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1. Systems-level effects of allosteric perturbations to a model molecular switch

Author

Perica, Tina, Mathy, Christopher JP, Xu, Jiewei, Jang, Gwendolyn Μ, Zhang, Yang, Kaake, Robyn, Ollikainen, Noah, Braberg, Hannes, Swaney, Danielle L, Lambright, David G, Kelly, Mark JS, Krogan, Nevan J, and Kortemme, Tanja

Subjects
Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Bioengineering, HIV/AIDS, Genetics, Aetiology, Underpinning research, 2.1 Biological and endogenous factors, 1.1 Normal biological development and functioning, Generic health relevance, Allosteric Regulation, Binding Sites, Catalytic Domain, GTPase-Activating Proteins, Guanine Nucleotide Exchange Factors, Guanosine Triphosphate, Kinetics, Monomeric GTP-Binding Proteins, Nuclear Proteins, Point Mutation, Protein Binding, Saccharomyces cerevisiae, Saccharomyces cerevisiae Proteins, General Science & Technology
Abstract

Molecular switch proteins whose cycling between states is controlled by opposing regulators1,2 are central to biological signal transduction. As switch proteins function within highly connected interaction networks3, the fundamental question arises of how functional specificity is achieved when different processes share common regulators. Here we show that functional specificity of the small GTPase switch protein Gsp1 in Saccharomyces cerevisiae (the homologue of the human protein RAN)4 is linked to differential sensitivity of biological processes to different kinetics of the Gsp1 (RAN) switch cycle. We make 55 targeted point mutations to individual protein interaction interfaces of Gsp1 (RAN) and show through quantitative genetic5 and physical interaction mapping that Gsp1 (RAN) interface perturbations have widespread cellular consequences. Contrary to expectation, the cellular effects of the interface mutations group by their biophysical effects on kinetic parameters of the GTPase switch cycle and not by the targeted interfaces. Instead, we show that interface mutations allosterically tune the GTPase cycle kinetics. These results suggest a model in which protein partner binding, or post-translational modifications at distal sites, could act as allosteric regulators of GTPase switching. Similar mechanisms may underlie regulation by other GTPases, and other biological switches. Furthermore, our integrative platform to determine the quantitative consequences of molecular perturbations may help to explain the effects of disease mutations that target central molecular switches.

Published
2021

2. A SARS-CoV-2 protein interaction map reveals targets for drug repurposing

Author

Gordon, David E, Jang, Gwendolyn M, Bouhaddou, Mehdi, Xu, Jiewei, Obernier, Kirsten, White, Kris M, O’Meara, Matthew J, Rezelj, Veronica V, Guo, Jeffrey Z, Swaney, Danielle L, Tummino, Tia A, Hüttenhain, Ruth, Kaake, Robyn M, Richards, Alicia L, Tutuncuoglu, Beril, Foussard, Helene, Batra, Jyoti, Haas, Kelsey, Modak, Maya, Kim, Minkyu, Haas, Paige, Polacco, Benjamin J, Braberg, Hannes, Fabius, Jacqueline M, Eckhardt, Manon, Soucheray, Margaret, Bennett, Melanie J, Cakir, Merve, McGregor, Michael J, Li, Qiongyu, Meyer, Bjoern, Roesch, Ferdinand, Vallet, Thomas, Mac Kain, Alice, Miorin, Lisa, Moreno, Elena, Naing, Zun Zar Chi, Zhou, Yuan, Peng, Shiming, Shi, Ying, Zhang, Ziyang, Shen, Wenqi, Kirby, Ilsa T, Melnyk, James E, Chorba, John S, Lou, Kevin, Dai, Shizhong A, Barrio-Hernandez, Inigo, Memon, Danish, Hernandez-Armenta, Claudia, Lyu, Jiankun, Mathy, Christopher JP, Perica, Tina, Pilla, Kala Bharath, Ganesan, Sai J, Saltzberg, Daniel J, Rakesh, Ramachandran, Liu, Xi, Rosenthal, Sara B, Calviello, Lorenzo, Venkataramanan, Srivats, Liboy-Lugo, Jose, Lin, Yizhu, Huang, Xi-Ping, Liu, YongFeng, Wankowicz, Stephanie A, Bohn, Markus, Safari, Maliheh, Ugur, Fatima S, Koh, Cassandra, Savar, Nastaran Sadat, Tran, Quang Dinh, Shengjuler, Djoshkun, Fletcher, Sabrina J, O’Neal, Michael C, Cai, Yiming, Chang, Jason CJ, Broadhurst, David J, Klippsten, Saker, Sharp, Phillip P, Wenzell, Nicole A, Kuzuoglu-Ozturk, Duygu, Wang, Hao-Yuan, Trenker, Raphael, Young, Janet M, Cavero, Devin A, Hiatt, Joseph, Roth, Theodore L, Rathore, Ujjwal, Subramanian, Advait, Noack, Julia, Hubert, Mathieu, Stroud, Robert M, Frankel, Alan D, Rosenberg, Oren S, Verba, Kliment A, Agard, David A, Ott, Melanie, Emerman, Michael, and Jura, Natalia

