Vitamin D Regulates the Expressions of AQP-1 and AQP-4 in Mice Kidneys.

AIM: Vitamin D plays an important role in water and salt homeostasis. The aim of our study was to investigate the underlying relationship of Vitamin D and Aquaporins (AQP). METHODS: The behaviors of 1α (OH)-ase knockout mice and wild type mice were observed before analysis. The ICR mice were treated with vehicle or paricalcitol, a vitamin D analogue, followed by animals receiving a standard diet and free access to drinking water either with aliskiren (renin blocker; 37.5 mg aliskiren in 100 ml water), or telmisartan (a angiotensin II type I receptor blocker; 40 mg telmisartan in 100 ml water) a week before study. The expressions of AQP-1, AQP-4, and renin in mice kidneys were detected by western bolting, immunohistochemistry, and immunofluorescence. RESULTS: Diuresis and polydipsia were observed in 1α (OH)-ase knockout mice, and a decreased water intake and urine output in ICR mice was observed after paricalcitol treatment. Compared with wild type, the AQP-1 expressions were increased in renal papilla and AQP-4 expressions were decreased in renal proximal tubule of 1α(OH) ase knockout mice. In addition, AQP-1 was decreased in renal papilla and AQP-4 expressions were increased in proximal tubule by suppressing renin activity or supplement of Vitamin D analogue. After injecting renin into the lateral ventricle of the 1α(OH)ase knockout mice, the renin expression level was decreased in the kidney, followed by the decrease of AQP-1 in renal papilla and increase of AQP-4 in proximal tubule. CONCLUSIONS: Overall, Vitamin D and renin inhibitors have synergistic effects in regulating water channels in mice kidneys.

Overexpression of the neuronal human (pro)renin receptor mediates angiotensin II-independent blood pressure regulation in the central nervous system.

Despite advances in antihypertensive therapeutics, at least 15-20% of hypertensive patients have resistant hypertension through mechanisms that remain poorly understood. In this study, we provide a new mechanism for the regulation of blood pressure (BP) in the central nervous system (CNS) by the (pro)renin receptor (PRR), a recently identified component of the renin-angiotensin system that mediates ANG II formation in the CNS. Although PRR also mediates ANG II-independent signaling, the importance of these pathways in BP regulation is unknown. Here, we developed a unique transgenic mouse model overexpressing human PRR (hPRR) specifically in neurons (Syn-hPRR). Intracerebroventricular infusion of human prorenin caused increased BP in Syn-hPRR mice. This BP response was attenuated by a NADPH oxidase (NOX) inhibitor but not by antihypertensive agents that target the renin-angiotensin system. Using a brain-targeted genetic knockdown approach, we found that NOX4 was the key isoform responsible for the prorenin-induced elevation of BP in Syn-hPRR mice. Moreover, inhibition of ERK significantly attenuated the increase in NOX activity and BP induced by human prorenin. Collectively, our findings indicate that an ANG II-independent, PRR-mediated signaling pathway regulates BP in the CNS by a PRR-ERK-NOX4 mechanism. NEW & NOTEWORTHY This study characterizes a new transgenic mouse model with overexpression of the human (pro)renin receptor in neurons and demonstrated a novel angiotensin II-independent mechanism mediated by human prorenin and the (pro)renin receptor in the central regulation of blood pressure.

Aliskiren suppresses atrial electrical and structural remodeling in a canine model of atrial fibrillation.

