EC:3.4.23.15 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:3.4.23.15 (renin)
35,795 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The distribution and biochemical properties of the renin activity present in the dog brain were compared with those of the lysosomal enzyme cathepsin D. Renin and cathepsin activity were present in all brain regions studied, in association with high angiotensinase activity. Brain renin activity was partially purified by ammonium sulfate fractionation and Sephadex gel filtration, resulting in the removal of angiotensinase activity. The specific brain renin activity increased approximately one hundred times during this procedure; cathepsin D activity accompanied the brain renin activity throughout the purification and showed a similar increase in specific activity. The renin and cathepsin activity in the partially purified preparation behaved identically during isoelectric focusing. The partially purified renin and cathepsin activity exhibited saturation kinetics with their respective substrates and were without activity above pH 6.0. Both enzyme activities were irreversibly inhibited by the pepsin inhibitor pepstatin, in nanomolar concentrations. These data, in conjunction with the literature concerning brain cathepsin, suggest that the renin activity in brain is due to cathepsin D, and that this renin activity exhibited by cathepsin D may be of limited significance under physiological conditions.
...
PMID:Renin activity in dog brain: enzymological similarity to cathepsin D. 18 Dec 41

A renin-like enzyme and acid protease (cathepsin) from whole and saline-pefused dog brains were separated by CM-cellulose chromatography with a linear NaCl gradient. Plasma renin and cathepsin were also separated using the same system. During the separation steps (in all the above cases) the specific activity of the brain renin-like enzyme was increased, while the specific activity of the brain cathepsin was decreased. Approximately a 70-fold increase in the specific activity of brain renin-like enzyme and a sixfold decrease in brain cathepsin specific activity was obtained from saline-perfused brain. The separation made it possible to study the pH optimum of the brain renin-like enzyme and acid protease. The brain renin-like enzyme showed optimal activity in the range of pH 6-7. Immunologically, the renin-like enzyme was distinctly different from dog kidney renin.
...
PMID:Separation of dog brain renin-like activity from acid protease activity. 39 94

In rats treated with DOCA plus high salt or with high salt alone, hypertensive rats with renal vascular lesions showed an incomplete suppression of KRA. Cathepsin activity of rat kidney was higher under high salt loading than in the control. Beta-glucuronidase activity was greatest in rats with renal vascular lesions and smallest in rats fed on normal chow. RNase and DNase activities were greater in rats with renal vascular lesions than in rats without renal vascular lesions under high salt loading. 2) In rats of both sexes SHR showed greater KRA and cathepsin activities than WK rat under high salt loading. In female rats DNase, RNase and beta-GPase activities were greater in SHR than in WK rat under high salt loading. 3) KRA was higher in SHRSP aged 10 months than in SHRSR, though KRA of SHR was smaller than KRA of WK rat. Cathepsin activity was greater in SHRSP than in SHRSR. DNase and beta-NAGA activities were greater in SHR than in WK rat. 4) In 7 weeks of age SHRSR showed more PRC than SHRSP. At the age of 10 months SHRSP showed higher PRC than WK rat. The roles renin and lysosomal enzymes in hypertensive renal vascular lesions were discussed to some extent.
...
PMID:Hypertensive vascular lesions and renin or lysosomal enzymes in rats. 115 86

The avian sarcoma/leukemia virus protease (PR), purified from avian myeloblastosis virus has a native molecular mass of 26 kDa, suggesting a dimer structure. The enzymatic activity of PR has been characterized using synthetic peptide substrates. PR is most active at pH 5.5, 35 degrees C and 2-3 M NaCl. Under these conditions PR cleaves decapeptides which are resistant in low ionic strength. This high, nonphysiological, salt concentration also increases the proteolytic activity of a cellular aspartic protease, pepsin. PR and pepsin show additional similarities: they both cleave a synthetic decapeptide at the same Tyr-Pro bond in low and high salt, while the cleavage site preferences of human renin and cathepsin-D in this substrate are altered at high salt concentrations. In addition, iodination of the tyrosine residue in this decapeptide causes an increase in the rates of hydrolysis by both PR and pepsin. However, Km values are too high to be estimated accurately for PR using Tyr-Pro and Tyr(I)-Pro decapeptides as substrates. Comparison of the digestion products of two additional decapeptides, altered in a single amino acid residue, shows that PR cleaves at fewer sites than all three cellular enzymes. Furthermore pepstatin, a strong inhibitor of pepsin, renin, and cathepsin-D has little effect on PR.
...
PMID:Avian retroviral protease and cellular aspartic proteases are distinguished by activities on peptide substrates. 253 48

