Nonselective and A2a-Selective Inhibition of Adenosine Receptors Modulates Renal Perfusion and Excretion Depending on the Duration of Streptozotocin-Induced Diabetes in Rats.

Long-lasting hyperglycaemia may alter the role of adenosine-dependent receptors (P1R) in the control of kidney function. We investigated how P1R activity affects renal circulation and excretion in diabetic (DM) and normoglycaemic (NG) rats; the receptors' interactions with bioavailable NO and H2O2 were also explored. The effects of adenosine deaminase (ADA, nonselective P1R inhibitor) and P1A2a-R-selective antagonist (CSC) were examined in anaesthetised rats, both after short-lasting (2-weeks, DM-14) and established (8-weeks, DM-60) streptozotocin-induced hyperglycaemia, and in normoglycaemic age-matched animals (NG-14, NG-60, respectively). The arterial blood pressure, perfusion of the whole kidney and its regions (cortex, outer-, and inner medulla), and renal excretion were determined, along with the in situ renal tissue NO and H2O2 signals (selective electrodes). The ADA treatment helped to assess the P1R-dependent difference in intrarenal baseline vascular tone (vasodilation in DM and vasoconstriction in NG rats), with the difference being more pronounced between DM-60 and NG-60 animals. The CSC treatment showed that in DM-60 rats, A2aR-dependent vasodilator tone was modified differently in individual kidney zones. Renal excretion studies after the ADA and CSC treatments showed that the balance of the opposing effects of A2aRs and other P1Rs on tubular transport, seen in the initial phase, was lost in established hyperglycaemia. Regardless of the duration of the diabetes, we observed a tonic effect of A2aR activity on NO bioavailability. Dissimilarly, the involvement of P1R in tissue production of H2O2, observed in normoglycaemia, decreased. Our functional study provides new information on the changing interaction of adenosine in the kidney, as well as its receptors and NO and H2O2, in the course of streptozotocin diabetes.

Animal models of hypertension: The status of nitric oxide and oxidative stress and the role of the renal medulla.

Hypertension significantly contributes to overall morbidity and mortality worldwide, and animal models of hypertension provide important tools to verify the physiological and molecular mechanisms underlying the development of the disease. A review of the most important models available would provide an insight into the appropriate targets to be addressed in the treatment of different forms of human hypertension. In the animal models discussed a special attention is given to the status and pathophysiological role of nitric oxide and its interaction with reactive oxygen species and oxidative stress. Another focus of the review are the processes running in the renal medulla which are still insufficiently explored. Deficient nitric oxide synthesis and its reduced bioavailability are important determinants of hypertension since NO is recognized as a major control factor of vascular tone homeostasis. For decades perfusion of the renal medulla has also been regarded as one of the blood pressure control factors and, noteworthily, the renal medulla belongs to the tissues with the highest NO content. The list of most often applied animal hypertension models reviewed here includes variants of salt-induced hypertension, the models with genetic background: such as spontaneously hypertensive rats (SHR) and Dahl salt sensitive (SS/SR) rats, Goldblatt 2K-1C hypertensive rats, and also the pharmacologically-plus-dietary salt-induced model known as DOCA-salt hypertension.

Role of Ang1-7 in renal haemodynamics and excretion in streptozotocin diabetic rats.

