Independent effects of sex and stress on fructose-induced salt-sensitive hypertension

Proximal tubule fructose metabolism is key to fructose-induced hypertension, but the roles of sex and stress are unclear. We hypothesized that females are resistant to the salt-sensitive hypertension caused by low amounts of dietary fructose compared to males and that the magnitude of the increase in blood pressure (BP) depends, in part, on amplification of the stress response of renal sympathetic nerves. We measured systolic BP (SBP) in rats fed high salt with either no sugar (HS), 20% glucose (GHS) or 20% fructose (FHS) in the drinking water for 7-8 days. FHS increased SBP in both males (Δ22 ± 9 mmHg; p < 0.046) and females (Δ16 ± 3 mmHg; p < 0.0007), while neither GHS nor HS alone induced changes in SBP in either sex. The FHS-induced increase in SBP as measured by telemetry in the absence of added stress (8 ± 2 mmHg) was significantly lower than that measured by plethysmography (24 ± 5 mmHg) (p < 0.014). However, when BP was measured by telemetry simulating the stress of plethysmography, the increase in SBP was significantly greater (15 ± 3 mmHg) than under low stress (8 ± 1 mmHg) (p < 0.014). Moderate-stress also increased telemetric diastolic (p < 0.006) and mean BP (p < 0.006) compared to low-stress in FHS-fed animals. Norepinephrine excretion was greater in FHS-fed rats than HS-fed animals (Male: 6.4 ± 1.7 vs.1.8 ± 0.4 nmole/kg/day; p < 0.02. Female 54 ± 18 vs. 1.2 ± 0.6; p < 0.02). We conclude that fructose-induced salt-sensitive hypertension is similar in males and females unlike other forms of hypertension, and the increase in blood pressure depends in part on an augmented response of the sympathetic nervous system to stress.

Abstract 076: Sex And Stress In Fructose-induced Salt-sensitive Hypertension

Proximal tubule fructose metabolism is key to fructose-induced hypertension, but the roles of sex and stress are unclear. We hypothesized that females are resistant to the salt-sensitive hypertension caused by low amounts of dietary fructose compared to males and that the magnitude of the increase in blood pressure (BP) depends, in part, on amplification of the stress response of renal sympathetic nerves. We measured systolic BP (SBP) in rats fed high salt with either no sugar (HS), 20% glucose (GHS) or 20% fructose (FHS) in the drinking water for 7-8 days. FHS increased SBP (p<0.03 vs basal) but neither GHS nor high salt alone raised SBP. FHS increased SBP significantly and similarly in both (male: Δ25±8 mm Hg; female: Δ19±2 mm Hg). FHS increased SBP by 24±5 mm Hg but only by 8±2 mm Hg when measured by plethysmography and telemetry, respectively (p<0.004). When SBP was measured by telemetry under low stress, FHS increased SBP by 8±1 mm Hg; on the contrary, when measured by telemetry under moderate stress conditions (simulating stress of plethysmography), FHS increased SBP by 15±3 mm Hg, a significantly greater increase (p<0.008). Norepinephrine excretion in rats subjected to moderate stress was 63±17 nmole/Kg/day for animals fed FHS but only 19±40 nmole/Kg/day for controls fed HS (p<0.02). We conclude that fructose-induced salt-sensitive hypertension is similar in males and females unlike other forms of hypertension, and the increase in blood pressure depends in part on an augmented response of the sympathetic nervous system to stress.

Mechanisms of decreased tubular flow-induced nitric oxide in Dahl salt-sensitive rat thick ascending limbs

Dahl salt-sensitive (SS) rat kidneys produce less nitric oxide (NO) than those of salt-resistant (SR) rats. Thick ascending limb (TAL) NO synthase 3 (NOS3) is a major source of renal NO, and luminal flow enhances its activity. We hypothesized that flow-induced NO is reduced in TALs from SS rats primarily due to NOS uncoupling and diminished NOS3 expression rather than scavenging. Rats were fed normal-salt (NS) or high-salt (HS) diets. We measured flow-induced NO and superoxide in perfused TALs and performed Western blots of renal outer medullas. For rats on NS, flow-induced NO was 35 ± 6 arbitrary units (AU)/min in TALs from SR rats but only 11 ± 2 AU/min in TALs from SS (P < 0.008). The superoxide scavenger tempol decreased the difference in flow-induced NO between strains by about 36% (P < 0.020). The NOS inhibitor N-nitro-l-arginine methyl ester (l-NAME) decreased flow-induced superoxide by 36 ± 8% in TALs from SS rats (P < 0.02) but had no effect in TALs from SR rats. NOS3 expression was not different between strains on NS. For rats on HS, the difference in flow-induced NO between strains was enhanced (SR rats: 44 ± 10 vs. SS: 9 ± 2 AU/min, P < 0.005). Tempol decreased the difference in flow-induced NO between strains by about 37% (P < 0.012). l-NAME did not significantly reduce flow-induced superoxide in either strain. HS increased NOS3 expression in TALs from SR rats but not in TALs from SS rats (P < 0.003). We conclude that 1) on NS, flow-induced NO is diminished in TALs from SS rats mainly due to NOS3 uncoupling such that it produces superoxide and 2) on HS, the difference is enhanced due to failure of TALs from SS rats to increase NOS3 expression.NEW & NOTEWORTHY The Dahl rat has been used extensively to study the causes and effects of salt-sensitive hypertension. Our study suggests that more complex processes other than simple scavenging of nitric oxide (NO) by superoxide lead to less NO production in thick ascending limbs of the Dahl salt-sensitive rat. The predominant mechanism involved depends on dietary salt. Impaired flow-induced NO production in thick ascending limbs most likely contributes to the Na+ retention associated with salt-sensitive hypertension.

Dietary fructose enhances angiotensin II-stimulated Na+ transport via activation of PKC-α in renal proximal tubules

Angiotensin II (ANG II) stimulates proximal nephron transport via activation of classical protein kinase C (PKC) isoforms. Acute fructose treatment stimulates PKC and dietary fructose enhances ANG II's ability to stimulate Na⁺ transport, but the mechanisms are unclear. We hypothesized that dietary fructose enhances ANG II's ability to stimulate renal proximal tubule Na⁺ reabsorption by augmenting PKC-α activation and increases in intracellular Ca²⁺. We measured total and isoform-specific PKC activity, basal and ANG II-stimulated oxygen consumption, a surrogate of Na⁺ reabsorption, and intracellular Ca²⁺ in proximal tubules from rats given either 20% fructose in their drinking water (fructose group) or tap water (control group). Total PKC activity was measured by ELISA. PKC-α, PKC-β, and PKC-γ activities were assessed by measuring particulate-to-soluble ratios. Intracelluar Ca²⁺ was measured using fura 2. ANG II stimulated total PKC activity by 53 ± 15% in the fructose group but not in the control group (-15 ± 11%, P < 0.002). ANG II stimulated PKC-α by 0.134 ± 0.026 but not in the control group (-0.002 ± 0.020, P < 0.002). ANG II increased PKC-γ activity by 0.008 ± 0.003 in the fructose group but not in the control group (P < 0.046). ANG II did not stimulate PKC-β in either group. ANG II increased Na⁺ transport by 454 ± 87 nmol·min^-1·mg protein^-1 in fructose group, and the PKC-α/β inhibitor Gö6976 blocked this increase (-96 ± 205 nmol·min^-1·mg protein^-1, P < 0.045). ANG II increased intracellular Ca²⁺ by 148 ± 53 nM in the fructose group but only by 43 ± 10 nM in the control group (P < 0.035). The intracellular Ca²⁺ chelator BAPTA blocked the ANG II-induced increase in Na⁺ transport in the fructose group. We concluded that dietary fructose enhances ANG II's ability to stimulate renal proximal tubule Na⁺ reabsorption by augmenting PKC-α activation via elevated increases in intacellular Ca²⁺.

Stretch-Induced Increases in Intracellular Ca Stimulate Thick Ascending Limb O2- Production and Are Enhanced in Dahl Salt-Sensitive Rats

Mechanical stretch raises intracellular Ca (Ca_i) in many cell types. Luminal flow-derived stretch stimulates O₂^- production by thick ascending limbs (THALs). Renal O₂^- is greater in Dahl salt-sensitive (SS) than salt-resistant (SR) rats. We hypothesized that mechanical stretch stimulates Ca influx via TRPV4 (transient receptor potential vanilloid type 4) which in turn raises Ca_i in THALs; these increases in Ca_i are necessary for stretch to augment O₂^- production; and stretch-stimulated, and therefore flow-induced, O₂^- production is enhanced in SS compared with SR THALs due to elevated Ca influx and increased Ca_i. Ca_i and O₂^- were measured in SS and SR THALs from rats on normal salt using Fura2-acetoxymethyl ester and dihydroethidium, respectively. Stretch raised Ca_i in SS by 270.4±48.9 nmol/L and by 123.6±27.0 nmol/L in SR THALs (P<0.02). Removing extracellular Ca eliminated the increases and differences in Ca_i between strains. Knocking down TRPV4 in SS THALs reduced stretch-induced Ca_i to SR levels (SS: 92.0±15.9 nmol/L; SR: 123.6±27.0 nmol/L). RN1734, a TRPV4 inhibitor, blunted stretch-elevated Ca_i by ≈75% and ≈66% in SS (P<0.03) and SR (P<0.04), respectively. Stretch augmented O₂^- production by 58.6±10.2 arbitrary fluorescent units/min in SS and by 24.4±2.6 arbitrary fluorescent units/min in SR THALs (P<0.05). Removal of extracellular Ca blunted stretch-induced increases in O₂^- and eliminated differences between strains. RN1734 reduced stretch-induced O₂^- by ≈70% in SS (P<0.005) and ≈60% in SR (P<0.01). Conclusions are as follows: (1) stretch activates TRPV4, which raises Ca_i in THALs; (2) the increase in Ca_i stimulates O₂^- production; and (3) stretch-induced O₂^- production is enhanced in SS THALs due to greater increases in Ca_i.

