Lori A. Smith

CGRP Activates Renal Pelvic Substance P Receptors by Retarding Substance P Metabolism

Substance P and calcitonin gene-related peptide (CGRP) are colocalized in renal pelvic sensory nerves. Increasing renal pelvic pressure results in an increase in afferent renal nerve activity that is blocked by a substance P receptor antagonist but not by a CGRP receptor antagonist. CGRP potentiates the effects of substance P by preventing the metabolism of substance P. Therefore, we examined whether CGRP enhanced the afferent renal nerve activity responses to substance P and increased renal pelvic pressure, a stimulus known to increase substance P release. Combined administration of substance P and CGRP into the renal pelvis resulted in an increase in afferent renal nerve activity (1392+/-217%. s; area under the curve of afferent renal nerve activity versus time) that was greater (P<0.01) than that produced by substance P (620+/-156%. s) or CGRP (297+/-96%. s) alone. Likewise, CGRP enhanced the afferent renal nerve activity response to increased renal pelvic pressure. During renal pelvic administration of the neutral endopeptidase inhibitor thiorphan, the afferent renal nerve activity response to substance P plus CGRP was similar to that produced by either neuropeptide alone. Because these studies suggested that CGRP potentiated the afferent renal nerve activity responses to substance P, we examined whether the afferent renal nerve activity response to CGRP was blocked by a substance P receptor antagonist, RP67580. RP67580 blocked the afferent renal nerve activity response to CGRP by 85+/-12% (P<0.02). We conclude that CGRP activates renal pelvic sensory nerves by retarding the metabolism of substance P, thereby increasing the amount of substance P available for stimulation of substance P receptors.

Amiloride-sensitive Na+channels in pelvic uroepithelium involved in renal sensory receptor activation

Stretching the renal pelvic wall increases ipsilateral afferent renal nerve activity (ARNA). This response is enhanced by inhibiting Na+-K+-ATPase with ouabain, suggesting a modulatory role for intracellular Na+ in the activation of mechanosensitive neurons. The messenger RNA for alpha-, beta-, and gamma-subunits of epithelial Na+ channels (ENaC) is found in collecting duct cells. Because ENaC subunits show homology with genes involved in mechanosensation, we examined whether ENaC mRNA could be found in the pelvic wall and whether the ARNA response to increased renal pelvic pressure was modulated by blockers of the Na+ channel. alpha-, beta-, and gamma-subunits are present in the pelvis. The messenger RNA for the beta- and gamma-subunits is readily detected by in situ hybridization throughout the uroepithelium. The ARNA response to increased renal pelvic pressure was reduced by 53 +/- 10% and 40 +/- 10% (P < 0.01) by renal pelvic perfusion with the inhibitors amiloride and benzamil, respectively. Amiloride inhibited the ouabain-induced enhancement of the ARNA response to increased renal pelvic pressure. The magnitude of this inhibition was inversely correlated with the magnitude of the amiloride-mediated blockade of the ARNA response to increased renal pelvic pressure (P < 0.001). Amiloride also reduced the ARNA response to renal pelvic administration of substance P, a mediator of the ARNA response to increased renal pelvic pressure. We conclude that the ENaC complex in the pelvic uroepithelium participates in the activation of renal pelvic mechanosensitive neurons.Stretching the renal pelvic wall increases ipsilateral afferent renal nerve activity (ARNA). This response is enhanced by inhibiting Na+-K+-ATPase with ouabain, suggesting a modulatory role for intracellular Na+ in the activation of mechanosensitive neurons. The messenger RNA for α-, β-, and γ-subunits of epithelial Na+channels (ENaC) is found in collecting duct cells. Because ENaC subunits show homology with genes involved in mechanosensation, we examined whether ENaC mRNA could be found in the pelvic wall and whether the ARNA response to increased renal pelvic pressure was modulated by blockers of the Na+channel. α-, β-, and γ-subunits are present in the pelvis. The messenger RNA for the β- and γ-subunits is readily detected by in situ hybridization throughout the uroepithelium. The ARNA response to increased renal pelvic pressure was reduced by 53 ± 10% and 40 ± 10% ( P < 0.01) by renal pelvic perfusion with the inhibitors amiloride and benzamil, respectively. Amiloride inhibited the ouabain-induced enhancement of the ARNA response to increased renal pelvic pressure. The magnitude of this inhibition was inversely correlated with the magnitude of the amiloride-mediated blockade of the ARNA response to increased renal pelvic pressure ( P < 0.001). Amiloride also reduced the ARNA response to renal pelvic administration of substance P, a mediator of the ARNA response to increased renal pelvic pressure. We conclude that the ENaC complex in the pelvic uroepithelium participates in the activation of renal pelvic mechanosensitive neurons.

