A series of cyclic active‐site‐directed inhibitors of the NS2B‐NS3 proteases from Zika (ZIKV), West Nile (WNV), and dengue‐4 (DENV4) viruses has been designed. The most potent compounds contain a reversely incorporated
d
‐lysine residue in the P1 position. Its side chain is connected to the P2 backbone, its α‐amino group is converted into a guanidine to interact with the conserved Asp129 side chain in the S1 pocket, and its C terminus is connected to the P3 residue via different linker segments. The most potent compounds inhibit the ZIKV protease with
K
i
values <5 nM. Crystal structures of seven ZIKV protease inhibitor complexes were determined to support the inhibitor design. All the cyclic compounds possess high selectivity against trypsin‐like serine proteases and furin‐like proprotein convertases. Both WNV and DENV4 proteases are inhibited less efficiently. Nonetheless, similar structure‐activity relationships were observed for these enzymes, thus suggesting their potential application as pan‐flaviviral protease inhibitors.
In recent years, crystallographic fragment screening has matured into an almost routine experiment at several modern synchrotron sites. The hits of the screening experiment, i.e. small molecules or fragments binding to the target protein, are revealed along with their 3D structural information. Therefore, they can serve as useful starting points for further structure-based hit-to-lead development. However, the progression of fragment hits to tool compounds or even leads is often hampered by a lack of chemical feasibility. As an attractive alternative, compound analogs that embed the fragment hit structurally may be obtained from commercial catalogs. Here, a workflow is reported based on filtering and assessing such potential follow-up compounds by template docking. This means that the crystallographic binding pose was integrated into the docking calculations as a central starting parameter. Subsequently, the candidates are scored on their interactions within the binding pocket. In an initial proof-of-concept study using five starting fragments known to bind to the aspartic protease endothiapepsin, 28 follow-up compounds were selected using the designed workflow and their binding was assessed by crystallography. Ten of these compounds bound to the active site and five of them showed significantly increased affinity in isothermal titration calorimetry of up to single-digit micromolar affinity. Taken together, this strategy is capable of efficiently evolving the initial fragment hits without major synthesis efforts and with full control by X-ray crystallography.
Zika virus (ZIKV) is a human pathogenic
arbovirus. So far, neither
a specific treatment nor a vaccination against ZIKV infections has
been approved. Starting from our previously described lead structure,
a series of 29 new macrocyclic inhibitors of the Zika virus protease
containing different linker motifs have been synthesized. By selecting
hydrophobic d-amino acids as part of the linker, numerous
inhibitors with K
i values < 5 nM were
obtained. For 12 inhibitors, crystal structures in complex with the
ZIKV protease up to 1.30 Å resolution were determined, which
contribute to the understanding of the observed structure–activity
relationship (SAR). In immunofluorescence assays, an antiviral effect
was observed for compound 26 containing a d-homocyclohexylalanine
residue in its linker segment. Due to its excellent selectivity profile
and low cytotoxicity, this inhibitor scaffold could be a suitable
starting point for the development of peptidic drugs against the Zika
virus and related flaviviruses.
Cyclization of small molecules is a widely applied strategy in drug design for ligand optimization to improve affinity, as it eliminates the putative need for structural preorganization of the ligand before binding, or to improve pharmacokinetic properties. In this work, we provide a deeper insight into the binding thermodynamics of a macrocyclic Zika virus NS2B/NS3 protease inhibitor and its linear analogs. Characterization of the thermodynamic binding profiles by isothermal titration calorimetry experiments revealed an unfavorable entropy of the macrocycle compared to the open linear reference ligands.Molecular dynamic simulations and X-ray crystal structure analysis indicated only minor benefits from macrocyclization to fixate a favorable conformation, while linear ligands retained some flexibility even in the protein-bound complex structure, possibly explaining the initially surprising effect of a higher entropic penalty for the macrocyclic ligand.
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