Glenn Solis

p47 phox Is Required for Afferent Arteriolar Contractile Responses to Angiotensin II and Perfusion Pressure in Mice

Myogenic and angiotensin contractions of afferent arterioles generate reactive oxygen species. Resistance vessels express neutrophil oxidase-2 and -4. Angiotensin II activates p47phox/neutrophil oxidase-2, whereas it downregulates NOX-4. Therefore, we tested the hypothesis that p47phox enhances afferent arteriolar angiotensin contractions. Angiotensin II infusion in p47phox +/+ but not −/− mice increased renal cortical NADPH oxidase activity (7±1–12±1 [P<0.01] versus 5±1–7±1 103 · RLU · min−1 · &mgr;g protein−1 [P value not significant]), mean arterial pressure (77±2–91±2 [P<0.005] versus 74±2–77±1 mm Hg [P value not significant]), and renal vascular resistance (7.5±0.4–10.1±0.7 [P<0.01] versus 7.9±0.4–8.3±0.4 mm Hg/mL · min−1 · gram kidney weight−1 [P value not significant]). Afferent arterioles from p47phox −/− mice had a lesser myogenic response (3.1±0.4 versus 1.4±0.2 dynes · cm−1 · mm Hg−1; P<0.02) and a lesser (P<0.05) contraction to 10−6 M angiotensin II (diameter change +/+: 9.3±0.2–3.4±0.6 &mgr;m versus −/−: 9.9±0.6–7.5±0.4 &mgr;m). Angiotensin and increased perfusion pressure generated significantly (P<0.05) more reactive oxygen species in p47phox +/+ than −/− arterioles. Angiotensin II infusion increased the maximum responsiveness of afferent arterioles from p47phox +/+ mice to 10−6 M angiotensin II yet decreased the response in p47phox −/− mice. The angiotensin infusion increased the sensitivity to angiotensin II only in p47phox +/+ mice. We conclude that p47phox is required to enhance renal NADPH oxidase activity and basal afferent arteriolar myogenic and angiotensin II contractions and to switch afferent arteriolar tachyphylaxis to sensitization to angiotensin during a prolonged angiotensin infusion. These effects likely contribute to hypertension and renal vasoconstriction during infusion of angiotensin II.

MYOGENIC RESPONSES OF MOUSE ISOLATED PERFUSED RENAL AFFERENT ARTERIOLES: EFFECTS OF SALT INTAKE AND REDUCED RENAL MASS

Because defects in renal autoregulation may contribute to renal barotrauma in chronic kidney disease, we tested the hypothesis that the myogenic response is diminished by reduced renal mass. Kidneys from 5/6 nephrectomized mice had only a minor increase in the glomerular sclerosis index. The telemetric mean arterial pressure (108±10 mm Hg) was unaffected after 3 months of high-salt intake (6% salt in chow) or reduced renal mass. Afferent arterioles from 5/6 nephrectomized mice and sham-operated controls were perfused ex vivo during step changes in pressure from 40 to 134 mm Hg. Afferent arterioles developed a constriction and a linear increase in active wall tension above a perfusion pressure of 36±6 mm Hg, without a plateau. The slope of active wall tension versus perfusion pressure defined the myogenic response, which was similar in sham mice fed normal or high-salt diets for 3 months (2.90±0.22 versus 3.22±0.40 dynes · cm−1/mm Hg; P value not significant). The myogenic response was unaffected after 3 days of reduced renal mass on either salt diet (3.39±0.61 versus 4.04±0.47 dynes · cm−1/mm Hg) but was reduced (P<0.05) in afferent arterioles from reduced renal mass groups fed normal and high salt at 3 months (2.10±0.28 and 1.35±0.21 dynes · cm−1/mm Hg). In conclusion, mouse renal afferent arterioles develop a linear increase in myogenic tone around the range of ambient perfusion pressures. This myogenic response is impaired substantially in the mouse model of prolonged reduced renal mass, especially during high salt intake.

Cyclooxygenase-1–Deficient Mice Have High Sleep-to-Wake Blood Pressure Ratios and Renal Vasoconstriction

We used cyclooxygenase-1 (COX-1)–deficient mice to test the hypothesis that COX-1 regulates blood pressure (BP) and renal hemodynamics. The awake time (AT) mean arterial pressures (MAPs) measured by telemetry were not different between COX-1+/+ and COX-1−/− (131±2 versus 126±3 mm Hg; NS). However, COX-1−/− had higher sleep time (ST) MAP (93±1 versus 97±2 mm Hg; P<0.05) and sleep-to-awake BP ratio (+8.6%; P<0.05). Under anesthesia with moderate sodium loading, COX-1−/− had higher MAP (109±5 versus 124±4 mm Hg; P<0.05), renal vascular resistance (23.5±1.6 versus 30.7±1.7 mm Hg · mL−1 · min−1 · g−1; P<0.05) and filtration fraction (33.7±2.1 versus 40.2±2.0%; P<0.05). COX-1−/− had a 89% reduction (P<0.0001) in the excretion of TxB2, a 76% reduction (P<0.01) in PGE2, a 40% reduction (P<0.0002) in 6-ketoPGF1&agr; (6keto), a 27% reduction (P<0.02) in 11-&bgr;PGF2&agr; (11&bgr;), a 35% reduction (P<0.01) in nitrate plus nitrite (NOx), and a 52% increase in metanephrine (P<0.02). The excretion of normetanephrine, a marker for sympathetic nervous activity, was reduced during ST in COX-1+/+ (6.9±0.9 versus 3.2±0.6 g · g−1 creatinine · 10−3; P<0.01). This was blunted in COX-1−/− (5.1±0.9 versus 4.9±0.7 g · g−1 creatinine · 10−3; NS). Urine collection during ST showed lower excretion of 6keto, 11&bgr;, NOx, aldosterone, sodium, and potassium than during AT in both COX-1+/+ and COX-1−/−, and there were positive correlations among these parameters (6keto versus NOx; P<0.005; 11&bgr; versus NOx; P<0.005; and NOx versus sodium; P<0.005). In conclusion, COX-1 mediates a suppressed sympathetic nervous activity and enhanced NO, which may contribute to renal vasodilatation and a reduced MAP while asleep or under anesthesia. COX-1 contributes to the normal nocturnal BP dipping phenomenon.

