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

Author

Boby, M.L., Fearon, D., Ferla, M., Filep, M., Koekemoer, L., Robinson, M.C., Chodera, J.D., Lee, A.A., London, N., Delft, A. von, Delft, F. von, Achdout, H., Aimon, A., Alonzi, D.S., Arbon, R., Aschenbrenner, J.C., Balcomb, B.H., Bar-David, E., Barr, H., Ben-Shmuel, A., Bennett, J., Bilenko, V.A., Borden, B., Boulet, P., Bowman, G.R., Brewitz, L., Brun, J., Bvnbs, S., Calmiano, M., Carbery, A., Carney, D.W., Cattermole, E., Chang, E., Chernyshenko, E., Clyde, A., Coffland, J.E., Cohen, G., Cole, J.C., Contini, A., Cox, L., Croll, T.I., Cvitkovic, M., Jonghe, S. De, Dias, A., Donckers, K., Dotson, D.L., Douangamath, A., Duberstein, S., Dudgeon, T., Dunnett, L.E., Eastman, P., Erez, N., Eyermann, C.J., Fairhead, M., Fate, G., Fedorov, O., Fernandes, R.S., Ferrins, L., Foster, R., Foster, H., Fraisse, L., Gabizon, R., García-Sastre, A., Gawriljuk, V.O., Gehrtz, P., Gileadi, C., Giroud, C., Glass, W.G., Glen, R.C., Glinert, I., Godoy, A.S., Gorichko, M., Gorrie-Stone, T., Griffen, E.J., Haneef, A., Hassell Hart, S, Heer, J., Henry, M., Hill, M., Horrell, S., Huang, Q.Y.J., Huliak, V.D., Hurley, M.F.D., Israely, T., Jajack, A., Jansen, J, Jnoff, E., Jochmans, D., John, T., Kaminow, B., Kang, L., Kantsadi, A.L., Kenny, P.W., Kiappes, J.L., Kinakh, S.O., Kovar, B., Krojer, T., La, V.N.T., Laghnimi-Hahn, S., Lefker, B.A., Levy, H., Lithgo, R.M., Logvinenko, I.G., Lukacik, P., Macdonald, H.B., MacLean, E.M., Makower, L.L., Malla, T.R., Marples, P.G., Matviiuk, T., McCorkindale, W., McGovern, B.L., Melamed, S., Melnykov, K.P., Michurin, O., Miesen, P., Mikolajek, H., Milne, B.F., Minh, D., Morris, A., Morris, G.M., Morwitzer, M.J., Moustakas, D., Mowbray, C.E., Nakamura, A.M., Neto, J.B., Neyts, J., Nguyen, L, Noske, G.D., Oleinikovas, V., Oliva, G., Overheul, G.J., Owen, C.D., Pai, R., Pan, J., Paran, N., Payne, A.M., Perry, B., Pingle, M., Pinjari, J., Politi, B., Powell, A., Pšenák, V., Pulido, I., Puni, R., Rangel, V.L., Reddi, R.N., Rees, P., Reid, S.P., Reid, L., Resnick, E., Ripka, E.G., Robinson, R.P., Rodriguez-Guerra, J., Rosales, R., Rufa, D.A., Saar, K., Saikatendu, K.S., Salah, E., Schaller, D., Scheen, J., Schiffer, C.A., Schofield, C.J., Shafeev, M., Shaikh, A., Shaqra, A.M., Shi, J., Shurrush, K., Singh, S., Sittner, A., Sjö, P., Skyner, R., Smalley, A., Smeets, B., Smilova, M.D., Solmesky, L.J., Spencer, J., Strain-Damerell, C., Swamy, V., Tamir, H., Taylor, J.C., Tennant, R.E., Thompson, W., Thompson, A., Tomásio, S., Tomlinson, C.W.E., Tsurupa, I.S., Tumber, A., Vakonakis, I., Rij, R.P. van, Vangeel, L., Varghese, F.S., Vaschetto, M., Vitner, E.B., Voelz, V., Volkamer, A., Walsh, M.A., Ward, W., Weatherall, C., Weiss, S., White, K.M., Wild, C.F., Witt, K.D., Wittmann, M., Wright, N., Yahalom-Ronen, Y., Yilmaz, N.K., Zaidmann, D., Zhang, I., Zidane, H., Zitzmann, N., Zvornicanin, S.N., Boby, M.L., Fearon, D., Ferla, M., Filep, M., Koekemoer, L., Robinson, M.C., Chodera, J.D., Lee, A.A., London, N., Delft, A. von, Delft, F. von, Achdout, H., Aimon, A., Alonzi, D.S., Arbon, R., Aschenbrenner, J.C., Balcomb, B.H., Bar-David, E., Barr, H., Ben-Shmuel, A., Bennett, J., Bilenko, V.A., Borden, B., Boulet, P., Bowman, G.R., Brewitz, L., Brun, J., Bvnbs, S., Calmiano, M., Carbery, A., Carney, D.W., Cattermole, E., Chang, E., Chernyshenko, E., Clyde, A., Coffland, J.E., Cohen, G., Cole, J.C., Contini, A., Cox, L., Croll, T.I., Cvitkovic, M., Jonghe, S. De, Dias, A., Donckers, K., Dotson, D.L., Douangamath, A., Duberstein, S., Dudgeon, T., Dunnett, L.E., Eastman, P., Erez, N., Eyermann, C.J., Fairhead, M., Fate, G., Fedorov, O., Fernandes, R.S., Ferrins, L., Foster, R., Foster, H., Fraisse, L., Gabizon, R., García-Sastre, A., Gawriljuk, V.O., Gehrtz, P., Gileadi, C., Giroud, C., Glass, W.G., Glen, R.C., Glinert, I., Godoy, A.S., Gorichko, M., Gorrie-Stone, T., Griffen, E.J., Haneef, A., Hassell Hart, S, Heer, J., Henry, M., Hill, M., Horrell, S., Huang, Q.Y.J., Huliak, V.D., Hurley, M.F.D., Israely, T., Jajack, A., Jansen, J, Jnoff, E., Jochmans, D., John, T., Kaminow, B., Kang, L., Kantsadi, A.L., Kenny, P.W., Kiappes, J.L., Kinakh, S.O., Kovar, B., Krojer, T., La, V.N.T., Laghnimi-Hahn, S., Lefker, B.A., Levy, H., Lithgo, R.M., Logvinenko, I.G., Lukacik, P., Macdonald, H.B., MacLean, E.M., Makower, L.L., Malla, T.R., Marples, P.G., Matviiuk, T., McCorkindale, W., McGovern, B.L., Melamed, S., Melnykov, K.P., Michurin, O., Miesen, P., Mikolajek, H., Milne, B.F., Minh, D., Morris, A., Morris, G.M., Morwitzer, M.J., Moustakas, D., Mowbray, C.E., Nakamura, A.M., Neto, J.B., Neyts, J., Nguyen, L, Noske, G.D., Oleinikovas, V., Oliva, G., Overheul, G.J., Owen, C.D., Pai, R., Pan, J., Paran, N., Payne, A.M., Perry, B., Pingle, M., Pinjari, J., Politi, B., Powell, A., Pšenák, V., Pulido, I., Puni, R., Rangel, V.L., Reddi, R.N., Rees, P., Reid, S.P., Reid, L., Resnick, E., Ripka, E.G., Robinson, R.P., Rodriguez-Guerra, J., Rosales, R., Rufa, D.A., Saar, K., Saikatendu, K.S., Salah, E., Schaller, D., Scheen, J., Schiffer, C.A., Schofield, C.J., Shafeev, M., Shaikh, A., Shaqra, A.M., Shi, J., Shurrush, K., Singh, S., Sittner, A., Sjö, P., Skyner, R., Smalley, A., Smeets, B., Smilova, M.D., Solmesky, L.J., Spencer, J., Strain-Damerell, C., Swamy, V., Tamir, H., Taylor, J.C., Tennant, R.E., Thompson, W., Thompson, A., Tomásio, S., Tomlinson, C.W.E., Tsurupa, I.S., Tumber, A., Vakonakis, I., Rij, R.P. van, Vangeel, L., Varghese, F.S., Vaschetto, M., Vitner, E.B., Voelz, V., Volkamer, A., Walsh, M.A., Ward, W., Weatherall, C., Weiss, S., White, K.M., Wild, C.F., Witt, K.D., Wittmann, M., Wright, N., Yahalom-Ronen, Y., Yilmaz, N.K., Zaidmann, D., Zhang, I., Zidane, H., Zitzmann, N., and Zvornicanin, S.N.

