Chronic hypertension and altered baroreflex responses in transgenic mice containing the human renin and human angiotensinogen genes

Urinary excretion of angiotensinogen reflects intrarenal angiotensinogen production

BACKGROUND

In rats maintained on a high salt diet (H/S) to suppress basal renal angiotensinogen levels, angiotensin II (Ang II) infusion for 13 days increased renal angiotensinogen mRNA and protein, thus providing a mechanism for further augmentation of intrarenal Ang II levels. The present study tested the hypothesis that enhanced intrarenal angiotensinogen formation during Ang II infusion is reflected by secretion into the tubular fluid leading to increased urinary excretion of angiotensinogen (UAGT).

METHODS

The effects of chronic Ang II infusion were examined on kidney and plasma Ang II levels and UAGT in male Sprague-Dawley rats maintained on an 8% salt diet for three weeks (N=10). Following one week on the H/S diet, Ang II (40 ng/min) was administered for two weeks via an osmotic minipump to one group (H/S + Ang II, N=5), while the remaining rats were sham-operated (H/S + Sham, N=5). Additionally, a control group was prepared with normal salt diet and sham-operation (N/S + Sham, N=5).

RESULTS

H/S alone did not alter systolic blood pressure (BP) (103 +/- 2 vs. 104 +/- 2 mm Hg), while Ang II infusion to H/S rats significantly increased systolic BP from 103 +/- 2 to 154 +/- 2 after two weeks. Intrarenal Ang II content in H/S + Ang II was significantly greater than H/S + Sham (435 +/- 153 vs. 65 +/- 14 fmol/g). Ang II infusion significantly increased UAGT (4.0 +/- 0.5 vs. 1.0 +/- 0.2 nmol Ang I/day by radioimmunoassay of generated Ang I; 57 +/- 15 vs. 14 +/- 2 densitometric units by Western blotting analysis) compared to Sham. UAGT by radioimmunoassay was highly correlated with kidney Ang II content (r=0.79); but not with plasma Ang II concentration (r=0.20).

CONCLUSIONS

These data demonstrate that chronic Ang II infusion increases urinary excretion rate of angiotensinogen, and suggest that UAGT provides a specific index of intrarenal angiotensinogen production in Ang II-dependent hypertension.

The brain renin-angiotensin system in transgenic mice carrying a highly regulated human renin transgene

We previously reported the generation of 2 novel transgenic mouse models containing the human renin (hREN) gene encoded on P1 artificial chromosomes (PAC) containing large amounts of 5'-flanking DNA. These mice exhibit a very narrow tissue-specific expression profile and exhibit tightly regulated expression in kidney in response to physiological cues. In brain, transcription of hREN occurs from an alternative upstream promoter, causing translation to initiate within exon-II and potentially generating an intracellular form of active renin. Double transgenic mice containing a PAC transgene and the human angiotensinogen (hAGT) gene (P+/A+) are moderately hypertensive. We tested whether increased RAS activity in the brain contributes to the mechanism of hypertension in P+/A+ double transgenic mice. Expression of hREN mRNA in brain was confirmed in 4 independent PAC transgenic lines and utilization of the alternative transcription start site in brain was confirmed in each line. Human REN immunostaining was observed in the dorsal cochlear nucleus, hypothalamus, and cortex. P+/A+ mice exhibited a greater fall in mean arterial pressure after intracerebroventricular injection of losartan than controls. P+/A+ mice exhibited a greater drop in arterial pressure after intravenous injection of a vasopressin V(1) receptor antagonist, and an equivalent drop in arterial pressure after intravenous injection of a ganglion blocker compared with controls. These results support the hypothesis that renin is endogenously expressed in the brain and suggest that increased brain RAS activity may contribute to the maintenance of moderate hypertension in P+/A+ transgenic mice at least in part by a vasopressin-dependent mechanism.

Endothelial dysfunction and blood pressure variability in selected inbred mouse strains

The genetic regulation of blood pressure (BP) and endothelial function is likely to be polygenic. Because there is considerable variability in basal BP among inbred mouse strains, the purpose of this study was to determine whether a similar variability in vascular function exists among 7 "normotensive" strains. We tested the hypothesis that compared with mice with higher BPs, mice with lower BPs would have greater aortic endothelial responses to acetylcholine (ACh). Mean BP ranged from 117 to 145 mm Hg among the 7 strains. The responses of aortic rings to ACh, sodium nitroprusside, and papaverine were assessed after submaximal precontraction with prostaglandin F(2alpha). The aortas from all strains relaxed in a concentration-dependent manner to sodium nitroprusside and papaverine, but responses to ACh were markedly impaired in the aortas, but not carotid arteries, from 129P3/J and 129X1/SvJ mice. Aortas from the other strains relaxed normally to ACh. Furthermore, the endothelium-dependent dilators ADP and A23187 caused similar relaxation in 129P3/J, 129X1/SvJ, and C57BL/6J mice. Although the data do not support the initial hypothesis, the impaired aortic response to ACh in the 129 strains is a novel finding and illustrates the potential impact that genetic background can have on vascular responsiveness.

A new model of congestive heart failure in the mouse due to chronic volume overload

OBJECTIVE

Recently, deletion of specific genes by so called knock-out techniques has become important for investigating the pathogenesis of various diseases. This form of genetic engineering is widely performed in murine models. There are, however, only a limited number of mouse models available in cardiovascular pathology. The objective of this study, therefore, was to develop a new model of overt congestive heart failure associated with myocardial hypertrophy in the mouse.

METHODS

Female C57/BL6 mice weighing 19-20 g were anesthetized with ether. After abdominal incision, the aorta was temporarily clamped proximal to the renal arteries. The aorta was then punctured with a needle (outer diameter 0.6 mm) and the needle was further advanced into the adjacent vena cava. After withdrawal of the needle, the aortic puncture site was sealed with cyanoacrylate glue. The clamp was removed, and the patency of the shunt was visually verified as swelling and mixing of venous and arterial blood in the vena cava. Sham-operated mice served as controls.

RESULTS

Perioperative mortality of mice with aortocaval shunt was 42%. Four weeks after shunt induction, mice showed a significant cardiac hypertrophy with a relative heart weight of 7.5+/-0.2 mg/100 g body weight (vs. 5.1+/-0.7 mg/100 g in control mice, P<0.001). While no changes in blood pressure and heart rate occurred, left ventricular enddiastolic pressure was significantly increased in mice with shunt, and left ventricular contractility was impaired from 6331+/-412 to 4170+/-296 mmHg/s (P<0.05). Plasma concentrations of atrial natriuretic peptide (ANP) and its second messenger cGMP as humoral markers of heart failure as well as ventricular expression of ANP- and brain natriuretic peptide (BNP)-mRNA were significantly increased in mice with shunt compared to control mice.

