EC:3.4.15.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.15.1 (ACE)
18,300 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This report summarizes the present data about the existence of components of the renin-angiotensin system in the rat brain. Angiotensinogen mRNA, mas proto-oncogene mRNA, angiotensin II (Ang II), and Ang II receptors have been mapped in the brain by using in situ hybridization, immunocytochemistry, and receptor autoradiography. These markers turned out to be widely distributed throughout the brain and to be not only restricted to areas related to cardiovascular control, but also to be present in functionally different areas, suggesting also other functions of angiotensin peptides. The distribution patterns of these components were correlated with data on the distribution of angiotensinogen, renin, angiotensin converting enzyme, and angiotensin fragments that revealed substantial topological mismatches. Using the model of "volume transmission," possible explanations for these mismatches are proposed. In this regard, a possible involvement of angiotensin fragments and the mas proto-oncogene in the functioning of the brain renin-angiotensin system is also discussed, demonstrating the increasing complexity of this central regulatory system.
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PMID:The brain renin-angiotensin system: localization and general significance. 138 66

Angiotensinogen is the precursor molecule of one of the most potent vasoactive substances, angiotensin-II. Angiotensinogen is normally synthesized in the liver and secreted into the plasma where it is converted into angiotensin-II by the combined proteolytic action of renin and angiotensin converting enzyme. Angiotensinogen levels in the plasma are modulated by a number of pathological and physiological factors. In order to understand the regulation of angiotensinogen gene expression, we have constructed an expression vector in which 688 bp of the 5'-flanking region of the rat angiotensinogen gene were attached to the chloramphenicol acetyl transferase (CAT) coding sequence. We have also obtained 5'-sequential deletion mutants from the rat angiotensinogen promoter attached to the CAT gene, and have identified multiple cis-acting DNA sequences involved in the regulation of angiotensinogen gene expression by transient transfection of these recombinant DNA molecules in human hepatoma cell lines, Hep3B, and HepG2.
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PMID:Identification of cis-acting DNA elements involved in the regulation of angiotensinogen gene expression. 155 46

The local renin-angiotensin system may regulate adrenal cell growth and function. Angiotensinogen, renin, and angiotensin converting enzyme gene expression were studied in four normal adrenal glands (removed from patients with renal carcinomas) and five aldosterone-secreting adenomas. Northern blot analysis showed expression of angiotensinogen messenger RNA (mRNA) in normal adrenals at levels approximately 35-fold lower than liver and sixfold lower than kidney. Similar angiotensinogen mRNA levels were present in two aldosteronomas, whereas a third had levels approximately 50% of those found in kidney. Renin mRNA was detectable in most normal adrenals and in three adenomas, one of which had relatively high renin mRNA levels. Angiotensin converting enzyme gene was expressed in adrenal tissue and in three adenomas. Portions from these normal adrenals and two of these aldosteronomas, as well as samples from two other adrenals and three aldosteronomas, were also studied in an in vitro superfusion system coupled with active renin radioimmunometric assay, angiotensin II/III, and aldosterone radioimmunoassay. Total amounts of active renin and angiotensin II/III released from normal adrenals during 270 minutes of superfusion were higher than the amounts released from aldosteronomas (312 +/- 35 versus 187 +/- 43 and 823 +/- 100 versus 436 +/- 55 pg/100 mg tissue, respectively; mean +/- SEM, p less than 0.05), whereas aldosterone release from the adenomatous tissue was approximately threefold higher (320 +/- 21 versus 115 +/- 18 ng/100 mg tissue; mean +/- SEM, p less than 0.01). Total amounts of active renin and angiotensin II/III released by normal or adenomatous adrenal samples exceeded threefold to fourfold the amounts extracted from similar samples of the same surgical specimen.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Local renin-angiotensin system in human adrenals and aldosteronomas. 159 71

The present study examined the presence and cellular distribution of angiotensinogen, the precursor to the angiotensin peptides, in the ovary of the normal cycling rat by immunocytochemistry. Angiotensinogen staining was present in the granulosa cells of maturing follicles and to a lesser extent in those undergoing atresia. Staining was not seen in the granulosa cells of primordial or early primary follicles. In maturing follicles intense staining for angiotensinogen was confined to the antral cell layers, cells of the cumulus oophorus and in the follicular fluid. Strong immunostaining was also seen in the germinal epithelium covering the ovary. Lighter angiotensinogen staining was observed in some parts of the cortical and medullary stroma and occasionally in corpora lutea. No variation in the intensity or pattern of angiotensinogen staining was observed throughout the estrous cycle. Comparison of the distribution of angiotensinogen with the previously described localization of renin, AII, angiotensin converting enzyme and AII receptors, suggests that there are a number of intra-ovarian sites at which AII could be produced.
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PMID:The immunocytochemical localization of angiotensinogen in the rat ovary. 220 93