Cyclooxygenase-2 Involved in Stimulation of Renal Mechanosensitive Neurons

Stretching of the renal pelvic wall activates renal mechanosensitive neurons, resulting in an increase in afferent renal nerve activity (ARNA). Prostaglandin (PG)E(2) plays a crucial role in the activation of renal mechanosensitive neurons through facilitation of the release of substance P from the sensory neurons in the renal pelvic wall. Because wall stretch may induce cyclooxygenase-2 activity, we examined whether cyclooxygenase-2 was expressed in the renal pelvic wall and whether activation of cyclooxygenase-2 contributed to the ARNA response produced through increased renal pelvic pressure. In situ hybridization showed a strong cyclooxygenase-2 mRNA signal in the papilla and subepithelial layer of the renal pelvic wall from time control kidneys and from kidneys exposed to 15 minutes of increased renal pelvic pressure in anesthetized surgically operated rats. In anesthetized rats, an increase in renal pelvic pressure increased ARNA by 40+/-2% and increased renal pelvic release of PGE(2) from 289+/-46 to 1379+/-182 pg/min (P<0.01). Renal pelvic perfusion with the cyclooxygenase-2 inhibitor etodolac reduced the increases in ARNA and PGE(2) by 66+/-7% and 55+/-13%, respectively (P<0.01). Likewise, the cyclooxygenase-2 inhibitor 5, 5-dimethyl-3-(3-fluorophenyl)-4-(4-methylsulfonyl)phenyl-2(5H)-furanone reduced the increases in ARNA and PGE(2) by 43+/-5% and 47+/-8%, respectively. We conclude that cyclooxygenase-2 is expressed in the renal pelvic wall and that the activation of cyclooxygenase-2 contributes to the stimulation of renal mechanosensitive neurons in the pelvic wall.

Renal Substance P–Containing Neurons and Substance P Receptors Impaired in Hypertension

In normotensive rats, increased renal pelvic pressure stimulates the release of prostaglandin E and substance P, which in turn leads to an increase in afferent renal nerve activity (ARNA) and a contralateral natriuresis, a contralateral inhibitory renorenal reflex. In spontaneously hypertensive rats (SHR), increasing renal pelvic pressure failed to increase afferent renal nerve activity. The inhibitory nature of renorenal reflexes indicates that impaired renorenal reflexes could contribute to increased sodium retention in SHR. Phorbol esters, known to activate protein kinase C, increase afferent renal nerve activity in Wistar-Kyoto rats (WKY) but not in SHR. We examined the mechanisms involved in the impaired responses to renal sensory receptor activation in SHR. The phorbol ester 4beta-phorbol 12,13-dibutyrate increased renal pelvic protein kinase C activity similarly in SHR and WKY. Increasing renal pelvic pressure increased afferent renal nerve activity in WKY (27+/-2%) but not in SHR. Renal pelvic release of prostaglandin E increased similarly in WKY and SHR, from 0.8+/-0.1 to 2.0+/-0.4 ng/min and 0.7+/-0.1 to 1.4+/-0.2 ng/min. Renal pelvic release of substance P was greater (P<.01) in WKY, from 16.3+/-3.8 to 41.8+/-7.4 pg/min, than in SHR, from 9.9+/-1.7 to 17.0+/-3.2 pg/min. In WKY, renal pelvic administration of substance P at 0.8, 4, and 20 microg/mL increased ARNA 382+/-69, 750+/-233, and 783+/-124% second (area under the curve of afferent renal nerve activity versus time). In SHR, substance P at 0.8 to 20 microg/mL failed to increase ARNA. These findings demonstrate that the impaired afferent renal nerve activity response to increased renal pelvic pressure is related to decreased release of substance P and/or impaired activation of substance P receptors.

Dietary sodium modulates the interaction between efferent renal sympathetic nerve activity and afferent renal nerve activity: role of endothelin

Increasing efferent renal sympathetic nerve activity (ERSNA) increases afferent renal nerve activity (ARNA), which in turn decreases ERSNA via activation of the renorenal reflexes in the overall goal of maintaining low ERSNA. We now examined whether the ERSNA-induced increases in ARNA are modulated by dietary sodium and the role of endothelin (ET). The ARNA response to reflex increases in ERSNA was enhanced in high (HNa)- vs. low-sodium (LNa) diet rats, 7,560 +/- 1,470 vs. 900 +/- 390%.s. The norepinephrine (NE) concentration required to increase PGE(2) and substance P release from isolated renal pelvises was 10 pM in HNa and 6,250 pM in LNa diet rats. In HNa diet pelvises 10 pM NE increased PGE(2) release from 67 +/- 6 to 150 +/- 13 pg/min and substance P release from 6.7 +/- 0.8 to 12.3 +/- 1.8 pg/min. In LNa diet pelvises 6,250 pM NE increased PGE(2) release from 64 +/- 5 to 129 +/- 22 pg/min and substance P release from 4.5 +/- 0.4 to 6.6 +/- 0.7 pg/min. In the renal pelvic wall, ETB-R are present on unmyelinated Schwann cells close to the afferent nerves and ETA-R on smooth muscle cells. ETA-receptor (R) protein expression in the renal pelvic wall is increased in LNa diet. In HNa diet, renal pelvic administration of the ETB-R antagonist BQ788 reduced ERSNA-induced increases in ARNA and NE-induced release of PGE(2) and substance P. In LNa diet, the ETA-R antagonist BQ123 enhanced ERSNA-induced increases in ARNA and NE-induced release of substance P without altering PGE(2) release. In conclusion, activation of ETB-R and ETA-R contributes to the enhanced and suppressed interaction between ERSNA and ARNA in conditions of HNa and LNa diet, respectively, suggesting a role for ET in the renal control of ERSNA that is dependent on dietary sodium.