The contribution of angiotensin (1-7) (Ang1-7) to control of extrarenal and renal function may be modified in diabetes. We investigated the effects of Ang1-7 supplementation on blood pressure, renal circulation and intrarenal reactivity (IVR) to vasoactive agents in normoglycaemic (NG) and streptozotocin diabetic rats (DM). In Sprague Dawley DM and NG rats, 3 weeks after streptozotocin (60 mg/kg i.p.) or solvent injection, Ang1-7 was administered (400 ng/min) over the next 2 weeks using subcutaneously implanted osmotic minipumps. For a period of 5 weeks, blood pressure (BP), 24 h water intake and diuresis were determined weekly. In anaesthetised rats, BP, renal total and cortical (CBF), outer (OMBF) and inner medullary (IMBF) perfusion and urine excretion were determined. To check IVR, a short-time infusion of acetylcholine or norepinephrine was randomly given to the renal artery. Unexpectedly, BP did not differ between NG and DM, and this was not modified by Ang-1-7 supplementation. Baseline IMBF was higher in NG vs. DM, and Ang1-7 treatment did not change it in NG but decreased it in DM. In the latter, Ang1-7 increased cortical IVR to vasoconstrictor and vasodilator stimuli. IMBF decrease after high acetylcholine dose seen in untreated NG was reverted to an increase in Ang1-7 treated rats. Irrespective of the glycaemia level, Ang1-7 did not modify BP. However, it impaired medullary circulation in DM, whereas in NG it rendered the medullary vasculature more sensitive to vasodilators. Possibly, the medullary hypoperfusion in DM was mediated by Ang1-7 activation of angiotensin AT-1 receptors which are upregulated by hyperglycaemia.

Interplay of the adenosine system and NO in control of renal haemodynamics and excretion: Comparison of normoglycaemic and streptozotocin diabetic rats.

The adenosine (Ado) system may participate in regulation of kidney function in diabetes mellitus (DM), therefore we explored its role and interrelation with NO in the control of renal circulation and excretion in normoglycemic (NG) and streptozotocin-diabetic (DM) rats. Effects of theophylline (Theo), a non-selective Ado receptor antagonist, were examined in anaesthetized NG or in streptozotocin induced diabetic (DM) rats, untreated or after blockade of NO synthesis with l-NAME. We measured arterial blood pressure (MABP), whole kidney blood flow and renal regional flows: cortical and outer- and inner-medullary (IMBF), determined as laser-Doppler fluxes. Renal excretion of water, total solutes and sodium and in situ renal tissue NO signal (selective electrodes) were also determined. Theo experiments disclosed minor baseline vasoconstrictor and vasodilator tone in the kidney of NG and DM rats, respectively. NO blockade increased baseline MABP and decreased renal haemodynamics, similarly in NG and DM rats, indicating comparable vasodilator influence of NO in the two groups. Unexpectedly, in all rats with intact NO synthesis, Ado receptor blockade increased kidney tissue NO. In NO-deficient NG and DM rats, Ado receptor blockade induced comparable renal vasodilatation, suggesting similar vasoconstrictor influence of the Ado system. However, DM rats showed an unexplained association of decreased MABP and IMBF and increased NO signal. Higher baseline renal excretion in DM rats indicated inhibition of renal tubular reabsorption due to the prevalence of natriuretic A2 over antinatriuretic A1 receptors. In conclusion, the experiments provided new insights in functional interrelation of adenosine and NO in normoglycaemia and streptozotocin-diabetes.

Modulating Role of Ang1-7 in Control of Blood Pressure and Renal Function in AngII-infused Hypertensive Rats.