Abstract

Item does not contain fulltext, We report the results of the COVID Moonshot, a fully open-science, crowdsourced, and structure-enabled drug discovery campaign targeting the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) main protease. We discovered a noncovalent, nonpeptidic inhibitor scaffold with lead-like properties that is differentiated from current main protease inhibitors. Our approach leveraged crowdsourcing, machine learning, exascale molecular simulations, and high-throughput structural biology and chemistry. We generated a detailed map of the structural plasticity of the SARS-CoV-2 main protease, extensive structure-activity relationships for multiple chemotypes, and a wealth of biochemical activity data. All compound designs (>18,000 designs), crystallographic data (>490 ligand-bound x-ray structures), assay data (>10,000 measurements), and synthesized molecules (>2400 compounds) for this campaign were shared rapidly and openly, creating a rich, open, and intellectual property-free knowledge base for future anticoronavirus drug discovery.

Published
2023

8. Structure of the Plasmodium falciparum heat shock protein 70-x substrate binding domain

Author

Schmidt, J and Vakonakis, I

Abstract

The malaria parasite Plasmodium falciparum extensively modifies erythrocytes that it invades by exporting a large complement of proteins to the host cell. Among these exported components is a single heat-shock 70 kDa class protein, PfHsp70-x, that supports the virulence and growth rate of the parasite during febrile episodes. The ATP-binding domain of PfHsp70-x has previously been resolved and showed the presence of potentially druggable epitopes that differ from those on human Hsp70 chaperones. Here, the crystallographic structure of the substrate-binding domain (SBD) of PfHsp70-x is presented in complex with a hydrophobic peptide. The PfHsp70-x SBD is shown to be highly similar to the counterpart from a human erythrocytic Hsp70 chaperone. The binding of substrate at the interface between β-sandwich and α-helical subdomains of this chaperone segment is also conserved between the malaria parasite and humans. It is hypothesized that the parasite may partly exploit human chaperones for intra-erythrocytic trafficking and maintenance of its exported proteome.

Published
2020

14. A dynamically interacting flexible loop assists oligomerisation of the Caenorhabditis elegans centriolar protein SAS-6

Author

Busch, J, Erat, M, Blank, I, Musgaard, M, Biggin, P, and Vakonakis, I

Subjects
lcsh:R, lcsh:Medicine, lcsh:Q, lcsh:Science
Abstract

Centrioles are conserved organelles fundamental for the organisation of microtubules in animal cells. Oligomerisation of the spindle assembly abnormal protein 6 (SAS-6) is an essential step in the centriole assembly process and may act as trigger for the formation of these organelles. SAS-6 oligomerisation is driven by two independent interfaces, comprising an extended coiled coil and a dimeric N-terminal globular domain. However, how SAS-6 oligomerisation is controlled remains unclear. Here, we show that in the Caenorhabditis elegans SAS-6, a segment of the N-terminal globular domain, unresolved in crystallographic structures, comprises a flexible loop that assists SAS-6 oligomerisation. Atomistic molecular dynamics simulations and nuclear magnetic resonance experiments suggest that transient interactions of this loop across the N-terminal dimerisation interface stabilise the SAS-6 oligomer. We discuss the possibilities presented by such flexible SAS-6 segments for the control of centriole formation.