Fructose reabsorption by rat proximal tubules: role of Na+-linked cotransporters and the effect of dietary fructose

Fructose consumption has increased because of widespread use of high-fructose corn syrup by the food industry. Renal proximal tubules are thought to reabsorb fructose. However, fructose reabsorption (J_fructose) by proximal tubules has not yet been directly demonstrated, nor the effects of dietary fructose on J_fructose. This segment expresses Na⁺- and glucose-linked transporters (SGLTs) 1, 2, 4, and 5 and glucose transporters (GLUTs) 2 and 5. SGLT4 and -5 transport fructose, but SGLT1 and -2 do not. Knocking out SGLT5 increases urinary fructose excretion. We hypothesize that J_fructose in the S2 portion of the proximal tubule is mediated by luminal entry via SGLT4/5 and basolateral exit by GLUT2 and that it is enhanced by a fructose-enriched diet. We measured J_fructose by proximal straight tubules from rats consuming either tap water (Controls) or 20% fructose (FRU). Basal J_fructose in Controls was 14.1 ± 1.5 pmol·mm^-1·min^-1. SGLT inhibition with phlorizin reduced J_fructose to 4.9 ± 1.4 pmol·mm^-1·min^-1 ( P < 0.008), whereas removal of Na⁺ diminished J_fructose by 86 ± 5% ( P < 0.0001). A fructose-enriched diet increased J_fructose from 12.8 ± 2.5 to 19.3 ± 0.5 pmol·mm^-1·min^-1, a 51% increase ( P < 0.03). Using immunofluorescence, we detected luminal SGLT4 and SGLT5 and basolateral GLUT2; GLUT5 was undetectable. The expression of apical transporters SGLT4 and SGLT5 was higher in FRU than in Controls [137 ± 10% ( P < 0.01) and 38 ± 14% ( P < 0.04), respectively]. GLUT2 was also elevated by 88 ± 27% ( P < 0.02) in FRU. We conclude that J_fructose by proximal tubules occurs primarily via Na⁺-linked cotransport processes, and a fructose-enriched diet enhances reabsorption. Transport across luminal and basolateral membranes is likely mediated by SGLT4/5 and GLUT2, respectively.

Abstract P278: Flow-Induced NO Deficiency in Thick Ascending Limbs of Dahl Salt-Sensitive Rats Fed a High Salt Diet is Due to Decreased NOS3 Expression

The effects of medullary NO on Na excretion are reduced in Dahl salt-sensitive (SS) compared to salt-resistant rats (SR). We have shown that flow-induced NO production by thick ascending limbs (THALs) of SS is reduced when rats are on a normal salt diet although NO synthase 3 protein expression was the same. In Sprague-Dawley rats a high-salt diet markedly increase NOS3 expression. It is unknown whether this is also the case for both SS and SR fed a high-salt diet. We hypothesized that flow-induced NO production by SS THALs is blunted in part due to a failure to increase NOS3 expression in response to dietary salt. SS and SR were fed normal and high-salt diets for 7-9 days. We measured systolic blood pressure (SBP); flow-induced NO in isolated THALs; and NOS3 protein expression in renal medullary lysates. SBP was 164.5±3.2 mm Hg ( n = 9) in SS and 130.1±4.8 in SR when fed a high-salt diet ( n = 7 ; p < 0.0001 ) . Flow-induced NO production by SS THALs from rats fed high salt was 9 ± 2 arbitrary units (AU)/min ( n = 6) while it was 44 ± 10 AU/min by SR tubules ( n = 6), significantly greater ( p < 0.005). NOS3 expression was 0.74 ± 0.08 AU ( n = 5) in THALs from SS on high salt while it was 1.26 ± 0.08 AU in tubules from SR ( n = 5), significantly greater ( p < 0.003). THAL NOS3 expression was unchanged by a high-salt diet in SS (1.01 ± 0.08 vs 1.11 ± 0.11; n = 5) but increased in SR. We conclude that decreased flow-induced NO production in high-salt-fed SS is at least partially due to failure to increase NOS3 expression.

NADPH oxidase 4-derived superoxide mediates flow-stimulated NKCC2 activity in thick ascending limbs

Luminal flow augments Na⁺ reabsorption in the thick ascending limb more than can be explained by increased ion delivery. This segment reabsorbs 30% of the filtered load of Na⁺, playing a key role in its homeostasis. Whether flow elevations enhance Na⁺-K⁺-2Cl^- cotransporter (NKCC2) activity and the second messenger involved are unknown. We hypothesized that raising luminal flow augments NKCC2 activity by enhancing superoxide ([Formula: see text]) production by NADPH oxidase 4 (NOX4). NKCC2 activity was measured in thick ascending limbs perfused at either 5 or 20 nl/min with and without inhibitors of [Formula: see text] production. Raising luminal flow from 5 to 20 nl/min enhanced NKCC2 activity from 4.8 ± 0.9 to 6.3 ± 1.2 arbitrary fluorescent units (AFU)/s. Maintaining flow at 5 nl/min did not alter NKCC2 activity. The superoxide dismutase mimetic manganese (III) tetrakis (4-benzoic acid) porphyrin chloride blunted NKCC2 activity from 3.5 ± 0.4 to 2.5 ± 0.2 AFU/s when flow was 20 nl/min but not 5 nl/min. When flow was 20 nl/min, NKCC2 activity showed no change with time. The selective NOX1/4 inhibitor GKT-137831 blunted NKCC2 activity when thick ascending limbs were perfused at 20 nl/min from 7.2 ± 1.1 to 4.5 ± 0.8 AFU/s but not at 5 nl/min. The inhibitor also prevented luminal flow from elevating [Formula: see text] production. Allopurinol, a xanthine oxidase inhibitor, had no effect on NKCC2 activity when flow was 20 nl/min. Tetanus toxin prevents flow-induced stimulation of NKCC2 activity. We conclude that elevations in luminal flow enhance NaCl reabsorption in thick ascending limbs by stimulating NKCC2 via NOX4 activation and increased [Formula: see text]. NKCC2 activation is primarily the result of insertion of new transporters in the membrane.

Abstract 069: Increased Stretch-induced O 2 - Production in Dahl Salt-sensitive Rats is Mediated by TRPV4

Medullary O 2 - production is elevated in Dahl salt-sensitive (SS) when compared to Dahl salt-resistant rats (SR), and this is one of the main contributors to salt-sensitive hypertension in this model. In thick ascending limbs (TALs), flow-induced O 2 - is caused by elevated ion delivery and cellular stretch. Mechanical stimulation by cellular stretch, in turn, leads to increases in intracellular calcium (Cai). We hypothesized that the elevated O 2 - production by SS TALs is due to greater stretch-induced increases in Cai mediated by Transient Receptor Potential Vanilloid (TRPV4). To test our hypothesis, we measured O 2 - and Cai in isolated, perfused TALs using the ratiometric dyes dihydroethidium and Fura2, respectively. Stretch led to a greater increase in Cai in SS (243±51 nM; n=9) compared to SR (124±27 nM; n=10; p<0.05 vs. SS). The increase in Cai and the difference between strains were blunted when tubules were treated with RN1734, a TRPV4 inhibitor (SS: 59±10 nM; SR: 24±3 nM; n=5 in each group). TRPV4 facilitates Ca influx into the cell. Thus we tested the effect of removing extracellular Ca on the response to stretch. When tubules were perfused and bathed with in Ca-free solutions stretch-induced increases in Cai and the difference between SS and SR TALs were completed eliminated (SS: 10±6 nM; SR: 8±4 nM; n=5 in each group). Transfecting SS TALs with an adenovirus expressing a TRPV4-small hairpin RNA abolished the difference in the stretch-induced Cai response between SS and SR tubules (SS: 75±15nM; SR: 56±28 nM; n=4 for each group). Stretch-induced O 2 - production was greater in SS TALs compared to SR tubules (SS: 59±10 AU/min; SR: 24±3 AU/min; p<0.02; n=5 for each group). The increase in O 2 - production caused by stretch and the difference between SS and SR TALs were eliminated when tubules were treated with the TRPV4 inhibitor RN1734 (SS: 15±7 AU/min; SR: 10±4 AU/min). Our results indicate that: 1) stretch increases Cai in SS and SR TALs and this is mediated by activation of TRPV4; 2) stretch raises Cai more in SS than SR tubules; 3) stretch-induced O 2 - production is elevated in SS TALs compared to those from SR and this is due to greater increases in Cai; and 4) differences in TRPV4 activation likely explain, in part, both the differences in stretch-induced Cai and O 2 - production.

Abstract P230: Uncoupling of NOS3 is Involved in Diminished Flow-induced No Production in Dahl Salt-sensitive Rat Thick Ascending Limbs

Increased luminal flow enhances nitric oxide (NO) production in thick ascending limbs (TALs). NO produced by NO synthase 3 (NOS3) inhibits Na transport. However, its effect on transport is reduced in Dahl salt-sensitive (SS) vs salt-resistant rats (SR). In Sprague-Dawley rat TALs, angiotensin II can acutely cause NOS3 to uncouple to produce superoxide (O 2 - ) thereby reducing NO production. We hypothesized that flow-induced NO production is decreased in SS TALs and that this is due to NOS3 uncoupling. We measured flow-induced NO in isolated perfused TALs using the fluorescent dye DAF-FM and performed Western blots of renal medullary lysates. Flow-induced NO production was reduced 69% in TALs from SS (11±2 arbitrary units (AU)/min, n=6) vs SR (35±6 AU/min, n=8, p < 0.008). This difference between strains was not due to altered NOS3 expression (NOS3/GAPDH ratio of 0.91 ± 0.08 for SS vs 1.09 ± 0.08 for SR; n = 5 for each). The difference in flow-induced NO between strains was slightly reduced in the presence of the superoxide (O 2 - ) scavenger tempol (19±2 vs 30±5 AU/min for SS and SR, respectively; n=9 for each strain, p < 0.04), suggesting that scavenging of NO by O 2 - plays only a minor role in the difference in flow-induced NO production between SS and SR thick ascending limbs. We next investigated whether NOS3 uncoupling could account for the difference between strains by using the fluorescent dye dihydroethidium to measure flow-induced O 2 - before and after treatment with the NOS inhibitor L-NAME. Blocking NOS3 reduced O 2 - production in SS TALs by 21±7%, from 38±5 to 30±5 AU/min (n=6, p < 0.05) whereas it had no effect in SR TALs (26±6 vs 28±3, n=5). We conclude that the diminished flow-induced NO in SS TALs is not due to differences in NOS3 expression nor acute flow-induced O 2 - , but rather in large part due to uncoupling of NOS3. Impaired flow-induced NO production in TALs could contribute to the Na retention associated with salt-sensitive hypertension.