CONCLUSIONS

The aortocaval shunt in the mouse constitutes a new model of overt congestive heart failure with impaired hemodynamic parameters and may be a useful tool to investigate the role of particular genes in the development of heart failure.

Genetic manipulation of the renin-angiotensin system in the kidney

Over the past 5 years, genetic manipulation has revolutionized the way we examine physiological processes by providing a targeted specificity that was not possible previously. The application of transgenesis and gene targeting has been applied to numerous physiological pathways; and both will remain important tools as we reach the completion of the human genome project and begin to assess the function of newly identified genes. The renin-angiotensin system (RAS) has been the target of numerous transgenic and gene targeting studies designed to help uncover its role in cardiovascular regulation and organ development. Each gene of the system has now been both over-expressed and knocked out. It will be discussed as to how new advances in tissue-specific gene targeting by both over-expression and gene ablation can be used as powerful tools to dissect the role of the RAS in individual tissues.

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.

Genetic evidence that lethality in angiotensinogen-deficient mice is due to loss of systemic but not renal angiotensinogen

Angiotensinogen (AGT)-deficient mice die shortly after birth presumably due to renal dysfunction caused by the presence of severe vascular and tubular lesions in the kidney. Because AGT is expressed in renal proximal tubule cells, we hypothesized that its loss may be the primary mediator of the lethal phenotype. We generated two models to test this hypothesis by breeding transgenic mice expressing human renin with mice expressing human AGT (hAGT) either systemically or kidney-specifically. We then bred double transgenic mice with AGT+/- mice, intercrossed the compound heterozygotes, and examined the offspring. We previously reported that the presence of the human renin and systemically expressed hAGT transgene complemented the lethality observed in AGT-/- mice. On the contrary, we show herein that the presence of the human renin and kidney-specific hAGT transgene cannot rescue lethality in AGT-/- mice. An analysis of newborns indicated that AGT-/- mice were born in normal numbers, and collection of dead 10-day old pups revealed an enrichment in AGT-/-. Importantly, we demonstrated that angiotensinogen protein and functional angiotensin II was generated in the kidney, and the kidney-specific transgene was temporally expressed during renal development similar to the endogenous AGT gene. These data strongly support the notion that the loss of systemic AGT, but not intrarenal AGT, is responsible for death in the AGT-/- mouse model. Taken together with our previous studies, we conclude that the intrarenal renin-angiotensin system located in the proximal tubule plays an important role in blood pressure regulation and may cause hypertension if overexpressed, but may not be required for continued development of the kidney after birth.

A novel effect of angiotensin on renal sympathetic nerve activity in mice

OBJECTIVE

The goals of this study were to characterize the effects of angiotensin II (Ang II) on renal sympathetic nerve activity (RSNA) and to define mechanisms of its actions in mice.

DESIGN

The experiments were performed in sodium pentobarbital anesthetized C57BL/6J mice to investigate the effects of intravenous administration of Ang II on RSNA recorded from renal sympathetic post-ganglionic nerve fibers.

RESULTS

Intravenous (i.v.) administration of Ang II (4 ng/g) increased arterial pressure and evoked a biphasic change in RSNA: inhibition of high-amplitude phasic bursts of RSNA secondary to the initial rise of arterial pressure followed by activation of low-amplitude continuously discharging RSNA that exceeded baseline activity (255 +/- 72% baseline, n = 8). The peak change of mean arterial pressure (MAP) was +60 +/- 4 mmHg (n = 8). In the same group of animals, norepinephrine (40 ng/g) caused an equivalent increase in MAP (+57 +/- 5 mmHg) and essentially abolished RSNA. The Ang II-induced activation of RSNA was dose-dependent (0.5-4 ng/g, n = 7) and was abolished by the Ang II type 1 (AT1) receptor blocker, losartan (10 microg/g, i.v.) (301 +/- 61 versus 117 +/- 22% baseline, before versus after losartan, n = 5). The ganglionic blocker, hexamethonium (30 microg/g, i.v.), eliminated baseline high-amplitude bursts of RSNA but did not blunt the Ang II-induced RSNA (n = 6). In baroreceptor denervated and vagotomized mice, Ang II failed to inhibit high-amplitude bursts of RSNA but continued to trigger low-amplitude continuous RSNA.

CONCLUSION

We conclude that Ang II activates renal sympathetic nerves that discharge in a continuous pattern, distinctly different than the normal baseline high-amplitude bursts of RSNA. The mechanism may involve direct activation of post-ganglionic sympathetic neurons mediated through AT1 receptors.

Mouse models of blood pressure regulation and hypertension

Human essential hypertension is recognized as a multifactorial disease involving many genes, but the causative genes have not yet been identified. For many years hypertension was studied primarily in the rat, but more recently several candidate genes for hypertension have been used to produce transgenic mice for gain of function and gene-targeted mice for loss of function studies. These genetically engineered mouse strains with hypertension or hypotension are providing insights into the mechanisms of blood pressure regulation. However, genetically engineered mice are used to study one gene at a time, and another complementary approach is needed for polygenic inheritance and gene interaction. The phenotype-driven approach to hypertension studies uses the natural variation among inbred strains and crosses to find quantitative trait loci. The four mouse crosses carried out so far have found several quantitative trait loci that are concordant with hypertension loci found in rats and humans.

Androgen-dependent regulation of human angiotensinogen expression in KAP-hAGT transgenic mice

We previously reported a novel transgenic model expressing human angiotensinogen from the kidney androgen-regulated protein promoter, and demonstrated sexually dimorphic expression. Herein, we investigated the hormonal regulation of this transgene. Testosterone increased transgene expression in female mice in a dose- and time-dependent manner and was not detectable 3-days after treatment was halted. High doses of estrogen were required to induce the transgene. Expression of transgene mRNA decreased after castration of male transgenic mice. As in females, however, transgene expression could be induced after administration of testosterone. Flutamide, an androgen receptor antagonist, dose dependently blocked transgene expression in males and blunted the induction caused by testosterone in females. Neither testosterone nor estrogen altered the proximal tubule cell-specific expression of the transgene. The data suggest that the level of transgene expression in this model can be controlled temporally and in magnitude by manipulating the levels of androgen. The fortuitous androgen regulation of this transgene can be used as a molecular "on-off" switch to control transgene expression and potentially manipulate blood pressure levels in this model.

