8 research outputs found

    The bacteriophage–phage-inducible chromosomal island arms race designs an interkingdom inhibitor of dUTPases

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    Stl, the master repressor of the Staphylococcus aureus pathogenicity islands (SaPIs), targets phage-encoded proteins to derepress and synchronize the SaPI and the helper phage life cycles. To activate their cycle, some SaPI Stls target both phage dimeric and phage trimeric dUTPases (Duts) as antirepressors, which are structurally unrelated proteins that perform identical functions for the phage. This intimate link between the SaPI’s repressor and the phage inducer has imposed an evolutionary optimization of Stl that allows the interaction with Duts from unrelated organisms. In this work, we structurally characterize this sophisticated mechanism of specialization by solving the structure of the prototypical SaPIbov1 Stl in complex with a prokaryotic and a eukaryotic trimeric Dut. The heterocomplexes with Mycobacterium tuberculosis and Homo sapiens Duts show the molecular strategy of Stl to target trimeric Duts from different kingdoms. Our structural results confirm the participation of the five catalytic motifs of trimeric Duts in Stl binding, including the C-terminal flexible motif V that increases the affinity by embracing Stl. In silico and in vitro analyses with a monomeric Dut support the capacity of Stl to recognize this third family of Duts, confirming this protein as a universal Dut inhibitor in the different kingdoms of life

    Use of an interactomics pipeline to assess the potential of new antivirals against SARS-CoV-2

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    (Póster 80) Background: In late 2019 SARS-CoV-2 infection appeared in China, becoming a pandemic in 2020. The scientific community reacted rapidly, characterizing the viral genome and its encoded proteins, aiming at interfering with viral spreading with vaccines and antivirals. The receptor binding domain (RBD) of the viral spike (S) protein plays a key role in cell entry of the virus. It interacts with the cellular receptor for SARS-CoV-2, the membrane-bound human Angiotensin Converting Ectoenzyme 2 (ACE2). With the goal of monitoring interference with this interaction by potential antiviral drugs, we have set up at the Institute for Biomedicine of Valencia (IBV-CSIC) an interactomics pipeline targeting the initial step of viral entry. Methods: For the production part of the pipeline (pure RBD/Spike variants and soluble ACE2), see parallel poster. These proteins allowed monitoring of the RBD/Spike-ACE2 interaction in presence or absence of potential inhibitors. Thermal shift assays (thermofluor) were used for initial detection of compound binding at different ligand/protein ratios and media conditions (pH, buffers, chaotropic agents). Next, binding affinity and on/off kinetics were characterized using Biolayer interferometry (BLI), Surface plasmon resonance (SPR), Microscale Thermophoresis (MST) and/or Isothermal titration calorimetry (ITC). For protein-protein interactions, we mostly used BLI or SPR, whereas for proteinsmall compound analysis MST was generally best. Protein aggregation-dissociation was monitored by size exclusion chromatography with multiangle light scattering (SEC-MALS). Results: Candidates proven by thermal shift assays to bind to RBD/spike protein without affecting the integrity of these proteins were subjected to quantitative affinity measurements. We successfully demonstrated that BLI, SPR and MST can be used to follow the interactions between SARS-CoV- 2 proteins and the putative drug candidates, as well as to monitor the interference with Spike-Ace2 binding of potential drug candidates. While BLI and SPR displayed reproducible results in the measurement of protein-protein interaction (applied to soluble ACE2 used as a decoy), they were less suitable for measuring the binding of small molecules. The fact that most small compounds were only soluble in organic solvents made difficult to obtain a low signal/noise while using BLI, necessary for the assessment of the binding. We overcame that problem by using MST. After dilution of the compounds to the final experimental concentrations, the technique could detect a significant binding signal enough to calculate binding parameters. MST also allowed to measure the degree of interference that each compound was having on RBD/Spike-ACE2 interaction. The pipeline has been customized and validated with compounds of very different nature provided by different groups belonging to the PTI and other external laboratories, as well as with different Ace2 decoys designed at the IBV. Conclusions: The interactomics platform at the IBV has been used to successfully develop two different antiviral approaches in order to fight COVID-19. It has allowed technical specialization of the staff as well as the development, in a very short period of time, of two ambitious projects. We have demonstrated that we can perform interactomic characterization for challenging projects as well as provide information about binding of antivirals to potential new SARS-CoV-2 variants of concern

    The structural role of SARS-CoV-2 genetic background in the emergence and success of spike mutations: The case of the spike A222V mutation

