Abstract
We report here a new drug design strategy for producing membrane-impermeant carbonic anhydrase (CA; EC 4.2.1.1) inhibitors selectively targeting the tumor-associated, membrane-bound human CAs IX and XII over off-target cytosolic isoforms. To date, this approach has only been pursued by including permanent positively charged pyridinium type or highly hydrophilic glycosidic moieties into the structure of aromatic sulfonamide CA inhibitors (CAIs). Aliphatic (propyl and butyl) sulfonic acid tails, deprotonated at physiological pH, were thus incorporated onto a benzenesulfonamide scaffold by a common 1,2,3-triazole linker and different types of spacers. Twenty such derivatives were synthesized and tested for their inhibition of target (hCAs IV, IX, and XII) and off-target CAs (hCAs I and II). Most sulfonate CAIs induced a potent inhibition of hCAs II, IX, and XII up to a low nanomolar KI range (0.9–459.4 nM) with a limited target/off-target CA selectivity of action. According to the drug design schedule, a subset of representative derivatives was assessed for their cell membrane permeability using Caco-2 cells and a developed FIA-MS/MS method. The complete membrane impermeability of the sulfonate tailed CAIs (≥98%) validated these negatively charged moieties as being suitable for achieving, in vivo, the selective targeting of the tumor-associated CAs over off-target ones.
Highlights
The World Health Organization (WHO) has defined cancer as a group of diseases involving abnormal cell growth with the potential of invade other parts of the body and spread to other organs
carbonic anhydrases (CAs) inhibitors (CAIs) of the coumarin, and sulfocoumarin types have been discovered that have shown good efficacy and significant isoform selectivity, sulfonamides remain unbeaten in terms of inhibitory potency
We report here a new drug design strategy for obtaining membrane-impermeant CAIs for selectively targeting the tumor-associated, membrane-bound hCAs IX and XII over off-target cytosolic isoforms
Summary
The World Health Organization (WHO) has defined cancer ( named malignant tumors and neoplasms) as a group of diseases involving abnormal cell growth with the potential of invade other parts of the body and spread to other organs. The high mortality rate is attributable to failure in the treatment of metastatic tumor and the development of drug resistance. Solid tumor cells show an inadequate delivery of oxygen, that is, hypoxia, because of a spatial disorganization and flow-based disruption of abnormal vasculature [3,4]. In the tumor intensively proliferating and expanding, distance between cells and existing vasculatures increases, hampering oxygen diffusion and creating an even more hypoxic environment [5,6,7]
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