Aliskiren, a direct renin inhibitor is expected to achieve sufficient suppression of renin-angiotensin system. We evaluated the effect of aliskiren on the electrical and structural remodeling in a canine atrial fibrillation (AF) model. Twenty-eight dogs were divided into three groups: (1) pacing control group (n = 12), with continuous atrial rapid pacing for 3 or 6 weeks, (2) pacing + aliskiren group (n = 12), with oral aliskiren (30 mg/kg/day), and (3) sham group (n = 4), no pacing nor drug administration. Electrophysiological properties and AF inducibility were evaluated every week. After the protocol, the left atrial tissue was sampled for the further histological and mRNA analysis. The electrical remodeling, AF inducibility, the left atrial enlargement and interstitial fibrosis were observed in pacing control group and were more prominent in the 6-week protocol (vs. 3 week, p < 0.05). The mRNA expressions of matricellular proteins exhibited upregulation in 3-week pacing control, but these upregulations became insignificant in 6 weeks. In contrast, collagen type 3 exhibited significant upregulation in 6 week but not in 3-week protocol. These changes were suppressed in the pacing + aliskiren group. Aliskiren suppressed the atrial remodeling in a canine AF model. This effect was accompanied by the suppression of tissue fibrosis.

Intracerebroventricular infusion of the (Pro)renin receptor antagonist PRO20 attenuates deoxycorticosterone acetate-salt-induced hypertension.

We previously reported that binding of prorenin to the (pro)renin receptor (PRR) plays a major role in brain angiotensin II formation and the development of deoxycorticosterone acetate (DOCA)-salt hypertension. Here, we designed and developed an antagonistic peptide, PRO20, to block prorenin binding to the PRR. Fluorescently labeled PRO20 bound to both mouse and human brain tissues with dissociation constants of 4.4 and 1.8 nmol/L, respectively. This binding was blocked by coincubation with prorenin and was diminished in brains of neuron-specific PRR-knockout mice, indicating specificity of PRO20 for PRR. In cultured human neuroblastoma cells, PRO20 blocked prorenin-induced calcium influx in a concentration- and AT(1) receptor-dependent manner. Intracerebroventricular infusion of PRO20 dose-dependently inhibited prorenin-induced hypertension in C57Bl6/J mice. Furthermore, acute intracerebroventricular infusion of PRO20 reduced blood pressure in both DOCA-salt and genetically hypertensive mice. Chronic intracerebroventricular infusion of PRO20 attenuated the development of hypertension and the increase in brain hypothalamic angiotensin II levels induced by DOCA-salt. In addition, chronic intracerebroventricular infusion of PRO20 improved autonomic function and spontaneous baroreflex sensitivity in mice treated with DOCA-salt. In summary, PRO20 binds to both mouse and human PRRs and decreases angiotensin II formation and hypertension induced by either prorenin or DOCA-salt. Our findings highlight the value of the novel PRR antagonist, PRO20, as a lead compound for a novel class of antihypertensive agents and as a research tool to establish the validity of brain PRR antagonism as a strategy for treating hypertension.

[Atypical vascular supply from the coeliac trunk. Recurrent bleeding from a duodenal ulcer]. / Atypische Gefässversorgung aus dem Truncus coeliacus. Rezidivblutung aus einem Ulcus duodeni.

Hemorrhagic duodenal ulcers should primarily be controlled by endoscopy. In cases of recurrent bleeding or if bleeding cannot be controlled endoscopically, open surgery is the gold standard. Rarely, atypical origin of arteries or additional atypical arteries may lead to further unexpected hemorrhagic recurrences and angiography with surgical intervention is the treatment of choice. In this article a rare case of an atypical visceral artery connecting the coeliac trunk and the gastroduodenal artery leading to recurrent bleeding from a duodenal ulcer is presented.

Intracellular and extracellular renin have opposite effects on the regulation of heart cell volume. Implications for myocardial ischaemia.