Angiotensin II stimulates superoxide production by nitric oxide synthase in thick ascending limbs

Angiotensin II (Ang II) causes nitric oxide synthase (NOS) to become a source of superoxide (O2 (-)) via a protein kinase C (PKC)-dependent process in endothelial cells. Ang II stimulates both NO and O2 (-) production in thick ascending limbs. We hypothesized that Ang II causes O2 (-) production by NOS in thick ascending limbs via a PKC-dependent mechanism. NO production was measured in isolated rat thick ascending limbs using DAF-FM, whereas O2 (-) was measured in thick ascending limb suspensions using the lucigenin assay. Consistent stimulation of NO was observed with 1 nmol/L Ang II (P < 0.001; n = 9). This concentration of Ang II-stimulated O2 (-) production by 50% (1.77 ± 0.26 vs. 2.62 ± 0.36 relative lights units (RLU)/s/μg protein; P < 0.04; n = 5). In the presence of the NOS inhibitor L-NAME, Ang II-stimulated O2 (-) decreased from 2.02 ± 0.29 to 1.10 ± 0.11 RLU/s/μg protein (P < 0.01; n = 8). L-arginine alone did not change Ang II-stimulated O2 (-) (2.34 ± 0.22 vs. 2.29 ± 0.29 RLU/s/μg protein; n = 5). In the presence of Ang II plus the PKC α/β1 inhibitor Gö 6976, L-NAME had no effect on O2 (-) production (0.78 ± 0.23 vs. 0.62 ± 0.11 RLU/s/μg protein; n = 7). In the presence of Ang II plus apocynin, a NADPH oxidase inhibitor, L-NAME did not change O2 (-) (0.59 ± 0.04 vs. 0.61 ± ×0.08 RLU/s/μg protein; n = 5). We conclude that: (1) Ang II causes NOS to produce O2 (-) in thick ascending limbs via a PKC- and NADPH oxidase-dependent process; and (2) the effect of Ang II is not due to limited substrate.

Luminal flow induces NADPH oxidase 4 translocation to the nuclei of thick ascending limbs

Superoxide (O₂⁻) exerts its physiological actions in part by causing changes in gene transcription. In thick ascending limbs flow‐induced O₂⁻ production is mediated by NADPH oxidase 4 (Nox4) and is dependent on protein kinase C (PKC). Polymerase delta interacting protein 2 (Poldip2) increases Nox4 activity, but it is not known whether Nox4 translocates to the nucleus and whether Poldip2 participates in this process. We hypothesized that luminal flow causes Nox4 translocation to the nuclei of thick ascending limbs in a PKC‐dependent process facilitated by Poldip2. To test our hypothesis, we studied the subcellular localization of Nox4 and Poldip2 using confocal microscopy and O₂⁻ production in the absence and presence of luminal flow. Luminal flow increased the ratio of nuclear to cytoplasmic intensity of Nox4 (N/C) from 0.3 ± 0.1 to 0.7 ± 0.1 (P < 0.01) and O₂⁻ production from 89 ± 15 to 231 ± 16 AU/s (P < 0.001). In the presence of flow PKC inhibition reduced N/C from 0.5 ± 0.1 to 0.2 ± 0.1 (P < 0.01). Flow‐induced O₂⁻ production was also blocked (flow: 142 ± 20 AU/s; flow plus PKC inhibition 26 ± 12 AU/s; P < 0.01). The cytoskeleton disruptor cytochalasin D (1 μmol/L) decreased flow‐induced Nox4 translocation by 0.3 ± 0.01 (P < 0.01); however, it did not reduce flow‐induced O₂⁻. Flow did not alter Poldip2 localization. We conclude that: (1) luminal flow elicits Nox4 translocation to the nucleus in a PKC‐ and cytoskeleton‐dependent process; (2) Nox4 activation occurs before translocation; and (3) Poldip2 is not involved in Nox4 nuclear translocation. Flow‐induced Nox4 translocation to the nucleus may play a role in O₂⁻‐dependent changes in thick ascending limbs.

Endogenous flow-induced nitric oxide reduces superoxide-stimulated Na/H exchange activity via PKG in thick ascending limbs

Luminal flow stimulates endogenous nitric oxide (NO) and superoxide (O2 (-)) production by renal thick ascending limbs (TALs). The delicate balance between these two factors regulates Na transport in TALs; NO enhances natriuresis, whereas O2 (-) augments Na absorption. Endogenous, flow-stimulated O2 (-) enhances Na/H exchange (NHE). Flow-stimulated NO reduces flow-induced O2 (-), a process mediated by cGMP-dependent protein kinase (PKG). However, whether flow-stimulated, endogenously-produced NO diminishes O2 (-)-stimulated NHE activity and the signaling pathway involved are unknown. We hypothesized that flow-induced NO reduces the stimulation of NHE activity caused by flow-induced O2 (-) via PKG in TALs. Intracellular pH recovery after an acid load was measured as an indicator of NHE activity in isolated, perfused rat TALs. l-Arginine, the NO synthase substrate, decreased NHE activity by 34 ± 5% (n = 5; P < 0.04). The O2 (-) scavenger tempol decreased NHE activity by 46 ± 8% (n = 6; P < 0.004) in the absence of NO. In the presence of l-arginine, the inhibitory effect of tempol on NHE activity was reduced to -19 ± 6% (n = 6; P < 0.03). The soluble guanylate cyclase inhibitor LY-83583 blocked the effect of l-arginine thus restoring tempol's effect on NHE activity to -42 ± 4% (n = 6; P < 0.0005). The PKG inhibitor KT-5823 also inhibited l-arginine's effect on tempol-reduced NHE activity (-43 ± 5%; n = 5; P < 0.03). We conclude that flow-induced NO reduces the stimulatory effect of endogenous, flow-induced O2 (-) on NHE activity in TALs via an increase in cGMP and PKG activation.

Abstract 045: Endogenous Flow-induced Superoxide Stimulates Na/H Exchange Activity Via PKC In Thick Ascending Limbs

Luminal flow stimulates Na reabsorption along the nephron and endogenous superoxide (O 2 - ) production by thick ascending limbs (TALs). The latter is due to protein kinase C (PKC) activation. Exogenously added O 2 - augments TAL Na reabsorption, a process also dependent on PKC. Luminal Na/H exchange (NHE) and Na/K/2Cl cotransport initiate TAL Na reabsorption. However, the role of endogenously-produced O 2 - in the stimulation of luminal NHE activity by flow, and the signaling pathway involved are unclear. We hypothesized that flow-induced production of endogenous O 2 - stimulates luminal NHE activity via PKC in TALs. Intracellular pH (pH i ) recovery was measured as an indicator of NHE activity in isolated, perfused rat TALs. Addition of the O 2 - scavenger tempol decreased total NHE activity by 39% (0.168 ± 0.035 vs 0.103 ± 0.026 pH i units/min; P < 0.01; n = 4) when luminal flow was 20 nl/min; whereas it had no effect when flow was 5 nl/min (0.131 ± 0.027 vs 0.128 ± 0.027 pH i units/min; n = 5). Using the NHE inhibitor 5-(N-ethyl-N-isopropyl)-amiloride (EIPA) in the bath to block basolateral NHE so that pH i recovery only reflected flow-enhanced luminal NHE activity, tempol caused a 30% reduction in pH i recovery (0.097 ± 0.018 vs 0.068 ± 0.015 pH i units/min; P < 0.04; n = 6). When these experiments were repeated with the general PKC inhibitor staurosporine, tempol had no effect (0.136 ± 0.018 vs 0.133 ± 0.007 pH i units/min; n = 4). Because PKC could mediate both induction of O 2 - by flow and the effect of O 2 - on luminal NHE activity, we used hypoxanthine/xanthine oxidase (HX/XO) to elevate O 2 - and examined the role of PKC. HX/XO increased luminal NHE activity by 118% (0.140 ± 0.047 vs 0.305 ± 0.053 pH i units/min; P < 0.02; n = 5); whereas staurosporine blocked this effect (0.134 ± 0.043 vs. 0.125 ± 0.030 pH i units/min; n = 3). The PKCα/β1-specific inhibitor Gö 6976 also blunted HX/XO’s effect (HX/XO: 0.072 ± 0.023 vs 0.170 ± 0.035 pH i units/min; P < 0.008; n = 5; HX/XO in presence of Gö 6976: 0.116 ± 0.029 vs 0.137 ± 0.025 pH i units/min; n = 5). We conclude that flow-induced O 2 - stimulates luminal NHE activity in TALs via PKCα/β1. This process may account for part of flow-stimulated bicarbonate reabsorption in this nephron segment.

