Polymerase chain reaction analysis of renin in rat aortic smooth muscle

Cell signaling, internalization, and nuclear localization of the angiotensin converting enzyme in smooth muscle and endothelial cells

The angiotensin converting enzyme (ACE) catalyzes the extracellular formation of angiotensin II, and degradation of bradykinin, thus regulating blood pressure and renal handling of electrolytes. We have previously shown that exogenously added ACE elicited transcriptional regulation independent of its enzymatic activity. Because transcriptional regulation generates from protein-DNA interactions within the cell nucleus we have investigated the initial cellular response to exogenous ACE and the putative internalization of the enzyme in smooth muscle cells (SMC) and endothelial cells (EC). The following phenomena were observed when ACE was added to cells in culture: 1) it bound to SMC and EC with high affinity (K(d) = 361.5 +/- 60.5 pM) and with a low binding occupancy (B(max) = 335.0 +/- 14.0 molecules/cell); 2) it triggered cellular signaling resulting in late activation of focal adhesion kinase and SHP2; 3) it modulated platelet-derived growth factor receptor-beta signaling; 4) it was endocytosed by SMC and EC; and 5) it transited through the early endosome, partially occupied the late endosome and the lysosome, and was localized to the nuclei. The incorporation of ACE or a fragment of it into the nuclei reached saturation at 120 min, and was preceded by a lag time of 40 min. Internalized ACE was partially cleaved into small fragments. These results revealed that extracellular ACE modulated cell signaling properties, and that SMC and EC have a pathway for delivery of extracellular ACE to the nucleus, most likely involving cell surface receptor(s) and requiring transit through late endosome/lysosome compartments.

Human-derived vascular smooth muscle cells produce angiotensin II by changing to the synthetic phenotype

We investigated whether vascular smooth muscle cells (VSMC)-derived from human produce angiotensin (Ang) II upon change from the contractile phenotype to the synthetic phenotype by incubation with fibronectin (FN). Expression of alpha-smooth muscle (SM) actin, apparent in the contractile phenotype, was decreased by FN. Expressions of matrix Gla and osteopontin, apparent in the synthetic phenotype, were increased by FN. Ang II measured by radioimmunoassay (RIA) was significantly increased in human VSMC by FN. Expression of mRNAs for Ang II-generating proteases cathepsin D, cathepsin G, ACE, and chymase was increased by FN. Expressions of cathepsin D and cathepsin G proteins were also increased by FN. Ang I-generating activity, which was inhibited by an aspartyl protease inhibitor pepstatin A, was readily detected in the conditioned medium from human VSMC. Antisense oligodeoxynucleotides (ODNs) that hybridize with cathepsin D and cathepsin G significantly inhibited FN-increased Ang II in conditioned medium and cell extracts. In VSMC conditioned medium, FN-induced elevation of Ang II was significantly inhibited by temocapril but not by chymostatin. Ang II type 1 receptor antagonist CV11974 completely, and antisense cathepsin D and cathepsin G ODNs partially inhibited the FN-stimulated growth of human VSMC. These results indicate that the change of homogeneous cultures of human VSMC from the contractile to the synthetic phenotype sequentially increases expression of proteases cathepsin D, cathepsin G, and ACE, production of Ang II and productions of growth factors, culminating in VSMC proliferation. These findings implicate a new mechanism for the pathogenesis of human vascular proliferative diseases.

Mitogen-activated protein kinase activity regulation role of angiotensin and endothelin systems in vascular smooth muscle cells

To examine whether angiotensin II and endothelins produced in vascular smooth muscle cells can play roles in the regulation of mitogen-activated protein (MAP) kinase activity in vascular smooth muscle cells, we measured the activity of MAP kinases in cultured vascular smooth muscle cells, and determined effects of renin-angiotensin and endothelin systems activators and inhibitors. Angiotensin II and endothelin-1 produced an activation of MAP kinase activity in vascular smooth muscle cells, whereas the angiotensin receptor antagonist, losartan and the endothelin receptor antagonist, cyclo (D-alpha-aspartyl-L-prolyl-D-valyl-L-leucyl-D-tryptophyl, BQ123) inhibited the enzyme activity. MAP kinase activity in vascular smooth muscle cells was also inhibited either by the renin inhibitor pepstatin A or by the angiotensin-converting enzyme inhibitor captopril. The degree of the inhibition of MAP kinase activity by pepstatin A, captopril and losartan was almost the same. Renin produced a considerable increase in MAP kinase activity and the renin-induced MAP kinase activation was inhibited by pepstatin A. The endothelin precursor big endothelin-1 produced an increase of MAP kinase activity in vascular smooth muscle cells, whereas the endothelin-converting enzyme inhibitor phosphoramidon inhibited the enzyme activity. These findings suggest that functional renin-angiotensin system and endothelin system are present in vascular smooth muscle cells and these systems tonically serve to increase MAP kinase activity. It appears that renin or renin-like substances play the determining role in the regulation of renin-angiotensin system in vascular smooth muscle cells.