The presence of angiotensinogen messenger RNA (mRNA) was detected in rat vascular and adipose tissue. Angiotensinogen mRNA in rat aorta was localized in the adventitia and surrounding adipose tissue, and not in the vascular smooth muscle. Freshly dispersed and cultured endothelial and aortic smooth muscle cells did not contain detectable amounts of angiotensinogen mRNA. In addition to periaortic adipose tissue, angiotensinogen mRNA was present in other fat depots of both brown and white types. To examine regulation of angiotensinogen gene expression, Sprague-Dawley rats were treated with angiotensin converting enzyme inhibitor or underwent bilateral nephrectomy. Relative levels of angiotensinogen mRNA in brown adipose tissues increased dramatically by 48 hours after bilateral nephrectomy. However, only one source of brown adipose tissue showed increased angiotensinogen mRNA levels after animals were treated for 5 days with converting enzyme inhibitor. In addition, angiotensinogen was released into the medium from incubated adipose tissues with levels increasing over a 2-hour period. These results demonstrate that angiotensinogen is synthesized by adipose tissue in the rat and may play a role in the function of this tissue.
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PMID:Location and regulation of rat angiotensinogen messenger RNA. 283 15

The components of the Renin-Angiotensin System (RAS) have been found to be expressed in the brain. Angiotensinogen, the high molecular weight precursor of the system, is widely distributed and expressed in areas not related to control of blood pressure and body fluid homeostasis as well. It has been shown that it is regulated by steroid hormones independently from the liver and that it is also regulated in a different manner in several brain areas. Angiotensin II, the effector peptide of the system, may be generated in the brain via the classical pathway, using renin and angiotensin converting enzyme or directly from angiotensinogen by cathepsin G or tonin. N-terminal peptides of angiotensin II have been found in several brain areas with ANG (1-7) involved in vasopressin release however without influence on blood pressure and with ANG III acting as potent as ANG II. Transgenic animals may be used to study the pathophysiology of an activated brain RAS.
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PMID:The brain renin-angiotensin system: molecular mechanisms of cell to cell interactions. 773 73

Several genes, including some encoding components of the renin angiotensin system, are associated with the risk of cardiovascular diseases. There have been reports linking a homozygous deletion allele of the angiotensin converting enzyme (ACE) gene (DD) with an increased risk of myocardial infarction, and some variants of the angiotensinogen gene with an increased risk of hypertension. In a case-control study of a caucasian population from New Zealand, we examined the associations with coronary heart disease (CHD) of ACE DD and of a mis-sense mutation with methionine to threonine aminoacid substitution at codon 235 in the angiotensinogen gene (T235). We studied 422 patients (mean age 62 years, 81% male) with documented CHD (50% with myocardial infarction) and 406 controls without known CHD (frequency-matched to cases by age and sex). Risk factors for CHD were assessed by standard questionnaire, physical examination, and blood tests. Genomic DNA from leucocytes was analysed for various ACE and angiotensinogen alleles. Angiotensinogen T235 homozygotes were at significantly increased risk of CHD generally (odds ratio 1.7, 2 p = 0.008) and of myocardial infarction specifically (1.8, 2 p = 0.009). Adjustment for several risk factors increased the estimate of CHD risk associated with this allele to 2.6 (2 p < 0.001) and the estimate for myocardial infarction risk to 3.4 (2 p < 0.001). By contrast, there was no evidence of a significant increase in the risk of CHD or myocardial infarction among individuals with ACE DD. We conclude that the T235 polymorphism of the angiotensinogen gene is an independent risk factor, which carries an approximately two-fold increased risk of CHD. In this study, however, ACE DD was not associated with any detectable increase in CHD risk.
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PMID:Association of angiotensinogen gene T235 variant with increased risk of coronary heart disease. 763 19