BACKGROUND: Indirect evidence suggests that angiotensin 1-7 (Ang1-7) may counterbalance prohypertensive actions of angiotensin II (AngII), via activation of vascular and/or renal tubular receptors to cause vasodilation and natriuresis/diuresis. We examined if Ang1-7 would attenuate the development of hypertension, renal vasoconstriction, and decreased natriuresis in AngII-infused rats and evaluated the mechanisms involved. METHODS: AngII, alone or with Ang1-7, was infused to conscious Sprague-Dawley rats for 13 days and systolic blood pressure (SBP) and renal excretion were repeatedly determined. In anesthetized rats, acute actions of Ang1-7 and effects of blockade of angiotensin AT1 or Mas receptors (candesartan or A-779) were studied. RESULTS: Chronic AngII infusion increased SBP from 143 ± 4 to 195 ± 6 mm Hg. With Ang1-7 co-infused, SBP increased from 133 ± 5 to 161 ± 5 mm Hg (increase reduced, P < 0.002); concurrent increases in urine flow (V) and sodium excretion (UNaV) were greater. In anesthetized normotensive or AngII-induced hypertensive rats, Ang1-7 infusion transiently increased mean arterial pressure (MABP), transiently decreased renal blood flow (RBF), and caused increases in UNaV and V. In normotensive rats, candesartan prevented the Ang1-7-induced increases in MABP and UNaV and the decrease in RBF. In anesthetized normotensive, rats intravenous A-779 increased MABP (114 ± 5 to 120 ± 5 mm Hg, P < 0.03) and urine flow. Surprisingly, these changes were not observed with A-779 applied during background Ang1-7 infusion. CONCLUSIONS: The results suggest that in AngII-dependent hypertension, Ang1-7 deficit contributes to sodium and fluid retention and thereby to BP elevation; a correction by Ang1-7 infusion seems mediated by AT1 and not Mas receptors.

Collecting duct prorenin receptor knockout reduces renal function, increases sodium excretion, and mitigates renal responses in ANG II-induced hypertensive mice.

Augmented intratubular angiotensin (ANG) II is a key determinant of enhanced distal Na+ reabsorption via activation of epithelial Na+ channels (ENaC) and other transporters, which leads to the development of high blood pressure (BP). In ANG II-induced hypertension, there is increased expression of the prorenin receptor (PRR) in the collecting duct (CD), which has been implicated in the stimulation of the sodium transporters and resultant hypertension. The impact of PRR deletion along the nephron on BP regulation and Na+ handling remains controversial. In the present study, we investigate the role of PRR in the regulation of renal function and BP by using a mouse model with specific deletion of PRR in the CD (CDPRR-KO). At basal conditions, CDPRR-KO mice had decreased renal function and lower systolic BP associated with higher fractional Na+ excretion and lower ANG II levels in urine. After 14 days of ANG II infusion (400 ng·kg-1·min-1), the increases in systolic BP and diastolic BP were mitigated in CDPRR-KO mice. CDPRR-KO mice had lower abundance of cleaved αENaC and γENaC, as well as lower ANG II and renin content in urine compared with wild-type mice. In isolated CD from CDPRR-KO mice, patch-clamp studies demonstrated that ANG II-dependent stimulation of ENaC activity was reduced because of fewer active channels and lower open probability. These data indicate that CD PRR contributes to renal function and BP responses during chronic ANG II infusion by enhancing renin activity, increasing ANG II, and activating ENaC in the distal nephron segments.

Influence of P2X receptors on renal medullary circulation is not altered by angiotensin II pretreatment.

BACKGROUND: Purine P2X and P2Y receptors (P2-R) are involved in control of renal circulation, especially in the medulla, wherein they appear to interact with angiotensin II (Ang II). Our experimental approach enabled examination of interaction with Ang II per se, in the absence of blood pressure elevation. In this whole-kidney functional study we focused on the influence of P2X1-R on perfusion of the renal medulla. METHODS: Acute experiments were conducted with normal rats, untreated or subjected to two weeks' infusion of Ang II (osmotic minipumps). Urethane was used for anesthesia because in Ang II-treated rats it normalized elevated blood pressure. MRS2159, a P2X1-R inhibitor, was infused intravenously or directly into the medulla. Renal blood flow (RBF, Transonic renal artery probe), perfusion of the outer and inner medulla (OM-BF, IM-BF; laser-Doppler fluxes), and sodium and water excretion and urine osmolality (Uosm) were measured. RESULTS: In untreated rats intravenous MRS2159 unexpectedly decreased RBF by 12±4% (p<0.02) and IM-BF by 7±2% (p<0.05). In Ang II-pretreated rats the inhibitor tended to increase RBF while OM-BF and IM-BF increased 14±5% and 12±2%, respectively (p<0.05 for both). Renal excretion was not affected, with or without Ang II treatment, while Uosm increased by about 150mosmol/kg H2O (p<0.05). Intramedullary MRS2159 increased IM-BF only, by 21±5% in untreated and 16±3% in Ang II-treated rats (p<0.04 for both). CONCLUSIONS: Tonic activity of P2X1 receptors participates in control of renal medullary perfusion and of the tubular processes involved in urine concentration, neither effect is modified by Ang II pretreatment.

