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Query: UMLS:C0020538 (hypertension)
 170,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The phenomenon of plasma renin activattion by acid dialysis and preincubation with trypsin was studied in normal human plasma. Activation of plasma renin by exposure to pH 3.3 was shown to require at least one dialysis step and could be inhibited by the presence of Trasylol, indicating the involvement of a protease in acid activation. Amniotic fluid exposed to pH 1.5 to destroy renin and renin substrate was also found to contain an enzyme capable of activating plasma renin. The Michaelis-Menten constant Km and the molecular weight of activated "renin" were found to be similar to those of normal plasma renin. Inactive renins or renin-like enzymes were partially purified from plasma by affinity chromatography on concanavalin A, precipitation with (NH4)2SO4 and isoelectric focusing. Trypsin and acid exposure gave similar results with regard to the activation of this zymogen, suggesting that trypsin and acid dialysis may increase plasma renin activity by the same mechanism.
Hypertension
PMID:Studies on renin activation in normal human plasma. 9 12

Plasma and serum of healthy subjects apparently contain a precursor form of renin, or 'prorenin,' which can be activated by the ice-cold temperature at which samples are customarily handled for prolonged periods in laboratories and blood banks. The effect of such prior cryoactivation for 9 days at 4 degrees C is to increase subsequent plasma renin activity (PRA) at 37 degrees C by 108 +/- 16.3% (mean +/- SE) over the nonactivated control value (P less than 0.001). At a lower temperature (-4 degrees C), the cryoactivation effect is considerably greater than at 4 degrees C. Cryoactivation is not obliterated by the prefreezing of plasma, or reduced by inclusion of bacteriostats. Nor is it attributable to any detectable reduction in angiotensinase activity. In rats, cryoactivation at 4 degrees C is much lower than in humans, suggesting a marked species difference either in prorenin concentration or in the rapidity of its spontaneous conversion after blood collection. Trypsin at near optimal concentrations also consistently activates human plasma prorenin, whether at 4, 23, or 37 degrees C indicating that cold is not an essential concomitant of tryptic activation. In excess, the magnitude of which varies among individuals, trypsin at first produces activation and later a decline in PRA, probably due to degradation of the reactants (prorenin, renin, angiotensinogen) and of the initial product (angiotensin I). The identity of angiotensin I in activated and control plasmas can be established by specific radioimmunoassay, and bioassay. Our data indicate that tryptic activation involves little direct production of angiotensin I but rather converts prorenin, thereby enhancing the angiotensin generating capacity of the plasma renin system itself. Tryptic activation in plasma of anaesthetized dogs is lower than in humans, but higher than in conscious or anaesthetized rabbits in whom the effect appears to be slight. In anaesthetized rats there is virtually no tryptic activation, which is in line with the results by cryoactivation. Since the renin--angiotensin systems of dogs, rabbits, and rats have been extensively studied in experimental models of human hypertension, these observed departures from human levels of cryoactivation and tryptic activation of prorenin deserve further investigation.
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PMID:Cryoactivation and tryptic activation of blood 'prorenin' in normal man and animals. 70 20

We have identified and characterized an anti-human renin monoclonal antibody R1-20-5 that is selective for human active renin. R1-20-5 binds active renin with a dissociation constant (Kd) of 2.5 x 10(-7) M/l and inhibits renin enzymatic activity with an inhibitory constant (IC50) of 1.4 x 10(-8) M/l. R1-20-5 competes with a synthetic renin inhibitor for binding with renin, demonstrating further that it is binding to or close to the active site. This antibody does not bind prorenin in human plasma or recombinant prorenin expressed by L-929 fibroblasts transfected with human renin gene. Furthermore, trypsin activation of prorenin resulted in immunoreactivity of the activated prorenin toward the antibody. In addition, an immunoaffinity column of R1-20-5 coupled to Sepharose retained active renin but had a low affinity for prorenin. A sensitive and rapid solid phase radioimmunoassay for active renin was developed using a "sandwich" technique employing R1-20-5 and a second non-active site-directed monoclonal antibody to human renin. Renin levels in human plasma samples were determined by the standard enzymatic assay, and by the direct radioimmunoassay for active renin, before and after trypsin activation. Trypsin treatment of plasma resulted in parallel increases in both the plasma renin enzymatic activity and in the plasma active renin concentration as measured by the direct radioimmunoassay. Overall, plasma immunoreactive active renin concentration correlated significantly with plasma renin enzymatic activity (r = 0.96, p less than 0.001). In summary, the monoclonal antibody R1-20-5 is selective for human active renin and should be a very useful tool for studies of the active enzyme in humans.
Hypertension 1992 Mar
PMID:Characterization of a monoclonal antibody specific for human active renin. 154 51