Contribution of circulating renin to local synthesis of angiotensin peptides in the heart

The activity of a local cardiac renin-angiotensin system (RAS) has long been suspected in the promotion of cardiac pathologies including hypertrophy, ischemia, and infarction. All of the components of the RAS cascade have been demonstrated to be synthesized within the heart with the possible exception of the first enzyme in the cascade, renin. In the current study, we provide direct evidence that circulating renin can contribute to cardiac-specific synthesis of angiotensin peptides. Furthermore, we demonstrate this effect is independent of blood pressure and that in animals of comparable blood pressure, elevated circulating renin significantly enhances cardiac fibrosis. These results may serve to explain some of the cardiac pathologies associated with the RAS.

Analysis of organ physiology in transgenic mice

The increasing availability of transgenic mouse models of gene deletion and human disease has mandated the development of creative approaches to characterize mouse phenotype. The mouse presents unique challenges to phenotype analysis because of its small size, habits, and inability to verbalize clinical symptoms. This review describes strategies to study mouse organ physiology, focusing on the cardiovascular, pulmonary, renal, gastrointestinal, and neurobehavioral systems. General concerns about evaluating mouse phenotype studies are discussed. Monitoring and anesthesia methods are reviewed, with emphasis on the feasibility and limitations of noninvasive and invasive procedures to monitor physiological parameters, do cannulations, and perform surgical procedures. Examples of phenotype studies are cited to demonstrate the practical applications and limitations of the measurement methods. The repertoire of phenotype analysis methods reviewed here should be useful to investigators involved in or contemplating the use of mouse models.

Transgenic and knockout mice to study the renin-angiotensin system and other interacting vasoactive pathways

Essential hypertension is an insidious disease in which the afflicted person risks disability and death from myocardial infarction and stroke. Many factors contribute to the development of essential hypertension, including environment, diet, daily stress, and genetics. Although several single gene disorders causing high blood pressure have been identified, the genetics of essential hypertension are much more complicated. The current hypothesis is that a combination of genetic variations in multiple genes may predispose a person to hypertension. Both overexpression and gene inactivation ("knockout") have proven useful tools to evaluate the genetics of essential hypertension and to identify pathways regulating blood pressure. Molecular and physiologic evaluations of transgenic and knockout mice carried out over the past 5 years have provided a plethora of information about the mechanisms of blood pressure regulation and the development and maintenance of hypertension. This review focuses on the newer mouse models that have been developed to investigate hypertension with an emphasis on vascular and renal mechanisms, contributed by the renin-angiotensin system, and other pathways intersecting with the renin-angiotensin system.

Impaired endothelial function in transgenic mice expressing both human renin and human angiotensinogen

BACKGROUND AND PURPOSE

Chronic hypertension is a risk factor for carotid vascular disease and stroke. Mechanisms that account for alterations in carotid and cerebral vascular function during hypertension are poorly defined and based almost exclusively on studies in the spontaneously hypertensive rat, a model in which hypertension has an unknown etiology and in which the genetic background is dissimilar to the most commonly used normotensive control, the Wistar-Kyoto rat.

METHODS

In this study we examined vascular function in a defined model of hypertension, double transgenic mice that overexpress both human renin (R+) and human angiotensinogen (A+). We studied vessels in vitro from R+/A+ mice as well as nontransgenic (R-/A-) and single transgenic (R-/A+ or R+/A-) littermate controls.

RESULTS

After submaximal precontraction with U46619 or prostaglandin F(2alpha), acetylcholine, which produces relaxation mediated by endothelial nitric oxide synthase, produced marked relaxation of carotid arteries in control mice but was impaired in R+/A+ mice. For example, 1 micromol/L acetylcholine relaxed the carotid artery by 79+/-4% versus 44+/-7% (P<0.01) in control and R+/A+ mice, respectively. Impaired responses to acetylcholine in R+/A+ mice could be restored toward normal with indomethacin (10 micromol/L). In contrast, relaxation of the carotid artery in response to nitroprusside and papaverine was similar in R+/A+ mice and control mice.

CONCLUSIONS

These findings indicate that acetylcholine-induced relaxation of carotid artery is impaired selectively in mice made hypertensive by expression of human renin and human angiotensinogen. The mechanism of this impairment may involve production of a cyclooxygenase-derived contracting factor.

Angiotensinogen concentrations and renin clearance : implications for blood pressure regulation

Renin (REN) requires seconds to convert angiotensinogen (AGT) to angiotensin I. We tested the hypothesis that this long catalytic cycle might indicate an influence of AGT concentrations on REN clearance. We studied 2 transgenic rat (TGR) strains for human (h) AGT; one strain has hAGT values approximately 7-fold higher than the other (68+/-18 versus 10+/-4 microg angiotensin I/mL). hREN (30 000 pg) was bolus-infused into both lines and into nontransgenic controls. The terminal half-life (T1/2beta) was increased (130 versus 82 minutes) and the metabolic clearance rate (MCR) was decreased (0.83+/-0.29 versus 2.2+/-0.66 microL. min(-1). g(-1)) in the high hAGT strain compared with the low hAGT strain. The difference was not related to volume of distribution at steady state. Infused hREN blocked with remikiren resulted in T1/2beta and MCR values that were not different from control values. Infused unblocked and blocked radiolabeled hREN was distributed similarly in the hAGT TGR strains. Infused mouse REN, which cannot convert hAGT, had similar T1/2beta and MCR values in hAGT TGR. Measuring REN with direct radioimmunoassay or by enzyme kinetic assay gave similar results. We next crossed homozygous hAGT TGR from both strains with homozygous hREN TGR. Heterozygous offspring from the low hAGT TGR strain had plasma REN activity, hREN concentration, and rat AGT values that were no different from those of their parents. However, TGR offspring with high hAGT values had massively elevated plasma REN activity and hREN concentration as well as elevated blood pressure, even though both the hREN and rREN genes are downregulated. We conclude that increased AGT concentrations decrease REN MCR and increase REN T1/2beta. The REN-AGT complex may stabilize plasma REN concentration and regulate plasma REN activity independent of renal REN secretion and angiotensin II-mediated feedback. These effects could augment angiotensin I generation and influence blood pressure. The notion that AGT is merely a passive substrate reservoir for REN should be revised.