Endogenous flow-induced superoxide stimulates Na/H exchange activity via PKC in thick ascending limbs

Luminal flow stimulates Na reabsorption along the nephron and activates protein kinase C (PKC) which enhances endogenous superoxide (O(2) (-)) production by thick ascending limbs (TALs). Exogenously-added O(2) (-) augments TAL Na reabsorption, a process also dependent on PKC. Luminal Na/H exchange (NHE) mediates NaHCO₃reabsorption. However, whether flow-stimulated, endogenously-produced O(2) (-) enhances luminal NHE activity and the signaling pathway involved are unclear. We hypothesized that flow-induced production of endogenous O2 (-) stimulates luminal NHE activity via PKC in TALs. Intracellular pH recovery was measured as an indicator of NHE activity in isolated, perfused rat TALs. Increasing luminal flow from 5 to 20 nl/min enhanced total NHE activity from 0.104 ± 0.031 to 0.167 ± 0.036 pH U/min, 81%. The O(2) (-) scavenger tempol decreased total NHE activity by 0.066 ± 0.011 pH U/min at 20 nl/min but had no significant effect at 5 nl/min. With the NHE inhibitor EIPA in the bath to block basolateral NHE, tempol reduced flow-enhanced luminal NHE activity by 0.029 ± 0.010 pH U/min, 30%. When experiments were repeated with staurosporine, a nonselective PKC inhibitor, tempol had no effect. Because PKC could mediate both induction of O2 (-) by flow and the effect of O(()-) on luminal NHE activity, we used hypoxanthine/xanthine oxidase to elevate O(2) (-). Hypoxanthine/xanthine oxidase increased luminal NHE activity by 0.099 ± 0.020 pH U/min, 137%. Staurosporine and the PKCα/β1-specific inhibitor Gö6976 blunted this effect. We conclude that flow-induced O(2) (-) stimulates luminal NHE activity in TALs via PKCα/β1. This accounts for part of flow-stimulated bicarbonate reabsorption by TALs.

Fructose stimulates Na/H exchange activity and sensitizes the proximal tubule to angiotensin II

The proximal nephron reabsorbs 60% to 70% of the fluid and sodium and most of the filtered bicarbonate via Na/H exchanger 3. Enhanced proximal nephron transport is implicated in hypertension. Our findings show that a fructose-enriched diet causes salt sensitivity. We hypothesized that fructose stimulates luminal Na/H exchange activity and sensitizes the proximal tubule to angiotensin II. Na/H exchange was measured in rat proximal tubules as the rate of intracellular pH (pHi) recovery in fluorescent units/s. Replacing 5 mmol/L glucose with 5 mmol/L fructose increased the rate of pHi recovery (1.8±0.6 fluorescent units/s; P<0.02; n=8). Staurosporine, a protein kinase C inhibitor, blocked this effect. We studied whether this effect was because of the addition of fructose or removal of glucose. The basal rate of pHi recovery was first tested in the presence of a 0.6-mmol/L glucose and 1, 3, or 5 mmol/L fructose added in a second period. The rate of pHi recovery did not change with 1 mmol/L but it increased with 3 and 5 mmol/L of fructose. Adding 5 mmol/L glucose caused no change. Removal of luminal sodium blocked pHi recovery. With 5.5 mmol/L glucose, angiotensin II (1 pmol/L) did not affect the rate of pHi recovery (change, -1.1±0.5 fluorescent units/s; n=9) but it increased the rate of pHi recovery with 0.6 mmol/L glucose/5 mmol/L fructose (change, 4.0±2.2 fluorescent units/s; P<0.02; n=6). We conclude that fructose stimulates Na/H exchange activity and sensitizes the proximal tubule to angiotensin II. This mechanism is likely dependent on protein kinase C. These results may partially explain the mechanism by which a fructose diet induces hypertension.

NADPH oxidase 4 mediates flow-induced superoxide production in thick ascending limbs

We previously showed that luminal flow stimulates thick ascending limb (TAL) superoxide (O(2)(-)) production by stretching epithelial cells and increasing NaCl transport, and reported that the major source of flow-induced O(2)(-) is NADPH oxidase (Nox). However, the specific Nox isoform involved is unknown. Of the three isoforms expressed in the kidney-Nox1, Nox2, and Nox4-we hypothesized that Nox4 is responsible for flow-induced O(2)(-) production in TALs. Measurable flow-induced O(2)(-) production at physiological flow rates of 0, 5, 10, and 20 nl/min was 5 ± 1, 9 ± 2, 36 ± 6, and 66 ± 8 AU/s, respectively. RT-PCR detected mRNA for all three Nox isoforms in the TAL. The order of RNA abundance was Nox2 > Nox4 >>> Nox1. Since all three isoforms are expressed in TALs and pharmacological inhibitors are not selective, we used rats transduced with siRNA and knockout mice. Nox4 siRNA knocked down Nox4 mRNA expression by 63 ± 7% but did not reduce Nox1 or Nox2 mRNA. Flow-induced O(2)(-) was 18 ± 9 AU/s in TALs transduced with Nox4 siRNA compared with 77 ± 9 AU/s in tubules transduced with scrambled siRNA. Flow-induced O(2)(-) was 81 ± 5 AU/s in Nox2 knockout mice compared with 83 ± 13 AU/s in wild-type mice. In TALs transduced with Nox1 siRNA, flow-induced O(2)(-) was 82 ± 7 AU/s. We conclude that Nox4 mediates flow-induced O(2)(-) production in TALs.

Angiotensin II stimulates superoxide production in the thick ascending limb by activating NOX4

Angiotensin II (ANG II) stimulates production of superoxide (O(2)(-)) by NADPH oxidase (NOX) in medullary thick ascending limbs (TALs). There are three isoforms of the catalytic subunit (NOX1, 2, and 4) known to be expressed in the kidney. We hypothesized that NOX2 mediates ANG II-induced O(2)(-) production by TALs. To test this, we measured NOX1, 2, and 4 mRNA and protein by RT-PCR and Western blot in TAL suspensions from rats and found three catalytic subunits expressed in the TAL. We measured O(2)(-) production using a lucigenin-based assay. To assess the contribution of NOX2, we measured ANG II-induced O(2)(-) production in wild-type and NOX2 knockout mice (KO). ANG II increased O(2)(-) production by 346 relative light units (RLU)/mg protein in the wild-type mice (n = 9; P < 0.0007 vs. control). In the knockout mice, ANG II increased O(2)(-) production by 290 RLU/mg protein (n = 9; P < 0.007 vs. control). This suggests that NOX2 does not contribute to ANG II-induced O(2)(-) production (P < 0.6 WT vs. KO). To test whether NOX4 mediates the effect of ANG II, we selectively decreased NOX4 expression in rats using an adenovirus that expresses NOX4 short hairpin (sh)RNA. Six to seven days after in vivo transduction of the kidney outer medulla, NOX4 mRNA was reduced by 77%, while NOX1 and NOX2 mRNA was unaffected. In control TALs, ANG II stimulated O(2)(-) production by 96%. In TALs transduced with NOX4 shRNA, ANG II-stimulated O(2)(-) production was not significantly different from the baseline. We concluded that NOX4 is the main catalytic isoform of NADPH oxidase that contributes to ANG II-stimulated O(2)(-) production by TALs.

Angiotensin II type 2 receptor-mediated inhibition of NaCl absorption is blunted in thick ascending limbs from Dahl salt-sensitive rats

NO reduces NaCl absorption by thick ascending limbs (TALs) by inhibiting the Na/K/2Cl cotransporter (NKCC2). We have shown that NO-induced inhibition of Na transport is reduced in Dahl salt-sensitive rat (SS) TALs. Angiotensin II increases NO production in TALs via angiotensin II type 2 receptor (AT(2)R). It is unknown whether AT(2)Rs regulate TAL NaCl absorption and whether this effect is reduced in SS rats. We hypothesized that AT(2)R activation decreases TAL Na transport via NO, and this effect is blunted in SS rats. In the presence of angiotensin II type 1 receptor antagonist losartan, AT(2)R activation with angiotensin II inhibited NKCC2 activity by 32±7% (P<0.03). AT(2)R antagonist PD-123319 abolished the effect of angiotensin II. Activation with the AT(2)R-selective agonist CGP42112A (10 nmol/L) decreased NKCC2 activity by 29±6% (P<0.03). The effect of CGP42112A on NKCC2 activity was blocked by PD-123319 and by NO synthase inhibitor N(G)-nitro-l-arginine methyl ester. In Dahl salt-resistant rat TALs, 1 nmol/L of CGP42112A decreased NKCC2 activity by 23±4% (P<0.01). In SS TALs, it had no effect. TAL AT(2)R mRNA did not differ in SS versus salt-resistant rats. We conclude the following: (1) TAL AT(2)R activation decreases Na absorption; (2) this effect is mediated by AT(2)R-induced stimulation of NO; (3) AT(2)R-induced reduction of NKCC2 activity is blunted in SS rats; and (4) defects in AT(2)R/NO signaling rather than decreased AT(2)R expression likely account for the blunted effect in SS TALs. Impaired AT(2)R-mediated signaling in TALs could contribute to the Na retention associated with salt-sensitive hypertension.

Tumor necrosis factor α decreases nitric oxide synthase type 3 expression primarily via Rho/Rho kinase in the thick ascending limb

Inappropriate Na(+) reabsorption by thick ascending limbs (THALs) induces hypertension. NO produced by NO synthase type 3 (NOS3) inhibits NaCl reabsorption by THALs. Tumor necrosis factor α (TNF-α) decreases NOS3 expression in endothelial cells and contributes to increases in blood pressure. However, the effects of TNF-α on THAL NOS3 and the signaling cascade are unknown. TNF-α activates several signaling pathways, including Rho/Rho kinase (ROCK), which is known to reduce NOS3 expression in endothelial cells. Therefore, we hypothesized that TNF-α decreases NOS3 expression via Rho/ROCK in rat THAL primary cultures. THAL cells were incubated with either vehicle or 1 nmol/L of TNF-α for 24 hours, and NOS3 expression was measured by Western blot. TNF-α decreased NOS3 expression by 51 ± 6% (P<0.002) and blunted stimulus-induced NO production. A 10-minute treatment with TNF-α stimulated RhoA activity by 60 ± 23% (P<0.04). Inhibition of Rho GTPase with 0.05 μg/mL of C3 exoenzyme blocked TNF-α-induced reductions in NOS3 expression by 30 ± 8% (P<0.02). Inhibition of ROCK with 10 μmol/L of H-1152 blocked TNF-α-induced decreases in NOS3 expression by 66 ± 15% (P<0.001). Simultaneous inhibition of Rho and ROCK had no additive effect. Myosin light chain kinase, NO, protein kinase C, mitogen-activated kinase kinase, c-Jun amino terminal kinases, and Rac-1 were also not involved in TNF-α-induced decreases in NOS3 expression. We conclude that TNF-α decreases NOS3 expression primarily via Rho/ROCK in rat THALs. These data suggest that some of the beneficial effects of ROCK inhibitors in hypertension could be attributed to the mitigation of TNF-α-induced reduction in NOS3 expression.

