Expression of components of the renin-angiotensin system in autosomal recessive polycystic kidney disease.

Hypertension is a common complication in children with autosomal recessive polycystic kidney disease (ARPKD) who have survived the neonatal period. No information is available regarding the mechanism of hypertension in this condition. The renin-angiotensin system (RAS) is thought to play a role in hypertension associated with the more common autosomal dominant polycystic kidney disease (ADPKD). Occasional reports have documented increased activity of the intrarenal RAS in ADPKD, with ectopic renin expression within cysts and dilated tubules. Because of similarities between ARPKD and ADPKD, we hypothesized that increased intrarenal RAS activity might also be found in ARPKD. We performed immunohistochemical studies on kidney tissues from two infants with ARPKD and two control kidneys. The cystic dilated tubules showed staining with the peanut lectin arachis hypogaea, a marker of distal tubules and collecting ducts, but not with lotus tetragonolobus, a marker of proximal tubules. Strong renin staining was seen in many cysts and tubules of ARPKD kidneys, but only in the afferent arterioles of the normal control kidneys. Angiotensinogen staining was also observed in some cysts and in proximal tubules. Staining for angiotensin-converting enzyme, angiotensin II type 1 receptor, and angiotensin II peptide was present in many cystic dilated tubules. These immunohistochemical studies document for the first time ectopic expression of components of the RAS in cystic-dilated tubules of ARPKD and suggest that overactivity of RAS could result in increased intrarenal angiotensin II production, which may contribute to the development of hypertension in ARPKD.     

Pressor responsiveness in renal prehypertensive rabbits with a denervated kidney

Norepinephrine was infused iv at several doses into four groups of conscious rabbits (six per group), and the pressor responses were recorded. The groups were 3-day sham-operated rabbits; 3-day, two-kidney rabbits with unilateral renal artery stenosis (RAS); 3-day, two-kidney rabbits with unilateral renal denervation; and 3-day, two-kidney rabbits with unilateral renal denervation plus RAS of the denervated kidney. The rabbits with RAS of an innervated kidney and those with RAS of a denervated kidney had the same pressor responses to norepinephrine, which were greater than the pressor responses in the sham-operated rabbits or in the rabbits with a denervated kidney but without RAS. Four additional groups of similarly prepared rabbits were infused with norepinephrine at 800 ng/min/kg body wt, and mean arterial pressure and cardiac output were determined before and during norepinephrine infusion. The rabbits with RAS of an innervated or of a denervated kidney had greater increases in total peripheral resistance as well as in mean arterial pressure during norepinephrine infusion than did the two groups of rabbits without RAS. This indicated that the rabbits with RAS also had increased vascular responses to norepinephrine. The concentration of norepinephrine in six denervated kidneys was extremely low as compared to that of six innervated kidneys. Because renal denervation did not diminish pressor and vascular hyperresponsiveness in 3-day RAS rabbits, the signal that originates in the kidney following RAS and that results ultimately in pressor and vascular hyperresponsiveness is not mediated by renal nerves.     

High Na intake increases renal angiotensin II levels and reduces expression of the ACE2-AT(2)R-MasR axis in obese Zucker rats

High sodium intake is known to regulate the renal renin-angiotensin system (RAS) and is a risk factor for the pathogenesis of obesity-related hypertension. The complex nature of the RAS reveals that its various components may have opposing effects on natriuresis and blood pressure regulation. We hypothesized that high sodium intake differentially regulates and shifts a balance between opposing components of the renal RAS, namely, angiotensin-converting enzyme (ACE)-ANG II-type 1 ANG II receptor (AT(1)R) vs. AT(2)-ACE2-angiotensinogen (Ang) (1-7)-Mas receptor (MasR), in obesity. In the present study, we evaluated protein and/or mRNA expression of angiotensinogen, renin, AT(1A/B)R, ACE, AT(2)R, ACE2, and MasR in the kidney cortex following 2 wk of a 8% high-sodium (HS) diet in lean and obese Zucker rats. The expression data showed that the relative expression pattern of ACE and AT(1B)R increased, renin decreased, and ACE2, AT(2)R, and MasR remained unaltered in HS-fed lean rats. On the other hand, HS intake in obese rats caused an increase in the cortical expression of ACE, a decrease in ACE2, AT(2)R, and MasR, and no changes in renin and AT(1)R. The cortical levels of ANG II increased by threefold in obese rats on HS compared with obese rats on normal salt (NS), which was not different than in lean rats. The HS intake elevated mean arterial pressure in obese rats (27 mmHg) more than in lean rats (16 mmHg). This study suggests that HS intake causes a pronounced increase in ANG II levels and a reduction in the expression of the ACE2-AT(2)R-MasR axis in the kidney cortex of obese rats. We conclude that such changes may lead to the potentially unopposed function of AT(1)R, with its various cellular and physiological roles, including the contribution to the pathogenesis of obesity-related hypertension.     

