Consortium of Southeastern Hypertension Control: Potential Mechanisms and Physiologic Actions of Intracellular Angiotensin II

Rapid metabolism of exogenous angiotensin II by catecholaminergic neuronal cells in culture media

Angiotensin II (AngII) acts on central neurons to increase neuronal firing and induce sympathoexcitation, which contribute to the pathogenesis of cardiovascular diseases including hypertension and heart failure. Numerous studies have examined the precise AngII-induced intraneuronal signaling mechanism in an attempt to identify new therapeutic targets for these diseases. Considering the technical challenges in studying specific intraneuronal signaling pathways in vivo, especially in the cardiovascular control brain regions, most studies have relied on neuronal cell culture models. However, there are numerous limitations in using cell culture models to study AngII intraneuronal signaling, including the lack of evidence indicating the stability of AngII in culture media. Herein, we tested the hypothesis that exogenous AngII is rapidly metabolized in neuronal cell culture media. Using liquid chromatography-tandem mass spectrometry, we measured levels of AngII and its metabolites, Ang III, Ang IV, and Ang-1-7, in neuronal cell culture media after administration of exogenous AngII (100 nmol/L) to a neuronal cell culture model (CATH.a neurons). AngII levels rapidly declined in the media, returning to near baseline levels within 3 h of administration. Additionally, levels of Ang III and Ang-1-7 acutely increased, while levels of Ang IV remained unchanged. Replenishing the media with exogenous AngII every 3 h for 24 h resulted in a consistent and significant increase in AngII levels for the duration of the treatment period. These data indicate that AngII is rapidly metabolized in neuronal cell culture media, and replenishing the media at least every 3 h is needed to sustain chronically elevated levels.

Nuclear angiotensin II type 2 (AT2) receptors are functionally linked to nitric oxide production

Expression of nuclear angiotensin II type 1 (AT(1)) receptors in rat kidney provides further support for the concept of an intracellular renin-angiotensin system. Thus we examined the cellular distribution of renal ANG II receptors in sheep to determine the existence and functional roles of intracellular ANG receptors in higher order species. Receptor binding was performed using the nonselective ANG II antagonist (125)I-[Sar(1),Thr(8)]-ANG II ((125)I-sarthran) with the AT(1) antagonist losartan (LOS) or the AT(2) antagonist PD123319 (PD) in isolated nuclei (NUC) and plasma membrane (PM) fractions obtained by differential centrifugation or density gradient separation. In both fetal and adult sheep kidney, PD competed for the majority of cortical NUC (> or =70%) and PM (> or =80%) sites while LOS competition predominated in medullary NUC (> or =75%) and PM (> or =70%). Immunodetection with an AT(2) antibody revealed a single approximately 42-kDa band in both NUC and PM extracts, suggesting a mature molecular form of the NUC receptor. Autoradiography for receptor subtypes localized AT(2) in the tubulointerstitium, AT(1) in the medulla and vasa recta, and both AT(1) and AT(2) in glomeruli. Loading of NUC with the fluorescent nitric oxide (NO) detector DAF showed increased NO production with ANG II (1 nM), which was abolished by PD and N-nitro-l-arginine methyl ester, but not LOS. Our studies demonstrate ANG II receptor subtypes are differentially expressed in ovine kidney, while nuclear AT(2) receptors are functionally linked to NO production. These findings provide further evidence of a functional intracellular renin-angiotensin system within the kidney, which may represent a therapeutic target for the regulation of blood pressure.

Differential expression of nuclear AT1 receptors and angiotensin II within the kidney of the male congenic mRen2. Lewis rat