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Infectious Diseases, Emerging Infectious Diseases, Coronaviruses, Coronaviruses Therapeutics and Interventions, Development of treatments and therapeutic interventions, 5.1 Pharmaceuticals, Infection, Good Health and Well Being, Animals, Antiviral Agents, Betacoronavirus, COVID-19, Chlorocebus aethiops, Cloning, Molecular, Coronavirus Infections, Drug Evaluation, Preclinical, Drug Repositioning, HEK293 Cells, Host-Pathogen Interactions, Humans, Immunity, Innate, Mass Spectrometry, Molecular Targeted Therapy, Pandemics, Pneumonia, Viral, Protein Binding, Protein Biosynthesis, Protein Domains, Protein Interaction Mapping, Protein Interaction Maps, Receptors, sigma, SARS-CoV-2, SKP Cullin F-Box Protein Ligases, Vero Cells, Viral Proteins, COVID-19 Drug Treatment, General Science & Technology
Abstract

A newly described coronavirus named severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which is the causative agent of coronavirus disease 2019 (COVID-19), has infected over 2.3 million people, led to the death of more than 160,000 individuals and caused worldwide social and economic disruption1,2. There are no antiviral drugs with proven clinical efficacy for the treatment of COVID-19, nor are there any vaccines that prevent infection with SARS-CoV-2, and efforts to develop drugs and vaccines are hampered by the limited knowledge of the molecular details of how SARS-CoV-2 infects cells. Here we cloned, tagged and expressed 26 of the 29 SARS-CoV-2 proteins in human cells and identified the human proteins that physically associated with each of the SARS-CoV-2 proteins using affinity-purification mass spectrometry, identifying 332 high-confidence protein-protein interactions between SARS-CoV-2 and human proteins. Among these, we identify 66 druggable human proteins or host factors targeted by 69 compounds (of which, 29 drugs are approved by the US Food and Drug Administration, 12 are in clinical trials and 28 are preclinical compounds). We screened a subset of these in multiple viral assays and found two sets of pharmacological agents that displayed antiviral activity: inhibitors of mRNA translation and predicted regulators of the sigma-1 and sigma-2 receptors. Further studies of these host-factor-targeting agents, including their combination with drugs that directly target viral enzymes, could lead to a therapeutic regimen to treat COVID-19.

Published
2020

3. A SARS-CoV-2-Human Protein-Protein Interaction Map Reveals Drug Targets and Potential Drug-Repurposing.

Author

Gordon, David E, Jang, Gwendolyn M, Bouhaddou, Mehdi, Xu, Jiewei, Obernier, Kirsten, O'Meara, Matthew J, Guo, Jeffrey Z, Swaney, Danielle L, Tummino, Tia A, Hüttenhain, Ruth, Kaake, Robyn M, Richards, Alicia L, Tutuncuoglu, Beril, Foussard, Helene, Batra, Jyoti, Haas, Kelsey, Modak, Maya, Kim, Minkyu, Haas, Paige, Polacco, Benjamin J, Braberg, Hannes, Fabius, Jacqueline M, Eckhardt, Manon, Soucheray, Margaret, Bennett, Melanie J, Cakir, Merve, McGregor, Michael J, Li, Qiongyu, Naing, Zun Zar Chi, Zhou, Yuan, Peng, Shiming, Kirby, Ilsa T, Melnyk, James E, Chorba, John S, Lou, Kevin, Dai, Shizhong A, Shen, Wenqi, Shi, Ying, Zhang, Ziyang, Barrio-Hernandez, Inigo, Memon, Danish, Hernandez-Armenta, Claudia, Mathy, Christopher JP, Perica, Tina, Pilla, Kala B, Ganesan, Sai J, Saltzberg, Daniel J, Ramachandran, Rakesh, Liu, Xi, Rosenthal, Sara B, Calviello, Lorenzo, Venkataramanan, Srivats, Lin, Yizhu, Wankowicz, Stephanie A, Bohn, Markus, Trenker, Raphael, Young, Janet M, Cavero, Devin, Hiatt, Joe, Roth, Theo, Rathore, Ujjwal, Subramanian, Advait, Noack, Julia, Hubert, Mathieu, Roesch, Ferdinand, Vallet, Thomas, Meyer, Björn, White, Kris M, Miorin, Lisa, Agard, David, Emerman, Michael, Ruggero, Davide, García-Sastre, Adolfo, Jura, Natalia, von Zastrow, Mark, Taunton, Jack, Schwartz, Olivier, Vignuzzi, Marco, d'Enfert, Christophe, Mukherjee, Shaeri, Jacobson, Matt, Malik, Harmit S, Fujimori, Danica G, Ideker, Trey, Craik, Charles S, Floor, Stephen, Fraser, James S, Gross, John, Sali, Andrej, Kortemme, Tanja, Beltrao, Pedro, Shokat, Kevan, Shoichet, Brian K, and Krogan, Nevan J

