Background and purpose: The recent development of the UT ligand palosuran (1-[2-(4-benzyl-4-hydroxy-piperidin-1-yl)-ethyl]-3-(2-methyl-quinolin-4-yl)-urea sulphate salt) has led to the proposition that urotensin-II (U-II) plays a significant pathological role in acute and chronic renal injury in the rat. Experimental approach: In the present study, the pharmacological properties of palosuran were investigated further using a series of radioligand binding and functional bioassays. Key results: Palosuran functioned as a 'primate-selective' UT ligand in recombinant cell membranes (monkey and human UT K i values of 4±1 and 5±1 nM), lacking appreciable affinity at other mammalian UT isoforms (rodent and feline K i values 41 mM). Paradoxically, however, palosuran lost significant (10-to 54-fold) affinity for native and recombinant human UT when radioligand binding was performed in intact cells (K i values of 50±3 and 276±67 nM). In accordance, palosuran also exhibited diminished activity in hUT (human urotensin-II receptor)-CHO (Chinese hamster ovary) cells (IC 50 323 ± 67 nM) and isolated arteries (K b 410 mM in rat aorta; K b 48.5 mM in cat arteries; K b 41.6 mM in monkey arteries; K b 2.2±0.6 mM in hUT transgenic mouse aorta). Relative to recombinant binding K i values, palosuran was subjected to a 392-to 690-fold reduction in functional activity in monkey isolated arteries. Such phenomena were peculiar to palosuran and were not apparent with an alternative chemotype, SB-657510 (2-bromo-N-[4-chloro-3-((R)-1-methyl-pyrrolidin-3-yloxy)-phenyl]-4,5-dimethoxybenzenesulphonamide HCl). Conclusions and implications: Collectively, such findings suggest that caution should be taken when interpreting data generated using palosuran. The loss of UT affinity/activity observed in intact cells and tissues cf. membranes offers a potential explanation for the disappointing clinical efficacy reported with palosuran in diabetic nephropathy patients. As such, the (patho)physiological significance of U-II in diabetic renal dysfunction remains uncertain.
Pulmonary edema is a common ailment of heart failure patients and has remained an unmet medical need due to dose-limiting side effects associated with current treatments. Preclinical studies in rodents have suggested that inhibition of transient receptor potential vanilloid-4 (TRPV4) cation channels may offer an alternativeand potentially superiortherapy. Efforts directed toward small-molecule antagonists of the TRPV4 receptor have led to the discovery of a novel sulfone pyrrolidine sulfonamide chemotype exemplified by lead compound 6. Design elements toward the optimization of TRPV4 activity, selectivity, and pharmacokinetic properties are described. Activity of leading exemplars 19 and 27 in an in vivo model suggestive of therapeutic potential is highlighted herein.
GSK3527497,
a preclinical candidate for the inhibition of TRPV4,
was identified starting from the previously reported pyrrolidine sulfonamide
TRPV4 inhibitors 1 and 2. Optimization of
projected human dose was accomplished by specifically focusing on
in vivo pharmacokinetic parameters CLu, Vdssu, and MRT. We highlight the use of conformational changes as a novel
approach to modulate Vdssu and present results that suggest
that molecular-shape-dependent binding to tissue components governs
Vdssu in addition to bulk physicochemical properties. Optimization
of CLu within the series was guided by in vitro metabolite
identification, and the poor FaSSIF solubility imparted by the crystalline
properties of the pyrrolidine diol scaffold was improved by the introduction
of a charged moiety to enable excellent exposure from high crystalline
doses. GSK3527497 is a preclinical candidate suitable for oral and
iv administration that is projected to inhibit TRPV4 effectively in
patients from a low daily clinical dose.
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