UNLABELLED: The influence of intracellular renin plus angiotensinogen (Ao) as well as angiotensin (Ang) II on cell volume was investigated in myocytes isolated from the heart of four-month-old cardiomyopathic hamsters (TO-2) and normal hamsters (F1B). Measurements of cell width and cell length were performed on quiescent cells using a Px-it imaging and computer system. The cell volume was calculated assuming the cells as elliptical cylinders and taking the cell depth equal to one third of cell width. For measurements of sodium pump current, the cells were voltage clamped (holding potential -40 mV) using the whole cell configuration. Cells were exposed to K-free solution to inhibit the pump and then to normal Krebs solution to reactivate the pump. In other experiments the cells were voltage clamped (holding potential -40 mV) and changes in the background current elicited by renin plus Ao or by Ang II were monitored. The results indicated that: a) intracellular dialysis of renin (128 pmol Ang I/ml) plus Ao (110 pmol Ang I generated by renin by exhaustion) decreased the cell volume concurrently with the activation of the sodium pump; b) intracellular losartan (10(-)8 M) or extracellular ouabain (10(-8) M) abolished the effect of renin plus Ao on cell volume; c) intracellular Ang II (10(-8) M), by itself, reduced cell volume and increased the pump current density; d) extracellular administration of renin plus Ao, at the same concentration used intracellularly, increased cell volume and inhibited the sodium pump. This increase of cell volume elicited by extracellular renin plus Ao was related to the activation of the Na-K-2Cl cotransporter; e) intracellular Ang II (10(-8) M) reversed cell swelling induced by hypotonic solutions. CONCLUSIONS: Intracellular and extracellular renin plus Ao have opposite effects on sodium pump and cell volume regulation in the failing heart. Both effects of renin plus Ao are dependent upon the formation of Ang II. Since intracellular Ang II counteracted the cell swelling induced by hypotonic solution, it is reasonable to think that the activation of the intracrine renin-angiotensin system might play a protective role during myocardial ischaemia by reducing cell volume.

Bloqueo combinado del SRAA en la enfermedad CV. ¿Qué sabíamos hasta ahora? / Combined blockade of the Renin-Angiotensin-Aldosterone System in cardiovascular disease. The evidence to date

Se revisan las ventajas terapéuticas de emplear la combinación de inhibidores de la enzima de conversión de la angiotensina y antagonistas de los receptores de la angiotensina II en patología cardiovascular. Los ensayos clínicos en insuficiencia cardiaca con la así denominada terapia dual han demostrado un beneficio de pequeña magnitud, aunque significativo, en rehospitalización y mortalidad cardiovascular. En la insuficiencia cardiaca o la disfunción ventricular tras infarto de miocardio, la combinación obtuvo la misma eficacia que el tratamiento con los fármacos por separado y, por el contrario, se asoció con un número de efectos adversos superior. La recomendación general de que se emplee antialdosterónicos en los casos de insuficiencia cardiaca avanzada limita el uso de la terapia dual en la práctica clínica, puesto que la terapia triple está contraindicada por el riesgo de inducir hiperpotasemia grave (AU)

This article reviews the therapeutic benefits of using a combination of angiotensin-converting enzyme inhibitors and angiotensin receptor antagonists in patients with cardiovascular disease. Clinical trials of what has been termed dual blockade in patients with heart failure have demonstrated small but significant reductions in cardiovascular rehospitalization and mortality. Given after myocardial infarction in patients with heart failure or left ventricular dysfunction, combination treatment was as effective as treatment with either type of agent alone, though there was an increase in the incidence of side effects. However, in clinical practice, the general recommendation that aldosterone antagonists should be administered in cases of advanced heart failure places a limit on the use of dual blockade since triple therapy is contraindicated because of the risk of inducing lifethreatening hyperkalemia (AU)

Neurohumoral mechanism in the natriuretic action of intracerebroventricular administration of renin.