Understanding hypertension through genetic manipulation in mice

With the advances in mouse molecular genetics and physiology during the last decade, the mouse has become the animal model of choice for studying the genetic basis of many diseases. Terms such as "transgenic" and "knockout" have become part of a colloquial language used in most research laboratories that are investigating human diseases. These terms refer to the two most commonly used methods for analyzing the function of a gene in vivo: overexpression (transgenic mouse) and deletion (knockout mouse). Both methods have proved to be extremely useful in establishing the importance of specific genes in genetic disorders, such as hypertension. The choice of genes being investigated in relationship to hypertension was governed by the knowledge of systems regulating vascular and renal physiology. Thus, it is not surprising that most of the focus was given to the renin-angiotensin system (RAS). Apart from the RAS, other systems known to regulate vascular tone and/or electrolyte and fluid homeostasis have also been analyzed using transgenic and knockout approaches. This review briefly summarizes some of the mouse models relevant to renal mechanisms of hypertension and then discusses the future of genetic manipulation in mice for studying the genetics of hypertension.

Renal physiology of the mouse

As the transgenic and gene-targeting technology has become an invaluable experimental approach to study the function of gene products, the need has been expanded to assess the physiology in the mouse, which is virtually the only animal species to which that new genetic technology can apply. In this regard, renal physiologists have also received fruits of success from modern technology in several key areas, and areas are expanding in both depth and scope.

Transgenic models as tools for studying the regulation of human renin expression

Transgenic mice and rats have become popular tools to study the regulation of gene expression and the consequences of protein over-production. Over the past decade, numerous transgenic models have been developed to study the mechanisms of human renin gene expression and the participation of the renin-angiotensin system in the development of hypertension. Herein we will provide an overview of what has been learned from the use of transgenic models for studying the human renin gene.

Highly regulated cell type-restricted expression of human renin in mice containing 140- or 160-kilobase pair P1 phage artificial chromosome transgenes

We generated transgenic mice with two P1 artificial chromosomes, each containing the human renin (HREN) gene and extending to -35 and -75 kilobase pairs, respectively. HREN protein production was restricted to juxtaglomerular cells of the kidney, and its expression was tightly regulated by angiotensin II and sodium. The magnitude of the up- and down-regulation in HREN mRNA caused by the stimuli tested was identical to the endogenous renin gene, suggesting tight physiological regulation. P1 artificial chromosome mice were mated with transgenic mice overexpressing human angiotensinogen to determine if there was a chronic compensatory down-regulation of the transgene. Despite a 3-fold down-regulation of HREN mRNA, plasma angiotensin II and blood pressure was modestly elevated in the double transgenic mice. Nevertheless, this elevation was significantly less than a different double transgenic model containing a poorly regulated HREN transgene. The increase in blood pressure, despite the decrease in HREN mRNA, suggests that the HREN gene can partially, but not completely, compensate for excess circulating angiotensinogen. These data suggest the possibility that increases in circulating or tissue angiotensinogen may cause an increase in blood pressure in humans, even in the presence of a functionally active servo-mechanism to down-regulate HREN expression.

Efficient liver-specific deletion of a floxed human angiotensinogen transgene by adenoviral delivery of Cre recombinase in vivo

Tissue-specific ablation of gene function is possible in vivo by the Cre-loxP recombinase system. We generated transgenic mice containing a human angiotensinogen gene flanked by loxP sites (hAGT(flox)). To examine the physiologic consequences of tissue-specific loss of angiotensinogen gene function in vivo, we constructed an adenovirus expressing Cre recombinase. Studies were performed in several independent lines of hAGT(flox) mice before and after intravenous administration of either Adcre or AdbetaGal as a control. Systemic administration of Adcre caused a significant decrease in circulating human angiotensinogen and markedly blunted the pressor response to administration of purified recombinant human renin. Southern blot analysis of genomic DNA from various organs revealed that the Cre-mediated deletion was liver-specific. Further analysis revealed the absence of full-length human angiotensinogen mRNA and protein in the liver but not the kidney of Adcre mice, consistent with the liver being the target for adenoviruses administered intravenously. These studies demonstrate that extra-hepatic sources of angiotensinogen do not contribute significantly to the circulating pool of angiotensinogen and provide proof-of-principle that the Cre-loxP system can be used effectively to examine the contribution of the systemic and tissue renin-angiotensin system to normal and pathological regulation of blood pressure.

Novel mechanism of hypertension revealed by cell-specific targeting of human angiotensinogen in transgenic mice

We tested the hypothesis that the tissue-specific intrarenal renin-angiotensin system (RAS) can participate in the regulation of blood pressure independently of its endocrine counterpart, by generating two transgenic models that differ in their tissue-specific expression of human angiotensinogen (AGT). Human AGT expression was driven by its endogenous promoter in the systemic model and by the kidney androgen-regulated protein promoter in the kidney-specific model. Using molecular, biochemical, and physiological measurements, we demonstrate that human AGT mRNA and protein are restricted to the kidney in the kidney-specific model. Plasma ANG II was elevated in the systemic model but not in the kidney-specific model. Nevertheless, blood pressure was markedly elevated in both the systemic and kidney-specific transgenic mice. Acute administration of the selective ANG II AT-1 receptor antagonist losartan lowered blood pressure in the systemic model but not in the kidney-specific model. These results provide evidence for the potential importance of the intrarenal RAS in blood pressure regulation by showing that expression of AGT specifically in the kidney leads to chronic hypertension independently of the endocrine RAS.

Circadian blood pressure and heart rate rhythms in mice

The circadian pattern of mean arterial pressure (MAP) and heart rate (HR) was measured in C57BL mice with carotid arterial catheters. Cardiovascular parameters were recorded continuously with a computerized monitoring system at a sampling rate of 100 Hz. The tethered animals were healthy, showing stabilized drinking and eating patterns within 2 days of surgery and little loss of body weight. Analysis of the 24-h pattern of MAP and HR was conducted using data from 3-6 consecutive days of recording. A daily rhythm of MAP was evident in all mice, with group mean dark and light values of 101.4 +/- 7.3 and 93.1 +/- 2.9 mmHg, respectively. The group mean waveform was bimodal, with peak values evident early and late in the dark period, and a trough during the middle of the light period. The phase of maximum and minimum values showed low within-group variance. Mean heart rate was greater at night than during the day (561.9 +/- 22.7 vs. 530.3 +/- 22.3 beats/min). Peak values generally occurred at dark onset, and minimum values during the middle of both the dark and the light periods. We conclude that it is possible to perform measurements of circadian cardiovascular parameters in the mouse, providing new avenues for the investigation of genetic models.