Subjects
Prevention, Vaccine Related, Biodefense, Infectious Diseases, Rare Diseases, Pneumonia & Influenza, Emerging Infectious Diseases, Lung, Pneumonia, 5.1 Pharmaceuticals, 2.2 Factors relating to the physical environment, Infection
Abstract

An outbreak of the novel coronavirus SARS-CoV-2, the causative agent of COVID-19 respiratory disease, has infected over 290,000 people since the end of 2019, killed over 12,000, and caused worldwide social and economic disruption1,2. There are currently no antiviral drugs with proven efficacy nor are there vaccines for its prevention. Unfortunately, the scientific community has little knowledge of the molecular details of SARS-CoV-2 infection. To illuminate this, we cloned, tagged and expressed 26 of the 29 viral proteins in human cells and identified the human proteins physically associated with each using affinity- purification mass spectrometry (AP-MS), which identified 332 high confidence SARS-CoV-2-human protein-protein interactions (PPIs). Among these, we identify 66 druggable human proteins or host factors targeted by 69 existing FDA-approved drugs, drugs in clinical trials and/or preclinical compounds, that we are currently evaluating for efficacy in live SARS-CoV-2 infection assays. The identification of host dependency factors mediating virus infection may provide key insights into effective molecular targets for developing broadly acting antiviral therapeutics against SARS-CoV-2 and other deadly coronavirus strains.

Published
2020

5. A complete allosteric map of a GTPase switch in its native cellular network

Author

Mathy, Christopher J P; https://orcid.org/0000-0002-5546-9733, Mishra, Parul, Flynn, Julia M, Perica, Tina; https://orcid.org/0000-0003-3152-8425, Mavor, David, Bolon, Daniel N A, Kortemme, Tanja, Mathy, Christopher J P; https://orcid.org/0000-0002-5546-9733, Mishra, Parul, Flynn, Julia M, Perica, Tina; https://orcid.org/0000-0003-3152-8425, Mavor, David, Bolon, Daniel N A, and Kortemme, Tanja

Abstract

Allosteric regulation is central to protein function in cellular networks. A fundamental open question is whether cellular regulation of allosteric proteins occurs only at a few defined positions or at many sites distributed throughout the structure. Here, we probe the regulation of GTPases-protein switches that control signaling through regulated conformational cycling-at residue-level resolution by deep mutagenesis in the native biological network. For the GTPase Gsp1/Ran, we find that 28% of the 4,315 assayed mutations show pronounced gain-of-function responses. Twenty of the sixty positions enriched for gain-of-function mutations are outside the canonical GTPase active site switch regions. Kinetic analysis shows that these distal sites are allosterically coupled to the active site. We conclude that the GTPase switch mechanism is broadly sensitive to cellular allosteric regulation. Our systematic discovery of new regulatory sites provides a functional map to interrogate and target GTPases controlling many essential biological processes.

