Effects of soluble guanylate cyclase stimulator on renal function in ZSF-1 model of diabetic nephropathy.

BACKGROUND: Diabetic nephropathy is associated with endothelial dysfunction and oxidative stress, in which the nitric oxide-soluble guanylate cyclase-cyclic guanosine monophosphate (NO-sGC-cGMP) signaling pathway is impaired. We hypothesize that sGC stimulator Compound 1 can enhance NO signaling, reduce proteinuria in a diabetic nephropathy preclinical model with diminished NO bioavailability and increased oxidized sGC. Therefore, we evaluated the effect of sGC stimulator Compound 1 on the renal effect in obese ZSF1 (ZSF1 OB) rats. MATERIALS AND METHODS: The sGC stimulator Compound 1, the standard of care agent Enalapril, and a combination of Compound 1 and Enalapril were administered chronically to obese ZSF1 rats for 6 months. Mean arterial pressure, heart rate, creatinine clearance for glomerular filtration rate (eGFR), urinary protein excretion to creatinine ratio (UPCR), and urinary albumin excretion ratio (UACR) were determined during the study. The histopathology of glomerular and interstitial lesions was assessed at the completion of the study. RESULTS: While both Compound 1 and Enalapril significantly reduced blood pressure, the combination of Compound 1 and Enalapril normalized blood pressure levels. Compound 1 improved eGFR and reduced UPCR and UACR. A combination of Enalapril and Compound 1 resulted in a marked reduction in UPCR and UACR and improved GFR. CONCLUSION: The sGC stimulator Compound 1 as a monotherapy slowed renal disease progression, and a combination of the sGC stimulator with Enalapril provided greater renal protection in a rodent model of diabetic nephropathy.

High-Throughput Screening to Identify Small Molecules That Selectively Inhibit APOL1 Protein Level in Podocytes.

High-throughput phenotypic screening is a key driver for the identification of novel chemical matter in drug discovery for challenging targets, especially for those with an unclear mechanism of pathology. For toxic or gain-of-function proteins, small-molecule suppressors are a targeting/therapeutic strategy that has been successfully applied. As with other high-throughput screens, the screening strategy and proper assays are critical for successfully identifying selective suppressors of the target of interest. We executed a small-molecule suppressor screen to identify compounds that specifically reduce apolipoprotein L1 (APOL1) protein levels, a genetically validated target associated with increased risk of chronic kidney disease. To enable this study, we developed homogeneous time-resolved fluorescence (HTRF) assays to measure intracellular APOL1 and apolipoprotein L2 (APOL2) protein levels and miniaturized them to 1536-well format. The APOL1 HTRF assay served as the primary assay, and the APOL2 and a commercially available p53 HTRF assay were applied as counterscreens. Cell viability was also measured with CellTiter-Glo to assess the cytotoxicity of compounds. From a 310,000-compound screening library, we identified 1490 confirmed primary hits with 12 different profiles. One hundred fifty-three hits selectively reduced APOL1 in 786-O, a renal cell adenocarcinoma cell line. Thirty-one of these selective suppressors also reduced APOL1 levels in conditionally immortalized human podocytes. The activity and specificity of seven resynthesized compounds were validated in both 786-O and podocytes.

Robust arterial spin labeling MRI measurement of pharmacologically induced perfusion change in rat kidneys.

Kidney diseases such as acute kidney injury, diabetic nephropathy and chronic kidney disease (CKD) are related to dysfunctions of the microvasculature in the kidney causing a decrease in renal blood perfusion (RBP). Pharmacological intervention to improve the function of the microvasculature is a viable strategy for the potential treatment of these diseases. The measurement of RBP is a reliable biomarker to evaluate the efficacy of pharmacological agents' actions on the microvasculature, and measurement of RBP responses to different pharmacological agents can also help elucidate the mechanism of hemodynamic regulation in the kidney. Magnetic resonance imaging (MRI) with flow-sensitive alternating inversion recovery (FAIR) arterial spin labeling (ASL) has been used to measure RBP in humans and animals. However, artifacts caused by respiratory and peristaltic motions limit the potential of FAIR ASL in drug discovery and kidney research. In this study, the combined anesthesia protocol of inactin with a low dose of isoflurane was used to fully suppress peristalsis in rats, which were ventilated with an MRI-synchronized ventilator. FAIR ASL data were acquired in eight axial slices using a single-shot, gradient-echo, echo-planar imaging (EPI) sequence. The artifacts in the FAIR ASL RBP measurement due to respiratory and peristaltic motions were substantially eliminated. The RBP responses to fenoldopam and L-NAME were measured, and the increase and decrease in RBP caused by fenoldopam and L-NAME, respectively, were robustly observed. To further validate FAIR ASL, the renal blood flow (RBF) responses to the same agents were measured by an invasive perivascular flow probe method. The pharmacological agent-induced responses in RBP and RBF are similar. This indicates that FAIR ASL has the sensitivity to measure pharmacologically induced changes in RBP. FAIR ASL with multislice EPI can be a valuable tool for supporting drug discovery, and for elucidating the mechanism of hemodynamic regulation in kidneys.