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    The S:A222V point mutation, within the G clade, was characteristic of the 20E (EU1) SARS-CoV-2 variant identified in Spain in early summer 2020. This mutation has since reappeared in the Delta subvariant AY.4.2, raising questions about its specific effect on viral infection. We report combined serological, functional, structural and computational studies characterizing the impact of this mutation. Our results reveal that S:A222V promotes an increased RBD opening and slightly increases ACE2 binding as compared to the parent S:D614G clade. Finally, S:A222V does not reduce sera neutralization capacity, suggesting it does not affect vaccine effectiveness

    New findings with the IBV decoy for cell entry inhibition of SARS-CoV-2, and unique structural data for soluble dimeric ACE2 bound to the viral S trimer

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    Resumen del trabajo presentado a las III Jornadas Científicas PTI+ Salud Global, celebradas en el Centro de Ciencias Humanas y Sociales (CCHS), CSIC (Madrid) del 20 al 22 de noviembre de 2023.[Background] The SARS-CoV-2 spike protein (S) mediates the interaction of the virus with cellular membrane receptor (angiotensin-converting enzyme 2, ACE2). In previous PTI meetings, we reported heterologous production in vitro of the ACE2 extracellular domains modified by site-directed mutagenesis to increase its affinity for the S protein, to enable it to be used as viral entry inhibitor (decoy) by competing with the membrane-bound cellular receptor. We now test the value of these decoys for: 1) binding to S variants that emerged during the evolution of the pandemic in viral lineages of concern; and 2) inhibiting experimental cellular infection by pseudotyped virus expressing these S variants. Cellular syncytia formation has been described in several organs as a manifestation of severe COVID-19, and likely has pathogenic impact. To test further our decoys’ effectiveness, we studied their impact on cellular syncytia formation within an experimental in vitro cell culture model. Searching for effective decoys, we produced monomeric and dimeric ACE2 proteins, depending on the respective absence/presence of the extracellular collectrin domain. Interestingly, there are no reported structures of dimeric soluble ACE2 bound to the S protein. After extensive knowledge-guided trial-and-error, we succeeded in visualizing by cryo-electron microscopy (cryoEM) this interaction (~7-Å-resolution), and in understanding the challenges inherent in determining such a complex structural organization.[Methods] 1) Recombinant production and purification of the monomeric or dimeric ACE2, their decoys the receptor binding domain (RBD) and the S protein variants of interest. We used baculovirus/insect cells to produce ACE2s and RBDs, and human Expi293F cells for the S proteins. 2) Biolayer interferometry for assessing protein-protein interactions; 3) Use of a model system for monitoring viral cellular infection and its inhibition by decoys. We used a pseudotyped engineered vesicular stomatitis virus expressing and exposing at its surface the desired S protein variant, to infect appropriate SARS-CoV-2-susceptible mammalian cells; 4) Single-particle cryoEM; 5) Syncytia formation testing using an engineered cultured cell system in which heterologous surface expression of the S protein in one cell type induces syncytium formation in other cells expressing membrane-bound ACE2.[Results] Our decoys proved highly effective in preventing cellular infection by pseudotyped virus expressing the S proteins of different SARS-CoV-2 variants of concern. Biophysical results have validated the maintained interaction between the decoy and the various S protein variants. When introduced into the cellular model system for syncytia formation, the decoys proved capable of decreasing such formation. Puzzlingly, the monomeric decoy was more effective than the dimeric one. The cryoEM images unveiled an ACE2 dimer configuration, where the subunits, resembling the previously reported monomer, were oriented at an angle of >60º, in which the vortex was the interlinked collectrin domains. Both catalytic domains engage with a single RBD of one subunit from different S trimers. The formation of a network at high stoichiometries of both components poses a challenge for structure determination by cryoEM.[Conclusions] Unlike therapeutic antibodies, which proved ineffective on variants not initially used for their production, our decoys should be effective in preventing infection by all widely widespread SARS-CoV-2 variants.Peer reviewe

    The structural role of SARS-CoV-2 genetic background in the emergence and success of spike mutations: the case of the spike A222V mutation