INTRODUCTION: Intracerebroventricular (i.v.t.) administration of renin (R) decreases urinary volume and increases urinary sodium excretion. We investigated whether i.v.t.-R-induced natriuresis could be associated with the release of atrial natriuretic peptide (ANP), its interaction with renal ANP-A receptors (ANPR-A) and the subsequent increase of urinary cyclic 3-5 guanosine monophosphate (cGMP). METHODS: In i.v.t. cannulated rats, the left carotid artery was catheterised with PE-50 tubing for blood collection, renin was injected i.v.t. and arterial blood samples were collected at 0, 2, 5, 10 and 15 minutes of injection, and urinary sodium and cGMP excretion at 1-, 3- and 6-hour periods of urine collection. Plasma ANP levels and urinary cGMP were determined by radioimmunoassay, and each urine sample was analysed for sodium concentration using a flame photometer. RESULTS: Our results demonstrate that i.v.t.-R administration increases plasma ANP levels after two minutes of injection and urinary cGMP concentration at 1-, 3- and 6 hour period of urine collection. The natriuretic action induced by i.v.t.-R was blunted by peripheral administration of anantin, an ANPR-A antagonist. We assessed the role of brain angiotensin II (Ang II) AT1-receptors on the i.v.t.-induced antidiuresis, natriuresis and cGMP urinary excretion, the last as an indirect index of ANP secretion. Blockade of brain Ang II AT1-receptors with losartan (LOS; 120 microg/3 microl, i.v.t.), inhibited the antidiuretic action and blocked the increased urinary sodium and cGMP excretion induced by i.v.t.-R (7.14 mGU/5 microl). The increase in urinary cGMP was independent of nitric oxide synthase stimulation, since L-NAME pre-treatment did not alter the renal actions induced by i.v.t.-R. CONCLUSIONS: Our results suggest that there is a link between the brain and the kidney. The activation of brain angiotensinergic neurons and stimulation of AT1- receptors may stimulate the release of ANP to the circulation. The released ANP circulates to the kidneys where it acts through renal ANPR-As and the consequent increase in cGMP to produce natriuresis.

Intracranial renin alters gustatory neural responses in the nucleus of the solitary tract of rats.

Activation of the renin-angiotensin system in the brain is considered important in the arousal and expression of sodium appetite. To clarify the effects of directly activating this hormonal cascade, taste neurons in the nucleus of the solitary tract of rats were tested with a battery of sapid stimuli after intracerebroventricular injection of renin or its vehicle. The rats were chronically prepared but lightly anesthetized during the recording procedure. Eighty-five taste neurons were tested: 46 after renin injections and 39 after vehicle. Neural activity was counted for 5.0-s periods without stimulation (spontaneous) and during stimulation with water and sapid chemicals. The averaged responses to each of the standard stimuli (0.1 M NaCl, 0.3 M sucrose, 0.01 M citric acid, and 0.01 M quinine hydrochloride) did not differ significantly between the two conditions. When the rats were tested with a concentration range of NaCl, however, after renin the average responses to the hypertonic 0.3 and 1.0 M stimuli were reduced to 74 and 70%, respectively, compared with those after vehicle injections. A similar tendency was evident for the subsample of neurons that responded best to NaCl, but the effect was smaller. These data are consistent with, but not as dramatic as, those reported after dietary-induced sodium appetite.

Elevated blood pressure in transgenic mice with brain-specific expression of human angiotensinogen driven by the glial fibrillary acidic protein promoter.

In addition to the circulatory renin (REN)-angiotensin system (RAS), a tissue RAS having an important role in cardiovascular function also exists in the central nervous system. In the brain, angiotensinogen (AGT) is expressed in astrocytes and in some neurons important to cardiovascular control, but its functional role remains undefined. We generated a transgenic mouse encoding the human AGT (hAGT) gene under the control of the human glial fibrillary acidic protein (GFAP) promoter to experimentally dissect the role of brain versus systemically derived AGT. This promoter targets expression of transgene products to astrocytes, the most abundant cell type expressing AGT in brain. All transgenic lines exhibited hAGT mRNA expression in brain, with variable expression in other tissues. In one line examined in detail, transgene expression was high in brain and low in tissues outside the central nervous system, and the level of plasma hAGT was not elevated over baseline. In the brain, hAGT protein was mainly localized in astrocytes, but was present in neurons in the subfornical organ. Intracerebroventricular (ICV) injection of human REN (hREN) in conscious unrestrained mice elicited a pressor response, which was abolished by ICV preinjection of losartan. Double-transgenic mice expressing the hREN gene and the GFAP-hAGT transgene exhibited a 15-mm Hg increase in blood pressure and an increased preference for salt. Blood pressure in the hREN/GFAP-hAGT mice was lowered after ICV, but not intravenous losartan. These studies suggest that AGT synthesis in the brain has an important role in the regulation of blood pressure and electrolyte balance.