Published
2023

13. The interface of protein structure, protein biophysics, and molecular evolution

Author

Liberles, David A., Teichmann, Sarah A., Bahar, Ivet, Bastolla, Ugo, Bloom, Jesse, Bornberg-Bauer, Erich, Colwell, Lucy J., Jason de Koning, A. P., Dokholyan, Nikolay V., Echave, Julian, Elofsson, Arne, Gerloff, Dietlind L., Goldstein, Richard A., Grahnen, Johan A., Holder, Mark T., Lakner, Clemens, Lartillot, Nicholas, Lovell, Simon C., Naylor, Gavin, Perica, Tina, Pollock, David D., Pupko, Tal, Regan, Lynne, Roger, Andrew, Rubinstein, Nimrod, Shakhnovich, Eugene, Sjölander, Kimmen, Sunyaev, Shamil, Teufel, Ashley I., Thorne, Jeffrey L., Thornton, Joseph W., Weinreich, Daniel M., and Whelan, Simon

Published
2012
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14. A SARS-CoV-2-Human Protein-Protein Interaction Map Reveals Drug Targets and Potential Drug-Repurposing

Author

Gordon, David E., primary, Jang, Gwendolyn M., additional, Bouhaddou, Mehdi, additional, Xu, Jiewei, additional, Obernier, Kirsten, additional, O’Meara, Matthew J., additional, Guo, Jeffrey Z., additional, Swaney, Danielle L., additional, Tummino, Tia A., additional, Hüttenhain, Ruth, additional, Kaake, Robyn M., additional, Richards, Alicia L., additional, Tutuncuoglu, Beril, additional, Foussard, Helene, additional, Batra, Jyoti, additional, Haas, Kelsey, additional, Modak, Maya, additional, Kim, Minkyu, additional, Haas, Paige, additional, Polacco, Benjamin J., additional, Braberg, Hannes, additional, Fabius, Jacqueline M., additional, Eckhardt, Manon, additional, Soucheray, Margaret, additional, Bennett, Melanie J., additional, Cakir, Merve, additional, McGregor, Michael J, additional, Li, Qiongyu, additional, Naing, Zun Zar Chi, additional, Zhou, Yuan, additional, Peng, Shiming, additional, Kirby, Ilsa T., additional, Melnyk, James E., additional, Chorba, John S., additional, Lou, Kevin, additional, Dai, Shizhong A., additional, Shen, Wenqi, additional, Shi, Ying, additional, Zhang, Ziyang, additional, Barrio-Hernandez, Inigo, additional, Memon, Danish, additional, Hernandez-Armenta, Claudia, additional, Mathy, Christopher J.P., additional, Perica, Tina, additional, Pilla, Kala B., additional, Ganesan, Sai J., additional, Saltzberg, Daniel J., additional, Ramachandran, Rakesh, additional, Liu, Xi, additional, Rosenthal, Sara B., additional, Calviello, Lorenzo, additional, Venkataramanan, Srivats, additional, Lin, Yizhu, additional, Wankowicz, Stephanie A., additional, Bohn, Markus, additional, Trenker, Raphael, additional, Young, Janet M., additional, Cavero, Devin, additional, Hiatt, Joe, additional, Roth, Theo, additional, Rathore, Ujjwal, additional, Subramanian, Advait, additional, Noack, Julia, additional, Hubert, Mathieu, additional, Roesch, Ferdinand, additional, Vallet, Thomas, additional, Meyer, Björn, additional, White, Kris M., additional, Miorin, Lisa, additional, Agard, David, additional, Emerman, Michael, additional, Ruggero, Davide, additional, García-Sastre, Adolfo, additional, Jura, Natalia, additional, Zastrow, Mark von, additional, Taunton, Jack, additional, Schwartz, Olivier, additional, Vignuzzi, Marco, additional, d’Enfert, Christophe, additional, Mukherjee, Shaeri, additional, Jacobson, Matt, additional, Malik, Harmit S., additional, Fujimori, Danica G., additional, Ideker, Trey, additional, Craik, Charles S., additional, Floor, Stephen, additional, Fraser, James S., additional, Gross, John, additional, Sali, Andrej, additional, Kortemme, Tanja, additional, Beltrao, Pedro, additional, Shokat, Kevan, additional, Shoichet, Brian K., additional, and Krogan, Nevan J., additional

Published
2020
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15. Biophysical basis of cellular multi-specificity encoded in a model molecular switch

Author

Perica, Tina, primary, Mathy, Christopher J. P., additional, Xu, Jiewei, additional, Jang, Gwendolyn M., additional, Zhang, Yang, additional, Kaake, Robyn, additional, Ollikainen, Noah, additional, Braberg, Hannes, additional, Swaney, Danielle L., additional, Lambright, David G., additional, Kelly, Mark J. S., additional, Krogan, Nevan J., additional, and Kortemme, Tanja, additional

Published
2020
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16. Prediction of gene expressivity through codon usage- mediated translational optimization

Author

Roller, Maša, Lucić, Vedran, Perica, Tina, and Vlahoviček, Kristian

Subjects
metagenomics, codon usage, translational optimization
Abstract

Despite degeneracy of the genetic code synonymous codons are not used with equal frequencies within a (meta)genome. Most importantly, genes that are expressed at high levels, i.e. housekeeping genes, use a preferred set codons. This finding allows us to predict gene expressivity within a (meta)genome by measuring the distance of each gene from a reference set of housekeeping genes.