Expression of the renin angiotensin system genes in the kidney and heart of ISIAH hypertensive rats

The content of mRNA of renin-angiotensin system (RAS) genes was measured in the kidney and heart of hypertensive ISIAH and normotensive WAG rats using the real-time PCR. A statistically significant decrease in the mRNA level of RAS genes was registered in the kidney of ISIAH rats, including Ren (by 45%), Ace (43%), AT1A (34%), COX-2 (50%). The level of myocardial expression of AT1A decreased by 28% while Ace expression increased by 80%. These results suggest reduction of renal RAS basal activity in the hypertensive ISIAH rats, and therefore this strain of rats may be referred to the group of models of low-renin hypertension. The ISIAH rats were also characterized by a two-fold increase in the connective tissue sodium concentration and also by a small (but statistically significant) increase in plasma sodium concentration (139 ± 0.3 mmol/l versus 136 ± 0.25 mmol/l in WAG rats). These results together with a tendency to a decrease of plasma aldosterone level also support existence of a classical low-renin hypertension in the ISIAH rats. It is suggested that altered function of renal ion channels represents a basis for the development of low renin hypertension in the ISIAH rats. In addition, impairments in renal system of NO synthesis may also contribute to the pathogenesis of arterial hypertension in the ISIAH rats.     

A fluorogenic near-infrared imaging agent for quantifying plasma and local tissue renin activity in vivo and ex vivo

The renin-angiotensin system (RAS) is well studied for its regulation of blood pressure and fluid homeostasis, as well as for increased activity associated with a variety of diseases and conditions, including cardiovascular disease, diabetes, and kidney disease. The enzyme renin cleaves angiotensinogen to form angiotensin I (ANG I), which is further cleaved by angiotensin-converting enzyme to produce ANG II. Although ANG II is the main effector molecule of the RAS, renin is the rate-limiting enzyme, thus playing a pivotal role in regulating RAS activity in hypertension and organ injury processes. Our objective was to develop a near-infrared fluorescent (NIRF) renin-imaging agent for noninvasive in vivo detection of renin activity as a measure of tissue RAS and in vitro plasma renin activity. We synthesized a renin-activatable agent, ReninSense 680 FAST (ReninSense), using a NIRF-quenched substrate derived from angiotensinogen that is cleaved specifically by purified mouse and rat renin enzymes to generate a fluorescent signal. This agent was assessed in vitro, in vivo, and ex vivo to detect and quantify increases in plasma and kidney renin activity in sodium-sensitive inbred C57BL/6 mice maintained on a low dietary sodium and diuretic regimen. Noninvasive in vivo fluorescence molecular tomographic imaging of the ReninSense signal in the kidney detected increased renin activity in the kidneys of hyperreninemic C57BL/6 mice. The agent also effectively detected renin activity in ex vivo kidneys, kidney tissue sections, and plasma samples. This approach could provide a new tool for assessing disorders linked to altered tissue and plasma renin activity and to monitor the efficacy of therapeutic treatments.     