ATP mediates flow-induced NO production in thick ascending limbs

Mechanical stimulation caused by increasing flow induces nucleotide release from many cells. Luminal flow and extracellular ATP stimulate production of nitric oxide (NO) in thick ascending limbs. However, the factors that mediate flow-induced NO production are unknown. We hypothesized that luminal flow stimulates thick ascending limb NO production via ATP. We measured NO in isolated, perfused rat thick ascending limbs using the fluorescent dye DAF FM. The rate of increase in dye fluorescence reflects NO accumulation. Increasing luminal flow from 0 to 20 nl/min stimulated NO production from 17 ± 16 to 130 ± 37 arbitrary units (AU)/min (P < 0.02). Increasing flow from 0 to 20 nl/min raised ATP release from 4 ± 1 to 21 ± 6 AU/min (P < 0.04). Hexokinase (10 U/ml) plus glucose, which consumes ATP, completely prevented the measured increase in ATP. Luminal flow did not increase NO production in the presence of luminal and basolateral hexokinase (10 U/ml). When flow was increased with the ATPase apyrase in both luminal and basolateral solutions (5 U/ml), NO levels did not change significantly. The P2 receptor antagonist suramin (300 μmol/l) reduced flow-induced NO production by 83 ± 25% (P < 0.03) when added to both and basolateral sides. Luminal hexokinase decreased flow-induced NO production from 205.6 ± 85.6 to 36.6 ± 118.6 AU/min (P < 0.02). Basolateral hexokinase also reduced flow-induced NO production. The P2X receptor-selective antagonist NF023 (200 μmol/l) prevented flow-induced NO production when added to the basolateral side but not the luminal side. We conclude that ATP mediates flow-induced NO production in the thick ascending limb likely via activation of P2Y receptors in the luminal and P2X receptors in the basolateral membrane.

Shear stress increases nitric oxide production in thick ascending limbs

We showed that luminal flow stimulates nitric oxide (NO) production in thick ascending limbs. Ion delivery, stretch, pressure, and shear stress all increase when flow is enhanced. We hypothesized that shear stress stimulates NO in thick ascending limbs, whereas stretch, pressure, and ion delivery do not. We measured NO in isolated, perfused rat thick ascending limbs using the NO-sensitive dye DAF FM-DA. NO production rose from 21 ± 7 to 58 ± 12 AU/min (P < 0.02; n = 7) when we increased luminal flow from 0 to 20 nl/min, but dropped to 16 ± 8 AU/min (P < 0.02; n = 7) 10 min after flow was stopped. Flow did not increase NO in tubules from mice lacking NO synthase 3 (NOS 3). Flow stimulated NO production by the same extent in tubules perfused with ion-free solution and physiological saline (20 ± 7 vs. 24 ± 6 AU/min; n = 7). Increasing stretch while reducing shear stress and pressure lowered NO generation from 42 ± 9 to 17 ± 6 AU/min (P < 0.03; n = 6). In the absence of shear stress, increasing pressure and stretch had no effect on NO production (2 ± 8 vs. 8 ± 8 AU/min; n = 6). Similar results were obtained in the presence of tempol (100 μmol/l), a O(2)(-) scavenger. Primary cultures of thick ascending limb cells subjected to shear stresses of 0.02 and 0.55 dyne/cm(2) produced NO at rates of 55 ± 10 and 315 ± 93 AU/s, respectively (P < 0.002; n = 7). Pretreatment with the NOS inhibitor l-NAME (5 mmol/l) blocked the shear stress-induced increase in NO production. We concluded that shear stress rather than pressure, stretch, or ion delivery mediates flow-induced stimulation of NO by NOS 3 in thick ascending limbs.

PKC-alpha mediates flow-stimulated superoxide production in thick ascending limbs

We showed that luminal flow increases net superoxide (O(2)(-)) production via NADPH oxidase in thick ascending limbs. Protein kinase C (PKC) activates NADPH oxidase activity in phagocytes, cardiomyocytes, aortic endothelial cells, vascular smooth muscle cells, and renal mesangial cells. However, the flow-activated pathway that induces NADPH oxidase activity in thick ascending limbs is unclear. We hypothesized that PKC mediates flow-stimulated net O(2)(-) production by thick ascending limbs. Initiation of flow (20 nl/min) increased net O(2)(-) production from 4 +/- 1 to 61 +/- 12 AU/s (P < 0.007; n = 5). The NADPH oxidase inhibitor apocynin completely blocked the flow-induced increase in net O(2)(-) production (2 +/- 1 vs. 1 +/- 1 AU/s; P > 0.05; n = 5). Flow-stimulated O(2)(-) was also blocked in p47(phox)-deficient mice. We measured flow-stimulated PKC activity with a fluorescence resonance energy transfer (FRET)-based membrane-targeted PKC activity reporter and found that the FRET ratio increased from 0.87 +/- 0.02 to 0.96 +/- 0.04 AU (P < 0.05; n = 6). In the absence of flow, the PKC activator phorbol 12-myristate 13-acetate (200 nM) enhanced net O(2)(-) production from 5 +/- 2 to 92 +/- 6 AU/s (P < 0.001; n = 6). The PKC-alpha- and betaI-selective inhibitor Gö 6976 (100 nM) decreased flow-stimulated net O(2)(-) production from 54 +/- 15 to 2 +/- 1 AU/s (P < 0.04; n = 5). Flow-induced net O(2)(-) production was inhibited in thick ascending limbs transduced with dominant-negative (dn)PKC-alpha but not dnPKCbetaI or LacZ (Delta = 11 +/- 3 AU/s for dnPKCalpha, 55 +/- 7 AU/s for dnPKCbetaI, and 63 +/- 7 AU/s for LacZ; P < 0.001; n = 6). We concluded that flow stimulates net O(2)(-) production in thick ascending limbs via PKC-alpha-mediated activation of NADPH oxidase.

Nitric oxide reduces flow-induced superoxide production via cGMP-dependent protein kinase in thick ascending limbs

We have shown that increased luminal flow induces O(2)(-) and nitric oxide (NO) production in thick ascending limbs (TALs). However, the interaction of flow-stimulated NO and O(2)(-) in TALs is unclear. We hypothesized that NO inhibits flow-induced O(2)(-) production in TALs via cGMP-dependent protein kinase (PKG). We measured flow-stimulated O(2)(-) production in rat TALs using dihydroethidium in the absence and presence of L-arginine (0.3 mM), the substrate for NO synthase. The addition of L-arginine reduced flow-induced net O(2)(-) production from 68 +/- 9 to 17 +/- 4 AU/s (P < 0.002). The addition of the NO synthase inhibitor N(G)-nitro-l-arginine methyl ester (L-NAME; 5 mM) in the presence of L-arginine stimulated production (L-arginine: 15 +/- 4 AU/s vs. L-arginine + L-NAME: 63 +/- 7 AU/s; P < 0.002). The guanylate cyclase inhibitor LY-83583 (10 microM) also enhanced flow-induced net O(2)(-) production in the presence of L-arginine (L-arginine: 7 +/- 4 AU/s vs. L-arginine + LY-83583: 53 +/- 7 AU/s; P < 0.01). In the presence of LY-83583, L-arginine only reduced flow-induced net O(2)(-) by 36% (LY-83583: 80 +/- 7 AU/s vs. LY-83583 + L-arginine: 51 +/- 3 AU/s; P < 0.006). The cGMP analog dibutyryl (db)-cGMP reduced flow-induced net O(2)(-) from 39 +/- 9 to 7 +/- 3 AU/s (P < 0.03). The PKG inhibitor KT-5823 (5 microM) partially restored flow-induced net O(2)(-) in the presence of L-arginine (L-arginine: 4 +/- 4 AU/s vs. L-arginine + KT-5823: 32 +/- 9 AU/s; P < 0.03) and db-cGMP (db-cGMP: 9 +/- 7 AU/s vs. db-cGMP + KT-5823: 54 +/- 5 AU/s; P < 0.01). Phosphodiesterase II inhibition had no effect on arginine-inhibited O(2)(-) production. We conclude that 1) NO reduces flow-stimulated O(2)(-) production, 2) this occurs primarily via the cGMP/PKG pathway, and 3) O(2)(-) scavenging by NO plays a minor role.