Effects of the antioxidant drug tempol on renal oxygenation in mice with reduced renal mass

We tested the hypothesis that reactive oxygen species (ROS) contributed to renal hypoxia in C57BL/6 mice with ⅚ surgical reduction of renal mass (RRM). ROS can activate the mitochondrial uncoupling protein 2 (UCP-2) and increase O(2) usage. However, UCP-2 can be inactivated by glutathionylation. Mice were fed normal (NS)- or high-salt (HS) diets, and HS mice received the antioxidant drug tempol or vehicle for 3 mo. Since salt intake did not affect the tubular Na(+) transport per O(2) consumed (T(Na/)Q(O2)), further studies were confined to HS mice. RRM mice had increased excretion of 8-isoprostane F(2α) and H(2)O(2), renal expression of UCP-2 and renal O(2) extraction, and reduced T(Na/)Q(O2) (sham: 20 ± 2 vs. RRM: 10 ± 1 μmol/μmol; P < 0.05) and cortical Po(2) (sham: 43 ± 2, RRM: 29 ± 2 mmHg; P < 0.02). Tempol normalized all these parameters while further increasing compensatory renal growth and glomerular volume. RRM mice had preserved blood pressure, glomeruli, and patchy tubulointerstitial fibrosis. The patterns of protein expression in the renal cortex suggested that RRM kidneys had increased ROS from upregulated p22(phox), NOX-2, and -4 and that ROS-dependent increases in UCP-2 led to hypoxia that activated transforming growth factor-β whereas erythroid-related factor 2 (Nrf-2), glutathione peroxidase-1, and glutathione-S-transferase mu-1 were upregulated independently of ROS. We conclude that RRM activated distinct processes: a ROS-dependent activation of UCP-2 leading to inefficient renal O(2) usage and cortical hypoxia that was offset by Nrf-2-dependent glutathionylation. Thus hypoxia in RRM may be the outcome of NADPH oxidase-initiated ROS generation, leading to mitochondrial uncoupling counteracted by defense pathways coordinated by Nrf-2.

Paracellular epithelial sodium transport maximizes energy efficiency in the kidney

Efficient oxygen utilization in the kidney may be supported by paracellular epithelial transport, a form of passive diffusion that is driven by preexisting transepithelial electrochemical gradients. Claudins are tight-junction transmembrane proteins that act as paracellular ion channels in epithelial cells. In the proximal tubule (PT) of the kidney, claudin-2 mediates paracellular sodium reabsorption. Here, we used murine models to investigate the role of claudin-2 in maintaining energy efficiency in the kidney. We found that claudin-2-null mice conserve sodium to the same extent as WT mice, even during profound dietary sodium depletion, as a result of the upregulation of transcellular Na-K-2Cl transport activity in the thick ascending limb of Henle. We hypothesized that shifting sodium transport to transcellular pathways would lead to increased whole-kidney oxygen consumption. Indeed, compared with control animals, oxygen consumption in the kidneys of claudin-2-null mice was markedly increased, resulting in medullary hypoxia. Furthermore, tubular injury in kidneys subjected to bilateral renal ischemia-reperfusion injury was more severe in the absence of claudin-2. Our results indicate that paracellular transport in the PT is required for efficient utilization of oxygen in the service of sodium transport. We speculate that paracellular permeability may have evolved as a general strategy in epithelial tissues to maximize energy efficiency.

Blood Pressure Control by a Secreted FGFBP1 (Fibroblast Growth Factor–Binding Protein)Novelty and Significance

Fibroblast growth factors (FGFs) participate in organ development and tissue maintenance, as well as the control of vascular function. The paracrine-acting FGFs are stored in the extracellular matrix, and their release is controlled by a secreted FGF-binding protein (FGF-BP, FGFBP1, and BP1) that modulates FGF receptor signaling. A genetic polymorphism in the human FGFBP1 gene was associated with higher gene expression and an increased risk of familial hypertension. Here, we report on the effects of inducible BP1 expression in a transgenic mouse model. Induction of BP1 expression in adult animals leads to a sustained rise in mean arterial pressure by >30 mm Hg. The hypertensive effect of BP1 expression is prevented by candesartan, an angiotensin II (AngII) receptor antagonist, or by tempol, an inhibitor of reactive oxygen species. In vivo, BP1 expression sensitizes peripheral resistance vessels to AngII constriction by 20-fold but does not alter adrenergic vasoconstriction. FGF receptor kinase inhibition reverses the sensitization to AngII. Also, constriction of isolated renal afferent arterioles by AngII is enhanced after BP1 expression and blocked by FGF receptor kinase inhibition. Furthermore, AngII-mediated constriction of renal afferent arterioles is abolished in FGF2−/− mice but can be restored by add-back of FGF2 plus BP1 proteins. In contrast to AngII, adrenergic constriction is not affected in the FGF2−/− model. Proteomics and gene expression analysis of kidney tissues after BP1 induction show that MAPK (mitogen-activated protein kinase) signaling via MKK4 (MAPK kinase 4), p38, and JNK (c-Jun N-terminal kinase) integrates the crosstalk of the FGF receptor and AngII pathways and thus impact vascular tone and blood pressure.