Increased oxidative stress, the renin-angiotensin system, and sympathetic overactivation induce hypertension in kidney androgen-regulated protein transgenic mice

Gender differences in the incidence and severity of hypertension have suggested the involvement of a sex-dependent mechanism. Transgenic (Tg) mice overexpressing kidney androgen-regulated protein (KAP) specifically in kidney showed hypertension associated with oxidative stress. Reactive oxygen species (ROS) are strongly implicated in the pathological signaling leading to hypertension in a framework that includes renin-angiotensin system (RAS) activation, increased sympathetic activity, and cardiac remodeling. In this report, we observed that plasma levels of angiotensin II and catecholamines were increased in KAP Tg mice, compared with wild-type animals. Systemic administration of Tempol, a membrane-permeative superoxide dismutase mimetic, reduced arterial pressure as well as urinary excretion of oxidative stress markers and reduced both angiotensin II and norepinephrine plasma levels in KAP Tg mice. Intracerebroventricular administration of Tempol also reduced arterial pressure in Tg mice. Moreover, administration of apocynin and DPI, inhibitors of NADPH oxidase, a major source of ROS, also reduced arterial pressure and both angiotensin II and norepinephrine plasma levels in Tg mice. Thus, we analyzed the involvement of the RAS and sympathetic nervous system in KAP Tg mouse hypertension. Both captopril and losartan reduced arterial blood pressure in Tg mice, as also occurred after β-adrenergic blockade with atenolol. Also, intracerebroventricular losartan administration reduced arterial pressure in KAP Tg mice. Our data demonstrate that hypertension in male KAP Tg mice is based on increased oxidative stress, increased sympathetic activity, and RAS activation. Moreover, our results suggest a role for increased oxidative stress in the CNS as a major cause of hypertension in these animals.     

Regulation of arterial pressure: role of pressure natriuresis and diuresis

The importance of the renal pressure natriuresis and diuresis mechanisms in long-term control of body fluid volumes and arterial pressure has been controversial and difficult to quantitate experimentally. Recent studies, however, have demonstrated that in several forms of chronic hypertension caused by aldosterone, angiotensin II (AngII), vasopressin, or norepinephrine and adrenocorticotropin, increased renal arterial pressure is essential for maintaining normal excretion of sodium and water in the face of reduced renal excretory capability. When renal arterial pressure was servo-controlled in these models of hypertension, sodium and water retention continued unabated, causing ascites, pulmonary edema, or even complete circulatory collapse within a few days. Apparently, other mechanisms for volume homeostasis, such as the various natriuretic and diuretic factors that have been postulated, are not sufficiently powerful to maintain fluid balance in the absence of increased renal arterial pressure when renal excretory function is reduced in these forms of hypertension. The intrarenal mechanisms responsible for pressure natriuresis and diuresis are not entirely clear, but they seem to involve small increases in glomerular filtration rate and filtered load as well as reductions in fractional reabsorption in proximal and distal tubules. During chronic disturbances of arterial pressure additional factors, especially changes in AngII and aldosterone formation, act to amplify the effectiveness of the basic renal pressure natriuresis and diuresis mechanisms in regulating arterial pressure and body fluid volumes.     

Pressor and vascular responsiveness in renal prehypertensive rabbits with a nonfiltering kidney

This study examined the possibility that the renal tubules are the site of the sensors that respond to renal artery stenosis (RAS) and which initiate the events leading to pressor hyperresponsiveness. A nonfiltering kidney (NFK) was produced in 32 rabbits by 2 hr of total renal ischemia plus permanent ligation of the ureter; the opposite kidney remained undisturbed. Sixteen of these rabbits also received RAS of the NFK. An additional 16 rabbits received RAS without production of a NFK, and 16 more rabbits were sham-operated controls. In acute experiments 3 days later in conscious rabbits, infusions of norepinephrine at several doses resulted in greater increases in mean arterial pressure in the RAS rabbits, with filtering kidneys (2-K, 1-clip) and with NFKs (2-K, 1-clip with NFK), than in the NFK rabbits without RAS (2-K control with NFK) or in the control rabbits (2-K control). Measurements of cardiac output revealed greater increases in total peripheral resistance as well as in mean arterial pressure in response to norepinephrine in the RAS rabbits both without and with a NFK. Because production of a NFK in rabbits did not prevent the development of pressor and vascular hyperresponsiveness 3 days after RAS, these studies indicated that the renal sensors that detect changes in the kidney following RAS and which initiate the series of events leading to pressor and vascular hyperresponsiveness, probably are not located in the renal tubules.     