Endothelin-1 inhibits thick ascending limb transport via Akt-stimulated nitric oxide production

Endothelin-1 inhibits sodium reabsorption in the thick ascending limb (THAL) via stimulation of nitric oxide (NO) production. The mechanism whereby endothelin-1 stimulates THAL NO is unknown. We hypothesized that endothelin-1 stimulates THAL NO production by activating phosphatidylinositol 3-kinase (PI3K), stimulating Akt activity, and phosphorylating NOS3 at Ser1177. This enhances NO production and inhibits sodium transport. We measured 1) NO production by fluorescence microscopy using DAF2-DA, 2) Akt activity using a fluorescence resonance energy transfer-based Akt reporter, 3) phosphorylated NOS3 and Akt by Western blotting, and 4) NKCC2 activity by fluorescence microscopy. In isolated THAL, endothelin-1 (1 nmol/liter) increased NO production from 0.23 +/- 0.24 to 2.81 +/- 0.32 fluorescence units/min (p < 0.001; n = 5) but failed to stimulate NO production in THALs isolated from NOS3-/- mice. Wortmannin (150 nmol/liter), a PI3K inhibitor, reduced endothelin-1-stimulated NO by 83% (0.49 +/- 0.13 versus 3.31 +/- 0.49 fluorescence units/min for endothelin-1 alone; p < 0.006; n = 5). Endothelin-1 stimulated Akt activity by 0.16 +/- 0.02 arbitrary units as measured by fluorescence resonance energy transfer (p < 0.001; n = 5) and increased phosphorylation of Akt at Ser473 by 56 +/- 11% (p < 0.002; n = 7). Dominant-negative Akt blocked endothelin-1-induced NO by 60 +/- 8% (p < 0.001 versus control; n = 6), and an Akt inhibitor had a similar effect. Endothelin-1 increased phosphorylation of NOS3 at Ser1177 by 89 +/- 24% (p < 0.01; n = 7) but had no effect on Ser633. Endothelin-1 inhibited NKCC2 activity, an effect that was blocked by dominant-negative Akt and NOS inhibition. We conclude that endothelin-1 stimulates THAL NO production by activating PI3K, stimulating Akt activity, and phosphorylating NOS3 at Ser1177. This enhances NO production and inhibits sodium transport.

Cellular stretch increases superoxide production in the thick ascending limb

Superoxide (O(2)(-)) is an important regulator of kidney function. We have recently shown that luminal flow stimulates O(2)(-) production in the thick ascending limb (TAL), attributable in part to mechanical factors. Stretch, pressure and shear stress all change when flow increases in the TAL. We hypothesized that stretch rather than shear stress or pressure per se stimulates O(2)(-) production by TALs. We measured O(2)(-) production in isolated perfused rat TALs using fluorescence microscopy and dihydroethidium. Tubules were perfused with a Na-free solution to eliminate the confounding effect of Na transport. Flow induced an increase in O(2)(-) production from 29+/-4 to 90+/-8 AU/s (P<0.002; n=5). The response to flow is rapidly reversible. O(2)(-) production by TALs perfused at 10 nL/min decreased from 113+/-6 to 25+/-10 AU/s (P<0.003; n=4) 15 minutes after flow was stopped. Increasing pressure and stretch in the absence of shear stress caused a significant increase in O(2)(-) production (40+/-6 to 118+/-17 AU/s; P<0.02; n=5). In contrast, eliminating shear stress had no effect (107+/-9 versus 108+/-10 AU/s; n=5). Increasing stretch by 27+/-2% in the presence of flow while reducing pressure stimulated O(2)(-) production from 66+/-7 to 84+/-9 AU/s (29+/-8%; P<0.02; n=5). Tempol inhibited this increase (n=5). We conclude that increasing stretch rather than pressure or shear stress accounts for the mechanical aspect of flow-induced O(2)(-) production in the TAL. Stretch of the TAL during hypertension, diabetes, and salt loading may contribute to renal damage.

Flow increases superoxide production by NADPH oxidase via activation of Na-K-2Cl cotransport and mechanical stress in thick ascending limbs

Superoxide (O2−) regulates renal function and is implicated in hypertension. O2−production increases in response to increased ion delivery in thick ascending limbs (TALs) and macula densa and mechanical strain in other cell types. Tubular flow in the kidney acutely varies causing changes in ion delivery and mechanical stress. We hypothesized that increasing luminal flow stimulates O2−production by NADPH oxidase in TALs via activation of Na-K-2Cl cotransport. We measured intracellular O2−in isolated rat TALs using dihydroethidium in the presence and absence of luminal flow and inhibitors of NADPH oxidase, Na-K-2Cl cotransport, and Na/H exchange. In the absence of flow, the rate of O2−production was 5.8 ± 1.4 AU/s. After flow was initiated, it increased to 29.7 ± 4.3 AU/s ( P < 0.001). O2−production was linearly related to flow. Tempol alone and apocynin alone blocked the flow-induced increase in O2−production (3.5 ± 1.7 vs. 4.5 ± 2.8 AU/s and 8.2 ± 2.1 vs. 10.6 ± 2.8 AU/s, respectively). Furosemide decreased flow-induced O2−production by 55% (37.3 ± 5.2 to 16.8 ± 2.8 AU/s; P < 0.002); however, dimethylamiloride had no effect. Finally, we examined whether changes in mechanical forces are involved in flow-induced O2−production by using a Na-free solution to perfuse TALs. In the absence of NaCl, luminal flow enhanced O2−production (1.5 ± 0.5 to 13.5 ± 1.1 AU/s; P < 0.001), ∼50% less stimulation than when flow was increased in the presence of luminal NaCl. We conclude that flow stimulates O2−production in TALs via activation of NADPH oxidase and that NaCl absorption due to Na-K-2Cl cotransport and flow-associated mechanical factors contribute equally to this process.

Superoxide stimulates NaCl absorption in the thick ascending limb via activation of protein kinase C

Abnormal production of superoxide (O(2)(-)) contributes to hypertension, in part because of its effects on the kidney. The thick ascending limb absorbs 20% to 30% of the filtered load of NaCl. O(2)(-) stimulates NaCl absorption by the thick ascending limb by enhancing Na(+)/K(+)/2Cl(-) cotransporter activity; however, the signaling mechanism is unknown. We hypothesized that O(2)(-) stimulates NaCl absorption by activating protein kinase C (PKC). To test this, we measured the effect of O(2)(-) on: (1) Cl(-) absorption in the presence and absence of PKC inhibitors, (2) total PKC activity, and (3) activation of specific PKC isoforms. Isolated perfused medullary thick ascending limbs were exposed to O(2)(-) generated by xanthine oxidase (1 mU/mL) and hypoxanthine (0.5 mmol/L). O(2)(-) increased Cl(-) absorption by 42% (from 76.2+/-3.6 to 108.2+/-11.9 pmol/min per millimeter; n=5; P<0.05). After treatment with the general PKC inhibitor staurosporine (10 nmol/L), O(2)(-) did not stimulate Cl(-) absorption (Delta-5.7+/-8.6%; n=6). In thick ascending limb suspensions, O(2)(-) increased total PKC activity by 33% (from 66+/-11 to 88+/-12 mU/mg protein; n=5; P<0.05) and increased PKC-alpha and PKC-delta activity by 1.75- and 0.37-fold, respectively. The PKC-alpha/beta-selective inhibitor Gö976 (100 nmol/L) blocked the ability of O(2)(-) to stimulate Cl(-) absorption by isolated perfused medullary thick ascending limbs (Delta4.5+/-15.0%; n=5). The role of PKC-delta could not be studied because of cell necrosis caused by the selective inhibitor rottlerin. We conclude that PKC-alpha is required for O(2)(-)-stimulated NaCl absorption in the thick ascending limb.

Aquaporin-1 Transports NO Across Cell Membranes

NO plays a role in the regulation of blood pressure through its effects on renal, cardiovascular, and central nervous system function. It is generally thought to freely diffuse through cell membranes without need for a specific transporter. The water channel aquaporin-1 transports low molecular weight gases in addition to water and is expressed in cells that produce or are the targets of NO. Consequently, we tested the hypothesis that aquaporin-1 transports NO. In cells expressing aquaporin-1, NO permeability correlated with water permeability. NO transport was reduced by 71% by HgCl2, an inhibitor of aquaporin-1. Transport of NO by aquaporin-1 saturated at 3 micromol/L NO and displayed a K(1/2) (the concentration of NO that produces half of the maximum transport rate) of 0.54 micromol/L. Reconstitution of purified aquaporin-1 into lipid vesicles increased NO influx by 316%. In endothelial cells, lowering aquaporin-1 expression with a small interfering RNA (siRNA) blunted aquaporin-1 expression by 54% and NO release by 44%. We conclude that NO transport by aquaporin-1 may allow cells to control intracellular NO levels and effects. NO transport by aquaporin-1 may play a role in central nervous system, vascular and renal function, and consequently blood pressure. Disruption of NO transport by aquaporin-1 offers an alternate cause for diseases currently explained by inadequate NO bioavailability.

Differential effects of superoxide on luminal and basolateral Na+/H+ exchange in the thick ascending limb

Superoxide (O2−) increases Na+ reabsorption in the thick ascending limb (THAL) by enhancing Na/K/2Cl cotransport. However, the effects of O2− on other THAL transporters, such as Na+/H+ exchangers, are unknown. We hypothesized that O2− stimulates Na+/H+ exchange in the THAL. We assessed total Na+/H+ exchange activity by measuring recovery of intracellular pH (pHi) after acid loading in isolated perfused THALs before and after adding xanthine oxidase (XO) and hypoxanthine (HX). We found that XO and HX decreased total pHi recovery rate from 0.26 ± 0.05 to 0.21 ± 0.04 pH units/min ( P < 0.05), and this net inhibition decreased steady-state pHi from 7.52 to 7.37. Because THALs have different Na+/H+ exchanger isoforms on the luminal and basolateral membrane, we tested the effects of xanthine oxidase and hypoxanthine on luminal and basolateral Na+/H+ exchange by adding dimethylamiloride to either the bath or lumen. Xanthine oxidase and hypoxanthine increased luminal Na+/H+ exchange from 3.5 ± 0.8 to 6.7 ± 1.4 pmol·min−1·mm−1 ( P < 0.01) but decreased basolateral Na+/H+ exchange from 10.8 ± 1.8 to 6.8 ± 1.1 pmol·min−1·mm−1 ( P < 0.007). To ascertain whether these effects were caused by O2− or H2O2, we examined the ability of tempol, a superoxide dismutase mimetic, to block these effects. In the presence of tempol, xanthine oxidase and hypoxanthine had no effect on luminal or basolateral Na+/H+ exchange. We conclude that O2− inhibits basolateral and stimulates luminal Na+/H+ exchangers, perhaps because different isoforms are expressed on each membrane. Inhibition of basolateral Na+/H+ exchange may enhance stimulation of luminal Na+/H+ exchange by providing additional protons to be extruded across the luminal membrane. Together, the effects of O2− on Na+/H+ exchange may increase net HCO3− reabsorption by the THAL.