Appropriate regulation of renin and blood pressure in 45-kb human renin/human angiotensinogen transgenic mice

The renin-angiotensin system is normally subject to servo control mechanisms that suppress plasma renin levels in response to increased blood pressure and increase plasma renin levels when blood pressure falls. In most species, renin is rate limiting, and angiotensinogen circulates at a concentration close to the Km, so varying the concentration of either can affect the rate of angiotensin formation. However, only the plasma renin level responds to changes in blood pressure and sodium balance to maintain blood pressure homeostasis. Therefore, the high plasma human renin levels and the hypertension of mice and rats containing both human renin and angiotensinogen transgenes indicate inappropriate regulation of renin and blood pressure. These anomalies led us to develop new lines of transgenic mice with a longer human renin gene fragment (45 kb) than earlier lines (13 to 15 kb). Unlike their predecessors, the 45-kb hREN mice secrete human renin only from the kidneys, and both the human and mouse renins respond appropriately to physiological stimuli. To determine whether blood pressure is also regulated appropriately, we crossed these new 45-kb hREN mice with mice containing the human angiotensinogen gene. All doubly transgenic mice were normotensive like their singly transgenic and nontransgenic littermates. Moreover, among doubly transgenic mice, both human and mouse plasma renin concentrations were suppressed relative to the singly transgenic 45-kb hREN mice. These findings demonstrate the importance of appropriate cell and tissue specificity of gene expression in constructing transgenic models and affirm the pivotal role played by renal renin secretion in blood pressure control.

Hypertension-induced end-organ damage : A new transgenic approach to an old problem

Angiotensin (Ang) II-induced organ damage has fascinated students of hypertension since the work of Wilson and Byrom. We are investigating a double transgenic rat (dTGR) model, in which rats transgenic for the human angiotensinogen and renin genes are crossed. These rats develop moderately severe hypertension but die of end-organ cardiac and renal damage by week 7. The heart shows necrosis and fibrosis, whereas the kidneys resemble the hemolytic-uremic syndrome vasculopathy. Surface adhesion molecules (ICAM-1 and VCAM-1) are expressed early on the endothelium, while the corresponding ligands are found on circulating leukocytes. Leukocyte infiltration in the vascular wall accompanies PAI-1, MCP-1, and VEGF expression. The expression of TGF-beta and deposition of extracellular matrix proteins follows, which is accompanied by fibrinoid vasculitis in small vessels of the heart and kidneys. Angiotensin-converting enzyme inhibitors and AT1 receptor blockers each lowered blood pressure and shifted pressure natriuresis partially leftward by different mechanisms. When combined, they normalized blood pressure, pressure natriuresis, and protected from vasculopathy completely. Renin inhibition lowered blood pressure partially, but protected from vasculopathy completely. Endothelin receptor blockade had no influence on blood pressure but protected from vasculopathy and improved survival. We show evidence that Ang II stimulates oxidative stress directly or indirectly via endothelin 1 and that NFkappaB is upregulated in this model. We speculate that the transcription factors NFkappaB and AP-1 are involved with initiating chemokine and cytokine expression, leading to the above cascade. The unique model and our pharmacological probes will enable us to test these hypotheses.

Kidney is the only source of human plasma renin in 45-kb human renin transgenic mice

Prorenin is expressed in certain extrarenal tissues, but normally only the kidneys process prorenin to renin and secrete renin into the circulation. Although transgenic animal lines containing the human renin (hREN) structural gene with either 0.9-kb or 3-kb 5'-flanking DNA express the transgene appropriately in renal juxtaglomerular cells and secrete hREN into the circulation, the source of the circulating renin is not known. In the present study, we observed that 13-kb hREN transgenic mice that contain the structural gene and 0.9-kb 5'-flanking DNA express hREN mRNA in many unusual tissues. We also observed that circulating hREN levels in 13-kb hREN mice increased after bilateral nephrectomy. These results suggested that the hREN gene is expressed at inappropriate locations where prorenin might be processed to renin. To determine if more distal sequences flanking the hREN gene might contribute to cell and tissue specificity, we used a 45-kb hREN genomic fragment that contained the structural gene and about 25-kb 5'- and 8-kb 3'-flanking DNA sequences to generate 3 separate transgenic lines that contained the intact transgene sequences. Ribonuclease protection assays revealed a much narrower tissue distribution of hREN expression than in the 13-kb hREN transgenic mice. In each 45-kb hREN line, hREN mRNA was present only in the kidney, adrenal, lung, eye, ovary, and brain. Moreover, 24 hours after nephrectomy, human plasma renin fell to very low levels, indistinguishable from those of nontransgenic littermates, indicating that their circulating hREN is of renal origin. These studies suggest that sequences flanking the structural gene, missing from previous hREN transgenic lines, suppress renin gene expression at inappropriate extrarenal sites where cellular proteases, to which prorenin is not normally exposed, could convert prorenin to renin, resulting in abnormal secretion of renin into the plasma.

The brain renin-angiotensin system contributes to the hypertension in mice containing both the human renin and human angiotensinogen transgenes

We have previously shown that mice transgenic for both the human renin and human angiotensinogen genes (RA+) exhibit appropriate tissue- and cell-specific expression of both transgenes, have 4-fold higher plasma angiotensin II (AII) levels, and are chronically hypertensive. However, the relative contribution of circulating and tissue-derived AII in causing hypertension in these animals is not known. We hypothesized that the brain renin-angiotensin system contributes to the elevated blood pressure in this model. To address this hypothesis, mean arterial pressure (MAP) and heart rate were measured in conscious, unrestrained mice after they were instrumented with intracerebroventricular cannulae and carotid arterial and jugular vein catheters. Intracerebroventricular administration of the selective AII type 1 (AT-1) receptor antagonist losartan (10 microgram, 1 microL) caused a significantly greater peak fall in MAP in RA+ mice than in nontransgenic RA- controls (-29+/-4 versus -4+/-2 mm Hg, P<0.01). To explore the mechanism of a central renin-angiotensin system-dependent hypertension in RA+ mice, we determined the relative depressor responses to intravenous administration of the ganglionic blocking agent hexamethonium (5 mg/kg) or an arginine vasopressin (AVP) V1 receptor antagonist (AVPX, 10 microgram/kg). Hexamethonium caused equal lowering of MAP in RA+ mice and controls (-46+/-3 versus -52+/-3, P>0.05), whereas AVPX caused a significantly greater fall in MAP in RA+ compared with RA- mice (-24+/-2 versus -6+/-1, P<0.01). Consistent with this was the observation that circulating AVP was 3-fold higher in RA+ mice than in control mice. These results suggest that increased activation of central AT-1 receptors, perhaps those located at sites involved in AVP release from the posterior pituitary gland, plays a role in the hypertension in RA+ mice. Furthermore, our finding that both human transgenes are expressed in brain regions of RA+ mice known to be involved in cardiovascular regulation raises the possibility that augmented local production of AII and increased activation of AT-1 receptors at these sites is involved.