Production of angiotensin II by homogeneous cultures of vascular smooth muscle cells from spontaneously hypertensive rats

Production of angiotensin II (Ang II) in spontaneously hypertensive rats (SHR)-derived vascular smooth muscle cells (VSMC) has now been investigated. A nonpeptide antagonist (CV-11974) of Ang II type 1 receptors inhibited basal DNA synthesis in VSMC from SHR, but it had no effect on cells from Wistar-Kyoto (WKY) rats. Ang II-like immunoreactivity, determined by radioimmunoassay after HPLC, was readily detected in conditioned medium and extracts of SHR-derived VSMC, whereas it was virtually undetectable in VSMC from WKY rats. Isoproterenol increased the amount of Ang II-like immunoreactivity in conditioned medium and extracts of SHR-derived VSMC, whereas the angiotensin-converting enzyme inhibitor delapril significantly reduced the amount of Ang II-like immunoreactivity in conditioned medium and extracts of these cells. Reverse transcription-polymerase chain reaction analysis revealed that the abundance of mRNAs encoding angiotensinogen, cathepsin D, and angiotensin-converting enzyme was greater in VSMC from SHR than in cells from WKY rats. The abundance of cathepsin D protein by Western blotting was greater in VSMC from SHR than in cells from WKY rats. Ang I-generating and acid protease activities were detected in VSMC from SHR, but not in cells from WKY rats. These results suggest that SHR-derived VSMC generate Ang II with increases in angiotensinogen, cathepsin D, and angiotensin-converting enzyme, which contribute to the basal growth. Production of Ang II by homogeneous cultures of VSMC is considered as a new mechanism of hypertensive vascular disease.

Effects of long-term treatment with angiotensin-converting enzyme inhibitor on angiotensin II and prostacyclin release from mesenteric arteries in spontaneously hypertensive rats

To evaluate the long-term effects of an angiotensin-converting enzyme inhibitor (ACEI) on vascular angiotensin II (AII), eicosanoid production and vascular reactivities, we treated spontaneously hypertensive rats (SHR) with alacepril for 6 weeks and perfused the isolated mesenteric arterial bed which contains resistance vessels. Alacepril significantly lowered the arterial blood pressure. Changes in perfusion pressure in response to norepinephrine (NE) were attenuated, and isoproterenol-stimulated AII release from the perfused mesenteric arterial beds was inhibited in the alacepril-treated SHR. Vasodilation induced by acetylcholine (Ach) and prostacyclin (PGI2) release was significantly increased in the vasculature of the alacepril-treated SHR. Alacepril exerted no effect on cyclic GMP (cGMP) formation, but increased cAMP formation in the vasculature. These findings suggest that ACEI inhibits AII formation and facilitates PGI2 production in the resistance vessels, which leads to blunting of the pressor response to NE and improvement of endothelial function in SHR. These humoral and mechanical changes in the vasculature may contribute to the depressor and organ protective effects of ACEI.

Identification of vasopressin mRNA in rat aorta

We have reported previously that several blood vessels of the rat and cow contain immunoreactive vasopressin and further suggested that this peptide might be produced locally. To provide additional support for this hypothesis, we conducted the present study to determine whether mRNA for arginine vasopressin is also present in blood vessels. Ribonuclease protection analysis of total RNA isolated from rat hypothalamus and aorta revealed the presence of arginine vasopressin message in both tissues but not in RNA isolated from liver, a tissue devoid of vasopressin. Subsequent comparison of the autoradiographic intensities of the signals in these two tissues indicated that vasopressin message was 100- to 1000-fold lower in aorta. Additional studies showed that RNA isolated from endothelium-denuded vessels contained levels of arginine vasopressin message similar to those in intact vessels, indicating that endothelium was not a major source of this message. These data were substantiated by further studies using a vasopressin radioimmunoassay, which showed that vasopressin peptide levels in intact and endothelium-denuded vessels did not differ. Thus, the present study showed that rat aorta contains arginine vasopressin mRNA as well as the vasopressin peptide and that both the message and the peptide are contained in nonendothelial structures. However, the data do not rule out endothelium as a possible source of vasopressin. These studies add further support to the hypothesis that blood vessels are capable of producing vasopressin.