We established a new congenic model of hypertension, the mRen(2). Lewis rat and assessed the intracellular expression of angiotensin peptides and receptors in the kidney. The congenic strain was established from the backcross of the (mRen2)27 transgenic rat that expresses the mouse renin 2 gene onto the Lewis strain. The 20-wk-old male congenic rats were markedly hypertensive compared with the Lewis controls (systolic blood pressure: 195 +/- 2 vs. 107 +/- 2 mmHg, P < 0.01). Although plasma ANG II levels were not different between strains, circulating levels of ANG-(1-7) were 270% higher and ANG I concentrations were 40% lower in the mRen2. Lewis rats. In contrast, both cortical (CORT) and medullary (MED) ANG II concentrations were 60% higher in the mRen2. Lewis rats, whereas tissue ANG I was 66 and 84% lower in CORT and MED. For both strains, MED ANG II, ANG I, and ANG-(1-7) were significantly higher than CORT levels. Intracellular ANG II binding distinguished nuclear (NUC) and plasma membrane (PM) receptor using the ANG II radioligand 125I-sarthran. Isolated CORT nuclei exhibited a high density (Bmax >200 fmol/mg protein) and affinity for the sarthran ligand (KD<0.5 nM); the majority of these sites (>95%) were the AT1 receptor subtype. CORT ANG II receptor Bmax and KD values in nuclei were 75 and 50% lower, respectively, for the mRen2. Lewis vs. the Lewis rats. In the MED, the PM receptor density (Lewis: 50 +/- 4 vs. mRen2. Lewis: 21 +/- 5 fmol/mg protein) and affinity (Lewis: 0.31 +/- 0.1 vs. 0.69 +/- 0.1 nM) were lower in the mRen2. Lewis rats. In summary, the hypertensive mRen2. Lewis rats exhibit higher ANG II in both CORT and MED regions of the kidney. Evaluation of intracellular ANG II receptors revealed lower CORT NUC and MED PM AT1 sites in the mRen2. Lewis. The downregulation of AT1 sites in the mRen2. Lewis rats may reflect a compensatory response to dampen the elevated levels of intrarenal ANG II.

Angiotensin II type 1 receptor activation increases microvascular permeability via a calcium dependent process1

BACKGROUND

Elevated serum angiotensin II (Ang II) has been implicated in the endothelial barrier dysfunction associated with shock. We hypothesized that the increase in microvascular permeability seen with activation of the type 1 (AT1) receptor is a calcium dependent process.

MATERIALS AND METHODS

Microvascular hydraulic permeability (Lp) was measured in rat mesenteric venules using the Landis micro-occlusion model. A 100 mm KCl (HK) solution was used to negate the electrochemical potential of calcium influx, and measures of Lp were obtained before and after 20 ng/ml Ang II plus HK solution (n = 5). Intracellular calcium dependence on AT1 activation was evaluated two ways: 1) Lp changes were measured in response to 10 microm of the type 1 receptor agonist [SAR] [1]-angiotensin II in HK solution (n = 6), and 2) Lp changes were measured in response to 25 microg/ml of the type 2 (AT2) receptor blocker PD-123319 (PD) plus 20 ng/ml Ang II in HK solution (n = 6).

RESULTS

As expected, HK perfusion (P < 0.08) and Ang II plus HK solution (P < 0.42) did not affect Lp. Although perfusion of [SAR] [1]-angiotensin II in HK solution (P < 0.001) and PD plus Ang II in HK solution (P < 0.003) both significantly increased Lp, the magnitude of this response was less than that observed with Ang II alone.

CONCLUSIONS

Abrogation of intracellular calcium influx during AT1 activation blunted the known Ang II induced increase in microvascular permeability. Although the effect observed during AT1 activation was blunted by the HK solution, a significant elevation of Lp was still observed. This suggests that Ang II activation of the AT1 receptor increases microvascular permeability primarily, but not exclusively, via modulation of endothelial intracellular calcium ion levels.

Angiotensin II type 1 receptor activation increases microvascular hydraulic permeability

BACKGROUND

In addition to its vasoconstricting effects, angiotensin II (Ang II) has also demonstrated the ability to modulate microvessel permeability. We hypothesized that activation of the angiotensin II type 1 receptor (AT1) would increase hydraulic permeability.

METHODS

Hydraulic permeability (L(p)) was measured in rat mesenteric venules using the Landis micro-occlusion technique. Paired measures of L(p) were obtained at baseline and after perfusion with the AT1 agonist, [Sar(1)]-angiotensin II, at 10 micromol/L (n=6) and 100 micromol/L (n=6). Activation of the AT1 receptor was also achieved by perfusion with 20 nmol/L Ang II plus the angiotensin II type 2 receptor (AT2) antagonist, PD123319. In these studies, 30 micromol/L (n=6) and 300 micromol/L (n=6) of PD123319 were used.