Antisense oligonucleotide inhibition of angiotensinogen in the brains of rats and sheep.

Phosphorothioated antisense oligodeoxynucleotides (ODNs) that were complementary to various parts of the rat or sheep mRNA encoding angiotensinogen were synthesized by conventional techniques. Their effectiveness as blockers of angiotensinogen synthesis in the brain was tested by bioassay. This involved measuring the effect of centrally administered antisense ODNs on water drinking that occurred in response to intracerebroventricular injection of hog renin. Renin-induced drinking requires brain angiotensinogen for the generation of angiotensin I and then angiotensin II to stimulate thirst. Intracerebroventricular injection of an 18-mer antisense ODN (0.5 microg twice in 24 h) complementary to the 5'-end start codon for rat angiotensinogen mRNA caused a pronounced inhibition of renin-induced drinking. This effect appeared to be specific for this region of the codon because antisense ODNs directed against other regions of rat angiotensinogen mRNA were ineffective, and renin-induced drinking was not inhibited by intracerebroventricular injection of scrambled or mismatched sequences of the effective ODN or by intraperitoneal injection of it. Intracerebroventricular injection of antisense ODN (0.5 microg twice in 24 h) did not inhibit appetite or affect water drinking in response to some other dipsogenic stimuli, thus demonstrating the specificity of its action against renin-induced drinking. By contrast, intracerebroventricular administration of 625 microg of an antisense ODN directed against the corresponding 5'-end start codon region of sheep angiotensinogen mRNA did not inhibit intracerebroventricular renin-induced drinking in sheep. These data show that while intracerebroventricularly administered antisense may be used effectively in rodents, the method is not necessarily applicable in larger mammals.

Blood pressure reduction and diabetes insipidus in transgenic rats deficient in brain angiotensinogen.

Angiotensin produced systemically or locally in tissues such as the brain plays an important role in the regulation of blood pressure and in the development of hypertension. We have established transgenic rats [TGR(ASrAOGEN)] expressing an antisense RNA against angiotensinogen mRNA specifically in the brain. In these animals, the brain angiotensinogen level is reduced by more than 90% and the drinking response to intracerebroventricular renin infusions is decreased markedly compared with control rats. Blood pressure of transgenic rats is lowered by 8 mmHg (1 mmHg = 133 Pa) compared with control rats. Crossbreeding of TGR(ASrAOGEN) with a hypertensive transgenic rat strain exhibiting elevated angiotensin II levels in tissues results in a marked attenuation of the hypertensive phenotype. Moreover, TGR(ASrAOGEN) exhibit a diabetes insipidus-like syndrome producing an increased amount of urine with decreased osmolarity. The observed reduction in plasma vasopressin by 35% may mediate these phenotypes of TGR(ASrAOGEN). This new animal model presenting long-term and tissue-specific down-regulation of angiotensinogen corroborates the functional significance of local angiotensin production in the brain for the central regulation of blood pressure and for the pathogenesis of hypertension.

Effects of human prorenin in rats transgenic for human angiotensinogen.

