Mpro from SARS‐CoV‐2 is described along with neutron and X‐ray data collection.

Published

2020

31. Structural plasticity of SARS-CoV-2 3CL Mpro active site cavity revealed by room temperature X-ray crystallography

Author

Lucy Stols, Robert Jedrzejczak, Hugh O'Neill, Leighton Coates, Andrzej Joachimiak, Daniel W. Kneller, Gwyndalyn Phillips, Paul Langan, and Andrey Kovalevsky

Subjects

0301 basic medicine, Polyproteins, Stereochemistry, Science, medicine.medical_treatment, Protein domain, General Physics and Astronomy, Plasma protein binding, 010402 general chemistry, medicine.disease_cause, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Protein structure, Hydrolase, medicine, lcsh:Science, Coronavirus, Multidisciplinary, Protease, biology, Chemistry, Active site, General Chemistry, 0104 chemical sciences, 030104 developmental biology, biology.protein, lcsh:Q

Abstract

The COVID-19 disease caused by the SARS-CoV-2 coronavirus has become a pandemic health crisis. An attractive target for antiviral inhibitors is the main protease 3CL Mpro due to its essential role in processing the polyproteins translated from viral RNA. Here we report the room temperature X-ray structure of unliganded SARS-CoV-2 3CL Mpro, revealing the ligand-free structure of the active site and the conformation of the catalytic site cavity at near-physiological temperature. Comparison with previously reported low-temperature ligand-free and inhibitor-bound structures suggest that the room temperature structure may provide more relevant information at physiological temperatures for aiding in molecular docking studies.

Published

2020

32. Structural Plasticity of the SARS-CoV-2 3CL Mpro Active Site Cavity Revealed by Room Temperature X-ray Crystallography

Author

Daniel W. Kneller, Gwyndalyn Phillips, Hugh M. O'Neill, Robert Jedrzejczak, Lucy Stols, Paul Langan, Andrzej Joachimiak, Leighton Coates, and Andrey Kovalevsky

Abstract

The COVID-19 disease caused by the SARS-CoV-2 Coronavirus has become a pandemic health crisis. An attractive target for antiviral inhibitors is the main protease 3CL Mpro due to its essential role in processing the polyproteins translated from viral RNA. Here we report the room temperature X-ray structure of unliganded SARS-CoV-2 3CL Mpro, revealing the resting structure of the active site and the conformation of the catalytic site cavity. Comparison with previously reported low-temperature ligand-free and inhibitor-bound structures suggest that the room temperature structure may provide more relevant information at physiological temperatures for aiding in molecular docking studies.

Published

2020

33. Supercomputer-Based Ensemble Docking Drug Discovery Pipeline with Application to Covid-19

Author

Mathialakan Thavappiragasam, Gilchan Park, Kendall G. Byler, Leighton Coates, Laura Zanetti-Polzi, Jeffrey M. Larkin, Junqi Yin, John A. Gunnels, Omar Demerdash, Loukas Petridis, Ada Sedova, Carlos Soto, Aaron Scheinberg, Mai Zahran, Scott LeGrand, Jens Glaser, Jerome Baudry, Stephan Irle, Samuel Yen-Chi Chen, Andrey Kovalevsky, Isabella Daidone, Julie C. Mitchell, Arvind Ramanathan, Connor J. Cooper, Duncan Poole, V. Q. Vuong, Diogo Santos-Martins, David M. Rogers, Shinjae Yoo, Y. Shen, Oscar Hernandez, A. Tsaris, Swen Boehm, Debsindhu Bhowmik, Travis J Lawrence, Daniel W. Kneller, Shih-Hsien Liu, Jeremy C. Smith, Line Pouchard, Matthew B. Baker, Stefano Forli, Sally R. Ellingson, Anna Pavlova, Rupesh Agarwal, Micholas Dean Smith, Atanu Acharya, James C. Gumbart, Andreas F. Tillack, John D. Eblen, Josh V. Vermaas, and Jerry M. Parks

Subjects

Enhanced sampling, Computer science, Protein Conformation, General Chemical Engineering, Drug Evaluation, Preclinical, Viral Nonstructural Proteins, Replica exchange, 01 natural sciences, Molecular Docking Simulation, Molecular dynamics, 010304 chemical physics, Drug discovery, AutoDock, Supercomputer, Supercomputers, Preclinical, Spike Glycoprotein, Computer Science Applications, Spike Glycoprotein, Coronavirus, Coronavirus disease 2019 (COVID-19), Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Chemical, Library and Information Sciences, Antiviral Agents, Article, Autodock vina, Computational science, Databases, Structure-Activity Relationship, Artificial Intelligence, 0103 physical sciences, Humans, Computer Simulation, Binding Sites, SARS-CoV-2, COVID-19, Proteins, General Chemistry, 0104 chemical sciences, COVID-19 Drug Treatment, Coronavirus, 010404 medicinal & biomolecular chemistry, Massively parallel supercomputing, Docking (molecular), Drug Design, Drug Evaluation, Databases, Chemical