Discovery of Dihydrobenzoxazepinone (GS-6615) Late Sodium Current Inhibitor (Late INai), a Phase II Agent with Demonstrated Preclinical Anti-Ischemic and Antiarrhythmic Properties.

Late sodium current (late INa) is enhanced during ischemia by reactive oxygen species (ROS) modifying the Nav 1.5 channel, resulting in incomplete inactivation. Compound 4 (GS-6615, eleclazine) a novel, potent, and selective inhibitor of late INa, is currently in clinical development for treatment of long QT-3 syndrome (LQT-3), hypertrophic cardiomyopathy (HCM), and ventricular tachycardia-ventricular fibrillation (VT-VF). We will describe structure-activity relationship (SAR) leading to the discovery of 4 that is vastly improved from the first generation late INa inhibitor 1 (ranolazine). Compound 4 was 42 times more potent than 1 in reducing ischemic burden in vivo (S-T segment elevation, 15 min left anteriorior descending, LAD, occlusion in rabbits) with EC50 values of 190 and 8000 nM, respectively. Compound 4 represents a new class of potent late INa inhibitors that will be useful in delineating the role of inhibitors of this current in the treatment of patients.

A novel, potent, and selective inhibitor of cardiac late sodium current suppresses experimental arrhythmias.

Inhibition of cardiac late sodium current (late I(Na)) is a strategy to suppress arrhythmias and sodium-dependent calcium overload associated with myocardial ischemia and heart failure. Current inhibitors of late I(Na) are unselective and can be proarrhythmic. This study introduces GS967 (6-[4-(trifluoromethoxy)phenyl]-3-(trifluoromethyl)-[1,2,4]triazolo[4,3-a]pyridine), a potent and selective inhibitor of late I(Na), and demonstrates its effectiveness to suppress ventricular arrhythmias. The effects of GS967 on rabbit ventricular myocyte ion channel currents and action potentials were determined. Anti-arrhythmic actions of GS967 were characterized in ex vivo and in vivo rabbit models of reduced repolarization reserve and ischemia. GS967 inhibited Anemonia sulcata toxin II (ATX-II)-induced late I(Na) in ventricular myocytes and isolated hearts with IC(50) values of 0.13 and 0.21 µM, respectively. Reduction of peak I(Na) by GS967 was minimal at a holding potential of -120 mV but increased at -80 mV. GS967 did not prolong action potential duration or the QRS interval. GS967 prevented and reversed proarrhythmic effects (afterdepolarizations and torsades de pointes) of the late I(Na) enhancer ATX-II and the I(Kr) inhibitor E-4031 in isolated ventricular myocytes and hearts. GS967 significantly attenuated the proarrhythmic effects of methoxamine+clofilium and suppressed ischemia-induced arrhythmias. GS967 was more potent and effective to reduce late I(Na) and arrhythmias than either flecainide or ranolazine. Results of all studies and assays of binding and activity of GS967 at numerous receptors, transporters, and enzymes indicated that GS967 selectively inhibited late I(Na). In summary, GS967 selectively suppressed late I(Na) and prevented and/or reduced the incidence of experimentally induced arrhythmias in rabbit myocytes and hearts.

Evaluation of bioimpedance spectroscopy for the measurement of body fluid compartment volumes in rats.