Cell suspensions were prepared from rat renal cortical tissue by dispersion with 0.1% collagenase. Unit gravity sedimentation in a 1%-4% Ficoll gradient resulted in a single-cell suspension enriched in juxtaglomerular (JG) cells. Both the cellular renin activity and the amount of renin released into the supernatant increased with time when the suspensions were incubated for 1 hour at 37 degrees C in tissue culture medium. These cells responded to epinephrine and norepinephrine by increasing both synthesis and release of renin. The response was blocked by timolol but not by phenoxybenzamine. Cell suspensions prepared in the same manner but using 0.25% trypsin as the dispersing enzyme neither synthesized nor released renin into the tissue culture medium when similarly incubated. Trypsin-dispersed cells did not respond to catecholamine stimulation. Renin synthesis and release in collagenase-dispersed JG cells were unaltered by changes in Na, K, or Ca ion concentrations. Angiotensin II inhibited release, while saline extracts of clipped kidney from renal hypertensive rats stimulated renin release by these cells.
Hypertension
PMID:Responses of juxtaglomerular cell suspensions to various stimuli. 626 Jun 44

Normal plasma contains inactive renin, which becomes active when plasma is dialyzed to pH 3.3 and to pH 7.5, or treated with pepsin or trypsin. Under optimal conditions, each of these procedures activated the same quantity of renin, which was not further increased by repeating or combining two procedures, thus suggesting that the same pool of inactive renin was activated by each procedure. When plasma was fractionated by gel filtration, dialysis activated very little renin in eluates. Trypsin activated renin, but under some conditions also destroyed renin. Pepsin fully activated the inactive renin in eluates without evidence of destruction of renin. The pepsin-activated renin of normal plasma eluted from Sephadex G-100 in a peak of apparent molecular weight (MW) 58,000 and from Sephacryl S-200 with apparent MW 53,000, like big renin in plasma of patients with diabetic nephropathy. Inactive renin was usually increased in amount in plasma of sodium-depleted normal men, but the elution volume did not change with sodium intake. When renin was fully activated in plasma incubated with pepsin or trypsin, the apparent MW of the main peak of big renin did not change appreciably. Inactive renin in plasma was usually increased after sodium depletion, but the elution volume did not change. Active renin of normal plasma had an apparent MW near 41,000 on both gels. Thus, we conclude that big renin is present in normal plasma in amounts at least equal to and usually greater than active renin (the ratio depending on sodium intake) and that pepsin activation readily demonstrates big renin in eluates from gel filtration.
Hypertension
PMID:Inactive renin of high molecular weight (big renin) in normal human plasma. Activation by pepsin, trypsin, or dialysis to pH 3.3 and 7.5. 678 Apr 60

The mechanism of activation of inactive renin was studied in normal human plasma. The molecular weight of active renin and those of inactive renin before and after activation were analyzed by sephadex gel filtration. Active renin of human plasma had a molecular weight of 48,000 +/- 1000. Trypsin treatment and cold treatment activated inactive renin of a molecular weight of 54,000 +/- 1000. The inactive renin apparently did not change its molecular weight after activation. "Cryoactivation" of inactive renin was possible only when whole plasma was used. When the whole plasma was fractionated by gel filtration, cryoactivation was not observed in any of the fractions. Cryoactivation requires certain plasma factor(s) contained in some fractions. Plasma kallikrein is likely to be a major factor required for the cryoactivation of inactive renin, whereas some other factors may also participate in this mechanism.
Hypertension
PMID:Studies on the activation and molecular weight of inactive renin in human plasma. 699 73