RESULTS

[Sar(1)]-angiotensin II increased L(p) 2-fold with the 10 micromol/L dose (P=.04) and 4-fold with the 100 micromol/L dose (P < .001). The L(p) peak due to [Sar(1)]-angiotensin II occurred sooner than the peak observed with Ang II. PD123319 (30 micromol/L) plus 20 nmol/L Ang II increased L(p) 5-fold (P=.003), while PD123319 (300 micromol/L) plus 20 nmol/L Ang II increased L(p) 20-fold (P < .0001). The magnitude of the effect due to PD123319 (300 micromol/L) plus Ang II (20 nmol/L) was approximately twice the summation of effects due to PD123319 (300 micromol/L) alone and Ang II (20 nmol/L) alone.

CONCLUSIONS

We conclude that endothelial cell Ang II receptors play an important role in modulating transendothelial fluid flux. Activating the AT1 receptor increases L(p); the AT2 receptor may operate to oppose this action. Pharmacologic manipulation of Ang II receptors may be beneficial during shock states to limit intravascular fluid loss.

Dose-Dependent Actions and Temporal Effects of Angiotensin II on Microvascular Permeability

BACKGROUND

Angiotensin II is a potent vasoconstrictor that is elevated after shock. Previous studies suggest that angiotensin II may directly modulate the endothelial barrier. Our hypothesis was that angiotensin II would increase microvascular hydraulic permeability in a dose-dependent fashion.

METHODS

Hydraulic permeability (Lp) is a measure of water flow across the endothelial barrier. Lp was measured in rat mesenteric venules using the modified Landis micro-occlusion technique. Venules were first perfused with Ringer's solution and baseline measurements of Lp were obtained. The venules were then recannulated and perfused with angiotensin II at 0.2 ng/mL (n = 5), 2.0 ng/mL (n = 5), 20 ng/mL (n = 8), and 200 ng/mL (n = 5), before final Lp measurements.

RESULTS

Baseline values for Lp averaged 1.35 +/- 0.12. The 20-ng/mL and 200-ng/mL concentrations of angiotensin II significantly increased Lp to 3.86 +/- 0.4 (p < 0.0008) and 7.94 +/- 1.1 (p < 0.005), respectively. The maximal effect of angiotensin II was seen at 15 minutes of perfusion. Units for Lp are x 10(-7) cm.s-1.cm H2O-1.

CONCLUSION

Angiotensin II affects a dose-dependent increase in microvascular permeability. This suggests that angiotensin II is involved in modulating intravascular fluid flux across the vessel wall. This effect is opposite to that observed in other vasoconstrictors that are up-regulated after trauma.

The intracrine hypothesis and intracellular peptide hormone action

There is evidence that many peptide growth factors and hormones act in the intracellular space after either internalization or retention in their cells of synthesis. These factors, commonly called intracrines, are structurally diverse while sharing some common functional features. Reports of intracellular peptide hormone binding and action are reviewed here. Also, this laboratory has made proposals regarding the origin and actions of intracrines and these areas are further explored. Intracrine interactions and the relationship of intracrines to transcription factors are discussed. The intracellular/intracrine renin-angiotensin system (iRAS) is reviewed to illustrate the intracrine analogue of a well-established physiological system. The role of intracrine action in metazoan development is also considered.