Luminal flow induces eNOS activation and translocation in the rat thick ascending limb

Nitric oxide (NO) produced by endothelial NO synthase (eNOS) acts as an autacoid to inhibit NaCl absorption in the thick ascending limb of the loop of Henle (THAL). In the vasculature, shear stress activates eNOS. We hypothesized that increasing luminal flow activates eNOS and enhances NO production in the THAL. We measured NO production by isolated, perfused THALs using a NO-sensitive microelectrode. Increasing luminal flow from 0 to 20 nl/min increased NO production by 43.1 ± 4.1 pA/mm of tubule ( n = 10, P < 0.05), and this response was blunted (92%) by the NOS inhibitor l-ωnitro-methylarginine ( P < 0.05). We studied the effect of flow on eNOS subcellular localization. In the absence of flow, eNOS was diffusely localized throughout the cell (basolateral = 33 ± 4%; middle = 27 ± 3%; apical = 40 ± 4% of total eNOS). Increasing luminal flow induced eNOS translocation to the apical membrane, as evidenced by a 60% increase in eNOS immunoreactivity in the apical membrane (from 40 ± 4 to 65 ± 2%; n = 6; P < 0.05). Disrupting the actin cytoskeleton with cytochalasin D (10 μM) reduced flow-induced NO production by 62% (from 37.1 ± 3.4 to 14.0 ± 2.4 pA/mm tubule, n = 7, P < 0.04) and blocked flow-induced eNOS translocation. Flow also increased the amount of phosphorylated eNOS (Ser1179) at the apical membrane (from 25 ± 2 to 56 ± 2%; P < 0.05). We conclude that increasing luminal flow induces eNOS activation and translocation to the apical membrane in THALs. These are the first data showing that flow regulates eNOS in epithelial cells. This may be an important mechanism for regulation of NO levels in the renal medulla.

Luminal flow induces eNOS activation and translocation in the rat thick ascending limb. II. Role of PI3-kinase and Hsp90

Endothelial nitric oxide synthase (eNOS) regulates NaCl absorption by the thick ascending limb of the loop of Henle (THAL). We found that augmenting luminal flow induces eNOS activation and translocation to the apical membrane of THALs (Ortiz PA, Hong NJ, and Garvin JL. Am J Physiol Renal Physiol 287: F274-F280, 2004). In other cells, eNOS activation by shear stress is mediated by phosphatidylinositol 3-OH kinase (PI3)-kinase. We hypothesized that luminal flow induces eNOS activation via PI3-kinase. Pretreatment of THALs with wortmannin, a PI3-kinase inhibitor, significantly reduced flow-induced nitric oxide (NO) release by 75% (from 53.6 +/- 6 to 13.2 +/- 5.7 pA/mm). Increasing luminal flow from 0 to 20 nl/min induced eNOS translocation to the apical membrane, whereas in the presence of wortmannin eNOS translocation was prevented (basolateral = 32 +/- 2%, middle = 38 +/- 1%, apical = 30 +/- 1%, n = 5, not significant vs. no flow). We next studied which PI3-kinase product mediates eNOS translocation. Addition of PI(3,4,5)P(3) (5 microM) in the absence of flow increased NO levels (P < 0.05) and induced eNOS translocation to the apical membrane (from 40 +/- 4 to 60 +/- 2% of total eNOS, n = 6, P < 0.05). Incubation with PI(3,4)P(2) or PI(4,5)P(2) did not change eNOS localization. We next tested whether heat shock protein (Hsp)90 is involved in eNOS translocation. The Hsp90 inhibitor geldanamycin blocked flow-induced eNOS translocation to the apical membrane (n = 6). Flow also induced translocation of Hsp90 to the apical membrane (from 35 +/- 2 to 57 +/- 2%; P < 0.05) in a PI3-kinase-dependent manner. We conclude that luminal flow induces eNOS translocation and activation in the THAL via PI3-kinase and that Hsp90 is involved in eNOS translocation to the apical membrane.

Gene transfer of eNOS to the thick ascending limb of eNOS-KO mice restores the effects of L-arginine on NaCl absorption

The thick ascending limb of the loop of Henle (THAL) plays an essential role in the regulation of sodium and water homeostasis by the kidney. l-Arginine, the substrate for nitric oxide synthase (NOS), decreases NaCl absorption by THALs. We hypothesized that eNOS produces the NO that regulates THAL NaCl transport and that selective expression of eNOS in the THAL of eNOS knockout(-/-) mice would restore the effects of l-arginine on NaCl absorption. eNOS-/- mice were anesthetized, the left kidney was exposed, and the renal interstitium was injected with recombinant adenoviral vectors that expressed green fluorescent protein (GFP) or eNOS driven by the promoter of the Na/K/2Cl cotransporter Ad-NKCC2GFP and Ad-NKCC2eNOS, respectively. In Ad-NKCC2eNOS-transduced kidneys, eNOS expression was detected 7 days after injection but was absent in Ad-NKCC2GFP-transduced kidneys. In THALs from eNOS-/- mice transduced with Ad-NKCC2eNOS, adding L-arginine increased DAF-2DA fluorescence, a measure of NO production, by 9.1+/-1.1% (P<0.05; n=5), but not in THALs transduced with Ad-NKCC2GFP. In THALs from eNOS-/- mice transduced with Ad-NKCC2eNOS, Cl absorption averaged 85.9+/-11.8 pmol/min per millimeter. Adding l-arginine (1 mmol/L) to the bath decreased Cl absorption to 59.7+/-11.0 pmol/min per millimeter (P<0.05; n=6). In THALs transduced with Ad-NKCC2GFP, Cl absorption averaged 96.0+/-21.0 pmol/min per millimeter. Adding L-arginine to the bath did not significantly affect Cl absorption (100.6+/-20.6 pmol/min per millimeter; n=4). We concluded that gene transfer of eNOS to the THAL of eNOS-/- mice restores L-arginine-induced inhibition of NaCl transport and NO production. These data indicate that eNOS is essential for the regulation of THAL NaCl transport by NO.

An in vivo method for adenovirus-mediated transduction of thick ascending limbs

BACKGROUND

The thick ascending limb of the loop of Henle (THAL) plays an important role in the maintenance of salt, water, and acid-base balance. While techniques for gene transfer of renal vascular cells and some tubular segments have been described, in vivo transduction of THALs has not been successful. We hypothesized that in vivo injection of adenoviral vectors into the renal medulla would result in efficient transduction of THALs.

METHODS

We injected recombinant adenoviruses containing the reporter gene, green fluorescent protein (GFP), driven by either the cytomegalovirus promoter (Ad-CMVGFP) or the promoter for the Na/K/2 Cl cotransporter (Ad-NKCC2GFP), which is THAL-specific, into the outer medullary interstitium of Sprague-Dawley rat kidneys. Kidneys were removed at various times after viral injection and analyzed for GFP expression.

RESULTS

Western blots revealed strong GFP expression in the outer medulla (which is composed primarily of THALs) 5 days after Ad-CMVGFP injection. We quantified THAL transduction efficiency by scoring the number of fluorescent tubules in THALs suspensions, which showed that at least 77 +/- 3% of THAL expressed GFP. To specifically transduce THALs, we injected Ad-NKCC2GFP into the medullary interstitium. As determined by Western blot, GFP expression was only detected in the outer medulla. Immunohistochemistry and confocal microscopy showed that GFP was localized to tubular cells positive for Tamm-Horsfall protein. Thus, GFP fluorescence was only detected in THALs, not in cortical, inner medulla or vascular cells. Time-course studies showed that GFP expression in THALs was measurable from 4 to 14 days, peaked at 7 days, and had returned to background levels by 21 days.

CONCLUSION

This method facilitates highly efficient, THAL-specific transduction. While application of this technique for gene therapy in humans is unlikely due to the transient gene expression observed and the impossibility for repeated injections of adenoviral vectors, this method provides a valuable tool for investigators studying regulation and mechanisms of THAL ion transport and its relationship to whole-kidney physiology and pathophysiology.

High-salt diet increases sensitivity to NO and eNOS expression but not NO production in THALs

L-Arginine inhibits thick ascending limb (THAL) NaCl absorption by activating endothelial NO synthase (eNOS) and increasing NO production. Inhibition of renal NO production combined with a high-salt diet produces hypertension, and the THAL has been implicated in salt-sensitive hypertension. We hypothesized that a high-salt diet enhances the inhibitory action of L-arginine on NaCl absorption by THALs because of increased eNOS expression and NO production. To test this, we used isolated THALs from rats on a normal-salt (NS) or high-salt diet (HS) for 7 to 10 days. L-Arginine (1 mmol/L) decreased chloride absorption by 56+/-10% in THALs from rats on a HS diet, but only 29+/-3% in THALs from rats on a NS diet. eNOS expression in isolated THALs from rats on a HS diet was increased by 3.9-fold compared with NS (P<0.03). However, L-arginine increased NO levels to the same extent in THALs from both groups, as measured with DAF-2 DA or a NO-sensitive electrode. To determine whether a HS diet increases the sensitivity of the THAL to NO, we tested the effects of the NO donor spermine NONOate on chloride absorption. In THALs from rats on a HS diet, 1 and 5 micromol/L spermine NONOate reduced chloride absorption by 35+/-5% and 58+/-6%, respectively. In contrast, these same concentrations of spermine NONOate reduced chloride absorption by 4+/-4% (P<0.03 versus HS diet) and 43+/-9% in THALs from rats on a NS diet. We conclude that a HS diet enhances the effect of NO in the THAL. L-Arginine-stimulated NO production was not enhanced by a HS diet, despite increased eNOS protein.

