Michael I. Oliverio

Distinct roles for the kidney and systemic tissues in blood pressure regulation by the renin-angiotensin system

Angiotensin II, acting through type 1 angiotensin (AT(1)) receptors, has potent effects that alter renal excretory mechanisms. Control of sodium excretion by the kidney has been suggested to be the critical mechanism for blood pressure regulation by the renin-angiotensin system (RAS). However, since AT(1) receptors are ubiquitously expressed, precisely dissecting their physiological actions in individual tissue compartments including the kidney with conventional pharmacological or gene targeting experiments has been difficult. Here, we used a cross-transplantation strategy and AT(1A) receptor-deficient mice to demonstrate distinct and virtually equivalent contributions of AT(1) receptor actions in the kidney and in extrarenal tissues to determining the level of blood pressure. We demonstrate that regulation of blood pressure by extrarenal AT(1A) receptors cannot be explained by altered aldosterone generation, which suggests that AT(1) receptor actions in systemic tissues such as the vascular and/or the central nervous systems make nonredundant contributions to blood pressure regulation. We also show that interruption of the AT(1) receptor-mediated short-loop feedback in the kidney is not sufficient to explain the marked stimulation of renin production induced by global AT(1) receptor deficiency or by receptor blockade. Instead, the renin response seems to be primarily determined by renal baroreceptor mechanisms triggered by reduced blood pressure. Thus, the regulation of blood pressure by the RAS is mediated by AT(1) receptors both within and outside the kidney.

Angiotensin II regulates cellular immune responses through a calcineurin-dependent pathway

The renin-angiotensin system (RAS) is a key regulator of vascular tone and blood pressure. In addition, angiotensin II also has a number of cellular effects that may contribute to disease pathogenesis. Using Agtr1a(-/-) mice, which lack AT(1A) receptors for angiotensin II, we have identified a novel function of the RAS to modulate the immune system. We find that angiotensin II, acting through type 1 (AT(1)) receptors on immune cells, triggers the proliferation of splenic lymphocytes. These actions contribute to the vigor of cellular alloimmune responses. Within lymphoid organs, sufficient components of the RAS are present to activate AT(1) receptors during an immune response, promoting cell growth. These actions require activation of calcineurin phosphatase. In an in vivo model of cardiac transplantation, the absence of AT(1) signaling accentuates the immunosuppressive effects of the calcineurin inhibitor cyclosporine. We conclude that inhibition of AT(1) receptor signaling should be useful as an anti-inflammatory and immunosuppressive therapy. Furthermore, the actions of the RAS to promote lymphocyte activation may contribute to inflammation that characterizes a number of diseases of the heart and the vascular system.

Divergent functions of angiotensin II receptor isoforms in the brain.

The renin-angiotensin system (RAS) plays a critical role in cardiovascular and fluid homeostasis. The major biologically active peptide of the RAS is angiotensin II, which acts through G protein-coupled receptors of two pharmacological classes, AT(1) and AT(2). AT(1) receptors, expressed in brain and peripheral tissues, mediate most classically recognized actions of the RAS, including blood pressure homeostasis and regulation of drinking and water balance. In rodents, two highly homologous AT(1) receptor isoforms, termed AT(1A) and AT(1B) receptors, are expressed at different levels in major forebrain cardiovascular and fluid regulatory centers, with AT(1A) expression generally exceeding AT(1B) expression, but the relative contributions of these receptor subtypes to central angiotensin II responses are not known. We used gene targeting in combination with a unique system for maintaining catheters in the cerebral ventricles of conscious mice to test whether there are differential roles for AT(1A) and AT(1B) receptors in responses elicited by angiotensin II in the brain. Here we show that the blood pressure increase elicited by centrally administered angiotensin II can be selectively ascribed to the AT(1A) receptor. However, the drinking response requires the presence of AT(1B) receptors. To our knowledge, this is the first demonstration of a primary and nonredundant physiological function for AT(1B) receptors.