Renal nerves and experimental hypertension: evidence and controversy

Noradrenergic fibers innervate various parts of the nephron and can contribute to sodium and water homeostasis by influencing hemodynamic variables, tubular reabsorptive mechanisms, and renin release. As renal function is considered to be a primary determinant of arterial pressure, efferent renal nerves may be an important link between the central nervous system and the kidney in the development and maintenance of hypertension. Little is known about the relative importance of renal nerves and their interactions with other factors in influencing renal function chronically. There is disagreement about the evidence for enhanced noradrenergic drive to the kidney in hypertensive rats, as the renal nerve firing rate, neurotransmitter release and metabolism, and receptor properties are generally not studied in association with measurements of renal function. However, chronic renal denervation has been shown to significantly affect arterial pressure in diverse forms of experimental hypertension in rats, including genetic models, as well as renovascular, mineralocorticoid, neurogenic, and angiotensin II hypertension. The actual mechanisms responsible for this effect of renal denervation are not clear, but presumably reflect changes in the arterial pressure-urinary sodium output relationship. On the whole, there is reasonable correlation between neurophysiological, biochemical, and renal denervation studies in the spontaneously hypertensive rat, suggesting that renal nerves do play a role in the onset of hypertension in these animals. The effect of renal denervation in other models of hypertension seems less clear, with recent reports showing that renal denervation does not alter the hypertensive process in renovascular, mineralocorticoid, and salt-related hypertension.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hypertension after bilateral kidney irradiation in young and adult rats

The mechanism of a rise in blood pressure after kidney irradiation is unclear but most likely of renal origin. We have investigated the role of the renin-angiotensin system and dietary salt restriction in the development of systolic hypertension after bilateral kidney irradiation in young and adult rats. Three to 12 months after a single X-ray dose of 7.5 or 12.5 Gy to both kidneys of young and adult rats, the systolic blood pressure (SBP) and plasma renin concentration (PRC) were measured regularly. A single X-ray dose of 12.5 Gy caused a moderate rise in SBP and a slight reduction in PRC in both young and adult rats. A dose of 7.5 Gy did not significantly alter the SBP or PRC during the follow-up period of 1 year. In a second experiment, the kidneys of young rats received an X-ray dose of 20 Gy. Subsequently, rats were kept on a standard diet (110 mmol sodium/kg) or a sodium-poor diet (10 mmol sodium/kg). On both diets, SBP started to rise rapidly 3 months after kidney irradiation. Sodium balance studies carried out at that time revealed an increased sodium retention in the irradiated rats compared to controls on the same diet. In rats on a low sodium intake, there was neither a delay nor an alleviation in the development of hypertension. Compared to controls, the PRC tended to be lower in irradiated rats up to 4 months after irradiation. Subsequently, malignant hypertension developed in all 20 Gy rats, resulting in pressure natriuresis, stimulating the renin-angiotensin system. Our findings indicated that hypertension after bilateral kidney irradiation was not primarily the result of an activation of the renin-angiotensin system. Although there were some indications that sodium retention played a role, dietary sodium restriction did not influence the development of hypertension.     

Historical perspective of the renin-angiotensin system

Researchers continue to be fascinated with the renin-angiotensin system (RAS) more than 100 yr after its discovery because of its powerful role in controlling sodium balance, body fluid volumes, and arterial pressure. Development of drugs that block different components of this system has led to powerful treatments for hypertension, heart failure, diabetes, and other diseases. Molecular approaches to studying this system offer new possibilities for better understanding the physiology and pathophysiology of the RAS, and for developing new therapeutic paradigms. Our challenge in the future will be to effectively utilize the technological advances that are taking place in virtually all areas of science, including the RAS, and to translate them into a better understanding of the pathophysiology and treatment of human diseases.     