Enalapril protects mice from pulmonary hypertension by inhibiting TNF-mediated activation of NF-kappaB and AP-1

The present study was undertaken to investigate the effects of treatment with the angiotensin-converting enzyme (ACE) inhibitor enalapril in a mouse model of pulmonary hypertension induced by bleomycin. Bleomycin-induced lung injury in mice is mediated by enhanced tumor necrosis factor-alpha (TNF) expression in the lung, which determines the murine strain sensitivity to bleomycin, and murine strains are sensitive (C57BL/6) or resistant (BALB/c). Bleomycin induced significant pulmonary hypertension in C57BL/6, but not in BALB/c, mice; average pulmonary arterial pressure (PAP) was 26.4 +/- 2.5 mmHg (P < 0.05) vs. 15.2 +/- 3 mmHg, respectively. Bleomycin treatment induced activation of nuclear factor (NF)-kappaB and activator protein (AP)-1 and enhanced collagen and TNF mRNA expression in the lung of C57BL/6 but not in BALB/c mice. Double TNF receptor-deficient mice (in a C57BL/6 background) that do not activate NF-kappaB or AP-1 in response to bleomycin did not develop bleomycin-induced pulmonary hypertension (PAP 14 +/- 3 mmHg). Treatment of C57BL/6 mice with enalapril significantly (P < 0.05) inhibited the development of pulmonary hypertension after bleomycin exposure. Enalapril treatment inhibited NF-kappaB and AP-1 activation, the enhanced TNF and collagen mRNA expression, and the deposition of collagen in bleomycin-exposed C57BL/6 mice. These results suggest that ACE inhibitor treatment decreases lung injury and the development of pulmonary hypertension in bleomycin-treated mice.

Effect of angiotensin II on microvascular permeability

BACKGROUND

Angiotensin II (Ang II) is a potent vasoconstrictor that is released during shock and sepsis. It is known to have activity on vascular endothelial cells. We hypothesized that Ang II plays a role in the modulation of fluid flux across the microvascular endothelium.

MATERIALS AND METHODS

Hydraulic permeability (L(p)) is a measure of water flow across the endothelial barrier. L(p) was measured in rat mesenteric venules using the modified Landis micro-occlusion technique. To determine the effect of Ang II in basal states, venules were perfused with control Ringer's and measures of L(p) obtained before and after a subsequent perfusion with 20 ng/ml Ang II (n = 5). In additional studies 10 microM ATP was used to activate the endothelium, thereby increasing the L(p) approximately 3-fold. Measures of L(p) were then obtained before and after a subsequent perfusion with 20 ng/ml Ang II (n = 6).

RESULTS

In the basal state, Ang II significantly increased L(p) from 1.45 +/- 0.29 to 3.45 +/- 0.28 (P = 0.013). Following activation by ATP, Ang II decreased L(p) from 4.51 +/- 0.45 to 3.05 +/- 0.28 (P = 0.02). Units for L(p) are x10(-7) cm s(-1) x cm H(2)O(-1).

CONCLUSIONS

Ang II increased microvascular permeability under basal conditions while in the activated state it decreased microvascular permeability. In addition to its vasopressor function this differential action of Ang II in modulating fluid flux across the fsendothelium in basal versus activated states may be of benefit under pathophysiological conditions and may be amenable to pharmacologic manipulation.

Mechanisms and functions of AT(1) angiotensin receptor internalization

The type 1 (AT(1)) angiotensin receptor, which mediates the known physiological and pharmacological actions of angiotensin II, activates numerous intracellular signaling pathways and undergoes rapid internalization upon agonist binding. Morphological and biochemical studies have shown that agonist-induced endocytosis of the AT(1) receptor occurs via clathrin-coated pits, and is dependent on two regions in the cytoplasmic tail of the receptor. However, it is independent of G protein activation and signaling, and does not require the conserved NPXXY motif in the seventh transmembrane helix. The dependence of internalization of the AT(1) receptor on a cytoplasmic serine-threonine-rich region that is phosphorylated during agonist stimulation suggests that endocytosis is regulated by phosphorylation of the AT(1) receptor tail. beta-Arrestins have been implicated in the desensitization and endocytosis of several G protein-coupled receptors, but the exact nature of the adaptor protein required for association of the AT(1) receptor with clathrin-coated pits, and the role of dynamin in the internalization process, are still controversial. There is increasing evidence for a role of internalization in sustained signal generation from the AT(1) receptor. Several aspects of the mechanisms and specific function of AT(1) receptor internalization, including its precise mode and route of endocytosis, and the potential roles of cytoplasmic and nuclear receptors, remain to be elucidated.