Abstract

We present a supercomputer-driven pipeline for in silico drug discovery using enhanced sampling molecular dynamics (MD) and ensemble docking. Ensemble docking makes use of MD results by docking compound databases into representative protein binding-site conformations, thus taking into account the dynamic properties of the binding sites. We also describe preliminary results obtained for 24 systems involving eight proteins of the proteome of SARS-CoV-2. The MD involves temperature replica exchange enhanced sampling, making use of massively parallel supercomputing to quickly sample the configurational space of protein drug targets. Using the Summit supercomputer at the Oak Ridge National Laboratory, more than 1 ms of enhanced sampling MD can be generated per day. We have ensemble docked repurposing databases to 10 configurations of each of the 24 SARS-CoV-2 systems using AutoDock Vina. Comparison to experiment demonstrates remarkably high hit rates for the top scoring tranches of compounds identified by our ensemble approach. We also demonstrate that, using Autodock-GPU on Summit, it is possible to perform exhaustive docking of one billion compounds in under 24 h. Finally, we discuss preliminary results and planned improvements to the pipeline, including the use of quantum mechanical (QM), machine learning, and artificial intelligence (AI) methods to cluster MD trajectories and rescore docking poses.

Published

2020

34. Design, Synthesis, and X-ray Studies of Potent HIV-1 Protease Inhibitors with P2-Carboxamide Functionalities

Author

Arun K. Ghosh, Yuan-Fang Wang, Nobuyo Higashi-Kuwata, Irene T. Weber, Shin-ichiro Hattori, Daniel W. Kneller, Hiroaki Mitsuya, Alessandro Grillo, Satish Kovela, Jakka Raghavaiah, and Megan E. Johnson

Subjects

Protease, biology, Bicyclic molecule, Chemistry, Ligand, medicine.drug_class, Stereochemistry, medicine.medical_treatment, Organic Chemistry, Carboxamide, Ether, Biochemistry, chemistry.chemical_compound, HIV-1 protease, Amide, Drug Discovery, medicine, biology.protein, Acetamide

Abstract

[Image: see text] The design, synthesis, biological evaluation, and X-ray structural studies are reported for a series of highly potent HIV-1 protease inhibitors. The inhibitors incorporated stereochemically defined amide-based bicyclic and tricyclic ether derivatives as the P2 ligands with (R)-hydroxyethylaminesulfonamide transition-state isosteres. A number of inhibitors showed excellent HIV-1 protease inhibitory and antiviral activity; however, ligand combination is critical for potency. Inhibitor 4h with a difluorophenylmethyl as the P1 ligand, crown-THF-derived acetamide as the P2 ligand, and a cyclopropylaminobenzothiazole P2′-ligand displayed very potent antiviral activity and maintained excellent antiviral activity against selected multidrug-resistant HIV-1 variants. A high resolution X-ray structure of inhibitor 4h-bound HIV-1 protease provided molecular insight into the binding properties of the new inhibitor.

Published

2019

35. Revertant mutation V48G alters conformational dynamics of highly drug resistant HIV protease PRS17

Author

Andrey Kovalevsky, Daniel W. Kneller, Shelley H. Burnaman, Irene T. Weber, and Yuan-Fang Wang

Subjects

Protein Conformation, medicine.medical_treatment, Mutant, medicine.disease_cause, Article, Amprenavir, HIV Protease, Catalytic Domain, Drug Resistance, Viral, Materials Chemistry, medicine, Enzyme kinetics, Physical and Theoretical Chemistry, Spectroscopy, Darunavir, chemistry.chemical_classification, Mutation, Protease, Chemistry, HIV Protease Inhibitors, Resistance mutation, Computer Graphics and Computer-Aided Design, Molecular biology, Enzyme, Pharmaceutical Preparations, medicine.drug