The physiological role of prorenin is unknown; however, the possibility that prorenin inhibits renin locally has been suggested. We tested the hypothesis that prorenin may be an endogenous competitor for renin uptake in the tissue. We also investigated whether prorenin can be activated to active renin and affect mean arterial pressure (MAP). Isolated perfused hindquarters of rats transgenic for human angiotensinogen were infused with human renin and/or prorenin. The plateau phase of angiotensin (Ang) I release 15 minutes after cessation of infusions was used as a parameter for renin uptake. Renin (10 ng/mL for 15 minutes) caused sustained release of Ang I (153+/-16 fmol/mL). Coinfusion with a 15-fold excess of prorenin did not affect local Ang I formation (153+/-19 fmol/mL). Prorenin infusion alone showed no activation to active renin. In addition, we investigated MAP and plasma Ang II levels after injection of saline (DeltaMAP, -1+/-2 mm Hg; 40+/-5 fmol/mL Ang II), 9 ng renin (DeltaMAP, +37+/-3 mm Hg; 378+/-39 fmol/mL), and 144 ng prorenin (DeltaMAP, +10+/-5 mm Hg; 61+/-5 fmol/mL) and the coinjection of renin and prorenin (DeltaMAP, +41+/-4 mm Hg; 305+/-23 fmol/mL) in anesthetized rats. The data show that prorenin was not activated to active renin and did not affect MAP in short-term experiments. Renin-induced Ang formation was not affected by prorenin. Renin may have been taken up specifically because of its physical and chemical properties or because of nonspecific sequestration in the extravascular space. We conclude that prorenin does not act as an endogenous antagonist for the long-lasting effects of renin in the vascular wall. Moreover, prorenin does not affect acute renin-related effects on blood pressure.

Localization and production of angiotensin II in the isolated perfused rat heart.

We used a modification of the isolated perfused rat heart, in which coronary effluent and interstitial transudate were separately collected, to investigate the localization and production of angiotensin II (Ang II) in the heart. During combined renin (0.7 to 1.5 pmol Ang I/mL per minute) and angiotensinogen (6 to 12 pmol/mL) perfusion (4 to 8 mL/min) for 60 minutes (n=3), the steady-state levels of Ang II in interstitial transudate in two consecutive 10-minute periods were 4.3+/-1.5 and 3.6+/-1.5 fmol/mL compared with 1.1+/-0.4 and 1.1+/-0.6 fmol/mL in coronary effluent (mean+/-half range). During perfusion with Ang II (n=5), steady-state Ang II in interstitial transudate was 32+/-19% of arterial Ang II compared with 65+/-16% in coronary effluent (mean+/-SD, P<.02). During perfusion with Ang I (n=5), Ang II in interstitial transudate was 5.1+/-0.6% of arterial Ang I compared with 2.2+/-0.3% in coronary effluent (P<.05). The tissue concentration of Ang II in the combined renin/angiotensinogen perfusions (per gram) was as high as the concentration in interstitial transudate (per milliliter). Addition of losartan (10(-6) mol/L) to the renin/angiotensinogen perfusion (n=3) had no significant effect on the tissue level of Ang II, whereas losartan in the perfusions with Ang I (n=5) or Ang II (n=5) decreased tissue Ang II to undetectably low levels. The results indicate that the heart is capable of producing Ang II and that this can lead to higher levels in tissue than in blood plasma. Cardiac Ang II does not appear to be restricted to the extracellular fluid. This is in part due to AT1-receptor-mediated cellular uptake of extracellular Ang II, but our results also raise the possibility of intracellular Ang II production.

Local angiotensin II generation in the rat heart: role of renin uptake.

To elucidate the local effects of renin in the coronary circulation, we examined local angiotensin (Ang) I and II formation, as well as coronary vasoconstriction in response to renin administration, and compared the effects with exogenous infused Ang I. We perfused isolated hearts from rats overexpressing the human angiotensinogen gene in a Langendorff preparation and measured the hemodynamic effects and the released products. We also investigated cardiac Ang I conversion, including the contribution of non-angiotensin-converting enzyme-dependent Ang II-generating pathways. Finally, we studied Ang I conversion in vitro in heart homogenates. Renin and Ang I infusion both generated Ang II. Ang II release and vasoconstriction continued after renin infusion was stopped, even though renin disappeared immediately from the perfusate. In contrast, after Ang I infusion, Ang II release and coronary flow returned to basal levels. Ang I conversion (Ang II/Ang I ratio) was higher after renin infusion (0.109+/-0.027 versus 0.026+/-0.003, 15 minutes, P<.02) compared with infused Ang I. Remikiren added to the renin infusion abolished Ang I and II; captopril suppressed only Ang II, whereas an AT1 receptor blocker did not affect Ang I and II formation. All the drugs prevented renin-induced coronary flow changes. Total cardiac Ang II-forming activity was only partially inhibited by cilazaprilat (4.1+/-0.1 fmol x min(-1) x mg[-1]) and on a larger extent by chymostatin (2.6+/-0.3 fmol x min(-1) x mg[-1]) compared with control values (5.6+/-0.4 fmol x min(-1) x mg[-1]). We conclude that renin can be taken up by cardiac or coronary vascular tissue and induces long-lasting local Ang II generation and vasoconstriction. Locally formed Ang I was converted more effectively than infused Ang I. Furthermore, the comparison of in vivo and in vitro Ang I conversion suggests that in vitro assays may underestimate the functional contribution of angiotensin-converting enzyme to intracardiac Ang II formation.

