Structural basis for the bi-specificity of USP25 and USP28 inhibitors.

The development of cancer therapeutics is often hindered by the fact that specific oncogenes cannot be directly pharmaceutically addressed. Targeting deubiquitylases that stabilize these oncogenes provides a promising alternative. USP28 and USP25 have been identified as such target deubiquitylases, and several small-molecule inhibitors indiscriminately inhibiting both enzymes have been developed. To obtain insights into their mode of inhibition, we structurally and functionally characterized USP28 in the presence of the three different inhibitors AZ1, Vismodegib and FT206. The compounds bind into a common pocket acting as a molecular sink. Our analysis provides an explanation why the two enzymes are inhibited with similar potency while other deubiquitylases are not affected. Furthermore, a key glutamate residue at position 366/373 in USP28/USP25 plays a central structural role for pocket stability and thereby for inhibition and activity. Obstructing the inhibitor-binding pocket by mutation of this glutamate may provide a tool to accelerate future drug development efforts for selective inhibitors of either USP28 or USP25 targeting distinct binding pockets.

MD-Based Assessment of Covalent Inhibitors in Noncovalent Association Complexes: Learning from Cathepsin K as a Test Case.

A sufficiently stable noncovalent association complex between a covalent inhibitor and its protein target is regarded as a prerequisite for the formation of a covalent complex. As this transient form can hardly be assessed experimentally, computational modeling is required to probe the suitability of a given ligand at this particular stage. To investigate which criteria should be fulfilled by suitable candidates in a molecular dynamics (MD) assessment, a systematic study was conducted with 20 complexes of cathepsin K, a papain-like cysteine protease of pharmaceutical relevance. The covalent inhibitors in these complexes were converted to their pre-reaction states, and the resulting noncovalent complexes were subjected to MD simulations. The critical distance between the electrophilic and nucleophilic reaction partners was monitored as a potential parameter to assess the suitability for covalent bond formation. Across various warhead types, a distance between 3.6 and 4.0 Å, comparable to the sum of the generalized Born radii of carbon and sulfur, was found to be stably maintained under appropriate conditions. The protonation state of the catalytic dyad and the resulting solvation pattern dramatically affected the noncovalent binding mode and the distance of the warhead to the active site. For several complexes, fluctuations in the orientation of the warhead were observed due to torsional rotations in adjacent bonds. This observation helped to explain the gradual transitions from noncovalent to covalent complexes observed in the crystal structures of three closely related nitrile-based inhibitors. According to comparative simulations conducted for a set of 13 cathepsin S complexes, the overall findings of the study appear to be transferable to related cysteine proteases as targets of covalent inhibitors.

Photoswitchable Pseudoirreversible Butyrylcholinesterase Inhibitors Allow Optical Control of Inhibition in Vitro and Enable Restoration of Cognition in an Alzheimer's Disease Mouse Model upon Irradiation.

To develop tools to investigate the biological functions of butyrylcholinesterase (BChE) and the mechanisms by which BChE affects Alzheimer's disease (AD), we synthesized several selective, nanomolar active, pseudoirreversible photoswitchable BChE inhibitors. The compounds were able to specifically influence different kinetic parameters of the inhibition process by light. For one compound, a 10-fold difference in the IC50-values (44.6 nM cis, 424 nM trans) in vitro was translated to an "all or nothing" response with complete recovery in a murine cognition-deficit AD model at dosages as low as 0.3 mg/kg.

Warhead Reactivity Limits the Speed of Inhibition of the Cysteine Protease Rhodesain.

Viral and parasitic pathogens rely critically on cysteine proteases for host invasion, replication, and infectivity. Their inhibition by synthetic inhibitors, such as vinyl sulfone compounds, has emerged as a promising treatment strategy. However, the individual reaction steps of protease inhibition are not fully understood. Using the trypanosomal cysteine protease rhodesain as a medically relevant target, we design photoinduced electron transfer (PET) fluorescence probes to detect kinetics of binding of reversible and irreversible vinyl sulfones directly in solution. Intriguingly, the irreversible inhibitor, apart from its unlimited residence time in the enzyme, reacts 5 times faster than the reversible one. Results show that the reactivity of the warhead, and not binding of the peptidic recognition unit, limits the rate constant of protease inhibition. The use of a reversible inhibitor decreases the risk of off-target side effects not only by allowing its release from an off-target but also by reducing the rate constant of binding.

Highly Selective Butyrylcholinesterase Inhibitors with Tunable Duration of Action by Chemical Modification of Transferable Carbamate Units Exhibit Pronounced Neuroprotective Effect in an Alzheimer's Disease Mouse Model.

In this study, the carbamate structure of pseudo-irreversible butyrylcholinesterase (BChE) inhibitors was optimized with regard to a longer binding to the enzyme. A set of compounds bearing different heterocycles (e.g., morpholine, tetrahydroisoquinoline, benzimidazole, piperidine) and alkylene spacers (2 to 10 methylene groups between carbamate and heterocycle) in the carbamate residue was synthesized and characterized in vitro for their binding affinity, binding kinetics, and carbamate hydrolysis. These novel BChE inhibitors are highly selective for hBChE over human acetycholinesterase (hAChE), yielding short-, medium-, and long-acting nanomolar hBChE inhibitors (with a half-life of the carbamoylated enzyme ranging from 1 to 28 h). The inhibitors show neuroprotective properties in a murine hippocampal cell line and a pharmacological mouse model of Alzheimer's disease (AD), suggesting a significant benefit of BChE inhibition for a disease-modifying treatment of AD.