Chronic sodium balance and blood pressure response to captopril in conscious mice

The influence of chronic administration of the converting enzyme inhibitor captopril on blood pressure and sodium balance was evaluated in conscious Swiss Webster mice. Arterial pressure was measured with chronic indwelling catheters, and sodium balance was determined by infusing sodium intravenously in isotonic saline and collecting urine 24 h/d. Experiments to validate sodium balance measurements in mice demonstrated recovery of 100+/-3% of sodium intake under steady-state conditions (n=20 mice on 70 individual days, sodium intake range 160 to 1000 micromol/d). It was further demonstrated that mean arterial pressure, heart rate, and body weight were unaltered from 115+/-7 mm Hg, 646+/-12 bpm, and 34+/-0.6 g, respectively, as sodium intake was increased stepwise from 150 to 900 micromol NaCl per day. An additional validation group (n=7) demonstrated that daily and cumulative sodium balance can be accurately determined during and after the intravenous administration of an agent known to alter renal sodium handling (furosemide 50 mg. kg-1. d-1). Experiments were then performed to examine the influence of intravenous captopril infusion (40 mg. kg-1. d-1, n=7) in mice in which the daily sodium intake was fixed at approximately 200 micromol/d. This dose of captopril was determined to significantly decrease the pressor response to a 10-ng bolus of angiotensin I (Ang I) from 24+/-5 in the control state to 6+/-2 mm Hg (n=5). After 5 days of infusion of the converting enzyme inhibitor, mean arterial pressure significantly fell from 114+/-3 to 58+/-2 mm Hg, body weight significantly decreased from 36+/-1 to 33+/-1 g, and cumulative sodium balance significantly decreased to -270+/-55 micromol. These parameters returned toward control during 5 postcontrol days. Results of this study demonstrate that accurate sodium balance measurements can be obtained from individual conscious mice over a 5-fold range of sodium intake. The experiments also indicate that converting enzyme inhibition has a potent influence to lower blood pressure in normal mice; the hypotensive response appears to be due in part to increased urinary sodium excretion.

Renal sympathetic nerve activity in mice: comparison between mice and rats and between normal and endothelin-1 deficient mice

Recently generated knockout mice with disrupted genes encoding endothelin (ET)-1 showed an elevation of arterial blood pressure (AP) and supplied an evidence for intrinsic ET-1 as one of the physiological regulators of systemic AP. Little is yet known, however, why deficiency of ET-1, which was originally found as a potent vasoconstrictor, led to higher AP in these mice. To address this apparent paradox, we first developed a method to measure renal sympathetic nerve activity (RSNA) in mice using rats as reference and successively compared it between normal and ET-1 deficient mice. RSNA was successfully recorded in urethane-anesthetized and artificially ventilated mice by a slight modification of the method used for rats. At basal condition, mean AP (MAP) and RSNA in ET-1 deficient mice (105+/-2 mmHg and 9.71+/-1.49 muVs, n=20) were significantly higher than those in wild-type mice (96+/-2 mmHg and 5. 07+/-0.70 muVs, n=25). Basal heart rate (HR) and baroreflex-control of HR was not significantly different between the two. On the other hand, resting RSNA, RSNA range, and maximum RSNA were significantly greater in ET-1 deficient mice, and thus MAP-RSNA relationship was upwards reset. Hypoxia-induced increase in RSNA was not different between ET-1 deficient (73.4+/-9.4%) and wild-type mice (91.2+/-12.0%), while hypercapnia-induced one was significantly attenuated in ET-1 deficient mice (18.8+/-3.6 vs. 39.1+/-5.2% at 10% CO2). These results indicate that endogenous ET-1 participates in the central chemoreception of CO2 and reflex control of the RSNA. Baroreceptor resetting and normally preserved hypoxia-induced chemoreflex may explain a part of the elevation of AP in ET-1 deficient mice.

Transgenic animal models for the functional analysis of vasoactive peptides

The interplay of vasoactive peptide systems is an essential determinant of blood pressure regulation in mammals. While the endothelin and the renin-angiotensin systems raise blood pressure by inducing vasoconstriction and sodium retention, the kallikrein-kinin and the natriuretic-peptide systems reduce arterial pressure by eliciting vasodilatation and natriuresis. Transgenic technology has proven to be very useful for the functional analysis of vasoactive peptide systems. As an outstanding example, transgenic rats overexpressing the mouse Ren-2 renin gene in several tissues become extremely hypertensive. Several other transgenic rat and mouse strains with genetic modifications of components of the renin-angiotensin system have been developed in the past decade. Moreover, in recent years gene-targeting technology was employed to produce mouse strains lacking these proteins. The established animal models as well as the main insights gained by their analysis are summarized in this review.

Transgenesis and Gene Targeting in the Mouse

As more effort is made to identify genes responsible for hypertension in human populations and genetically hypertensive animal models, the need for experimental systems in which the functional significance of genes, gene variants, and quantitative trait loci (QTL) can be determined is becoming increasingly important. Over the past five years, transgenic and gene-targeting technology has been utilized to study the cardiovascular effects of over-expression or ablation of genes which have been considered candidates in the genetic basis of hypertension. This review focuses on the most recent major advances in this area, and how this technology aids in our understanding of the molecular mechanisms by which newly discovered genes or gene variants affect blood pressure in the whole organism. We also discuss the potential use of transgenic models in refining the location of a QTL, and discuss some of the limitations and potential pitfalls in the application of these tools to the field of hypertension research. The coupling of genetic manipulations afforded by transgenesis and gene targeting, along with advances in our ability to assess the cardiovascular phenotype in the mouse, provides us with a powerful system for examining the genes responsible for causing essential hypertension.

Appropriate regulation of human renin gene expression and secretion in 45-kb human renin transgenic mice

To create physiological models of the human renin-angiotensin system in transgenic animals, the component genes should be expressed in the correct tissues and cells and respond appropriately to physiological stimuli. We recently showed that mice carrying a 45-kb human renin genomic fragment, containing approximately 25 kb 5'-flanking DNA and 6 kb 3'-flanking DNA, express the transgene in a highly cell- and tissue-specific pattern. More importantly, in contrast to previous models, human renin in the circulating plasma of these mice is derived exclusively from the kidneys. In the present study, we tested the responses of both human and mouse renal renin expression and secretion of the 45-kb hREN transgenic mice to a variety of physiological and pharmacological stimuli. A sodium-deficient diet, angiotensin-converting enzyme inhibition, and beta1-adrenergic stimulation each increased both human and mouse plasma renin concentration significantly, whereas elevated blood pressure and/or increased plasma angiotensin II levels suppressed them. Human and mouse renal renin mRNA levels changed similarly but to a lesser degree. These studies demonstrate that human renin synthesis and secretion respond appropriately in 45-kb hREN mice to physiological stimuli. This most likely results from appropriate cell-specific expression of the transgene conferred by the extended transgene flanking sequences.