Angiotensinogen antisense oligonucleotides and fluid intake.

The effectiveness of antisense oligonucleotides (ODNs) to angiotensinogen on intracerebrovenricularly injected renin induced thirst was investigated. As a corollary, information would be gained about the role of centrally synthesised angiotensinogen in the neural mechanisms subserving water drinking in rats. Stable, easily synthesised phosphorothioate antisense oligonucleotides (18 mer), one of which included the sequence encompassing the translation start site, were injected into the lateral ventricle of rats. The drinking response to a number of dipsogenic stimuli was tested. Antisense significantly reduced (by about 50%) the volume of water drunk in response to intracerebroventricular (icv) renin or isoproterenol but did not reduce drinking in response to the physiological challenge of icv angiotensin II, icv carbachol, intravenous hypertonic saline, water deprivation or subcutaneous injection of polyethylene glycol. Only one out of four antisense probes gave positive results, while mismatch or scrambled oligonucleotides did not inhibit water intake. This finding reduces the probability that the results observed are non-specific. In these experiments, an ODN specific for angiotensinogen was discovered and was produced easily in large enough amounts and stabilised against intracellular nucleases without floss of cellular access or biological effect.

Dose effects of human renin in rats transgenic for human angiotensinogen.

We examined the effect of chronic human renin infusion and human renin inhibition on blood pressure in a unique transgenic rat model. We infused incremental doses of human renin (1 to 500 ng/h) with minipumps for 10 days into rats harboring the human angiotensinogen gene [TGR (hAOGEN)1623]. We measured blood pressure and heart rate continuously by telemetry. We found that human renin at 5 ng/h was necessary to increase blood pressure, whereas 10 ng/h caused systolic blood pressure to increase to 215 +/- 13 mm Hg. Heart rate decreased initially but then increased by 100 beats per minute compared with basal values. Drinking behavior also increased. Doses as high as 500 ng/h did not increase blood pressure further. A linear relationship was found between the log of plasma renin activity and systolic blood pressure that increased in slope from days 2 to 9. Rat angiotensinogen levels were low and not influenced by human renin infusion. Human angiotensinogen levels remained stable until 500 ng/h human renin was infused, at which time they decreased by 50% at 9 days. Rat renin gene expression (RNase protection assay) was decreased by human renin infusion, whereas rat and human angiotensinogen gene expressions in liver and kidney as well as angiotensin-converting enzyme gene expression in kidney were not affected. The human renin inhibitor Ro 42-5892 was given by gavage repeatedly to rats receiving human renin at 40 ng/h. Ro 42-5892 lowered blood pressure promptly to basal values. High human renin hypertension in this model is dose dependent, features a steeper relationship between blood pressure and plasma renin activity over time, and is associated with tachycardia and increased drinking. We conclude that the human angiotensinogen transgenic rat offers new perspectives in the study of human renin-induced hypertension.

No evidence for involvement of angiotensin II in spatial learning in water maze in rats.

