Your search keyword '"Macieik A"' showing total 3 results

1. A Pan-respiratory Antiviral Chemotype Targeting a Transient Host Multiprotein Complex

Author

Andreas Müller-Schiffmann, Maya Michon, Anuradha F. Lingappa, Shao Feng Yu, Li Du, Fred Deiter, Sean Broce, Suguna Mallesh, Jackelyn Crabtree, Usha F. Lingappa, Amanda Macieik, Lisa Müller, Philipp Niklas Ostermann, Marcel Andrée, Ortwin Adams, Heiner Schaal, Robert J. Hogan, Ralph A. Tripp, Umesh Appaiah, Sanjeev K. Anand, Thomas W. Campi, Michael J. Ford, Jonathan C. Reed, Jim Lin, Olayemi Akintunde, Kiel Copeland, Christine Nichols, Emma Petrouski, A. Raquel Moreira, I-ting Jiang, Nicholas DeYarman, Ian Brown, Sharon Lau, Ilana Segal, Danielle Goldsmith, Shi Hong, Vinod Asundi, Erica M. Briggs, Ngwe Sin Phyo, Markus Froehlich, Bruce Onisko, Kent Matlack, Debendranath Dey, Jaisri R. Lingappa, M. Dharma Prasad, Anatoliy Kitaygorodskyy, Dennis Solas, Homer Boushey, John Greenland, Satish Pillai, Michael K. Lo, Joel M. Montgomery, Christina F. Spiropoulou, Carsten Korth, Suganya Selvarajah, Kumar Paulvannan, and Vishwanath R. Lingappa

Subjects

Drug, Innate immune system, biology, viruses, media_common.quotation_subject, Common cold, medicine.disease, biology.organism_classification, Virology, Article, Virus, Cell culture, medicine, Viral disease, Porcine epidemic diarrhea virus, Cytokine storm, media_common

Abstract

Antiviral compounds displaying several remarkable features have been identified by a uniquely enabling drug screen and advanced through validation in two animal models, and in human primary bronchial epithelial cells grown to an air-liquid interface (ALI) and infected with SARS-CoV-2 (Brazil). Activity is observed in the nanomolar range in mammalian cells in vitro against the six viral families causing most human respiratory viral disease, irrespective of strain, including SARS-CoV-2 delta variant. A substantial barrier to development of viral resistance is demonstrated for influenza (FLUV). The drug target is an allosteric site on a novel host multi-protein complex (MPC) formed transiently, in an energy-dependent fashion, and composed of proteins implicated in viral lifecycles and innate immunity. The composition of this host MPC is modified in viral family-specific ways by FLUV and CoV, and substantially restored to the uninfected state with drug treatment. SQSTM1/p62, a key regulator of the autophagy pathway of innate immunity is i) found in the target MPC from uninfected cells, ii) lost upon infection, and iii) restored by drug treatment of infected cells, as assessed by drug resin affinity chromatography. A small subset of 14-3-3 is identified as the host protein to which the drug is bound. Advanced compounds with good oral bioavailability, half-life, lung exposure, and safety are approaching criteria for a Target Product Profile. We propose these novel drug targets to comprise a previously unappreciated molecular basis for homeostasis that is modified by viruses to facilitate their propagation and is restored by treatment with the therapeutic compounds presented. This discovery has transformative implications for treating respiratory viral-related disease, applicable to everything from COVID-19, seasonal influenza, common ‘winter viruses’ (respiratory syncytial virus, parainfluenza virus, rhinovirus, etc.), emerging respiratory viruses, and prevention of virus-induced asthma/COPD exacerbations. Treating respiratory viral disease with these host-targeted pan-respiratory viral family active compounds early, upon onset of symptoms of viral upper respiratory infection, irrespective of cause, should protect against progression to lower respiratory tract or systemic infection, the hallmarks of serious illness.

Published

2021

2. Host–rabies virus protein–protein interactions as druggable antiviral targets

Author

Xianfu Wu, Vishwanath R. Lingappa, Christine Nichols, M. Dharma Prasad, Vinod Asundi, Andy Atuegbu, Usha F. Lingappa, Debendranath Dey, Michael Corpuz, Shao Feng Yu, Clarence R. Hurt, William Hansen, Alfredo Calayag, Charles E. Rupprecht, Emma Harrell, Hong Shi, Amanda Macieik, James A. Ellison, Jean Francis, Jaisri R. Lingappa, and W. Ian Lipkin

Subjects

whole pathway screen, Viral capsid assembly, viral-host interaction, Druggability, medicine.disease_cause, Drug Discovery, Chlorocebus aethiops, protein heterogeneity, Multidisciplinary, Drug discovery, Nucleocapsid Proteins, drug discovery paradigm, Infectious Diseases, Capsid, PNAS Plus, 5.1 Pharmaceuticals, Host-Pathogen Interactions, Development of treatments and therapeutic interventions, Infection, Biotechnology, medicine.drug_class, Molecular Sequence Data, Immunology, Computational biology, Microbial Sensitivity Tests, Biology, Antiviral Agents, Protein–protein interaction, Vaccine Related, Viral Proteins, Rare Diseases, assembly intermediate, Biodefense, Virology, medicine, Animals, Humans, Protein Interaction Domains and Motifs, Amino Acid Sequence, Vero Cells, Cell-Free System, Virus Assembly, Prevention, FOS: Clinical medicine, Rabies virus, ABCE1, Emerging Infectious Diseases, Orphan Drug, Good Health and Well Being, biology.protein, Antiviral drug

Abstract

We present an unconventional approach to antiviral drug discovery, which is used to identify potent small molecules against rabies virus. First, we conceptualized viral capsid assembly as occurring via a host-catalyzed biochemical pathway, in contrast to the classical view of capsid formation by self-assembly. This suggested opportunities for antiviral intervention by targeting previously unappreciated catalytic host proteins, which were pursued. Second, we hypothesized these host proteins to be components of heterogeneous, labile, and dynamic multi-subunit assembly machines, not easily isolated by specific target protein-focused methods. This suggested the need to identify active compounds before knowing the precise protein target. A cell-free translation-based small molecule screen was established to recreate the hypothesized interactions involving newly synthesized capsid proteins as host assembly machine substrates. Hits from the screen were validated by efficacy against infectious rabies virus in mammalian cell culture. Used as affinity ligands, advanced analogs were shown to bind a set of proteins that effectively reconstituted drug sensitivity in the cell-free screen and included a small but discrete subfraction of cellular ATP-binding cassette family E1 (ABCE1), a host protein previously found essential for HIV capsid formation. Taken together, these studies advance an alternate view of capsid formation (as a host-catalyzed biochemical pathway), a different paradigm for drug discovery (whole pathway screening without knowledge of the target), and suggest the existence of labile assembly machines that can be rendered accessible as next-generation drug targets by the means described.

Published

2013

3. Cell-Free Protein Synthesizing Systems As Tools for Discovery of Drugs Inhibiting Viral Capsid Assembly

Author

Jennifer Welsh, Clarence R. Hurt, M. Dharma Prasad, Vinod Asundi, Kiel Copeland, Jean Francis, William Hansen, Colm A. Kelleher, Vishwanath R. Lingappa, Nick Hahner, Amanda Macieik, Jaisri R. Lingappa, Emma Harrell, and Debendranath Dey

Subjects

Pharmacology, Viral capsid assembly, Virology, Cell free, Computational biology, Biology

Published

2010