Aortic and Carotid Arterial Stiffness and Epigenetic Regulator Gene Expression Changes Precede Blood Pressure Rise in Stroke-Prone Dahl Salt-Sensitive Hypertensive Rats

Multiple clinical studies show that arterial stiffness, measured as pulse wave velocity (PWV), precedes hypertension and is an independent predictor of hypertension end organ diseases including stroke, cardiovascular disease and chronic kidney disease. Risk factor studies for arterial stiffness implicate age, hypertension and sodium. However, causal mechanisms linking risk factor to arterial stiffness remain to be elucidated. Here, we studied the causal relationship of arterial stiffness and hypertension in the Na-induced, stroke-prone Dahl salt-sensitive (S) hypertensive rat model, and analyzed putative molecular mechanisms. Stroke-prone and non-stroke-prone male and female rats were studied at 3- and 6-weeks of age for arterial stiffness (PWV, strain), blood pressure, vessel wall histology, and gene expression changes. Studies showed that increased left carotid and aortic arterial stiffness preceded hypertension, pulse pressure widening, and structural wall changes at the 6-week time-point. Instead, differential gene induction was detected implicating molecular-functional changes in extracellular matrix (ECM) structural constituents, modifiers, cell adhesion, and matricellular proteins, as well as in endothelial function, apoptosis balance, and epigenetic regulators. Immunostaining testing histone modifiers Ep300, HDAC3, and PRMT5 levels confirmed carotid artery-upregulation in all three layers: endothelial, smooth muscle and adventitial cells. Our study recapitulates observations in humans that given salt-sensitivity, increased Na-intake induced arterial stiffness before hypertension, increased pulse pressure, and structural vessel wall changes. Differential gene expression changes associated with arterial stiffness suggest a molecular mechanism linking sodium to full-vessel wall response affecting gene-networks involved in vascular ECM structure-function, apoptosis balance, and epigenetic regulation.     

Activity and responsiveness of the renin-angiotensin system in the aging rat

The systemic renin-angiotensin system (RAS) is suppressed in normal aging, but the activity of the tissue RAS is not well defined. We examined the systemic and intrarenal RAS status of aging normal rats and responses to suppression and stimulation of the production of endogenous ANG II. Studies were performed in young (3 mo) and early aging (15 mo) male Sprague-Dawley rats. Angiotensin-converting enzyme inhibitors modestly decreased mean arterial pressure (MAP) in young (3 mo) and early aging (15 mo) rats and limited proteinuria in the older rats. There were no significant age-related effects on renal function or on endogenous RAS activity. Intravenous infusion of the precursor ANG I led to comparable increases in MAP in younger and older rats. In contrast, the renal effects (reduction in glomerular filtration and plasma flow rates) were exaggerated in the older animals. Intrarenal arterial ANG I did not affect MAP in any group. In young rats, there were no significant hemodynamic effects in either the ipsilateral (infused) or the contralateral (noninfused) kidney. In the older rats, both kidneys had a significant fall in renal renal plasma flow rate (RPF) with left renal arterial infusion of ANG I. Accordingly, these studies early in the course of aging found only subtle changes in the activity, responsiveness, and metabolism of the RAS. Thus early aging is associated with a modest but important increase in sensitivity to RAS stimulation.     

The extracellular cAMP-adenosine pathway regulates expression of renal D1 dopamine receptors in diabetic rats

Activation of D1 dopamine receptors expressed in the kidneys promotes the excretion of sodium and regulates sodium levels during increases in dietary sodium intake. A decrease in the expression or function of D1 receptors results in increased sodium retention which can potentially lead to the development of hypertension. Studies have shown that in the absence of functional D1 receptors, in null mice, the systolic, diastolic, and mean arterial pressures are higher. Previous studies have shown that the expression and function of D1 receptors in the kidneys are decreased in animal models of diabetes. The mechanisms that down-regulate the expression of renal D1 receptor gene in diabetes are not well understood. Using primary renal cells and acutely isolated kidneys from the streptozotocin-induced rat diabetic model, we demonstrate that the renal D1 receptor expression is down-regulated by the extracellular cAMP-adenosine pathway in vitro and in vivo. In cultures of primary renal cells, a 3 mm, 60-h cAMP treatment down-regulated the expression of D1 receptors. In vivo, we determined that the plasma and urine cAMP levels as well as the expression of 5'-ectonucleotidase, tissue-nonspecific alkaline phosphatase, and adenosine A2a receptors are significantly increased in diabetic rats. Inhibitors of 5'-ectonucleotidase and tissue-nonspecific alkaline phosphatase, α,β-methyleneadenosine 5'-diphosphate, and levamisole, respectively, blocked the down-regulation of D1 receptors in the primary renal cells and in the kidney of diabetic animals. The results suggest that inhibitors of the extracellular cAMP-adenosine pathway reverse the down-regulation of renal D1 receptor in diabetes.     