Abstract

Drug resistance is a serious problem for controlling the HIV/AIDS pandemic. Current antiviral drugs show several orders of magnitude worse inhibition of highly resistant clinical variant PRS17 of HIV-1 protease compared with wild-type protease. We have analyzed the effects of a common resistance mutation G48V in the flexible flaps of the protease by assessing the revertant PRS17(V48G) for changes in enzyme kinetics, inhibition, structure, and dynamics. Both PRS17 and the revertant showed about 10-fold poorer catalytic efficiency than wild-type enzyme (0.55 and 0.39 μM(−1)min(−1) compared to 6.3 μM(−1)min(−1)). Clinical inhibitors, amprenavir and darunavir, showed 2-fold and 8-fold better inhibition, respectively, of the revertant than of PRS17, although the inhibition constants for PRS17(V48G) were still 25 to 1,200-fold worse than for wild-type protease. Crystal structures of inhibitor-free revertant and amprenavir complexes with revertant and PRS17 were solved at 1.3-1.5 Å resolution. The amprenavir complexes of PRS17(V48G) and PRS17 showed no significant differences in the interactions with inhibitor, although changes were observed in the conformation of Phe53 and the interactions of the flaps. The inhibitor-free structure of the revertant showed flaps in an open conformation, however, the flap tips do not have the unusual curled conformation seen in inhibitor-free PRS17. Molecular dynamics simulations were run for 1 μs on the two inhibitor-free mutants and wild-type protease. PRS17 exhibited higher conformational fluctuations than the revertant, while the wild-type protease adopted the closed conformation and showed the least variation. The second half of the simulations captured the transition of the flaps of PRS17 from a closed to a semi-open state, whereas the flaps of PRS17(V48G) tucked into the active site and the wild-type protease retained the closed conformation. These results suggest that mutation G48V contributes to drug resistance by altering the conformational dynamics of the flaps.

Published

2021

36. Direct visualization of SARS-CoV-2 main protease electrostatics using neutron crystallography

Author

Leighton Coates, Gwyndalyn Phillips, Stephanie Galanie, Daniel W. Kneller, and Andrey Kovalevsky

Subjects

Physics, Protease, medicine.medical_treatment, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Condensed Matter Physics, Electrostatics, Biochemistry, Visualization, Inorganic Chemistry, Crystallography, Structural Biology, medicine, General Materials Science, Neutron, Physical and Theoretical Chemistry

Published

2021

37. Potent HIV-1 Protease Inhibitors Containing Carboxylic and Boronic Acids: Effect on Enzyme Inhibition and Antiviral Activity and Protein-Ligand X-ray Structural Studies

Author

William L. Robinson, Hiroaki Mitsuya, Yuki Takamatsu, Irene T. Weber, Daniel W. Kneller, Arun K. Ghosh, Megan E. Johnson, Satish Kovela, Zilei Xia, Manabu Aoki, and Yuan-Fang Wang

Subjects

Models, Molecular, medicine.drug_class, Anti-HIV Agents, Carboxylic acid, medicine.medical_treatment, Carboxylic Acids, Molecular Conformation, Carboxamide, Crystallography, X-Ray, Ligands, 01 natural sciences, Biochemistry, Article, Cell Line, chemistry.chemical_compound, HIV-1 protease, HIV Protease, Drug Discovery, medicine, Humans, General Pharmacology, Toxicology and Pharmaceutics, Phenylboronic acid, Darunavir, Pharmacology, chemistry.chemical_classification, Protease, biology, 010405 organic chemistry, Organic Chemistry, HIV Protease Inhibitors, Boronic Acids, 0104 chemical sciences, 010404 medicinal & biomolecular chemistry, Enzyme, chemistry, biology.protein, HIV-1, Molecular Medicine, Boronic acid, medicine.drug

Abstract

We report here the synthesis and biological evaluation of phenylcarboxylic acid and phenylboronic acid containing HIV-1 protease inhibitors and their functional effect on enzyme inhibition and antiviral activity in MT-2 cell lines. Inhibitors bearing bis-THF ligand as P2 ligand and phenylcarboxylic acids and carboxamide as the P2’ ligands, showed very potent HIV-1 protease inhibitory activity. However, carboxylic acid containing inhibitors showed very poor antiviral activity compared to carboxamide-derived inhibitors which showed good antiviral IC(50) value. Boronic acid-derived inhibitor with bis-THF as the P2 ligand showed very potent enzyme inhibitory activity, but it showed relatively reduced antiviral activity compared to darunavir in the same assay. Boronic acid-containing inhibitor with a P2-Crn-THF ligand also showed potent enzyme K(i) but significantly reduced antiviral activity. We have evaluated antiviral activity against a panel of highly drug-resistant HIV-1 variants. One of the inhibitors maintained good antiviral activity against HIV(DRV)(R)(P20) and HIV(DRV)(R)(P30) viruses. We have determined high resolution X-ray structures of two synthetic inhibitors bound to HIV-1 protease and obtained molecular insight into the ligand-binding site interactions.

