Characterisation of Photoaffinity-Based Chemical Probes by Fluorescence Imaging and Native-State Mass Spectrometry.

Chemical probes are small-molecule reagents used by researchers for labelling and detection of biomolecules. We present the design, synthesis, and characterisation of a panel of 11 structurally diverse photoaffinity labelling (PAL) probes as research tools for labelling the model enzyme carbonic anhydrase (CA) in challenging environments, including in protein mixtures and cell lysates. We targeted the ubiquitous CA II as well as the two cancer-associated CAs (CA IX and CA XII) that are of high priority as potential biomarkers of aggressive and/or multidrug-resistant cancer. We utilise an atypical biophysical approach, native state mass spectrometry, to monitor the initial protein-probe binding and subsequent UV crosslinking efficiency of the protein:probe complex. This mass spectrometry methodology represents a new approach for chemical probe optimisation and development that might have broader applications to chemical probe characterisation beyond this study. This also represents one of the first studies, to the best of our knowledge, in which a comprehensive set of PAL probes has been used to establish the relationship between probe structure, noncovalent protein-probe binding, and covalent protein-probe crosslinking efficiency. Our results demonstrate the benefits of a comprehensive analysis of chemical probe structure-activity relationships to support the development of optimum chemical probes.

An Unusual Natural Product Primary Sulfonamide: Synthesis, Carbonic Anhydrase Inhibition, and Protein X-ray Structures of Psammaplin C.

Psammaplin C is one of only two described natural product primary sulfonamides. Here we report the synthesis of psammaplin C and evaluate the inhibition profile against therapeutically relevant carbonic anhydrase (CA) zinc metalloenzymes. The compound exhibited unprecedented inhibition of an important cancer-associated isozyme, hCA XII, with a Ki of 0.79 nM. The compound also displayed good isoform selectivity for hCA XII over other CAs. We present the first reported protein X-ray crystal structures of psammaplin C in complex with human CAs. We engineered the easily crystallized hCA II enzyme to mimic both the hCA IX and hCA XII binding sites and then utilized protein X-ray crystallography to determine the binding pose of psammaplin C within the hCA II, hCA IX, and hCA XII mimic active sites, all to high resolution. This is the first time a natural product primary sulfonamide inhibitor has been assessed for inhibition and binding to CAs.

Design and synthesis of thiourea compounds that inhibit transmembrane anchored carbonic anhydrases.

A library of 32 novel glycoconjugate thiourea-bridged benzene sulfonamides have been synthesized from the reaction of glycosyl isothiocyanates with a panel of simple benzene sulfonamides comprising either a free amine or hydrazide. All compounds were investigated for their ability to inhibit the enzymatic activity of five human carbonic anhydrase (hCA) isozymes: hCA I, II and membrane-associated isozymes IX, XII and XIV. A physicochemical feature of the free sugar thioureido glycoconjugates was high water solubility (> 20 mg/mL), as well many of these compounds exhibited a desirable potency and CA isozyme selectivity profile. From this library several inhibitors displayed excellent potency-selectivity profiles for transmembrane anchored CAs over off-target CA I and II. These molecules provide potential dual-acting candidates for the development of inhibitors that target the extracellular CAs (IX, XII and XIV)-either directly as free sugars (membrane impermeable) or indirectly as acetylated prodrugs, becoming free sugars upon esterase hydrolysis.