Early superoxide scavenging accelerates renal microvascular rarefaction and damage in the stenotic kidney

Renal artery stenosis (RAS), the main cause of chronic renovascular disease (RVD), is associated with significant oxidative stress. Chronic RVD induces renal injury partly by promoting renal microvascular (MV) damage and blunting MV repair in the stenotic kidney. We tested the hypothesis that superoxide anion plays a pivotal role in MV dysfunction, reduction of MV density, and progression of renal injury in the stenotic kidney. RAS was induced in 14 domestic pigs and observed for 6 wk. Seven RAS pigs were chronically treated with the superoxide dismutase mimetic tempol (RAS+T) to reduce oxidative stress. Single-kidney hemodynamics and function were quantified in vivo using multidetector computer tomography (CT) and renal MV density was quantified ex vivo using micro-CT. Expression of angiogenic, inflammatory, and apoptotic factors was measured in renal tissue, and renal apoptosis and fibrosis were quantified in tissue sections. The degree of RAS and blood pressure were similarly increased in RAS and RAS+T. Renal blood flow (RBF) and glomerular filtration rate (GFR) were reduced in the stenotic kidney (280.1 ± 36.8 and 34.2 ± 3.1 ml/min, P < 0.05 vs. control). RAS+T kidneys showed preserved GFR (58.5 ± 6.3 ml/min, P = not significant vs. control) but a similar decreases in RBF (293.6 ± 85.2 ml/min) and further decreases in MV density compared with RAS. These changes were accompanied by blunted angiogenic signaling and increased apoptosis and fibrosis in the stenotic kidney of RAS+T compared with RAS. The current study shows that tempol administration provided limited protection to the stenotic kidney. Despite preserved GFR, renal perfusion was not improved by tempol, and MV density was further reduced compared with untreated RAS, associated with increased renal apoptosis and fibrosis. These results suggest that a tight balance of the renal redox status is necessary for a normal MV repair response to injury, at least at the early stage of RVD, and raise caution regarding antioxidant strategies in RAS.     

Local and systemic renin–angiotensin system participates in cardiopulmonary–renal interactions in monocrotaline-induced pulmonary hypertension in the rat

Renin–angiotensin system (RAS) is one of the pathophysiological mechanisms in heart failure. Recently, involvement of the kidney in the disease progression has been proposed in patients with pulmonary arterial hypertension (PAH). We hypothesized that local and systemic RAS could be the central regulators of cardiopulmonary–renal interactions in experimental monocrotaline-induced pulmonary hypertension (PH) in rats. Male 12-week-old Wistar rats were injected subcutaneously with monocrotaline (60 mg/kg). The experiment was terminated 4 weeks after monocrotaline administration. Using RT-PCR, we measured the expression of RAS-related genes in right and left ventricles, lungs and kidneys, together with indicators of renal dysfunction and damage. We observed a significantly elevated expression of angiotensin-converting enzyme (ACE) in both left and right ventricles and kidneys (P < 0.05), but a significantly decreased ACE in the lungs (P < 0.05). Kidneys showed a significant 2.5-fold increase in renin mRNA (P < 0.05) along with erythropoietin, TGFβ₁, COX-2, NOS-1 and nephrin. Expression of erythropoietin correlated inversely with hemoglobin oxygen saturation and positively with renin expression. In conclusion, monocrotaline-induced PH exhibited similar alterations of ACE expression in the left and right ventricles, and in the kidney, in contrast to the lungs. Increased renal renin was likely a consequence of renal hypoxia/hypoperfusion, as was increased renal erythropoietin expression. Alterations in RAS in the monocrotaline model are probably a result of hypoxic state, and while they could serve as a compensatory mechanism at a late stage of the disease, they could be viewed also as an indicator of multiorgan failure in PAH.