Local renin-angiotensin system in the microcirculation of spontaneously hypertensive rats

We studied the local renin-angiotensin system in the microcirculation of cremaster muscle in spontaneously hypertensive rats (SHR) and their normotensive Wistar-Kyoto (WKY) controls. We used intravital microscopy in an original preparation of cremaster isolated from its normal blood supply and externally perfused with physiological solution, thus allowing the exclusion of circulating converting enzyme, circulating renin, and circulating angiotensinogen. We classified arterioles studied as second-, third-, and fourth-order, with mean diameters, respectively, of 67 +/- 6, 35 +/- 2, and 17 +/- 1 microns in WKY controls and 61 +/- 5, 34 +/- 2, and 16 +/- 1 microns in SHR. No difference between WKY controls and SHR was found for arteriolar vasoconstrictions in response to topical administration of 0.01 to 1 nmol/mL angiotensin II. Conversely, in response to 0.01 to 1 nmol/mL angiotensin I, significantly more arteriolar vasoconstriction was found in SHR cremaster muscle. In both strains, responses to angiotensin I were significantly inhibited by 10 nmol/mL of the angiotensin-converting enzyme inhibitor lisinopril. When angiotensinogen-rich, renin-free plasma containing 2.3 nmol/mL angiotensinogen was administered, almost no vasoconstriction was found in WKY controls, but significant constrictions were observed in SHR (23 +/- 4%, 30 +/- 5%, and 41 +/- 4% for second-, third-, and fourth-order arterioles, respectively). In SHR, vasoconstriction in response to angiotensinogen-rich, renin-free plasma was dose dependent, was inhibited by lisinopril, and was not found 24 hours after bilateral nephrectomy. Topical administration of 1.2 micrograms/mL renin did not induce arteriolar vasoconstriction in either WKY or SHR cremaster muscle.(ABSTRACT TRUNCATED AT 250 WORDS)

Renin is not synthesized by cardiac and extrarenal vascular tissues. A review of experimental evidence

A comprehensive review of physiological and molecular biological evidence refutes claims for synthesis of renin by cardiac and vascular tissues. Cardiovascular tissue renin completely disappears after binephrectomy. Residual putative reninlike activity, where investigated, has had the characteristics of lysosomal acid proteases. Occasional reports of renin or renin mRNA in vascular and cardiac tissues can be ascribed to failure to remove the kidneys 24 hours beforehand, overloading of detection systems, problems with stringency in identification, and illegitimate transcripts after more than 25 cycles of polymerase chain reaction. Others, using more stringent criteria, have failed to detect cardiac and vascular renin mRNA. Accordingly, a growing number of investigators have concluded that the kidneys are the only source of cardiovascular tissue renin. Although prorenin is secreted from extrarenal tissues as well as from the kidneys, there is no evidence that it is ever converted to renin in the circulation. The kidney is the only tissue with known capacity to convert prorenin to renin and to secrete active renin into the circulation. Accordingly, renin of renal origin determines plasma and hence, extracellular fluid renin levels. In these loci, angiotensin (Ang) I, formed by renin cleavage of circulating and interstitial fluid angiotensinogen, is in turn cleaved by angiotensin converting enzyme, located in plasma and extracellular fluids and on the luminal surface of pulmonary and systemic vascular endothelial cells, to Ang II, which perfuses and bathes the heart and vasculature. Consistent with this model, plasma renin and angiotensin and the antihypertensive action of renin inhibitors, converting enzyme inhibitor, or Ang II antagonists all disappear after binephrectomy. Thus, the plasma renin level, via Ang II formation, determines renin system vasoconstrictor activity, the antihypertensive potential of anti-renin system drugs, and the risk of heart attack in hypertensive patients. This analysis redirects renin research to renal mechanisms that create the plasma renin level, to renal prorenin biosynthesis and its processing to renin, and to their regulated secretion, extracellular distribution, and possible binding to by target tissues. In this context, it is still possible that changes in circulating and interstitial renin substrate or available converting enzyme might exert subtle modulating influences on Ang II formation. However, this analysis redefines the importance of plasma renin measurements to assess clinical situations, because plasma renin is the only known initiator driving the cardiovascular renin-angiotensin system, and its strength can be measured.