Published
2010

17. Codon usage at the level of microbial communities

Author

Lucić, Vedran, Roller Milošević, Maša, Perica, Tina, Vlahoviček, Kristian, Nagy, Karoly, and Marialigeti, Karoly

Subjects
microbial ecosystem, metagenomics, high-throughput genomics, computational biology
Abstract

I will present the computational analysis of genomic data from microbial community sequencing projects in terms of synonymous codon usage (CU). The main hypothesis is that microbial communities behave as meta-genomes, with concerted evolution and selection for similar codon usage patterns across the entire ecological niche. We have demonstrated that codon usage patterns are non-random in each metagenome data-set and that there is a pronounced and statistically significant bias in use of synonymous codons across each metagenome, moreover that different metagenomes show different CU bias. We have further explored the effect of microbial genomes optimizing codon usage for translational efficiency (by selecting for synonymous codons that match the tRNA abundance and contribute to mRNA stability) in order to predict the expressivity of functionally characterized genes and to rank the gene functions according to their predicted expressivity within the entire metagenome. This revealed the existence of metagenome-wide optimization for lifestyle-specific genes (e.g. Sargasso sea metagenome shows optimization for amino acid transport across the membrane while the whale carcass metagenome selects for energy conversion functions). Finally, we have demonstrated that metagenomes contain functional categories with highly conserved CU patterns (i.e. high CU bias) and we have determined that genes in these functional categories may be candidates for horizontal gene transfer.

Published
2009

18. Codon usage bias in metagenomes

Author

Lucić, Vedran, Perica, Tina, Roller Milošević, Maša, and Vlahoviček, Kristian

Subjects
metagenomes, codon, bias, bioinformatics, metagenomi, kodoni, bioinformatika, metegenomes
Abstract

Nejednako korištenje istoznačnih kodona je prevladavajuće obilježje kod prokariota u kojem se sinonimni kodoni koriste različitom učestalošću među različitim vrstama ili čak između gena unutar istog genoma. Ovo je obilježje povezano sa zastupljenošću tRNA u stanici i može se koristiti za predviđanje razine ekspresije proteina na način da usporedimo frekvencije korištenja kodona s referentnim setom kućepaziteljskih gena. Cilj našeg istraživanja je otkriti obrasce korištenja kodona unutar metagenomskih sekvenci i provjeriti prisutnost nejednakog korištenja istoznačnih kodona na razini mikrobnih zajednica. Istražili smo učestalost korištenja sinonimnih kodona u tri metagenomska uzorka i pokazali da: a) različiti metagenomi iskazuju različite obrasce korištenja kodona, i b) genske se funkcije unutar metagenoma s visokom ekspresivnošću (u usporedbi s meta-ribosomalnim setom) podudaraju s ekološkim zahtjevima okoliša, što upućuje da se različite vrste unutar mikrobnih zajednica zaista ponašaju poput meta-genoma.

Published
2009

19. Codon usage bias in metagenomes

Author

Lucić, Vedran, Perica, Tina, Vlahoviček, Kristian, and Gerlind Wallon

Subjects
metagenomes, codon, bias, bioinformatics
Abstract

Codon usage (CU) bias is an effect predominant in prokaryotes whereby synonymous codons are used with different frequencies between different species and even between genes within a single genome. This effect is related to tRNA abundance and can be used to predict expressivity of proteins by comparing their CU with that of a reference set of housekeeping genes. Our aim was to investigate codon usage patterns within metagenomic sequences and test for a presence or absence of CU bias at the level of a microbial community. We investigated synonymous CU frequencies in three metagenome samples and have demonstrated that a) different metagenomes exhibit different patterns in codon usage, and b) gene functions within a metagenome with high predicted expressivity (compared to the meta-ribosomal set) correlate well with the ecological requirements within the environment, suggesting that different species within a microbial community indeed behave as a meta-genome.