     

CircNr1h4 regulates the pathological process of renal injury in salt‐sensitive hypertensive mice by targeting miR‐155‐5p

Circular RNAs are a class of widespread and diverse endogenous RNAs that may regulate gene expression in various diseases, but their regulation and function in hypertensive renal injury remain unclear. In this study, we generated ribosomal‐depleted RNA sequencing data from normal mouse kidneys and from injured mouse kidneys induced by deoxycorticosterone acetate‐salt hypertension and identified at least 4900 circRNA candidates. A total of 124 of these circRNAs were differentially expressed between the normal and injured kidneys. Furthermore, we characterized one abundant circRNA, termed circNr1h4, which is derived from the Nr1h4 gene and significantly down‐regulated in the injured kidneys. RNA sequencing data and qPCR analysis also showed many microRNAs and mRNAs, including miR‐155‐5p and fatty acid reductase 1 (Far1), were differentially expressed between the normal and injured kidney and related to circNr1h4. In vitro, the silencing of circNr1h4 or overexpression of miR‐155‐5p significantly decreased Far1 levels and increased reactive oxygen species. Mechanistic investigations indicated that circNr1h4 acts as a competing endogenous RNA for miR‐155‐5p, leading to regulation of its target gene Far1. Our study provides novel insight into the molecular mechanisms underlying kidney injury in hypertension, which will be required to develop therapeutic strategies of targeting circRNAs for hypertensive kidney injury.     

Abnormalities of sodium pump function in hypertension and the role of endogenous cardiotonic steroids.

Elevated arterial blood pressure is a common heritable susceptibility in the human population. The high penetrance of this trait in industrialized societies may be influenced by the interactions of environmental factors and common genetic variants. This review examines the role of the renal sodium pump (sodium, potassium-ATPase, NKA) in hypertension and its integration into mechanisms of body sodium balance. In particular, renal NKA provides an appealing target by which inherited factors caninfluence renal sodium reabsorption. Recent work has indicated how some such genetic mechanisms may function. In this paper, the capacity of renal NKA to integrate environmental and heritable factors to increase blood pressure are examined.     

Pressure diuresis mechanism in the control of renal function and arterial pressure

Precise knowledge of the interrelationships between arterial pressure and urinary excretion of sodium and water is crucial to understanding the long-term control of arterial pressure. Although increases in renal perfusion pressure have been known for more than 35 years to inhibit tubular reabsorption, the mechanism of this pressure diuresis response, the humoral or physical factors involved, and even the nephron segments in which the changes in tubular function occur remain relatively unknown. This review focuses on the experimental evidence that supports current hypotheses concerning the mechanism of pressure diuresis. Specifically, it examines the possibility that pressure diuresis is caused by a small increase in glomerular filtration rate, alterations in the humoral or physical factors regulating proximal tubular reabsorption, and/or inhibition of tubular reabsorption in deep nephrons secondary to changes in hemodynamics in juxtamedullary nephrons. The concept originally proposed that the kidney serves as the dominant long-term controller of arterial pressure is largely based on the assumptions that the pressure diuresis phenomenon exists and that it occurs via a nonadaptive mechanism. It has been proposed that hypertension can develop only if the relationship between arterial pressure and sodium excretion is shifted toward higher pressures. The remainder of this review examines recent evidence indicating that an abnormality in the pressure natriuresis relationship may be associated with the development of hypertension in humans and in the genetic rat models of the disease.     

Renal dopamine receptors and hypertension

Dopamine has been recognized as an important modulator of central as well as peripheral physiologic functions in both humans and animals. Dopamine receptors have been identified in a number of organs and tissues, which include several regions within the central nervous system, sympathetic ganglia and postganglionic nerve terminals, various vascular beds, the heart, the gastrointestinal tract, and the kidney. The peripheral dopamine receptors influence cardiovascular and renal function by decreasing afterload and vascular resistance and promoting sodium excretion. Within the kidney, dopamine receptors are present along the nephron, with highest density on proximal tubule epithelial cells. It has been reported that there is a defective dopamine receptor, especially D(1) receptor function, in the proximal tubule of various animal models of hypertension as well as in humans with essential hypertension. Recent reports have revealed the site of and the molecular mechanisms responsible for the defect in D(1) receptors in hypertension. Moreover, recent studies have also demonstrated that the disruption of various dopamine receptor subtypes and their function produces hypertension in rodents. In this review, we present evidence that dopamine and dopamine receptors play an important role in regulating renal sodium excretion and that defective renal dopamine production and/or dopamine receptor function may contribute to the development of various forms of hypertension.