Published

2019

38. Malleability of the SARS-CoV-2 3CL Mpro Active-Site Cavity Facilitates Binding of Clinical Antivirals

Author

Daniel W. Kneller, Leighton Coates, Stephanie Galanie, Hugh O'Neill, Andrey Kovalevsky, and Gwyndalyn Phillips

Subjects

Hydrolases, drug design, viruses, medicine.medical_treatment, Viral Nonstructural Proteins, Pharmacology, Crystallography, X-Ray, Antiviral Agents, Article, Target validation, Telaprevir, protease inhibitor, Betacoronavirus, 03 medical and health sciences, chemistry.chemical_compound, Short Article, Structural Biology, Catalytic Domain, enzyme kinetics, Boceprevir, medicine, Humans, Protease Inhibitors, Protease inhibitor (pharmacology), Pandemics, Molecular Biology, X-ray crystallography, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Protease, SARS-CoV-2, 030302 biochemistry & molecular biology, Leupeptin, Temperature, COVID-19, 3CL Mpro, Cysteine Endopeptidases, Enzyme, Viral replication, chemistry, 3CL main protease, Narlaprevir, room temperature X-ray crystallography, hepatitis C clinical drugs, Coronavirus Infections, repurposing clinical drugs, medicine.drug

Abstract

The COVID-19 pandemic caused by SARS-CoV-2 requires rapid development of specific therapeutics and vaccines. The main protease of SARS-CoV-2, 3CL Mpro, is an established drug target for the design of inhibitors to stop the virus replication. Repurposing existing clinical drugs can offer a faster route to treatments. Here, we report on the binding mode and inhibition properties of several inhibitors using room temperature X-ray crystallography and in vitro enzyme kinetics. The enzyme active-site cavity reveals a high degree of malleability, allowing aldehyde leupeptin and hepatitis C clinical protease inhibitors (telaprevir, narlaprevir, and boceprevir) to bind and inhibit SARS-CoV-2 3CL Mpro. Narlaprevir, boceprevir, and telaprevir are low-micromolar inhibitors, whereas the binding affinity of leupeptin is substantially weaker. Repurposing hepatitis C clinical drugs as COVID-19 treatments may be a useful option to pursue. The observed malleability of the enzyme active-site cavity should be considered for the successful design of specific protease inhibitors., Graphical Abstract, Highlights • X-ray structures of SARS-CoV-2 3CL Mpro-inhibitor complexes at room temperature • Telaprevir, narlaprevir, and boceprevir bind and efficiently inhibit the enzyme • 3CL Mpro active-site cavity is malleable, accommodating large inhibitors • Hepatitis C clinical protease inhibitors can be repurposed to treat COVID-19, Kneller et al. used room temperature X-ray crystallography and in vitro enzyme kinetics to probe the binding of hepatitis C clinical protease inhibitors and the natural aldehyde leupeptin to the SARS-CoV-2 main protease (3CL Mpro). The study visualized significant malleability of the enzyme active-site cavity, providing insights for drug design.

Published

2020

39. Highly resistant HIV-1 proteases and strategies for their inhibition

Author

Irene T. Weber, Daniel W. Kneller, and Andres Wong-Sam

Subjects

Pharmacology, Proteases, Protease, medicine.medical_treatment, Drug target, Human immunodeficiency virus (HIV), HIV Protease Inhibitors, Biology, medicine.disease_cause, Virology, AIDS therapy, Orders of magnitude (mass), Article, HIV Protease, Drug Discovery, Drug Resistance, Viral, medicine, Biocatalysis, Molecular Medicine, Potency, HIV Protease Inhibitor, Humans

Abstract

The virally encoded protease is an important drug target for AIDS therapy. Despite the potency of the current drugs, infections with resistant viral strains limit the long-term effectiveness of therapy. Highly resistant variants of HIV protease from clinical isolates have different combinations of about 20 mutations and several orders of magnitude worse binding affinity for clinical inhibitors. Strategies are being explored to inhibit these highly resistant mutants. The existing inhibitors can be modified by introducing groups with the potential to form new interactions with conserved protease residues, and the flexible flaps. Alternative strategies are discussed, including designing inhibitors to bind to the open conformation of the protease dimer, and inhibition of the protease-catalyzed processing of the Gag-Pol precursor.

Published

2015