Localization of angiotensin peptide-forming enzymes of 3T3-F442A adipocytes

We have demonstrated that angiotensinogen is synthesized by 3T3-F442A cells and is hydrolyzed to angiotensins I and II (ANG I and II) by this model adipocyte system. This study was designed to determine whether ANG I is generated by renin or some other enzyme and where the formation of ANG I and/or II occurs in 3T3-F442A cells. Renin mRNA was not detected by Northern blot analysis of poly(A)(+)-selected RNA from cultures of fully differentiated adipocytes nor by the more sensitive polymerase chain reaction, implying that renin is not synthesized in this model adipocyte system. Hydrolysis of angiotensinogen to ANG I and II was demonstrated to be associated with the cell but not the media. Inhibitors, including EDTA, aimed at inactivating enzymes belonging to the serine, acid, or aspartyl proteases, and metalloproteases were ineffective in preventing the formation of either ANG I or II. Therefore the model adipocyte 3T3-F442A cell system forms ANG I and II in the absence of renin and angiotensin-converting enzyme. The unidentified enzymes responsible for peptide formation are associated with the cell itself.

Angiotensinogen is cleaved to angiotensin in isolated rat blood vessels

The cleavage of synthetic tetradecapeptide renin substrate has been used to infer the presence of renin in the walls of isolated blood vessels; however, the conversion of natural angiotensinogen to angiotensin in isolated blood vessels has not been reported. We studied the release of angiotensinogen and the formation of angiotensins in a bloodless, perfused, isolated hind limb preparation of the rat. Perfusion with a modified Tyrode's solution resulted in spontaneous release of 4.7 +/- 1.5 pmol per 30 minutes of angiotensinogen as measured directly by radioimmunoassay. Western blot further identified the released material as angiotensinogen. Spontaneous release of angiotensins I and II was demonstrated by high performance liquid chromatography and radioimmunoassay. When highly purified rat angiotensinogen was added to the perfusate, release of angiotensin II was increased 14-fold compared with saline infusion. Captopril (10 mumol/L) inhibited angiotensinogen-induced angiotensin II release by 67% and led to an increase in angiotensin I release by 301%. Bilateral nephrectomy 24 hours before the experiments reduced basal angiotensin release below the detection limit and blunted angiotensinogen-induced angiotensin II formation by 95%. We conclude that active renin is present in the vessel wall and interacts with its natural substrate to form angiotensin peptides. Our data support the notion that the bulk of vascular renin is taken up from the circulation.

Gene expression of the renin-angiotensin system in human tissues. Quantitative analysis by the polymerase chain reaction

Activation of tissue-specific gene expression of the components of the renin-angiotensin system (RAS) in humans may play an important role in cardiovascular regulation and pathophysiology. Studies of human tissue RAS expression, however, have been limited by the lack of availability of sufficient amounts of fresh human tissues and a sensitive method for detecting specific mRNAs. To demonstrate the presence of components of local RASs in humans we used the polymerase chain reaction (PCR) after reverse transcription to detect renin- angiotensinogen-, and angiotensin-converting enzyme-mRNA in small quantities of human tissues. Results indicated that all components of the RAS were widely expressed in human organ samples. In order to study changes of gene expression in small tissue samples (e.g., renal biopsies) obtained from patients, we established a competitive PCR assay for quantification of renin, using a 155-basepair deletion mutant of the human renin cDNA as an internal standard. Renin-mRNA concentration was quantitated in the kidney (1.74 +/- 0.2 pg renin/micrograms total RNA), adrenal gland (1.15 +/- 0.15 pg renin/micrograms total RNA), placenta (0.7 +/- 0.1 pg renin/micrograms total RNA), and saphenous vein (0.02 +/- 0.01 pg renin/micrograms total RNA). The method described here may serve as a highly sensitive tool to quantify alterations in gene expression in man under various pathophysiologic conditions. This study should provide the methodological basis for future studies of tissue RAS in human physiology and disease.