NO decreases thick ascending limb chloride absorption by reducing Na+-K+-2Cl− cotransporter activity

First published August 9, 2001; 10.1152/ajprenal.0075.2001.—We have reported that nitric oxide (NO) inhibits thick ascending limb (THAL) chloride absorption ( J Cl− ). NaCl transport in the THAL depends on apical Na+-K+-2Cl−cotransporters, apical K+ channels, and basolateral Na+-K+-ATPase. However, the transporter inhibited by NO is unknown. We hypothesized that NO decreases THAL J Cl− by inhibiting the Na+-K+-2Cl− cotransporter. THALs from Sprague-Dawley rats were isolated and perfused. Intracellular sodium ([Na+]i) and chloride concentrations ([Cl−]i) were measured with sodium green and SPQ, respectively. The NO donor spermine NONOate (SPM) decreased [Na+]i from 13.5 ± 1.2 to 9.6 ± 1.6 mM ( P < 0.05) and also decreased [Cl−]i ( P < 0.01). We next tested whether NO decreases Na+-K+-2Cl− cotransporter activity by measuring the initial rate of Na+ transport. In the presence of SPM in the bath, initial rates of Na+ entry were 49.6 ± 6.0% slower compared with control rates ( P < 0.05). To determine whether NO inhibits apical K+ channel activity, we measured the change in membrane potential caused by an increase in luminal K+ from 1 to 25 mM using a potential-sensitive fluorescent dye. In the presence of SPM, increasing luminal K+ concentration depolarized THALs to the same extent as it did in control tubules. We then tested whether a change in apical K+ permeability could affect NO-induced inhibition of THAL J Cl− . In the presence of luminal valinomycin, which increases K+permeability, addition of SPM decreased THAL J Cl− by 41.2 ± 10.4%, not significantly different from the inhibition observed in control tubules. We finally tested whether NO alters the affinity or maximal rate of Na+-K+-ATPase by measuring oxygen consumption rate (Qo 2) in THAL suspensions in the presence of nystatin in varying concentrations of Na+. In the presence of 10.5 mM Na+, nystatin increased Qo 2 to 119.1 ± 19.2 and 125.6 ± 23.4 nmol O2 · mg protein−1 · min−1 in SPM- and furosemide-treated tubules, respectively. In the presence of 145 mM extracellular Na+, nystatin increased Qo 2 by 104 ± 7 and 94 ± 20% in NO- and furosemide-treated tubules, respectively. We concluded that NO decreases THAL J Cl− by inhibiting Na+-K+-2Cl− cotransport rather than inhibiting apical K+ channels or the sodium pump.

NO decreases thick ascending limb chloride absorption by reducing Na(+)-K(+)-2Cl(-) cotransporter activity

We have reported that nitric oxide (NO) inhibits thick ascending limb (THAL) chloride absorption (J(Cl(-))). NaCl transport in the THAL depends on apical Na(+)-K(+)-2Cl(-) cotransporters, apical K(+) channels, and basolateral Na(+)-K(+)-ATPase. However, the transporter inhibited by NO is unknown. We hypothesized that NO decreases THAL J(Cl(-)) by inhibiting the Na(+)-K(+)-2Cl(-) cotransporter. THALs from Sprague-Dawley rats were isolated and perfused. Intracellular sodium ([Na(+)](i)) and chloride concentrations ([Cl(-)](i)) were measured with sodium green and SPQ, respectively. The NO donor spermine NONOate (SPM) decreased [Na(+)](i) from 13.5 +/- 1.2 to 9.6 +/- 1.6 mM (P < 0.05) and also decreased [Cl(-)](i) (P < 0.01). We next tested whether NO decreases Na(+)-K(+)-2Cl(-) cotransporter activity by measuring the initial rate of Na(+) transport. In the presence of SPM in the bath, initial rates of Na(+) entry were 49.6 +/- 6.0% slower compared with control rates (P < 0.05). To determine whether NO inhibits apical K(+) channel activity, we measured the change in membrane potential caused by an increase in luminal K(+) from 1 to 25 mM using a potential-sensitive fluorescent dye. In the presence of SPM, increasing luminal K(+) concentration depolarized THALs to the same extent as it did in control tubules. We then tested whether a change in apical K(+) permeability could affect NO-induced inhibition of THAL J(Cl(-)). In the presence of luminal valinomycin, which increases K(+) permeability, addition of SPM decreased THAL J(Cl(-)) by 41.2 +/- 10.4%, not significantly different from the inhibition observed in control tubules. We finally tested whether NO alters the affinity or maximal rate of Na(+)-K(+)-ATPase by measuring oxygen consumption rate (QO(2)) in THAL suspensions in the presence of nystatin in varying concentrations of Na(+). In the presence of 10.5 mM Na(+), nystatin increased QO(2) to 119.1 +/- 19.2 and 125.6 +/- 23.4 nmol O(2). mg protein(-1). min(-1) in SPM- and furosemide-treated tubules, respectively. In the presence of 145 mM extracellular Na(+), nystatin increased QO(2) by 104 +/- 7 and 94 +/- 20% in NO- and furosemide-treated tubules, respectively. We concluded that NO decreases THAL J(Cl(-)) by inhibiting Na(+)-K(+)-2Cl(-) cotransport rather than inhibiting apical K(+) channels or the sodium pump.

Nitric oxide inhibits sodium/hydrogen exchange activity in the thick ascending limb

Nitric oxide (NO) inhibits transport in various nephron segments, and the thick ascending limb (TAL) expresses nitric oxide synthase (NOS). However, the effects of NO on TAL transport have not been extensively studied. We tested the hypothesis that NO inhibits apical and basolateral Na(+)/H(+) exchange by the TAL by measuring intracellular pH (pH(i)) of isolated, perfused rat TALs using the fluorescent dye 2',7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF). The NO donor spermine NONOate (SPM, 10 microM) decreased steady-state pHi in medullary TALs from 7.18 +/- 0.13 to 7.13 +/- 0.14 (P < 0.02), whereas controls did not decrease significantly. We next measured the buffering capacity of medullary TALs and the rate at which they recovered from acid loads to investigate the mechanism whereby NO reduces steady-state pHi. SPM decreased H+ flux (JH) from 2.41 +/- 0.66 to 0.97 +/- 0.19 pmol. min(-1). mm(-1), 55%. To assure that the decrease in JH was due to NO, another donor, nitroglycerin (NTG; 10 microM), was used. NTG decreased J(H) from 1.65 +/- 0.11 to 1.07 +/- 0.24 pmol. min(-1). mm(-1), 37%. To determine the relative contributions of the apical and basolateral Na+/H+ exchangers, 5-(N,N-dimethyl)amiloride (DMA; 100 microM) was added to either bath or lumen. With DMA added to the bath, SPM decreased J(H) from 4.78 +/- 1.08 to 2.74 +/- 0.54 pmol. min(-1). mm(-1), an inhibition of 41%; and with DMA added to the lumen, SPM decreased J(H) from 2.31 +/- 0.29 to 1.74 +/- 0.27 pmol. min(-1). mm(-1), a reduction of 26%. Addition of DMA alone to both bath and lumen resulted in an 87% inhibition of JH. We conclude that NO inhibits both apical and basolateral Na+/H+ exchangers and consequently may play an important role in regulating pHi and may alter acid/base balance by directly affecting bicarbonate absorption in the TAL.

Short and long term effects of cytoskeleton-disrupting drugs on cytochrome P450 Cyp1a-1 induction in murine hepatoma 1c1c7 cells: suppression by the microtubule inhibitor nocodazole

Cultured murine hepatoma 1c1c7 cells were treated with either the actin filament-disrupting drug cytochalasin D or the microtubule inhibitors colchicine and nocadazole (NOC) to assess the role of the cytoskeleton in the process of cytochrome P450 Cyp1a-1 induction. Indirect fluorescence analyses demonstrated that microtubule or actin networks were disrupted within 1 hr of treatment and remained altered as long as cultures were maintained in the presence of the drugs. Treatment of cultures with cytochalasin D, colchicine, or NOC for 1 hr before the addition of dibenz[a,c]anthracene had no effect of Cyp1a-1 induction, as monitored by measurements of CYP1A1 mRNA. Pretreatment with NOC for > or = 18 hr produced populations of cells that had either a flat or rounded morphology. Both populations, when isolated 20-24 hr after NOC treatment, were arrested in the G2/M phase of the cell cycle (83-98% in G2/M versus approximately 7-10% in nontreated or solvent-treated cultures). Cyp1a-1 induction was suppressed in both of these populations, as monitored by measurement of CYP1A1 mRNA content (reductions of > 68%), 7-ethoxyresorufin O-deethylase activity (reductions of > 80%), or microsomal CYP1A1 protein content (reductions of > 80%). In contrast, overall [3H]leucine incorporation into protein was not affected. Cytosol prepared from these NOC-treated cultures bound approximately 39% of the radiolabeled 2,3,7,8-tetrachlorodibenzo-p-dioxin bound by cytosol isolated from solvent-treated cultures. Nuclear extracts prepared from cultures treated with NOC for 20-24 hr before in vivo exposure to inducer and cytoplasmic extracts isolated from similarly NOC-treated cultures that were exposed to inducer in vitro demonstrated reductions of > or = 54% and > or = 55%, respectively, in their abilities to bind to DNA, when analyzed by gel retardation analyses using an oligonucleotide corresponding to dioxin-responsive element D of the Cyp1a-1 gene. These studies suggest that ligand-dependent induction of Cyp1a-1 transcription is unaffected by short term disruption of the microfilament or microtubule network. However, long term exposure to microtubule inhibitors causes cells to pause in the G2/M stage of the cell cycle and modulates processes involved in the induction of Cyp1a-1 in these cells.