Disruption of the dopamine D3 receptor gene produces renin-dependent hypertension

Since dopamine receptors are important in the regulation of renal and cardiovascular function, we studied the cardiovascular consequences of the disruption of the D3 receptor, a member of the family of D2-like receptors, expressed in renal proximal tubules and juxtaglomerular cells. Systolic and diastolic blood pressures were higher (approximately 20 mmHg) in heterozygous and homozygous than in wild-type mice. An acute saline load increased urine flow rate and sodium excretion to a similar extent in wild-type and heterozygous mice but the increase was attenuated in homozygous mice. Renal renin activity was much greater in homozygous than in wild-type mice; values for heterozygous mice were intermediate. Blockade of angiotensin II subtype-1 receptors decreased systolic blood pressure for a longer duration in mutant than in wild-type mice. Thus, disruption of the D3 receptor increases renal renin production and produces renal sodium retention and renin-dependent hypertension.

Developmental expression of human angiotensinogen in transgenic mice

Transgenic mice containing the human angiotensinogen (HAGT) gene were utilized to determine the developmental regulation of HAGT expression. RNase protection assay on total RNA obtained from whole transgenic fetuses revealed that HAGT expression was first detected at embryonic day 8.5 (E8.5) and was abundant from E9.5 onward. The earliest expression of the HAGT transgene appeared to precede the earliest expression of the endogenous mouse AGT gene by 1-2 days. Northern blot analysis revealed moderate levels of HAGT mRNA in liver and kidney and low levels of HAGT mRNA in heart and brain from E16.5 (day 16.5 of gestation) onward. HAGT mRNA in liver, although abundant during late gestation and in 2-wk-old and adult mice, decreased transiently around birth. In situ hybridization performed on sections from whole fetuses revealed that HAGT mRNA was restricted to the developing liver and heart between E9.5 and E11.5 but became more widespread to include the developing aorta, brain, subcutaneous tissues, and vertebra at E13.5. In situ hybridization analysis on fetal kidneys from late gestation, newborn, and 2-wk-old mice demonstrated a progressive restriction of HAGT mRNA to developing cortical proximal tubular cells. These data illustrate the developmental tissue-specific regulation of HAGT expression and demonstrate that sequences present in the transgene can confer an appropriate developmental expression profile.

Regulatory elements required for human angiotensinogen expression in HepG2 cells are dispensable in transgenic mice

Previous researchers have identified two sequences present upstream (angiotensinogen gene-activating element [AGE2]) and downstream (d61-2) of the human angiotensinogen gene that act as cell-specific enhancers of transcription in transiently transfected HepG2 cells. To examine the importance of these two sequences in regulating tissue- and cell-specific expression of the gene in vivo, we generated transgenic mice containing the mutations in the context of a genomic transgene previously shown to exhibit appropriate tissue and cell specificity. The ability of these sequences to enhance transcription of a basal human angiotensinogen promoter was confirmed in transient transfection assays in HepG2 cells, and mutations within the AGE2 and d61-2 sequences abolished transactivation of the promoter. Tissue- and cell-specific expression was examined in three lines of transgenic mice carrying the d61-2 mutation, two lines of transgenic mice carrying the AGE2 mutation, and three founder transgenic mice carrying a double-mutant construct. Although the absolute levels of expression varied among lines, the pattern of tissue-specific expression was essentially unaltered by the mutations. In situ hybridization confirmed that the mutations were also dispensable for proximal tubule-specific expression within the kidney. Finally, a comparison of transgene expression with transgene copy number revealed a direct proportionality in liver (R=.77, P=.0014) and kidney (R=.76, P=.0024). These results clearly demonstrate that these sites, which strongly induce promoter activity in cells in culture, are not required for appropriate expression of the gene when present in a genomic construct in vivo.

Long-term measurement of arterial blood pressure in conscious mice

This study describes a technique for the direct daily measurement of arterial blood pressure, sampling of arterial blood, and continuous intravenous infusion in free-moving, conscious, Swiss-Webster mice. Catheters were chronically implanted in the femoral artery and vein, tunneled subcutaneously, exteriorized at the back of the neck in a lightweight tethering spring, and attached to a swivel device at the top of the cage. Time-control experiments (n = 8) demonstrated stable values of mean arterial pressure (MAP, 116 +/- 1 mmHg) and heart rate (HR, 627 +/- 21 beats/min) for up to 35 days after catheter implantation. It was further observed that restraining mice (n = 7) increased MAP by 10 +/- 3 mmHg and HR by 78 +/- 8 beats/min from the values observed under free-moving conditions. To demonstrate the chronic use of the venous catheter, intravenous infusion of NG-nitro-L-arginine methyl ester (L-NAME, 8.6 mg.kg-1.day-1, n = 6) for 5 days significantly increased MAP from 117 +/- 4 to 131 +/- 4 mmHg without altering HR. In a final group of mice (n = 5), oral L-arginine (2% in drinking water) increased plasma arginine concentration from 90 +/- 7 to 131 +/- 17 microM and prevented L-NAME hypertension. These experiments illustrate the feasibility of long-term intravenous infusion, direct arterial blood pressure measurements, and arterial blood sampling in conscious mice.

Regulation of the cerebral circulation: role of endothelium and potassium channels

Several new concepts have emerged in relation to mechanisms that contribute to regulation of the cerebral circulation. This review focuses on some physiological mechanisms of cerebral vasodilatation and alteration of these mechanisms by disease states. One mechanism involves release of vasoactive factors by the endothelium that affect underlying vascular muscle. These factors include endothelium-derived relaxing factor (nitric oxide), prostacyclin, and endothelium-derived hyperpolarizing factor(s). The normal vasodilator influence of endothelium is impaired by some disease states. Under pathophysiological conditions, endothelium may produce potent contracting factors such as endothelin. Another major mechanism of regulation of cerebral vascular tone relates to potassium channels. Activation of potassium channels appears to mediate relaxation of cerebral vessels to diverse stimuli including receptor-mediated agonists, intracellular second messenger, and hypoxia. Endothelial- and potassium channel-based mechanisms are related because several endothelium-derived factors produce relaxation by activation of potassium channels. The influence of potassium channels may be altered by disease states including chronic hypertension, subarachnoid hemorrhage, and diabetes.

