Local generation of angiotensin in the kidney and in tissue culture

Collecting Duct Renin: A major player in Angiotensin II-dependent Hypertension

Recently, the focus of interest on the role of the renin angiotensin system in the pathophysiology of hypertension has shifted towards greater emphasis on new developments in local renin angiotensin systems in specific tissues. We have focused our recent investigations on the role of the intrarenal-intratubular RAS in hypertension. All of the components needed for angiotensin II generation are present within the various compartments in the kidney. This brief review is focused on recent evidence that inappropriate activation of renin in distal nephron segments, by acting on angiotensinogen generated in the proximal tubule cells and delivered to the distal nephron may contribute to increased distal intrarenal angiotensin II formation, sodium retention and development and progression of hypertension.

The human placental renin-angiotensin system

The human placenta and related tissues are considered to be examples of the recently accepted local renin-angiotensin systems (RAS). The brain is another example of a system that is thought to be regulated independently of the kidney and the role of angiotensin within the CNS as a neural mediator has drawn considerable attention. It has been known for a long time that many of the neuroendocrine mediators and receptors are expressed in the placenta and it has been suggested that there are many parallels between the classical neuroendocrine system and the placental one. The present review summarizes information that components of the RAS are expressed in uteroplacental tissues, are regulated by endogenous substances, and have important biological functions within this reproductive system. A comparison of similarities and differences between the classical and the placental RAS may provide clues to functions in other endocrine and neuroendocrine systems. The major components of the placental RAS that are considered are renin, prorenin, angiotensin I, angiotensin II, angiotensin converting enzyme (ACE), angiotensin receptors, and angiotensinogen (renin substrate). The factors that regulate these components at the cellular and the nuclear level are described. It is concluded that prorenin via angiotensin-dependent and angiotensin-independent mechanisms influences functions within uteroplacental tissues. Some of these actions are direct and others are mediated by the release of different signalling molecules. These features are similar to many neuroendocrine systems and utilize some of the same messengers.

Development and fate of the secretory granules of juxtaglomerular epithelioid cells

The development and fate of the secretory granules in murine, rat and human juxtaglomerular epithelioid cells were examined using ultrastructural and immunocytochemical methods. The formation of mature renin granules occurs by fusion of rhomboid protogranules followed by coalescence of their paracrystalline contents, and by the fusion of roundish juvenile granules having an amorphous internum. Protogranules with paracrystalline contents are prominent in animals with stimulated renin synthesis, indicating an overcharge in processing and/or packaging of the secretory product, renin, under these conditions. Various similarities between lysosomes/multivesicular bodies (MVBs) and juvenile renin granules have been observed. With the exception of small MVBs, no renin-negative organelles that could be regarded as lysosomes were found in epithelioid cells of mice and rats. Therefore, we suggest that renin granules are modified lysosomes. Immunocytochemical findings indicate that juvenile secretory granules of epithelioid cells represent the converting and activating compartment for prorenin. Endocytosed foreign tracers such as HRP or cationized ferritin are preferentially internalized by juvenile renin granules, which hence appear to be outstanding by their fusogeneity. Consequently, juvenile granules are probably responsible for the secretion of prorenin, and mature granules for that of active renin.

Sodium regulation of angiotensinogen mRNA expression in rat kidney cortex and medulla

Rat liver angiotensinogen cDNA (pRang 3) and mouse renin cDNA (pDD-1D2) were used to identify angiotensinogen and renin mRNA sequences in rat kidney cortex and medulla in rats on high and low salt diet. Angiotensinogen mRNA sequences were present in renal cortex and medulla in apparently equal proportions, whereas renin mRNA sequences were found primarily in renal cortex. Average relative signal of rat liver to whole kidney angiotensinogen mRNA was 100:3. Densitometric analysis of Northern blots demonstrated that renal cortical angiotensinogen mRNA concentrations increased 3.5-fold (P less than 0.001) and medulla, 1.5-fold (P less than 0.005) on low sodium compared with high sodium diet, whereas renal cortex renin mRNA levels increased 6.8-fold (P less than 0.0005). Dietary sodium did not significantly influence liver angiotensinogen mRNA levels. These findings provide evidence for sodium regulation of renal renin and angiotensinogen mRNA expressions, which supports potential existence of an intrarenally regulated RAS and suggest that different factors regulate renal and hepatic angiotensinogen.