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    The S:A222V point mutation, within the G clade, was characteristic of the 20E (EU1) SARS-CoV-2 variant identified in Spain in early summer 2020. This mutation has now reappeared in the Delta subvariant AY.4.2, raising questions about its specific effect on viral infection. We report combined serological, functional, structural and computational studies characterizing the impact of this mutation. Our results reveal that S:A222V promotes an increased RBD opening and slightly increases ACE2 binding as compared to the parent S:D614G clade. Finally, S:A222V does not reduce sera neutralization capacity, suggesting it does not affect vaccine effectiveness.This research work was supported by the European Commission–NextGenerationEU through the CSIC Global Health Platform. Additionally, authors would like to acknowledge economic support from the Spanish Ministry of Science and Innovation through Grants: PID2019-104757RB-I00 funded by MCIN/AEI/ 10.13039/501100011033, RTI2018-094399-A-I00, and “ERDF A way of making Europe”, by the “European Union”, Grant SEV 2017-0712 funded by MCIN/AEI /10.13039/501100011033, the “Comunidad Autónoma de Madrid" through Grant: S2017/BMD3817, and the European Union (EU) and Horizon 2020 through grants: Marie-Curie Fellowship EnLaCES (MSCA IF 2020, Proposal: 101024130) (to JK), HighResCells (ERC - 2018 - SyG, Proposal: 810057), and iNEXT-Discovery (Proposal: 871037). AM, VR, JB and JLL are funded by CIBERER-ISCIII (proposal: COV20/00437), Fondo Supera COVID-19 (proposal: CSICCOVID19-082), Banco Santander (Proposal: BlockAce), and CSIC PTI Salud Global (Proposal: 202080E110). VR is funded by the Spanish Ministry of Science and Innovation through Grant PID2020-120322RB-C21. IC is funded by project PID2019-104477RB-100, Fondo COVID COV20/00140 and ERC CoG 101001038. MC is funded by the RyC program from the Spanish Ministry of Science and Innovation, the Generalitat Valenciana (SEJI/2019/011).N

    Estudios estructurales y funcionales de dUTPasas, una amplia familia de enzimas metabólicas con funciones reguladoras

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    El dUTP es el nucleótido no canónico mayoritario en la célula. Su errónea incorporación en el ADN dispara los sistemas de reparación, los cuales pueden causar la muerte celular por una actuación ininterrumpida. Con el objetivo de prevenir esta situación, y conocida la incapacidad de las ADN polimerasas de distinguir entre el dTTP y el dUTP, las células poseen las proteínas dUTPasas (Duts), capaces de degradar este nucleótido no canónico y, en consecuencia, aumentar la ratio dTTP/dUTP en el pool de nucleótidos celular. A parte de la hidrólisis del dUTP, las Duts poseen otras funciones moonlighting, entre las cuales destaca la capacidad de Duts de fagos de Staphylococcus aureus de interaccionar con el principal represor de sus islas de patogenicidad (SaPIs, de sus siglas en inglés Staphylococcus aureus Patogenicity Islands), Stl, desreprimiendo la isla y permitiendo su transducción. En Tesis anteriores desarrolladas en el laboratorio donde se ha realizado ésta, se ha descifrado el mecanismo molecular de estas Duts, tanto diméricas como triméricas, en su interacción con el represor Stl de la SaPIbov1, el cual utiliza una estrategia de mimetización del sustrato de la Dut. En esta Tesis se ha confirmado la utilización de un mecanismo de interacción común de Stl a Duts triméricas de fago, Duts triméricas de procariotas, y Duts triméricas de eucariotas. Para ello se ha resuelto la estructura tridimensional de StlN-ter en complejo con Dut de Mycobacterium tuberculosis y con Dut humana. Además, se ha confirmado la interacción de Stl con la tercera familia de Duts, las monoméricas, de las cuales aún no se había descrito la interacción y con la cual se ratifica el carácter universal del Stl como inhibidor de Duts. Se propone, asimismo, un mecanismo de interacción muy similar al utilizado con las Duts de fago triméricas y en el que participarían residuos de los 5 motivos conservados. Por otro lado, la Dut de M. tuberculosis posee un loop especifico de género de 5 aminoácidos, cuya presencia determina la supervivencia de la bacteria. En esta Tesis se ha intentado identificar proteínas del propio organismo capaces de interaccionar con la Dut y el mecanismo molecular utilizado, con la finalidad de ampliar las funciones moonlighting descritas para las Duts y descifrar el posible papel de este loop en el proceso. Finalmente, junto a las Duts monomérica y triméricas, se ha hecho hincapié en una familia de proteínas íntimamente relacionadas, las MazG, propuestas como el ancestro de las Duts diméricas. En esta Tesis, se ha analizado el mecanismo molecular de la inhibición en presencia de diversos cationes divalentes sustituyentes al Mg2+, con el objetivo de descifrar si estas proteínas podrían poseer alguna función moonlighting

    The estructural role of SARS-Cov-2 genetic background on the emergence and scucess of Spike mutations: the case of the Spike A222 mutation

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    The S:A222V point mutation, within the G clade, was characteristic of the 20E (EU1) SARS-CoV-2 variant identified in Spain in early summer 2020. This mutation has since reappeared in the Delta subvariant AY.4.2, raising questions about its specific effect on viral infection. We report combined serological, functional, structural and computational studies character-izing the impact of this mutation. Our results reveal that S:A222V promotes an increased RBD opening and slightly increases ACE2 binding as compared to the parent S:D614G clade. Finally, S:A222V does not reduce sera neutralization capacity, suggesting it does not affect vaccine effectivenes
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