Published
2008

27. Biochemistry and genetics are coming together to improve our understanding of genotype to phenotype relationships.

Author

Notbohm J and Perica T

Abstract

Since genome sequencing became accessible, determining how specific differences in genotypes lead to complex phenotypes such as disease has become one of the key goals in biomedicine. Predicting effects of sequence variants on cellular or organismal phenotype faces several challenges. First, variants simultaneously affect multiple protein properties and predicting their combined effect is complex. Second, effects of changes in a single protein propagate through the cellular network, which we only partially understand. In this review, we emphasize the importance of both biochemistry and genetics in addressing these challenges. Moreover, we highlight work that blurs the distinction between biochemistry and genetics fields to provide new insights into the genotype-to-phenotype relationships., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published
2024
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28. A SARS-CoV-2-Human Protein-Protein Interaction Map Reveals Drug Targets and Potential Drug-Repurposing.

Author

Gordon DE, Jang GM, Bouhaddou M, Xu J, Obernier K, O'Meara MJ, Guo JZ, Swaney DL, Tummino TA, Huettenhain R, Kaake RM, Richards AL, Tutuncuoglu B, Foussard H, Batra J, Haas K, Modak M, Kim M, Haas P, Polacco BJ, Braberg H, Fabius JM, Eckhardt M, Soucheray M, Bennett MJ, Cakir M, McGregor MJ, Li Q, Naing ZZC, Zhou Y, Peng S, Kirby IT, Melnyk JE, Chorba JS, Lou K, Dai SA, Shen W, Shi Y, Zhang Z, Barrio-Hernandez I, Memon D, Hernandez-Armenta C, Mathy CJP, Perica T, Pilla KB, Ganesan SJ, Saltzberg DJ, Ramachandran R, Liu X, Rosenthal SB, Calviello L, Venkataramanan S, Liboy-Lugo J, Lin Y, Wankowicz SA, Bohn M, Sharp PP, Trenker R, Young JM, Cavero DA, Hiatt J, Roth TL, Rathore U, Subramanian A, Noack J, Hubert M, Roesch F, Vallet T, Meyer B, White KM, Miorin L, Rosenberg OS, Verba KA, Agard D, Ott M, Emerman M, Ruggero D, García-Sastre A, Jura N, von Zastrow M, Taunton J, Ashworth A, Schwartz O, Vignuzzi M, d'Enfert C, Mukherjee S, Jacobson M, Malik HS, Fujimori DG, Ideker T, Craik CS, Floor S, Fraser JS, Gross J, Sali A, Kortemme T, Beltrao P, Shokat K, Shoichet BK, and Krogan NJ

Abstract

An outbreak of the novel coronavirus SARS-CoV-2, the causative agent of COVID-19 respiratory disease, has infected over 290,000 people since the end of 2019, killed over 12,000, and caused worldwide social and economic disruption 1,2 . There are currently no antiviral drugs with proven efficacy nor are there vaccines for its prevention. Unfortunately, the scientific community has little knowledge of the molecular details of SARS-CoV-2 infection. To illuminate this, we cloned, tagged and expressed 26 of the 29 viral proteins in human cells and identified the human proteins physically associated with each using affinity-purification mass spectrometry (AP-MS), which identified 332 high confidence SARS-CoV-2-human protein-protein interactions (PPIs). Among these, we identify 67 druggable human proteins or host factors targeted by 69 existing FDA-approved drugs, drugs in clinical trials and/or preclinical compounds, that we are currently evaluating for efficacy in live SARS-CoV-2 infection assays. The identification of host dependency factors mediating virus infection may provide key insights into effective molecular targets for developing broadly acting antiviral therapeutics against SARS-CoV-2 and other deadly coronavirus strains., Competing Interests: Conflicts: The Krogan Laboratory has received research support from Vir Biotechnology and F. Hoffmann-La Roche. Kevan Shokat has consulting agreements for the following companies involving cash and/or stock compensation: Black Diamond Therapeutics, BridGene Biosciences, Denali Therapeutics, Dice Molecules, eFFECTOR Therapeutics, Erasca, Genentech/Roche, Janssen Pharmaceuticals, Kumquat Biosciences, Kura Oncology, Merck, Mitokinin, Petra Pharma, Qulab Inc. Revolution Medicines, Type6 Therapeutics, Venthera, Wellspring Biosciences (Araxes Pharma). Jack Taunton is a cofounder and shareholder of Global Blood Therapeutics, Principia Biopharma, Kezar Life Sciences, and Cedilla Therapeutics. Jack Taunton and Phillip P. Sharp are listed as inventors on a provisional patent application describing PS3061.

Published
2020
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