We have studied the dog as a potential model for the human plasma prorenin-renin system. On a regular sodium intake, healthy conscious dogs apparently have a much lower plasma renin activity (PRA) than healthy human volunteers. Cryoactivation of prorenin is virtually absent in dogs, in contrast to that in humans, but becomes more effective after preacidification of the plasma. The concentration of trypsin required for optimal activation of prorenin is 6 to 10 times higher for dog plasma, revealing a prorenin:renin ratio about 10 times greater than in humans. Dialysis of posttryptic plasma decreases the PRA, but it remains 5 times higher than in pretryptic plasma, indicating that activation is not totally dependent on any renin system component that has been rendered dialyzable by trypsin, e.g., substrate converted to tetradecapeptide (TDP). This argues against the view that tryptic activation is attributable to angiotensin production from TDP by the action of cathepsin D, rather than from new renin converted from prorenin. The posttryptic increase in PRA is evident whether plasma incubation is carried out at pH 6.0 or at 7.4, and can be largely blocked by pepstatin, which also implicates a prorenin-renin mechanism rather than TDP-cathepsin. The low PRA in dogs, the negligible cryoactivation and its improvement by preacidification, and the requirement and tolerance of high trypsin concentrations, all point to greater protease inhibition in dog plasma and/or departures from the enzyme(s) responsible for human prorenin activation. Moreover, the tryptic activation of prorenin is not completed quickly as in human plasma, but carries over into the posttryptic stage of angiotensin generation, even in the presence of excess soybean trypsin inhibitor (SBTI), and other potent inhibitors. Such ongoing prorenin activation cannot be attributed only to trypsin itself, nor to kallikrein (both are inhibited by SBTI), but rather to some other enzyme(s) derived by the action of trypsin. This new prorenin convertase activity (possibly renin itself) can be effectively transferred from trypsinized to control dog plasma, in which it greatly accelerates prorenin activation. Thus, contrary to other reports, dog plasma has a high content of activatable prorenin, and with appropriate methodological changes, the dog can be used as an animal model for physiological and biochemical studies of the prorenin-renin system.
...
PMID:Plasma prorenin in humans and dogs. Species differences and further evidence of a systemic activation cascade. 634 Dec 16

Evidence is presented for the involvement of proteinases from Candida albicans in the pathogenesis of acronecrosis that occurred in a young woman and which coincided with Candida sepsis. Secretory acid Candida proteinase by immunofluorescence was traced in the obstructed blood vessels of necrotic skin that was infested with yeast. The specificity of immunofluorescence was proven by exclusion of cross reactivity with pepsin, cathepsin-D, acid erythrocyte proteinase and porcine renin. The possible molecular mechanisms of interference of fungal proteinases are discussed with respect to the renin-angiotensin system and blood coagulation.
...
PMID:On the role of proteinases from Candida albicans in the pathogenesis of acronecrosis. 636 77

Using a radioimmunoassay directed toward the COOH-terminal, biologically active region of mammalian neurotensin (NT), the rapid (within seconds) generation of immunoreactive NT (iNT) during acid extraction of mammalian and avian gastric tissues has been demonstrated. Levels of iNT were shown to increase 25-200-fold in time. The reaction occurred in 0.1 N HCl and 2 N acetic acid and was prevented by raising the pH above 5 or by adding acetone. The temperature and pH dependence and the ability of pepstatin A to inhibit the reaction suggested the involvement of a pepsin-related acid protease. Furthermore, the reaction could be mimicked by incubating a stabilized gastric extract with hog pepsin at pH 2. Size exclusion chromatography demonstrated the presence of a precursor-like substance with an apparent Mr of 60,000. Although iNT generated in avian and mammalian gastric extracts could be distinguished chromatographically from NT in that species, the partially purified gastric iNT was active in a bioassay for NT which quantitates changes in vascular permeability after intradermal injection into rats. One might suggest that iNT serves as a signal within the gastric lumen, being generated at low pH by secreted pepsin. It is also possible that iNT could be formed within blood or gastric interstitial fluid by the action of pepsin-related (cathepsin or renin-like) enzymes at normal physiologic pH.
...
PMID:Rapid proteolytic generation of neurotensin-related peptide(s) and biologic activity during extraction of rat and chicken gastric tissues. 646 66