The cloning of renin, angiotensinogen and angiotensin converting enzyme genes have established a widespread presence of these components of the renin-angiotensin system in multiple tissues. New sites of gene expression and peptide products in different tissues has provided strong evidence for the production of angiotensin independently of the endocrine blood borne system. In addition, the cloning of the angiotensin receptor (AT1) gene has confirmed the widespread distribution of angiotensin and suggested new functions for the peptide. This review of various tissues shows the variation in gene expression between tissues and angiotensin levels, and the fragmentary state of our knowledge in this area. As yet we cannot state that the gene expression of the substrates, enzymes and peptide products are involved in a single cell synthesis. This is not so much evidence against a paracrine function for tissue angiotensin, as lack of detailed, accurate intracellular information. The low abundance of renin in brain, spleen, lung and thymus compared to kidney, adrenal, heart, testes, and submandibular gland may suggest that there are both tissue renin-angiotensin systems (RAS) and nonrenin-angiotensin systems (NRAS). The NRAS could function through cleavage of angiotensinogen by serine proteinases such as tonin and cathepsin G to form Ang II directly. Although much angiotensinogen is extracellular and could therefore be a site of synthesis outside of the cell, intracellular angiotensinogen in a NRAS process could produce Ang II intracellularly without requiring extracellular conversion of Ang I to Ang II by ACE. In summary, renin mRNA is found in high concentrations in kidney, adrenal and testes and decreasing lower concentrations in ovary, liver, brain, spleen, lung and thymus. Angiotensinogen mRNA is found in the following tissues in descending order of abundance: liver, fat cells, brain (glial cells), kidney, ovary, adrenal gland, heart, lung, large intestine and stomach. It is debatable whether angiotensinogen and renin mRNA are expressed in blood vessels. The evidence that is lacking for a paracrine function of angiotensin is a complete description of the intracellular molecular synthesis and release of Ang II from single cells of promising tissues. Such tissues, SMG, ovary, testes, adrenal, pituitary and brain (neurons and glia) are potent sources of RAS components for future studies. Although the evidence for a paracrine function of angiotensin II is incomplete, it is an important concept for progressing toward the understanding of tissue peptide physiology and the significance of their gene regulation.
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PMID:Levels of angiotensin and molecular biology of the tissue renin angiotensin systems. 842 6

Angiotensin II exerts its action via at least two distinct receptor subtypes designated AT1 and AT2. AT1 receptors seem to be responsible for most of the known angiotensin II effects while the role of AT2 receptors is not yet clear. Adipocytes of adult rats express exclusively the AT1 subtype. Angiotensin II stimulates prostacyclin release in adult rat adipocytes and in mouse preadipocytes. In the latter prostacyclin release is completely blocked by an AT2 receptor antagonist. Adipocyte angiotensin II receptors seem to be regulated by age and fat mass. Blockade of these receptors by an AT1 antagonist seems to prevent adipose tissue hypertrophy. Moreover, adipose tissue contains all the main components of the renin-angiotensin system such as angiotensinogen, angiotensin converting enzyme, angiotensin II and angiotensin II receptors. Angiotensinogen expression in adipocytes is stimulated by a high fat diet concurrent with enlargement of fat mass, associated with insulin resistance. Angiotensin converting enzyme inhibitors improve insulin sensitivity. Taken together, there is evidence of interaction between insulin and angiotensin II in regulation of adipose tissue metabolism and cellularity. Clarification of these interactions could lead to significant progress in pharmacological treatment of obesity and its comorbidity.
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PMID:The role of angiotensin II and its receptors in regulation of adipose tissue metabolism and cellularity. 878 38

We analyzed the components of the renin-angiotensin system (RAS) in ocular tissues of normal rabbit eyes and compared the results with those measured in rabbit eyes with proliferative vitreoretinopathy and ocular hypertension. Proliferative vitreoretinopathy was induced by injection of human platelets into the vitreous humor, and ocular hypertension was induced by injection of alpha-chymotrypsin into the posterior chamber. Angiotensinogen, renin, angiotensin converting enzyme (ACE), angiotensin II (Ang II), and Ang II receptors were assessed using conventional biochemical techniques. The vascularized tissues of normal eyes contained high renin and ACE activities concomitant with low concentration of angiotensinogen and Ang II. In general, in the ocular humors, the opposite was found. The Ang II receptor density was highest in the uveal tract [range 35-190 fmol/mg protein]. The AT1 receptor subtype predominated [> 80%]. The RAS was only minimally different in the two pathological models except that, in ocular hypertension, the renin activity in the uveal tract was reduced [-50%]. Also, the ratio of AT1 to AT2 receptors changed as compared to control, although the total receptor density remained unaltered. In conclusion, we present evidence for the presence of a complete local RAS in the rabbit eye, which is only marginally affected by the two pathological models studied.
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PMID:The renin-angiotensin system in the rabbit eye. 887 36

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