Estimation of apparent molecular weight (mw) of inactive renin by gel filtration of human plasma was found to be inaccurate when "acid activation" or "cryoactivation" was used for detection; recoveries were only 5% to 20%. Trypsin activation produced greater recoveries, but the apparent elution volume of inactive renin varied with the concentration of trypsin used; the presence of trypsin inhibitors increased trypsin requirements to 100 to 200 micrograms/ml in the 60,000 dalton region, while low protein concentration in the 50,000 dalton region resulted in destruction of renin by as little as 10 microgram/ml trypsin. A composite trypsin-activated inactive renin peak corresponded to a mw of 56,000 +/- 1500 daltons (104% to 120% recovery), while active plasma renin was 48,000 +/- 2000 daltons. When this prorenin-like substance was isolated by affinity chromatography, it was found to be completely inactive. It was also nearly free of trypsin inhibitors, so that a single trypsin concentration correctly identified and confirmed the elution characteristics of inactive renin peak following gel filtration. The apparent mw of trypsin-activated inactive renin was slightly lower (52,000 daltons) than that of inactive renin. Human renal cortex was also found to contain a trypsin-activable form of renin. Like plasma inactive renin, it could be isolated by chromatography on Cibacron blue-agarose (Affi-Gel blue). It was found to be completely inactive following passage over a pepstatin affinity column. This inactive renal renin, as well as a similar substance in perfusate of normal human kidney, had a mw of 49,500 +/- 1000, while active renal renin was 39,500 +/- 500. Trypsin-activated inactive renal renin had a mw of 46,500 +/- 500; its pH optimum was identical with that of active renal renin, and it no longer bound to Cibacron blue-agarose. We conclude that both human plasma and kidney contain an inactive, prorenin-like substance that can be detected reliably by trypsin activation. There appear to be slight differences in the apparent mw of plasma renins and kidney renin, but the similarity of other characteristics suggests that the inactive, prorenin-like substances in renal cortex, renal perfusate, and plasma may be one and the same substance.
Hypertension
PMID:Detection and isolation of inactive, large molecular weight renin in human kidney and plasma. 702 14

Inactive renin and active renin from human kidney and human plasma were prepared in highly purified forms by three steps of chromatography on Octyl-Sepharose, immunoaffinity chromatography, and pepstatin-amino hexyl Sepharose CL-4B. The inactive renin and active renin from human kidney had molecular weights of 51,000 and 44,000 as measured by a calibrated gel filtration column run with internal molecular weight standards. Molecular weights of plasma inactive renin and active renin were 56,000 and 51,000 respectively. Both inactive and active renins were found to be heterogeneous, consisting of several components with different isoelectric points. Renal inactive renin has higher pI values of 6.40, 6.10, 5.90, 5.61, and 5.40. Renal active renin has pI values of 5.73, 5.40, 5.25, and 5.13. The pI values of plasma inactive renin were 6.37, 6.08, 5.77, 5.36, and 5.25; of plasma active renin, 5.68, 5.40, 5.33, and 5.25. Trypsin activation and plasmin activation of plasma inactive renin produced an active enzyme with similar molecular weight but lower pI values. Acid activation of inactive renin did not change the molecular weight and pI values.
Hypertension
PMID:Isolation and activation of inactive renin from human kidney and plasma. Plasma and renal inactive renins have different molecular weights. 702 7

We isolated renin granules from cadaver kidneys using discontinuous sucrose density gradient centrifugation, and investigated the storage form of the renin from these granules. Approximately 23% of the total renin activity in the original homogenate was obtained from the surface phase between 1.6 and 1.7 M sucrose (Fraction 6). Granule renin extracted from the granules in Fraction 6 was separated into active and inactive renin using pepstatin affinity chromatography. Only the active renin had an affinity for pepstatin. The inactive renin, albeit activated by trypsin, was little activated by acidification. The proportion of inactive renin was about 25% of the total granule renin (active renin + inactive renin). Trypsin concentrations over 10 micrograms/ml resulted in a decrease in the renin activity of the trypsin-activated renin, but the enzymatic activity of active renin was decreased by trypsin. With gel filtration, the inactive renin revealed a single peak, and the molecular weight (MW) was 48,000. The active renin had a MW of 44,000. The inactive renin could be activated by trypsin without an apparent change in molecular weight.
Hypertension
PMID:The storage form of human renal renin. 704 Feb 25

The levels of active, inactive, and total renin (trypsin treatment) were measured in rat plasma before and after in vivo stimulation or suppression of active plasma renin. Stimulation of active renin was accompanied by either an increase (low sodium diet), no change (pentobarbital anesthesia plus hemorrhage), or fall (pentobarbital anesthesia) in the plasma levels of inactive renin, while suppression of active renin was accompanied by a fall (high sodium diet) or mild but nonsignificant increases (clonidine or saline infusion) of the inactive enzyme. These results suggest the possible independence of in vivo regulation of active and inactive renin in the rat. Trypsin activation of plasma fractions obtained by isoeletric focusing indicated a minimum of three activable forms of inactive renin (pH 4.4, 4.6, 4.8). Inactive enzymes could not be completely separated from active renins by this technique. Isoelectric focusing indicated a similar lowering of the isoelectric points of the five detectable active renins of rat plasma following in vivo stimulation of the renin system (ether anesthesia plus hemorrhage) or trypsin treatment of normal rat plasma before fractionation. These results indicate that similar renins are activated both in vivo and in vitro. Although trypsin is not the physiological activator of renin, a similar enzymatic cleavage resulting in activation appears to occur in vivo.
Hypertension
PMID:In vivo and in vitro alterations of active and inactive plasma renins in the rat. 704 Feb 41


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