Essential Role of AT1A Receptor in the Development of 2K1C Hypertension

Abstract—The aims of this study were to delineate the relative contribution of angiotensin II (ANG II) subtype 1A (AT1A) and 1B (AT1B) receptors to the development of two-kidney, one-clip (2K1C) Goldblatt hypertension in mice, to examine if increased nitric oxide synthase (NOS) activity counteracts the vasoconstrictor influences of ANG II in 2K1C hypertensive mice, and to determine the role of ANG II type 2 (AT2) receptors in 2K1C hypertension in mice. AT1A ANG II receptor knockout (AT1A−/−) and wild-type (AT1A+/+) mice underwent clipping of the right renal artery. Systolic blood pressure (SBP) was significantly lower in AT1A−/− compared with AT1A+/+ mice, and neither clip placement nor AT2 receptor blockade with PD 123319 (PD) altered SBP in AT1A−/− mice. A significant and sustained rise in SBP from 119±5 to 163±6 mm Hg was observed in the 2K1C AT1A+/+ mice from day 10 to day 26. Chronic PD infusion did not alter the course of hypertension in 2K1C/AT1A+/+. Acute PD infusion did not alter mean arterial pressure (MAP) in AT1A+/+, PD/AT1A+/+, 2K1C/AT1A+/+, PD/2K1C/AT1A+/+, AT1A−/−, PD/AT1A−/−, and PD/2K1C/AT1A−/− mice compared with basal levels. In contrast, acute PD infusion caused significant increases in MAP in 2K1C/AT1A−/− mice. The subsequent acute NOS inhibition caused greater increases in MAP in 2K1C/AT1A+/+ and PD/2K1C/AT1A+/+ mice than in AT1A+/+ and PD/AT1A+/+ mice. These results support the essential role of AT1A receptors in mediating 2K1C hypertension and support the hypothesis that augmented NO production serves as a counteracting system in this model of hypertension.

Urinary concentrating function in mice lacking EP3 receptors for prostaglandin E2

The actions of prostaglandin (PG) E2 are mediated by four distinct classes of PGE2 E-prostanoid (EP) receptors (EP1 through EP4). However, the in vivo functions of the individual EP receptor subtypes have not been delineated. To study the functions of one of these subtypes, the EP3 receptor, we generated EP3-deficient (-/-) mice by gene targeting. EP3 -/- animals survived in expected numbers, reproduced, and had no obvious abnormalities in their major organ systems. Because the EP3 receptor is expressed at high levels in the renal medulla and cortical collecting duct, and because previous studies have suggested that the EP3 receptor might antagonize the effects of vasopressin in the distal nephron, we examined urinary concentrating functions in EP3 -/- mice. Basal urine osmolality (UOsm) was similar in groups of EP3 -/- and wild-type (EP3 +/+) mice. However, after inhibition of endogenous PGE2 production by indomethacin, UOsm increased significantly in EP3 +/+ but not in EP3 -/- mice. Despite this insensitivity to acute inhibition of prostanoid production, EP3 -/- mice concentrated and diluted their urine normally in response to a series of physiological stimuli. This suggests that PGE2 acts through the EP3 receptor to modulate urinary concentrating mechanisms in the kidney, but these effects are not essential for normal regulation of urinary osmolality.The actions of prostaglandin (PG) E2 are mediated by four distinct classes of PGE2E-prostanoid (EP) receptors (EP1through EP4). However, the in vivo functions of the individual EP receptor subtypes have not been delineated. To study the functions of one of these subtypes, the EP3 receptor, we generated EP3-deficient (-/-) mice by gene targeting. EP3 -/- animals survived in expected numbers, reproduced, and had no obvious abnormalities in their major organ systems. Because the EP3 receptor is expressed at high levels in the renal medulla and cortical collecting duct, and because previous studies have suggested that the EP3 receptor might antagonize the effects of vasopressin in the distal nephron, we examined urinary concentrating functions in EP3-/- mice. Basal urine osmolality (UOsm) was similar in groups of EP3 -/- and wild-type (EP3 +/+) mice. However, after inhibition of endogenous PGE2 production by indomethacin, UOsm increased significantly in EP3 +/+ but not in EP3 -/- mice. Despite this insensitivity to acute inhibition of prostanoid production, EP3 -/- mice concentrated and diluted their urine normally in response to a series of physiological stimuli. This suggests that PGE2 acts through the EP3 receptor to modulate urinary concentrating mechanisms in the kidney, but these effects are not essential for normal regulation of urinary osmolality.

