The 1,2,3‐triazole has been successfully utilized as an amide bioisostere in multiple therapeutic contexts. Based on this precedent, triazole analogues derived from VX‐809 and VX‐770, prominent amide‐containing modulators of the cystic fibrosis transmembrane conductance regulator (CFTR), were synthesized and evaluated for CFTR modulation. Triazole 11, derived from VX‐809, displayed markedly reduced efficacy in F508del‐CFTR correction in cellular TECC assays in comparison to VX‐809. Surprisingly, triazole analogues derived from potentiator VX‐770 displayed no potentiation of F508del, G551D, or WT‐CFTR in cellular Ussing chamber assays. However, patch clamp analysis revealed that triazole 60 potentiates WT‐CFTR similarly to VX‐770. The efficacy of 60 in the cell‐free patch clamp experiment suggests that the loss of activity in the cellular assay could be due to the inability of VX‐770 triazole derivatives to reach the CFTR binding site. Moreover, in addition to the negative impact on biological activity, triazoles in both structural classes displayed decreased metabolic stability in human microsomes relative to the analogous amides. In contrast to the many studies that demonstrate the advantages of using the 1,2,3‐triazole, these findings highlight the negative impacts that can arise from replacement of the amide with the triazole and suggest that caution is warranted when considering use of the 1,2,3‐triazole as an amide bioisostere.
The multidrug transporter P-glycoprotein (Pgp)/ABCB1/MDR1 plays an important role in multidrug resistance (MDR) and detoxification owing to its ability to efflux an unusually large and chemically diverse set of substrates. Previous phenylalanine-to-alanine scanning mutagenesis of Pgp revealed that nearly all mutations retained full MDR function and still permitted substrate transport. This suggests that either the loss of any single aromatic side chain did not affect the ligand-binding modes or that highly adaptive and compensatory drug recognition is an intrinsic property including ligand-binding shifts that preserve function. To explore this hypothesis, the ATPase function and crystallographic localization of five single-site mutations in which the native aromatic residue directly interacted with the environmental pollutant BDE-100, as shown in previous crystal structures, were tested. Two mutants, Y303A and Y306A, showed strong BDE-100 occupancy at the original site (site 1), but also revealed a novel site 2 located on the opposing pseudo-symmetric half of the drug-binding pocket (DBP). Surprisingly, the F724A mutant structure had no detectable binding in site 1 but exhibited a novel site shifted 11 Å from site 1. ATPase studies revealed shifts in ATPase kinetics for the five mutants, but otherwise indicated a catalytically active transporter that was inhibited by BDE-100, similar to wild-type Pgp. These results emphasize a high degree of compensatory drug recognition in Pgp that is made possible by aromatic amino-acid side chains concentrated in the DBP. Compensatory recognition forms the underpinning of polyspecific drug transport, but also highlights the challenges associated with the design of therapeutics that evade efflux altogether.
Although the 1,2,3‐triazole is a commonly used amide bioisostere in medicinal chemistry, the structural implications of this replacement have not been fully studied. Employing X‐ray crystallography and computational studies, we report the spatial and electronic consequences of replacing an amide with the triazole in analogues of cystic fibrosis drugs in the VX‐770 and VX‐809 series. Crystallographic analyses quantify subtle differences in the relative positions and conformational preferences of the R1 and R2 substituents attached to the amide and triazole bioisosteres. Computational studies derived from the X‐ray data highlight the improved hydrogen bonding donor and acceptor capabilities of the amide in comparison to the triazole. This analysis of the spatial and electronic differences between the amide and 1,2,3‐triazole will inform medicinal chemists as they consider using the triazole as an amide bioisostere.
The Cover Feature shows a representation of the subtle structural differences between the trans‐amide and 1,2,3‐triazole bioisosteres. As amide looks into the mirror and sees triazole, the question arises: do they look alike? Below the cartoon is an X‐ray structure of an amide‐containing cystic fibrosis drug. The atoms in yellow highlight the drug's planar structure. Above the cartoon is an X‐ray structure of the notably less planar triazole analog. The image background is the region of the cystic fibrosis transmembrane conductance regulator (CFTR) in which these drugs bind. A description of the subtle structural differences between the amide and triazole can be found in the Full Paper by Jake E. Doiron, Christina A. Le, Stephen G. Aller, Mark Turlington et al.
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