Although the brain contains cathepsins at high concentrations which exhibit a non-specific renin-like activity at acidic pH, the presence of specific renin in the brain has been demonstrated by characterizing its specific properties. Renin was separated from cathepsin by affinity chromatography on casein-Sepharose. Brain renin showed neutral pH optima for the reaction to generate angiotensin I. The presence of inactive prorenin was also found. The isoelectric points of brain renin were significantly lower differences from that of renal or plasma renin. Immunohistochemical studies demonstrated a wide-spread localization of renin in many different regions. Angiotensin II, the final product of the prohormone-to-hormone conversion reaction mediated by renin and angiotensin converting enzyme, was found to exist in the same cell as renin by immunohistochemical studies of brain sections and with cloned and cultured neuroblastoma cells. This is the first demonstration of the mechanism of peptide hormone formation in neuronal cells. Similar intracellular formation was demonstrated in gonadotrophs of adenohypophysis. Coexistence of renin and angiotensin II was demonstrated in some cells. Electrophysiological studies have shown that angiotensin II functions to disinhibit the inhibition of neuronal response to electrical stimuli in the hippocampus.
...
PMID:Brain renin. 704 40

Myofibroblasts and their potential to generate angiotensin (Ang) II and transforming growth factor beta 1 (TGF-beta 1) at sites of infarction in the rat heart have been implicated in tissue repair. These cells likewise contribute to repair in a subcutaneous pouch model of fibrous tissue formation. Their appearance in pouch tissue coincides with high density ACE and Ang II receptor binding, suggesting a role for Ang II in tissue repair. Using pouch tissue studied at different time points of repair, the present study examined the expression of requisite mRNA for Ang peptide generation: angiotensinogen, Ao; an aspartyl protease, either cathepsin-D, Cat-D, or renin: and angiotensin converting enzyme, ACE, TGF-beta 1 and type I collagen mRNA expression was also addressed. Unlike pouch studied on day 2 and 4, at 7, 14 and 21 days, we found: (a) expression of Ao, Cat-D but not renin, ACE and TGF-beta 1 mRNA; (b) Ang I and Ang II peptides in pouch tissue and exudate; (c) the presence of Cat-D activity but no renin activity; (d) an increase in type I collagen mRNA with time; (e) upregulation of pouch tissue ACE mRNA expression by lisinopril treatment, whereas AT1 and AT2 receptor antagonists (losartan and PD 123177, respectively) downregulated the expression of mRNA for ACE, when compared to untreated controls; (f) downregulation of TGF-beta 1 mRNA expression by lisinopril and losartan compared to untreated controls; and (g) PD 123177 had no effect, whereas lisinopril and losartan treatment significantly (P < 0.05) reduced type I collagen mRNA expression. Thus, in this model of fibrous tissue formation, we found expression of component genes involved in Ang peptide (I and II) and TGF-beta 1 generation and Ang II upregulation of TGF-beta 1 expression, suggesting Ang II and/or TGF-beta 1 may upregulate type I collagen expression during tissue repair. Pharmacologic intervention studies with lisinopril or losartan indicate Ang II plays a role in the reciprocal regulation of ACE mRNA expression, which modulates Ang II levels at sites of repair.
...
PMID:Pouch tissue and angiotensin peptide generation. 971 Aug 8

The existence of a local renin-angiotensin system in the heart is still a controversial issue. This review discusses the evidence, obtained from studies in cardiac cells, in isolated perfused hearts and in intact animals and humans, both under normal and pathological conditions, for local production of prorenin, renin, angiotensinogen, angiotensin-converting enzyme, angiotensin I and angiotensin II at cardiac tissue sites. In addition, the role of alternative angiotensin-generating enzymes (cathepsin, chymase) and the possibility of (pro)renin uptake from the circulation is evaluated.
...
PMID:Is there a local renin-angiotensin system in the heart? 1069 Mar 2

1 2 Next >>