An endomorphine analog ([d-Ala(2)]-Endomorphin 2, TAPP) lowers blood pressure and enhances tissue nitric oxide in anesthetized rats.

BACKGROUND: Activation of opioid receptors can alter cardiovascular function, an action possibly mediated by nitric oxide (NO). In this study we examined the effects of ([d-Ala(2)]-Endomorphin 2, TAPP), a synthetic opioid µ-receptor agonist, on blood pressure (MABP), tissue NO bioavailability and renal hemodynamics and excretion. METHODS: In acute experiments with anesthetized normotensive male Sprague-Dawley rats TAPP was given as a short iv infusion at a dose of 1.2 or 12mg/kg and then MABP, renal medullary NO signal (polarographic electrode), total renal blood flow (RBF, renal artery Transonic probe), renal regional perfusion (laser-Doppler fluxes) and renal excretion were simultaneously measured over 2h. RESULTS: After 1.2mg/kg dose MABP decreased progressively from 121±7 to 114±9mmHg (-6%, p<0.05) while kidney tissue NO signal increased from 29.1±2.7 to 31.7±3.1nA (6%, p<0.04). Both effects were prevented by Naloxone methiodide, a peripheral opioid receptor inhibitor. RBF and renal regional perfusion were not altered by either dose of TAPP; renal sodium excretion changes were highly variable and were not affected by Naloxone pretreatment. CONCLUSIONS: Briefly, we found that in anesthetized normotensive rats stimulation of peripheral opioid receptors with TAPP caused a prolonged decrease in arterial pressure, a change that was associated and probably causally related to an increase in tissue NO. The data suggest that synthetic opioids that do not penetrate the blood-brain barrier and are potentially non-addictive could be considered for antihypertensive therapy.

Role of atrial natriuretic peptide in mediating the blood pressure-independent natriuresis elicited by systemic inhibition of nitric oxide.

While it is clearly recognized that increased intrarenal nitric oxide (NO) levels elicit natriuresis, confounding data showing that systemic nitric oxide synthase inhibition (NOSi) also increases sodium excretion (UNaV) poses a conundrum. This response has been attributed to the associated increases in arterial pressure (AP); however, the increases in AP and in UNaV are temporally dissociated. The changes in regional renal haemodynamics induced by NOSi could also contribute to the alterations of UNaV. To evaluate the roles of AP and non-AP mechanisms mediating the natriuresis, N ω-nitro-L-arginine methyl ester hydrochloride (L-NAME) was infused i.v. at doses ranging from 5 to 50 µg/kg/min in anaesthetized rats. UNaV, perfusion of the cortex (cortical blood flow, CBF) and medulla (medullary blood flow, MBF) with laser-Doppler flowmetry and glomerular filtration rate (GFR) were measured. UNaV increased from 0.6 ± 0.2 to 1.6 ± 0.1 µmol/kg/min (P < 0.05) with the lower nonpressor doses. With the higher doses, AP increased from 116 ± 4 to 122 ± 4 mmHg and UNaV increased from 1.1 ± 0.3 to 3.3 ± 0.7 µmol/min/g (P < 0.002). UNaV increased similarly in a group where renal AP was maintained at baseline levels. The associated reductions in CBF (17 ± 5 and 38 ± 5 %) and MBF (27 ± 6 and 52 ± 6 %) would be expected to attenuate rather than contribute to the natriuresis. Plasma atrial natriuretic peptide (ANP) concentrations increased significantly following NOSi. Anantin, a natriuretic peptide receptor-A blocker, prevented or reversed the L-NAME-induced natriuresis without altering the L-NAME-induced changes in AP or CBF. The results indicate that increased ANP and related natriuretic peptides mediate the AP-independent natriuresis, at least partly, elicited by systemic L-NAME infusion and help resolve the conundrum of natriuresis during systemic NOSi.