INTRODUCTION: Bioimpedance spectroscopy (BIS) has been used in human and large animal research to assess body fluid compartment volumes (BFC) such as total body water (TBW), extracellular fluid volume (ECFV), and intracellular fluid volume (ICFV). To date, the application of BIS for determination of BFC in small research animals has been limited. METHODS: We sought to evaluate the sensitivity and consistency of BIS for the determination of BFC in male SD rats. Thus, in separate series of experiments, we a) compared BFC values determined using BIS to BFC values obtained using radioisotope indicator dilution methods; b) examined day-to-day intra- and inter-rat BFC variability in small (267.8±5.4 g) and large (372.6±5.6 g) rats (n=8/group) as compared to empirical normative mammalian values; c) evaluated the sensitivity of BIS to detect time-dependent responses to repeated administration of a potent diuretic; and d) compared empirically generated BFC data to predicted osmotically-induced ECFV and ICFV shifts in response to i.v. administration of hypotonic (0.3%), isotonic (0.9%) or hypertonic (3.0%) saline (n=6/concentration). RESULTS: BFC values generated using radioisotope dilution agreed with those generated using BIS. BIS reliably detected differences between small and large rats (p<0.001), and was associated with low (<3.5%) day-to-day, intra-animal coefficient of variation (%=Standard Deviation/mean). BIS detected small reductions (~10%) in ECFV induced by as few as 2 days of the loop diuretic, furosemide, relative to vehicle treatment (70.8±1.5 ml vs. 84.0±1.5 ml; respectively, p<0.05). BIS rapidly detected shifts between ECFV and ICFV in response to osmotic saline challenge, and these responses were similar to physiologically predicted responses. DISCUSSION: The current studies support using BIS as a means of sensitively and reliably performing repeated measurements of BFC in rats of a) differing sizes, b) in response to therapeutic agents known to influence renal sodium handling and c) in response to osmotic challenge.

Differential effects of angiotensin II on atherogenesis at the aortic sinus and descending aorta of apolipoprotein-E-deficient mice.

Angiotensin (Ang) II infusion increases atherosclerosis and leads to the formation of abdominal aortic aneurysms in apolipoprotein E-deficient (ApoE-/-) mice. Conversely, blockade of the renin-angiotensin system (RAS) decreases atherosclerosis in this model. However, there are conflicting data in the literature concerning responses to both Ang II infusion and RAS blockade which may depend on age, sex, dose, duration of treatment, and the site at which lesion area was measured. In the present study we examined the effects of Ang II infusion on lesion formation in male ApoE-/- mice both at the aortic sinus and in the descending aorta, starting at different ages, and varying in duration. We also tested the effects of the Ang II receptor antagonist losartan at different doses in both males and females. Blood pressure and plasma renin concentration (PRC) were measured as indicators of the hemodynamic and neurohormonal effects of these treatments. Administration of Ang II increased lesion area much more in the descending aorta than at the aortic sinus. However, spontaneous lesion development at the aortic sinus was much greater than in more distal regions of the aorta. Aneurysms were observed in all treatment groups but were less severe in animals treated from 4 weeks age, possibly because of protective remodeling. Losartan treatment reduced lesion area at the aortic sinus, although differences were only significant in female mice. These findings demonstrate regional and temporal differences in the sensitivity of the aorta to the effects of RAS stimulation and blockade, and may help to explain some of the discrepancies between previous reports from other laboratories.

Nitric oxide synthase inhibition accelerates the pressor response to low-dose angiotensin II, exacerbates target organ damage, and induces renin escape.

Because nitric oxide may attenuate both the pressor and cytotoxic effects of angiotensin II (Ang II), we investigated whether nitric oxide synthase (NOS) inhibition might accelerate the slow pressor effect of Ang II, and augment target organ damage. Using conscious, chronically catheterized rats, we previously observed that low-dose Ang II (10 ng/kg/min) rapidly increased mean arterial pressure (MAP) by approximately 25 mm Hg. The MAP then remained at this level for 2 to 4 days, and then increased again during the next 5 days by a further 25 mm Hg to a second plateau. In the present study, 7 days of N(omega)-nitro-l-arginine methyl ester (L-NAME; 10 microg/kg/min) alone increased MAP by 16 mm Hg. When Ang II was added to L-NAME, MAP increased as much as with Ang II alone, but then continued to increase until day 4, reaching a plateau as high as that reached only on day 9 of Ang II alone. In approximately half the rats infused with L-NAME + Ang II, plasma renin escaped from Ang II-induced suppression after day 4 of Ang II, and continued to increase for the duration of the study. On the first day that Ang II was added to L-NAME, urinary protein excretion and plasma cardiac troponin T increased, indicating early target organ damage. By the end of the study, all rats treated with L-NAME + Ang II developed tubulointerstitial and glomerular injuries, fibrosis of the renal and cardiac arteries, and cardiac interstitial fibrosis. Target organ damage was greater in rats that developed renin escape than in those in which plasma renin remained suppressed, but was minimal in rats infused with Ang II or L-NAME alone. Taken together, these findings suggest that endogenous NO normally attenuates the pressor response to low-dose Ang II for several days, and protects from Ang II-induced target organ damage. Under conditions of reduced NO bioavailability, which may result from endothelial insufficiency, relatively small changes in circulating Ang II levels may damage target organs. Moreover, renal damage leading to renin escape may initiate a vicious cycle of elevated Ang II production, leading to higher blood pressure and greater target organ damage.