Adrián Velázquez‐Campoy scite author profile

SARS (severe acute respiratory syndrome) is caused by a newly discovered coronavirus. A key enzyme for the maturation of this virus and, therefore, a target for drug development is the main protease 3CL(pro) (also termed SARS-CoV 3CL(pro)). We have cloned and expressed in Escherichia coli the full-length SARS-CoV 3CL(pro) as well as a truncated form containing only the catalytic domains. The recombinant proteins have been characterized enzymatically using a fluorescently labeled substrate; their structural stability in solution has been determined by differential scanning calorimetry, and novel inhibitors have been discovered. Expression of the catalytic region alone yields a protein with a reduced catalytic efficiency consistent with the proposed regulatory role of the alpha-helical domain. Differential scanning calorimetry indicates that the alpha-helical domain does not contribute to the structural stability of the catalytic domains. Analysis of the active site cavity reveals the presence of subsites that can be targeted with specific chemical functionalities. In particular, a cluster of serine residues (Ser139, Ser144, and Ser147) was identified near the active site cavity and was susceptible to being targeted by compounds containing boronic acid. This cluster is highly conserved in similar proteases from other coronaviruses, defining an attractive target for drug development. It was found that bifunctional aryl boronic acid compounds were particularly effective at inhibiting the protease, with inhibition constants as strong as 40 nM. Isothermal titration microcalorimetric experiments indicate that these inhibitors bind reversibly to 3CL(pro) in an enthalpically favorable fashion, implying that they establish strong interactions with the protease molecule, thus defining attractive molecular scaffolds for further optimization.

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Isothermal titration calorimetry to determine association constants for high-affinity ligands

Velázquez‐Campoy¹,

2006

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An important goal in drug development is to engineer inhibitors and ligands that have high binding affinities for their target molecules. In optimizing these interactions, the precise determination of the binding affinity becomes progressively difficult once it approaches and surpasses the nanomolar level. Isothermal titration calorimetry (ITC) can be used to determine the complete binding thermodynamics of a ligand down to the picomolar range by using an experimental mode called displacement titration. In a displacement titration, the association constant of a high-affinity ligand that cannot be measured directly is artificially lowered to a measurable level by premixing the protein with a weaker competitive ligand. To perform this protocol, two titrations must be carried out: a direct titration of the weak ligand to the target macromolecule and a displacement titration of the high-affinity ligand to the weak ligand-target macromolecule complex. This protocol takes approximately 5 h.

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Structural stability of SARS-CoV-2 3CLpro and identification of quercetin as an inhibitor by experimental screening

Abián

Ortega-Alarcón

Jiménez-Alesanco

et al. 2020

International Journal of Biological Macromolecules

221

211

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The global health emergency generated by coronavirus disease 2019 (COVID-19) has prompted the search for preventive and therapeutic treatments for its pathogen, the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). There are many potential targets for drug discovery and development to tackle this disease. One of these targets is the main protease, Mpro or 3CLpro, which is highly conserved among coronaviruses. 3CLpro is an essential player in the viral replication cycle, processing the large viral polyproteins and rendering the individual proteins functional. We report a biophysical characterization of the structural stability and the catalytic activity of 3CLpro from SARS-CoV-2, from which a suitable experimental in vitro molecular screening procedure has been designed. By screening of a small chemical library consisting of about 150 compounds, the natural product quercetin was identified as reasonably potent inhibitor of SARS-CoV-2 3CLpro (K i ~ 7 μM). Quercetin could be shown to interact with 3CLpro using biophysical techniques and bind to the active site in molecular simulations. Quercetin, with well-known pharmacokinetic and ADMET properties, can be considered as a good candidate for further optimization and development, or repositioned for COVID-19 therapeutic treatment.

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