Long-term culture of renin containing tissue

Thin cortical tissue explants from kidneys of hydronephrotic mice were excised and incubated in different culture media containing growth and proliferation factors. Over a period of several months the content of renin in the explants and in the culture medium was repeatedly measured, to define the conditions necessary for the maintenance of renin production in a long-term culture. The best results were obtained when culturing the renal tissue in Dulbecco's medium (DMEM) with 10% fetal calf serum, 6 units/100 ml platelet-derived growth factor and 200 ng/ml glycylhistidyllysine. Renin was still present within the cells and in the culture medium after more than six months. Prevention of dedifferentiation, as evidenced in this case by the maintenance of renin production, seemed to be dependent on specific extracellular matrix proteins of renal origin. If the explants were dissociated from their matrix components by collagenase, a gradual loss of renin production was observed within 5 days. Complementation of the collagenase-digested cell suspension with different nonrenal extracellular matrix materials did not afford the stabilizing effect of the original pericellular matrix.

Effects of converting enzyme inhibitors: ramipril and enalapril on peptide action and sympathetic neurotransmission in the isolated heart

The role of converting enzyme (CE) in heart function was studied by assessing the inhibition of CE activity in rat heart tissue and in isolated perfused hearts from rat, guinea-pig and rabbit (Langendorff technique). Angiotensin I (ANG I) added to the perfusate reduced coronary flow (FLO) in all species, increased force of contraction (CON) in rats, decreased CON in guinea-pigs and had no effect on CON in rabbits. In contrast, bradykinin (BK) increased FLO in all species, decreased CON in rats, increased CON in guinea-pigs and had no effect on CON in rabbits. The CE inhibitors ramipril (HOE498) 1 mg/kg and enalapril (MK421) 30 mg/kg given orally 1 h prior to killing of the animals inhibited the ANG I effects and potentiated the BK effects but had no effects on the action of ANG II. The same doses of the two CE inhibitors produced up to 24 h inhibition of CE activity measured biochemically in the heart after single oral doses. Electrical sympathetic stimulation of the cardiac nerves (SNS) in isolated rabbit heart resulted in an increase of HR and CON and in an initial decrease and subsequent increase of FLO. The effects of SNS on HR and FLO were significantly reduced following HOE498 (1 mg/kg) pretreatment. The results suggest that local CE is involved in the regulation of peptide effects in the heart, including the ANG II-mediated facilitation of neurotransmission.

Detection of renin mRNA in mouse testis by hybridization with renin cDNA probe

Using 32P-labeled DNA complementary to mouse submaxillary gland renin mRNA, we probed mRNA gel blots from mouse testis and kidney tissues. Poly(A)-RNA from testis contained a hybridizable RNA species which was blotted onto nitrocellulose paper. The molecular size of testicular renin mRNA (approximately 1600 nucleotides in length) was not significantly different from tht of kidney renin mRNA. Densitometric scan revealed that the content of renin mRNA in mouse testis was approximately 5-fold lower than that in mouse kidney. These results support the proposal that mouse testicular cells synthesize renin.

Evidence for intracellular formation of angiotensins: coexistence of renin and angiotensin-converting enzyme in Leydig cells of rat testis

Leydig cells were purified from rat testes by discontinuous metrizamide density gradient and were shown to contain renin (EC 3.4.99.1), angiotensin-converting enzyme (dipeptidyl carboxypeptidase, (EC 3.4.15.1), and the peptide hormone angiotensins I, II and III as determined by the combined HPLC and radioimmunoassay. In germinal cells only angiotensin II (AII) was found at a significant level. These findings provide evidence for intracellular formation of AII in testicular cells and demonstrate that an intracellular renin-angiotensin system exists in normal non-transformed cells.