Renal growth and development in mice lacking AT1A receptors for angiotensin II.

To examine the role of the type 1A (AT1A) angiotensin receptor in renal growth and development, we analyzed F2 progeny from a series of crosses between F1 mice that were heterozygous for a targeted disruption of the AT1Areceptor gene [ Agtr1A-(+/-)]. Among 21-day-old weanling F2 mice, we found that 194 (32%) were homozygous for the wild-type allele Agtr1A-(+/+), 299 (49%) were Agtr1A-(+/-), and 119 (19%) were Agtr1A-(-/-). This differed significantly from the proportions predicted by Mendelian genetics ( P = 0.01), suggesting that the complete absence of AT1Areceptors is associated with a mild survival disadvantage. Agtr1A-(-/-) mice grew normally, and we found no significant differences in body weight or heart and kidney weights in Agtr1A-(+/+) and Agtr1A-(-/-) mice examined at 21, 60, and 100 days. Protein and DNA content of kidneys and hearts were also similar in weanling or adult Agtr1A-(+/+) and Agtr1A-(-/-) mice. By light microscopy with immunohistochemistry, kidneys from Agtr1A-(-/-) were essentially normal, with two exceptions: 1) there was marked hypertrophy of the juxtaglomerular apparatus (JGA) and proximal expansion of renin-producing cells along the afferent arterioles, and 2) some glomeruli showed evidence of mesangial expansion. We did not find the severe renal vascular lesions or papillary atrophy that have been observed in angiotensinogen- or angiotensin converting enzyme-deficient animals. We conclude that the AT1A receptor is not essential for the normal organogenesis of the kidney; however, its absence is associated with mild mesangial expansion and JGA hypertrophy.

Pressure-overload hypertrophy is unabated in mice devoid of AT1A receptors

Mechanisms controlling cardiac growth are under intense investigation. Among these, the renin-angiotensin system has received great interest. In the current study, we tested the hypothesis that the renin-angiotensin system was not an obligate factor in cardiac hypertrophy. We examined the left ventricular hypertrophic response to a pressure overload in mice devoid of the AT1A receptor, the putative major effector of the growth response of the renin-angiotensin system. Aortic banding produced similar transband gradients in wild-type and AT1A knockout mice. The left ventricular mass-to-body weight ratio increased from 3.44 ± 0.08 to 5.62 ± 0.25 in wild-type ascending aortic-banded mice. The response in the knockout mice was not different (from 2.97 ± 0.13 to 5.24 ± 0.37). We conclude that the magnitude of cardiac hypertrophy is not affected by the absence of the AT1A receptor and its signaling pathway and that this component of the renin-angiotensin system is not necessary in cardiac hypertrophy.Mechanisms controlling cardiac growth are under intense investigation. Among these, the renin-angiotensin system has received great interest. In the current study, we tested the hypothesis that the renin-angiotensin system was not an obligate factor in cardiac hypertrophy. We examined the left ventricular hypertrophic response to a pressure overload in mice devoid of the AT1A receptor, the putative major effector of the growth response of the renin-angiotensin system. Aortic banding produced similar transband gradients in wild-type and AT1A knockout mice. The left ventricular mass-to-body weight ratio increased from 3.44 +/- 0.08 to 5.62 +/- 0.25 in wild-type ascending aortic-banded mice. The response in the knockout mice was not different (from 2.97 +/- 0.13 to 5.24 +/- 0.37). We conclude that the magnitude of cardiac hypertrophy is not affected by the absence of the AT1A receptor and its signaling pathway and that this component of the renin-angiotensin system is not necessary in cardiac hypertrophy.