There is increasing evidence suggesting angiotensin II (AII) may inhibit memory formation in a range of conditioned avoidance and habituation learning tasks in rodents. We were interested to determine if AII might also play an inhibitory role in spatial learning. Angiotensin-converting enzyme (ACE) inhibitors, which block the formation of AII from AI, improve acquisition and/or retention of basal performance inhibited by the muscarinic receptor antagonist, scopolamine, in conditioned avoidance and habituation tasks. In hooded Wistar rats, over 5 days of training in a water maze neither the ACE inhibitor, ceranapril 5 and 50 micrograms/kg/day, nor the ACE inhibitor, ramipril 2 and 10 mg/kg/day, altered the increase in path length produced by administration of scopolamine 0.75 mg/kg/day. In probe trails (without platform), on the last day of training, ceranapril 50 micrograms/kg produced a 35% further deterioration in performance in the scopolamine-treated rats (P < 0.02). Administration of the substrate, renin, that leads to AII formation, did not alter water maze performance over 5 days of training. The angiotensin receptor antagonist, losartan, has been shown to improve basal and scopolamine-impaired performance in a habituation task and reverse the inhibition in long-term potentiation produced by diazepam. However, neither losartan 10 and 30 mg/kg/day nor ramipril 2 and 10 mg/kg/day reversed diazepam-impaired (3 mg/kg/day) acquisition of the spatial memory task over 5 days of training. These studies suggest AII does not inhibit spatial learning in rats in the constant platform position water maze task nor does it mediate the inhibitory effects of scopolamine or diazepam in this task.

Effects of central alpha-adrenergic agonists on hormone-induced 3% NaCl and water intake.

Male rats received intracerebroventricular (ICV) renin (600 ng) or daily subcutaneous injections of deoxycorticosterone (5 mg) to induce 3% NaCl and water intake. Noradrenaline (NOR; 40-160 nmol) and clonidine (CLO; 5-20 nmol) injected ICV induced 70 to 100% inhibition of the intakes. Phenylephrine (PHE; 40-160 nmol) injected ICV induced 60 to 95% inhibition of the intakes. NOR and PHE induced a stronger inhibition on the 3% NaCl intake induced by renin than on the intake induced by deoxycorticosterone (DOC), and CLO did the opposite. CLO was always more effective than PHE to induce inhibition of the intakes. The results suggest that NOR inhibits hormone (angiotensin II, aldosterone)-induced NaCl intake by acting mainly on alpha 2-adrenergic receptors.

Human renin-dependent hypertension in rats transgenic for human angiotensinogen.

To examine the utility of rats transgenic for human angiotensinogen in the study of human renin-induced hypertension, we first developed assays to measure both the human and rat renin-angiotensin systems in these rats. We used human and mouse renin, transgenic human angiotensinogen, and the human renin inhibitor Ro 42-5892 to determine human- and rat-specific plasma angiotensinogen concentrations, renin activity, and renin concentration. The assays were validated with rat and human plasma mixed in known amounts and with plasma from rats transgenic for human renin. We then tested the human angiotensinogen-transgenic rats by infusing recombinant human renin over 10 days (50 ng/h, n=4) with osmotic minipumps. High human angiotensinogen transgene expression was found in the liver, brain, kidney, gastrointestinal tract, and aorta, whereas rat angiotensinogen gene expression was detected in the liver and brain. During human renin infusion, blood pressure increased to >200/150 mm Hg. Before infusion, human angiotensinogen was 100-fold greater than rat angiotensinogen (141 +/- 73 versus 1.2 +/- 0.16 microg angiotensin l/mL); the relation was not changed by renin infusion. Plasma renin activity increased 300-fold; human plasma renin concentration increased to very high levels (449 +/- 262 ng of angiotensin I per mL per hour), whereas rat plasma renin concentration decreased to undetectable levels. Thus, chronic human renin infusion resulted in severe hypertension with extreme plasma renin activity and plasma renin concentration. However, even at these levels, human angiotensinogen was not rate limiting and angiotensin II was not a significant stimulus for angiotensinogen production. We conclude that these transgenic rats represent a novel model of human renin-dependent hypertension.