Dietary sodium modulates the interaction between efferent and afferent renal nerve activity by altering activation of α2-adrenoceptors on renal sensory nerves

Activation of efferent renal sympathetic nerve activity (ERSNA) increases afferent renal nerve activity (ARNA), which then reflexively decreases ERSNA via activation of the renorenal reflexes to maintain low ERSNA. The ERSNA-ARNA interaction is mediated by norepinephrine (NE) that increases and decreases ARNA by activation of renal α(1)-and α(2)-adrenoceptors (AR), respectively. The ERSNA-induced increases in ARNA are suppressed during a low-sodium (2,470 ± 770% s) and enhanced during a high-sodium diet (5,670 ± 1,260% s). We examined the role of α(2)-AR in modulating the responsiveness of renal sensory nerves during low- and high-sodium diets. Immunohistochemical analysis suggested the presence of α(2A)-AR and α(2C)-AR subtypes on renal sensory nerves. During the low-sodium diet, renal pelvic administration of the α(2)-AR antagonist rauwolscine or the AT1 receptor antagonist losartan alone failed to alter the ARNA responses to reflex increases in ERSNA. Likewise, renal pelvic release of substance P produced by 250 pM NE (from 8.0 ± 1.3 to 8.5 ± 1.6 pg/min) was not affected by rauwolscine or losartan alone. However, rauwolscine+losartan enhanced the ARNA responses to reflex increases in ERSNA (4,680 ± 1,240%·s), and renal pelvic release of substance P by 250 pM NE, from 8.3 ± 0.6 to 14.2 ± 0.8 pg/min. During a high-sodium diet, rauwolscine had no effect on the ARNA response to reflex increases in ERSNA or renal pelvic release of substance P produced by NE. Losartan was not examined because of low endogenous ANG II levels in renal pelvic tissue during a high-sodium diet. Increased activation of α(2)-AR contributes to the reduced interaction between ERSNA and ARNA during low-sodium intake, whereas no/minimal activation of α(2)-AR contributes to the enhanced ERSNA-ARNA interaction under conditions of high sodium intake.

Bradykinin and Protein Kinase C Activation Fail to Stimulate Renal Sensory Neurons in Hypertensive Rats

In normotensive rats, renal sensory receptor activation by increased ureteral pressure results in increased ipsilateral afferent renal nerve activity, decreased contralateral efferent renal nerve activity, and contralateral diuresis and natriuresis, a contralateral inhibitory renorenal reflex response. In spontaneously hypertensive rats (SHR), increasing ureteral pressure fails to increase afferent renal nerve activity. The nature of the inhibitory renorenal reflexes indicates that an impairment of the renorenal reflexes would contribute to the increased efferent renal nerve activity in SHR. We therefore examined whether there was a general decrease in the responsiveness of renal sensory receptors in SHR by comparing the afferent renal nerve activity responses to bradykinin in SHR and Wistar-Kyoto rats (WKY). In WKY, renal pelvic perfusion with bradykinin at 4, 19, 95, and 475 micromol/L increased afferent renal nerve activity by 1066 +/- 704, 2127 +/- 1121, 3517 +/- 1225, and 4476 +/- 1631% x second (area under the curve of afferent renal nerve activity versus time). In SHR, bradykinin at 4 to 95 micromol/L failed to increase afferent renal nerve activity. Bradykinin at 475 micromol/L increased afferent renal nerve activity in only 6 of 10 SHR. In WKY, renal pelvic perfusion with the phorbol ester 4beta-phorbol 12,13-dibutyrate, known to activate protein kinase C, resulted in a peak afferent renal nerve activity response of 24 +/- 4%. However, 4beta-phorbol 12,13-dibutyrate failed to increase afferent renal nerve activity in SHR. These findings demonstrate decreased responsiveness of renal pelvic sensory receptors to bradykinin in SHR. The impaired afferent renal nerve activity responses to bradykinin in SHR may be due to a lack of protein kinase C activation or a defect in the intracellular signaling mechanisms distal to protein kinase C activation.