The kidney androgen-regulated protein promoter confers renal proximal tubule cell-specific and highly androgen-responsive expression on the human angiotensinogen gene in transgenic mice

Transgenic mice were generated containing a 1542-base pair fragment of the kidney androgen-regulated protein (KAP) promoter fused to the human angiotensinogen (HAGT) gene with the goal of specifically targeting inducible expression of renin-angiotensin system components to the kidney. High level expression of both KAP-HAGT and endogenous KAP mRNA was evident in the kidney of male mice from two independent transgenic lines. Renal expression of the transgene in female mice was undetectable under basal conditions but could be strongly induced by administration of testosterone. Testosterone treatment did not cause a transcriptional induction in any other tissues examined. However, an analysis of six androgen target tissues in males revealed that the transgene was expressed in epididymis. No other extra-renal expression of the transgene was detected. In situ hybridization demonstrated that expression of HAGT (and KAP) mRNA in males and testosterone-treated females was restricted to proximal tubule epithelial cells in the renal cortex. Although there was no detectable human angiotensinogen protein in plasma, it was evident in the urine, consistent with a pathway of synthesis in proximal tubule cells and release into the tubular lumen. These results demonstrate that 1542 base pairs of the KAP promoter is sufficient to drive expression of a heterologous reporter gene in a tissue-specific, cell-specific, and androgen-regulated fashion in transgenic mice.

Complementation of reduced survival, hypotension, and renal abnormalities in angiotensinogen-deficient mice by the human renin and human angiotensinogen genes

The aim of this study was to determine whether elements of the human renin-angiotensin system (RAS) could functionally replace elements of the mouse RAS by complementing the reduced survival and renal abnormalities observed in mice carrying a gene-targeted deletion of the mouse angiotensinogen gene (mAgt). Double transgenic mice containing the human renin (HREN) and human angiotensinogen (HAGT) genes were bred to mice heterozygous for the mAgt deletion and the compound heterozygotes were identified and intercrossed. The resulting progeny (n = 139) were genotyped at each locus and the population was stratified into two groups: the first containing both human transgenes (RA+) and the second containing zero or one, but not both human transgenes (RA-). Despite appropriate Mendelian ratios of RA- mice that were wildtype (+/+), heterozygous (+/-), and homozygous (-/-) for the deletion of mAgt at birth, there was reduced survival of RA- mAgt-/- mice to adulthood (P < 0.001 by chi2). In contrast, we observed appropriate Mendelian ratios of RA+ mAgt+/+, RA+ mAgt+/-, and RA+ mAgt-/- mice at birth and in adults (P > 0.05 by chi2). These results demonstrate that the presence of both human transgenes rescues the postnatal lethality in mAgt-/- mice. The renal histopathology exhibited by RA- mAgt-/- mice, including thickened arterial walls, severe fibrosis, lymphocytic infiltration, and atrophied parenchyma, was also rescued in the RA+ mAgt-/- mice. Direct arterial blood pressure recordings in conscious freely moving mice revealed that BP (in mmHg) varied proportionally to mAgt gene copy number in RA+ mice (approximately 20 mmHg per mAgt gene copy, P < 0.001). BP in RA+ mAgt-/- mice (132+/-3, n = 14) was intermediate between wild-type (RA- mAgt+/+, 105+/-2, n = 9) and RA+ mAgt+/+ (174+/-3, n = 10) mice. These studies establish that the human renin and angiotensinogen genes can functionally replace the mouse angiotensinogen gene, and provides proof in principle that we can examine the regulation of elements of the human RAS and test the significance of human RAS gene variants by a combined transgenic and gene targeting approach.

High human renin hypertension in transgenic rats

We developed a model of spontaneously high human renin hypertension in the rat by producing two transgenic strains, one for human angiotensinogen with the endogenous promoter and one for human renin with the endogenous promoter. Neither transgenic strain was hypertensive. These strains were then crossed, producing a double transgenic strain. The double transgenic rats, both males and females, developed severe hypertension (mean systolic pressure, 200 mm Hg) and died after a mean of 55 days if untreated. The rats had a human plasma renin concentration of 269 +/- 381 (+/-SD) ng angiotensin I (Ang I)/mL per hour, plasma renin activity of 177 +/- 176 ng Ang I/mL per hour, rat angiotensinogen concentration of 1.49 +/- 1 microgram Ang I/mL, and human angiotensinogen concentration of 78 +/- 39 micrograms Ang I/mL (n = 49). Control rats had plasma renin activity of 3.7 +/- 3.9 ng Ang I/mL per hour and rat angiotensinogen of 1.32 +/- 0.16 micrograms Ang I/mL. Angiotensinogen transgene expression by RNase protection assay was ubiquitously present but most prominent in liver. Renin transgene expression was high in kidney but absent in liver. The rats featured severe cardiac hypertrophy, with increased cross section of cardiomyocytes but little myocardial fibrosis. The kidneys showed atrophic tubules, thickened vessel walls, and increased interstitium. Both the angiotensin-converting enzyme inhibitor lisinopril and the specific human renin inhibitor remikiren lowered blood pressure to normal values. Double transgenic mice have been developed that exhibit features quite similar to those described here; their gene expressions are similar. The specificity of rodent and human renin is similarly documented. Although many elegant physiological studies can now be done in mice, rats nevertheless offer flexibility, particularly in terms of detailed cardiac and renal physiology and pharmacology. We conclude that this double transgenic strain will facilitate simultaneous investigation of genetic and pathophysiological aspects of renin-induced hypertension. The fact that human renin can be studied in the rat is a unique feature of this model.

Regulation of human renin mRNA expression and protein release in transgenic mice

The renin-angiotensin system plays a major role in the regulation of blood pressure and electrolyte homeostasis in mammals. In this study, we subjected transgenic mice containing a human renin genomic construct to a variety of pharmacological and physiological manipulations to test whether expression of the human renin gene and release of active human renin in appropriately regulated in this model. These manipulations were designed to test major regulators of renin release, including angiotensin II, the macula densa, renal perfusion pressure, and beta-adrenergic receptors. We used human plasma renin concentration and human renal renin mRNA levels to document the response of the transgene to these stimuli. Human plasma renin concentration increased in response to both angiotensin-converting enzyme inhibition with captopril and isoproterenol and decreased after a high salt diet. A low salt or sodium-deficient diet did not stimulate renin release. Human renin mRNA levels in kidney increased after captopril but were unchanged in the other experimental groups. We also measured the levels of human renin mRNA in double transgenic mice containing the same human renin gene in addition to the human angiotensinogen gene. These mice are chronically hypertensive and have increased circulating levels of angiotensin II. Human renin mRNA levels in the kidney were paradoxically elevated compared with their single transgenic normotensive counterparts. These transgenic mice provide a model for examination of human renin regulation and may help elucidate the molecular mechanisms that regulate the gene in response to physiological cues.