Inhibition of adenosine-1 receptor-mediated preglomerular vasoconstriction in AT1Areceptor-deficient mice

The effect of the adenosine type 1 receptor agonist N 6-cyclohexyladenosine (CHA) on glomerular vascular reactivity was studied in male angiotensin II type 1A (AT1A) receptor knockout mice (9). Vascular reactivity was assessed as the response of stop-flow pressure (PSF) to infusion of CHA into loops of Henle using micropuncture techniques. In AT1A +/+ mice at ambient arterial blood pressure (96.7 ± 2.8 mmHg), the presence of CHA (10-5 M) in the perfusate increased PSF responses from 6.8 ± 0.6 to 14.3 ± 0.9 mmHg when the loop of Henle of the index nephron was perfused and from 0.7 ± 0.3 to 12.3 ± 1.0 mmHg when the loop of an adjacent nephron was perfused. At reduced arterial blood pressure (82.8 ± 1.3 mmHg), index nephron perfusion with CHA increased PSF responses from 4.5 ± 0.3 to 9.4 ± 0.4 mmHg. In AT1A -/- mice with a mean arterial blood pressure of 80 ± 1.9 mmHg, CHA increased PSF responses only from 0.1 ± 0.3 to 3.6 ± 0.54 mmHg during index nephron perfusion and from 0.25 ± 0.2 to 2.7 ± 0.55 mmHg during adjacent nephron perfusion, significantly less than in wild-type animals ( P < 0.001). Responses to CHA were intermediate in AT1A +/- mice. Thus AT1A receptor knockout mice show a markedly reduced constrictor response to CHA both in the presence and absence of simultaneous activation of the tubuloglomerular feedback system. These data support the notion of a functional interaction between adenosine and angiotensin II in the regulation of afferent arteriolar tone.

Neuroendocrine Effects of Dehydration in Mice Lacking the Angiotensin AT1a Receptor

Angiotensin (Ang) type 1a (AT1a) receptors are critical in the control of blood pressure and water balance. Experiments were performed to determine the influence of dehydration on brain Ang receptors and plasma vasopressin (VP) in mice lacking this receptor. Control or AT1a knockout (AT1aKO) male mice were give water ad libitum or deprived of water for 48 hours. Animals were anesthetized with halothane, blood samples were collected by heart puncture, and brains were processed for Ang-receptor autoradiography with 125I-sarthran (0.4 nmol/L). Dehydration produced an increase in AT1 receptors in the paraventricular nucleus (PVN) and anterior pituitary (AP) in control mice (PVN: 70+/-16 versus 146+/-10 fmol/mg protein; AP: 41+/-7 versus 86+/-15 fmol/mg protein). No changes were noted in the median preoptic nucleus. The majority of the brain receptors were of the AT1 subtype. There was little or no specific Ang binding in AT1aKO mice and no effect of dehydration. Plasma VP levels were elevated in the halothane-anesthetized animals (>200 pg/mL) with no significant effect of dehydration. A separate experiment was performed with decapitated mice anesthetized with pentobarbital. Dehydration increased plasma VP in control mice, from 3.3+/-0.6 to 13.3+/-4.7 pg/mL, whereas no change was noted in the AT1aKO mice, 5.1+/-0.3 versus 6.1+/-0.7 pg/mL (water versus dehydration). These results demonstrate a differential response to dehydration in mice lacking AT1a receptors. There was no evidence for AT1 receptors of any subtype in the brain regions examined and no effect of dehydration on VP secretion or brain Ang receptors.

Insights into the Functions of Type 1 (AT1) Angiotensin II Receptors Provided by Gene Targeting

The renin-angiotensin system (RAS) has a wide range of actions in biological processes ranging from development and reproduction to cardiovascular and renal functions. Most of these actions are mediated by the octapeptide hormone angiotensin II. The identified family of angiotensin II receptors is divided into two pharmacological classes: type 1 (AT1) and type 2 (AT2). The classically recognized actions of the RAS are primarily mediated by the AT1 subtype of angiotensin receptors, and these receptors are the targets of a new class of anti-hypertensive agents. In recent years, our understanding of the physiological functions of AT1 receptors has been advanced through the use of gene-targeting technology. In this review, we will summarize the emerging picture of AT1 receptor functions that has been provided by gene-targeting experiments.