Published
2019

18. PHIST proteins: at the center of host cell remodeling

Author

Warncke, J, Vakonakis, I, and Beck, H

Abstract

During the asexual cycle, Plasmodium falciparum extensively remodels the human erythrocyte to make it a suitable host cell. A large number of exported proteins facilitate this remodeling process, which causes erythrocytes to become more rigid, cytoadherent, and permeable for nutrients and metabolic products. Among the exported proteins, a family of 89 proteins, called the Plasmodium helical interspersed subtelomeric (PHIST) protein family, has been identified. While also found in other Plasmodium species, the PHIST family is greatly expanded in P. falciparum. Although a decade has passed since their first description, to date, most PHIST proteins remain uncharacterized and are of unknown function and localization within the host cell, and there are few data on their interactions with other host or parasite proteins. However, over the past few years, PHIST proteins have been mentioned in the literature at an increasing rate owing to their presence at various localizations within the infected erythrocyte. Expression of PHIST proteins has been implicated in molecular and cellular processes such as the surface display of PfEMP1, gametocytogenesis, changes in cell rigidity, and also cerebral and pregnancy-associated malaria. Thus, we conclude that PHIST proteins are central to host cell remodeling, but despite their obvious importance in pathology, PHIST proteins seem to be understudied. Here we review current knowledge, shed light on the definition of PHIST proteins, and discuss these proteins with respect to their localization and probable function. We take into consideration interaction studies, microarray analyses, or data from blood samples from naturally infected patients to combine all available information on this protein family.

Published
2016

19. Caenorhabditis elegans centriolar protein SAS-6 forms a spiral that is consistent with imparting a ninefold symmetry

Author

Hilbert, M., Erat, M. C., Hachet, V., Guichard, P., Blank, I. D., Fluckiger, I., Slater, L., Lowe, E. D., Hatzopoulos, G. N., Steinmetz, M. O., Gönczy, P., and Vakonakis, I.

Subjects
Models, Molecular, architecture, electron microscopy, Protein Conformation, Cell Cycle Proteins, Biological Sciences, centriolar, Crystallography, X-Ray, Microscopy, Electron, Animals, structure, SAS-5, Caenorhabditis elegans, Caenorhabditis elegans Proteins, X-ray crystallography
Abstract

Centrioles are evolutionary conserved organelles that give rise to cilia and flagella as well as centrosomes. Centrioles display a characteristic ninefold symmetry imposed by the spindle assembly abnormal protein 6 (SAS-6) family. SAS-6 from Chlamydomonas reinhardtii and Danio rerio was shown to form ninefold symmetric, ring-shaped oligomers in vitro that were similar to the cartwheels observed in vivo during early steps of centriole assembly in most species. Here, we report crystallographic and EM analyses showing that, instead, Caenorhabotis elegans SAS-6 self-assembles into a spiral arrangement. Remarkably, we find that this spiral arrangement is also consistent with ninefold symmetry, suggesting that two distinct SAS-6 oligomerization architectures can direct the same output symmetry. Sequence analysis suggests that SAS-6 spirals are restricted to specific nematodes. This oligomeric arrangement may provide a structural basis for the presence of a central tube instead of a cartwheel during centriole assembly in these species.