Adenosine effects on renal function in the rat: role of sodium intake and cytochrome P450.

BACKGROUND/AIMS: Adenosine (ADO) causes vasodilation in most tissues. In the kidney it can induce vasoconstriction or vasodilation, depending on the prevailing stimulation of A1 or A2 receptors (A1R, A2R). ADO-induced alterations of renal excretion may be secondary to haemodynamic changes, or reflect a direct influence on tubular transport. This whole-kidney study explored renal excretory responses to ADO receptor stimulation as related to renal haemodynamics sodium intake and cytochrome P450 (CYP-450) activity. METHODS: The effects of ADO or an A2aR agonist (DPMA) on urine flow (V), sodium excretion (UNaV) and total solute excretion were examined in anaesthetized Wistar rats on a low-sodium or high-sodium (HS) diet. Total renal blood flow (RBF; renal artery probe), and outer- and inner-medullary blood flows (OM-BF, IM-BF; laser-Doppler fluxes) were also determined. RESULTS: Consistent opposed effects of ADO and DPMA were only observed with the HS diet. ADO increased V (150%) and UNaV (100%); there were also significant increases in RBF, OM-BF and IM-BF. These changes were prevented by 1-aminobenzotriazol, a CYP-450 inhibitor. In HS rats, DPMA significantly decreased arterial blood pressure and renal excretion. CONCLUSIONS: Post-ADO diuresis/natriuresis was in part secondary to renal hyperperfusion; the response was probably mediated by CYP-450-dependent active agents. Selective A2aR stimulation induced systemic vasodilation, major hypotension, and a secondary decrease in renal excretion.

Renal nerves and nNOS: roles in natriuresis of acute isovolumetric sodium loading in conscious rats.

It was hypothesized that renal sympathetic nerve activity (RSNA) and neuronal nitric oxide synthase (nNOS) are involved in the acute inhibition of renin secretion and the natriuresis following slow NaCl loading (NaLoad) and that RSNA participates in the regulation of arterial blood pressure (MABP). This was tested by NaLoad after chronic renal denervation with and without inhibition of nNOS by S-methyl-thiocitrulline (SMTC). In addition, the acute effects of renal denervation on MABP and sodium balance were assessed. Rats were investigated in the conscious, catheterized state, in metabolic cages, and acutely during anesthesia. NaLoad was performed over 2 h by intravenous infusion of hypertonic solution (50 micromol.min(-1).kg body mass(-1)) at constant body volume conditions. SMTC was coinfused in amounts (20 microg.min(-1).kg(-1)) reported to selectively inhibit nNOS. Directly measured MABPs of acutely and chronically denervated rats were less than control (15% and 9%, respectively, P < 0.005). Plasma renin concentration (PRC) was reduced by renal denervation (14.5 +/- 0.2 vs. 19.3 +/- 1.3 mIU/l, P < 0.005) and by nNOS inhibition (12.4 +/- 2.3 vs. 19.6 +/- 1.6 mlU/l, P < 0.005). NaLoad reduced PRC (P < 0.05) and elevated MABP modestly (P < 0.05) and increased sodium excretion six-fold, irrespective of renal denervation and SMTC. The metabolic data demonstrated that renal denervation lowered sodium balance during the first days after denervation (P < 0.001). These data show that renal denervation decreases MABP and renin secretion. However, neither renal denervation nor nNOS inhibition affects either the renin down-regulation or the natriuretic response to acute sodium loading. Acute sodium-driven renin regulation seems independent of RSNA and nNOS under the present conditions.