Renorenal reflexes present in young and captopril-treated adult spontaneously hypertensive rats

In normotensive Sprague-Dawley rats and Wistar-Kyoto (WKY) rats stimulation of renal mechanoreceptors or chemoreceptors by increasing ureteral pressure or renal pelvic perfusion with 0.9 M NaCl results in a contralateral inhibitory renorenal reflex response with contralateral diuresis and natriuresis. However, in 14–15-week-old spontaneously hypertensive rats (SHR) renal sensory receptor stimulation failed to elicit a contralateral inhibitory renorenal reflex response. The present study was performed to examine whether the lack of a renorenal reflex response in SHR was related to elevated arterial pressure by studying the responses to renal sensory receptor stimulation in 5–6-week-old SHR and in 12–16-week-old SHR that had been treated with captopril from 3 weeks of age to prevent the development of hypertension. In 5–6-week-old SHR, mean arterial pressure was 113±3 mm Hg. Graded increases of ureteral pressure of 15 and 29 mm Hg resulted in graded increases in ipsilateral afferent renal nerve activity of 57±22% and 120±38%. Contralateral urinary sodium excretion increased from 0.26±0.06 to 0.35±0.07 μmol/min/g and from 0.36±0.08 to 0.46±0.11 μmol/min/g, respectively. In captopril-treated SHR, mean arterial pressure was 109±3 mm Hg. Increasing ureteral pressure by 34 mm Hg increased ipsilateral afferent renal nerve activity 65±21% and contralateral urinary sodium excretion from 1.28±0.24 to 1.53±0.30 μmol/min/g. Similar results were produced by renal chemoreceptor stimulation. It is concluded that renal sensory receptor stimulation results in a contralateral inhibitory renorenal reflex response in 5–6-week-old SHR and in SHR treated with captopril to prevent the development of hypertension. These results suggest that the previously demonstrated lack of a renorenal reflex response to renal sensory receptor stimulation hi hypertensive SHR is related to the maintenance of hypertension.

Endogenous Angiotensin II Modulates the Responsiveness of Renal Pelvic Mechanosensitive Neurons.

15 Increased (↑) renal pelvic pressure by increased urine flow rate or acute ureteral obstruction activates mechanosensitive neurons in the renal pelvic wall. Activation of these neurons increases ipsilateral afferent renal nerve activity (ARNA) and contralateral urinary sodium excretion (UNaV), i.e. a renorenal reflex. Activation of cyclooxygenase 2 (COX-2) contributes to the ARNA response to ↑ renal pelvic pressure. Since renal medullary COX-2 is upregulated by high Na+ diet, we studied if the responsiveness of renal mechanosensitive neurons is altered by changes in dietary Na+. High Na+ rats were placed on normal Na+ diet and 0.9% NaCl to drink and low Na+ rats on Na+ deficient diet and tap water. ↑ renal pelvic pressure 2.5, 7.5 and 15 mmHg for 3 min increased ipsi ARNA 10±1%†, 21±2%† and 37±5%† in 6 high Na+ rats and 1±0%, 10±0%† and 19±3%† in 5 low Na+ diet rats (†p<0.05). The contra UNaV responses paralleled the ARNA responses, being 0.4±0.1, 1.1±0.3 and 1.4±0.5 μE/min/g in high Na+ rats and 0±0, 0.1±0.1 and 0.2±0.1 μE/min/g in low Na+ rats. Thus, the renorenal reflexes are suppressed by low Na+ diet. Angiotensin (ANG) is increased by low Na+ diet to facilitate Na+ retention. Thus, we speculated that ANG would suppress the activation of the natriuretic renorenal reflexes in low Na+ diet rats. Renal pelvic pressure was increased before and during renal pelvic perfusion with the AT1 receptor antagonist losartan, 200 μg/ml, in low Na+ rats and before and during pelvic perfusion with ANGII, 15 nM, in high Na+ rats. In 8 low Na+ rats, losartan enhanced the ARNA responses to ↑ renal pelvic pressure 2.5 and 7.5 mmHg, ARNA responses being 2±1% and 14±1%‡ before and 13±2%‡ and 22±3%‡ during losartan. Conversely in 8 high Na+ rats, ANGII suppressed the ARNA responses to ↑ renal pelvic pressure, ARNA responses being 10±1%‡ and 23±3%‡ before and 1±1% and 11±2%‡ during ANGII (‡p<0.01). Conclusion: Changes in dietary Na+ modulate the responsiveness of the afferent renal nerves via the renin angiotensin system. Activation of the renorenal reflexes may contribute to increased UNaV during excess Na+ intake. Of note, renorenal reflexes are impaired in SHR which are characterized by Na+ retention.