Published
2013

22. An integrin phosphorylation switch: the effect of beta3 integrin tail phosphorylation on Dok1 and talin binding

Author

Oxley, CL, Anthis, NJ, Lowe, ED, Vakonakis, I, Campbell, ID, and Wegener, KL

Subjects
macromolecular substances
Abstract

Integrins play a fundamental role in cell migration and adhesion; knowledge of how they are regulated and controlled is vital for understanding these processes. Recent work showed that Dok1 negatively regulates integrin activation, presumably by competition with talin. To understand how this occurs, we used NMR spectroscopy and x-ray crystallography to investigate the molecular details of interactions with integrins. The binding affinities of beta3 integrin tails for the Dok1 and talin phosphotyrosine binding domains were quantified using 15N-1H hetero-nuclear single quantum correlation titrations, revealing that the unphosphorylated integrin tail binds more strongly to talin than Dok1. Chemical shift mapping showed that unlike talin, Dok1 exclusively interacts with the canonical NPXY motif of the beta3 integrin tail. Upon phosphorylation of Tyr 747 in the beta3 integrin tail, however, Dok1 then binds much more strongly than talin. Thus, we show that phosphorylation of Tyr 747 provides a switch for integrin ligand binding. This switch may represent an in vivo mechanism for control of integrin receptor activation. These results have implications for the control of integrin signaling by proteins containing phosphotyrosine binding domains.

Published
2016

23. Plasmodium falciparum PHIST proteins contribute to cytoadherence and anchor PfEMP1 to the host cell cytoskeleton

Author

Oberli, A, Zurbrugg, L, Rusch, S, Brand, F, Butler, M, Day, J, Cutts, E, Lavstsen, T, Vakonakis, I, and Beck, H

Subjects
parasitic diseases
Abstract

Adherence of Plasmodium falciparum infected erythrocytes to host endothelium is conferred through the parasite-derived virulence factor PfEMP1, the major contributor to malaria severity. PfEMP1 located at knob structures on the erythrocyte surface is anchored to the cytoskeleton, and the Plasmodium Helical Interspersed Sub-Telomeric (PHIST) gene family plays a role in many host cell modification including binding the intracellular domain of PfEMP1. Here, we show that conditional reduction of the PHIST protein PFE1605w strongly reduces adhesion of infected erythrocytes to the endothelial receptor CD36. Adhesion to other endothelial receptors was less affected or even unaltered by PFE1605w depletion, suggesting that PHIST proteins might be optimised for subsets of PfEMP1 variants. PFE1605w does not play a role for PfEMP1 transport, but directly interacts with both the intracellular segment of PfEMP1 and with cytoskeletal components. This is the first report of a PHIST protein interacting with key molecules of the cytoadherence complex and the host cytoskeleton and this functional role seems to play an essential role in the pathology of P. falciparum.

Published
2016

31. Deuterium isotope effects and fractionation factors of hydrogen-bonded A:T base pairs of DNA

Author

Vakonakis, I, Salazar, M, Kang, M, Dunbar, K, and LiWang, A

Abstract

Deuterium isotope effects and fractionation factors of N1.H3-N3 hydrogen bonded Watson-Crick A:T base pairs of two DNA dodecamers are presented here. Specifically, two-bond deuterium isotope effects on the chemical shifts of (13)C2 and (13)C4, (2)delta(13)C2 and (2)delta(13)C4, and equilibrium deuterium/protium fractionation factors of H3, Phi, were measured and seen to correlate with the chemical shift of the corresponding imino proton, delta(H3). Downfield-shifted imino protons associated with larger values of (2)delta(13)C2 and (2)delta(13)C4 and smaller Phi values, which together suggested that the effective H3-N3 vibrational potentials were more anharmonic in the stronger hydrogen bonds of these DNA molecules. We anticipate that (2)delta(13)C2, (2)delta(13)C4 and Phi values can be useful gauges of hydrogen bond strength of A:T base pairs.

Published
2003

42. N-terminal domain of C. reinhardtii SAS-6 homolog Bld12p

Author

Kitagawa, D., primary, Vakonakis, I., additional, Olieric, N., additional, Hilbert, M., additional, Keller, D., additional, Olieric, V., additional, Bortfeld, M., additional, Erat, M.C., additional, Flueckiger, I., additional, Goenczy, P., additional, and Steinmetz, M.O., additional

Published
2011
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