Demonstrating
intracellular protein target engagement is an essential step in the
development and progression of new chemical probes and potential small
molecule therapeutics. However, this can be particularly challenging
for poorly studied and noncatalytic proteins, as robust proximal biomarkers
are rarely known. To confirm that our recently discovered chemical
probe 1 (CCT251236) binds the putative transcription
factor regulator pirin in living cells, we developed a heterobifunctional
protein degradation probe. Focusing on linker design and physicochemical
properties, we generated a highly active probe 16 (CCT367766)
in only three iterations, validating our efficient strategy for degradation
probe design against nonvalidated protein targets.
Phenotypic screens, which focus on
measuring and quantifying discrete
cellular changes rather than affinity for individual recombinant proteins,
have recently attracted renewed interest as an efficient strategy
for drug discovery. In this article, we describe the discovery of
a new chemical probe, bisamide (CCT251236), identified using an unbiased
phenotypic screen to detect inhibitors of the HSF1 stress pathway.
The chemical probe is orally bioavailable and displays efficacy in
a human ovarian carcinoma xenograft model. By developing cell-based
SAR and using chemical proteomics, we identified pirin as a high affinity
molecular target, which was confirmed by SPR and crystallography.
Nitrile reductase QueF catalyzes the reduction of 2-amino-5-cyanopyrrolo[2,3-d]pyrimidin-4-one (preQ0) to 2-amino-5-aminomethylpyrrolo[2,3-d]pyrimidin-4-one (preQ1) in the biosynthetic pathway of the hypermodified nucleoside queuosine. It is the only enzyme known to catalyze a reduction of a nitrile to its corresponding primary amine and could therefore expand the toolbox of biocatalytic reactions of nitriles. To evaluate this new oxidoreductase for application in biocatalytic reactions, investigation of its substrate scope is prerequisite. We report here an investigation of the active site binding properties and the substrate scope of nitrile reductase QueF from Escherichia coli. Screenings with simple nitrile structures revealed high substrate specificity. Consequently, binding interactions of the substrate to the active site were identified based on a new homology model of E. coli QueF and modeled complex structures of the natural and non-natural substrates. Various structural analogues of the natural substrate preQ0 were synthesized and screened with wild-type QueF from E. coli and several active site mutants. Two amino acid residues Cys190 and Asp197 were shown to play an essential role in the catalytic mechanism. Three non-natural substrates were identified and compared to the natural substrate regarding their specific activities by using wild-type and mutant nitrile reductase.
The enzyme QueF catalyzes a four-electron reduction of a nitrile group into an amine, the only reaction of this kind known in biology. In nature, QueF converts 7-cyano-7-deazaguanine (preQ) into 7-aminomethyl-7-deazaguanine (preQ) for the biosynthesis of the tRNA-inserted nucleoside queuosine. The proposed QueF mechanism involves a covalent thioimide adduct between preQ and a cysteine nucleophile in the enzyme, and this adduct is subsequently converted into preQ in two NADPH-dependent reduction steps. Here, we show that the Escherichia coli QueF binds preQ in a strongly exothermic process (ΔH = -80.3 kJ/mol; -TΔS = 37.9 kJ/mol, K = 39 nm) whereby the thioimide adduct is formed with half-of-the-sites reactivity in the homodimeric enzyme. Both steps of preQ reduction involve transfer of the 4-pro-R-hydrogen from NADPH. They proceed about 4-7-fold more slowly than trapping of the enzyme-bound preQ as covalent thioimide (1.63 s) and are thus mainly rate-limiting for the enzyme's k (=0.12 s). Kinetic studies combined with simulation reveal a large primary deuterium kinetic isotope effect of 3.3 on the covalent thioimide reduction and a smaller kinetic isotope effect of 1.8 on the imine reduction to preQ 7-Formyl-7-deazaguanine, a carbonyl analogue of the imine intermediate, was synthesized chemically and is shown to be recognized by QueF as weak ligand for binding (ΔH = -2.3 kJ/mol; -TΔS = -19.5 kJ/mol) but not as substrate for reduction or oxidation. A model of QueF substrate recognition and a catalytic pathway for the enzyme are proposed based on these data.
Abstract:The cloning, expression and characterization of a nitrile reductase (NRed) from the thermophile Geobacillus kaustophilus is reported. The enzyme shows a 12-fold increase in activity in response to a temperature change from 25 8C to 658C. The substrate scope regarding its biocatalytic applicability was investigated by testing a range of common nitriles. The narrow substrate range observed for the wild-type enzyme prompted the rational design of GkNRed active site mutants based on a previously published homology model from Bacillus subtilis. The activities of the mutants and the wild-type enzyme were investigated in their structure-function relationship regarding the natural substrate 7-cyano-7-deazaguanine (preQ 0 ) as well as a range of synthesized preQ 0 -like substrate structures. A distinct dependence of the wild-type enzyme activity on specific structural modifications of the natural substrate was observed. Two non-natural nitriles derived from preQ 0 could be reduced to their corresponding amino compounds.
We report a new chemoenzymatic cascade starting with aldehyde synthesis by carboxylic acid reductase (CAR) followed by chemical in situ oxime formation. The final step to the nitrile is catalyzed...
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