Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.24.11 (CD10)
 9,792 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To determine the cellular localization of glandular kallikrein in the human pancreas, immunohistochemical studies were performed with a monospecific antibody against the antigenically identical urinary kallikrein (urokallikrein). The localization of glandular pancreatic kallikrein to the beta cells of the islets was the same as that of insulin in normal human pancreas and in two islet-cell tumors. When beta cells were lacking in islet-cell tumors or in the pancreas of a patient with juvenile-onset diabetes, kallikrein antigen was not detectable. Anti-urokallikrein absorbed with purified urinary or pancreatic kallikrein no longer identified a pancreatic antigen, whereas absorption with insulin had no effect. The beta-cell localization of human pancreatic kallikrein, an endopeptidase that, in concert with carboxypeptidase B, converts bovine proinsulin to a polypeptide with the electrophoretic mobility of insulin, suggests that pancreatic kallikrein may be involved in the physiologic activation of proinsulin.
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PMID:Identification of human glandular kallikrein in the beta cell of the pancreas. 22 May 34

A pancreatic endopeptidase localized to the beta-cells of the pancreas by immunohistochemical techniques has been purified to homogeneity by following its functional and antigenic characteristics as a glandular kallikrein (EC 3.4.21.8). The enzyme gave a single stained band on alkaline disc gel electrophoresis which corresponded in location with the kinin-generating activity eluted from a replicate gel, was of 54,000 molecular weight by gel filtration, was devoid of caseinolytic activity, elicited a monospecific antiserum in a rabbit, and gave a line of complete identity with a single constituent in pancreatic extract, crude urine, and purified urokallikrein when analyzed with monospecific antibody to urokallikrein. The pancreatic glandular kallikrein generated three cleavage products of increasing anodal mobility from bovine and porcine proinsulin, and the presence of pancreatic kininase or bovine carboxypeptidase B increased the quantity of these products. Although the conversion products did not correspond to diarginyl- and monoarginylinsulin, the product of intermediate mobility was also obtained when proinsulin was treated with a low concentration of trypsin in the presence of kininase. The most rapidly migrating product did correspond to desalanylinsulin in the reference standard. Kininase alone had no action on proinsulin, and aprotinin prevented cleavage by kallikrein alone or in combination with kininase. Although the chemical structure of the proinsulin cleavage products has not been established, human pancreatic kallikrein is considered a putative activator of proinsulin because of its location in the beta-cell, its preferential action on proinsulin and kininogen as compared to azocasein, and its capacity to generate insulin intermediate products that are further modified by human pancreatic kininase or bovine carboxypeptidase B.
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PMID:Sequential cleavage of proinsulin by human pancreatic kallikrein and a human pancreatic kininase. 38 42

The physiological role of renal kallikrein-kinin system in human is discussed by the three following topics. Localization of each component of renal kallikrein-kinin system: Kallikrein is localized in the apical site of the distal tubular epithelial cells and collecting ducts by the immunostaining method. Following the stop-flow method in dog kidney, kallikrein and kinin are recognized in the distal tubules. Kininase I, II and neutral endopeptidase (enkephalinase) are localized not only in the proximal tubules, but also in the distal tubules. The localization of kininases is further confirmed by the stop-flow method pretreated with specific inhibitors for each of the kininases. Sodium metabolism and renal kallikrein-kinin system: In normal subjects, fractional excretions of sodium and inorganic phosphorus which reflect the total and proximal sodium reabsorption, show significantly positive correlations for both urinary kallikrein and kinin excretions. In the case of 0.9% saline infusion, the activity of renal kallikrein-kinin system is augmented following the infusion as shown in the increases of urinary kallikrein and kinin excretions and the decreases of urinary kininases excretions. Relation to other renal depressor systems: The close relations among renal dopamine, kallikrein-kinin and prostaglandin systems have been suggested by a dopamine infusion study. Dopamine may augment the activity of the renal kallikrein-kinin system through both the increases of renal prekallikrein synthesis and kallikrein specific activity. From these studies reported up to the present, it is suggested that the renal kallikrein-kinin system produced in the distal nephron in the kidney may play a role in the sodium metabolism with other renal depressor systems in addition to its own action.
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PMID:Physiological role of renal kallikrein-kinin system in human. 255 57

In order to further clarify the role of renal kallikrein-kinin (K-K) system in primary aldosteronism (PA), daily urinary excretions of renal K-K system components including kallikrein (KAL), kinin (KIN), total kininase (K-ase), K-ase I, K-ase II and neutral endopeptidase (NEP) were measured in PA and normotensives (NT). In this study, a new method for the simultaneous determination of human urinary K-ase I, II and NEP was established and employed. The daily excretions of KAL was significantly higher in PA than that in NT, while no difference was found in KIN between PA and NT. On the other hand, total K-ase in PA (897 +/- 258 micrograms/min/day) was significantly higher than that in NT (209 +/- 6). NEP was also significantly higher in PA (262 +/- 22 micrograms/min/day) than that in NT (127 +/- 6), whereas there were no differences in K-ase I and K-ase II between PA and NT. The relative contributions of K-ase I, II and NEP to total K-ase in NT were 14, 27 and 59%, while those in PA were 12, 17 and 36%, respectively. As a result, these three K-ase contributed only 64% to the total K-ase in PA. These findings suggested that 1) NEP may play a major role in the catabolism of renal KIN in human, 2) NEP is accelerated in PA, 3) unknown K-ase, different from K-ase I, II or NEP, may exist in PA, and 4) accelerated renal K-ase activity may play some role on the disorder of renal water-sodium metabolism and high blood pressure in PA.
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PMID:Renal kininases in primary aldosteronism. 255 6

In order to clarify the significance of NEP in human renal kallikrein-kinin system, an assay system was developed for the simultaneous determination of kininase I, II and NEP activities in human. Each kininase activity was determined by measuring the hydrolysis of bradykinin in the presence of specific inhibitors of kininase I (2-mercaptomethyl-3-guanidinoethylthiopropanoic acid), kininase II (captopril) and NEP (phosphoramidon) in 8 normal subjects. The effects of the different assay buffers on kininase activities were also investigated by using a phosphate buffer. Total kininase, kininase I, II and NEP activities were 499 +/- 65 ng/min/ml (mean +/- S.E.), 55 +/- 8, 141 +/- 21 and 299 +/- 42, respectively in our method using a tris buffer, while a phosphate buffer brought about activities of 358 +/- 43, 45 +/- 5, 156 +/- 21 and 135 +/- 25 ng/min/ml. The relative contributions of kininase I, II and NEP to total kininase activity were 11, 29 and 59% in our assay system, while they were 13, 44 and 35% when a phosphate buffer was used. From these results it was suggested that 1) phosphate may inhibit urinary NEP activity, so that a tris buffer should be used as the incubation buffer, 2) NEP is the major component of human urinary kininases, and 3) NEP may play an important role in the renal kallikrein-kinin system.
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PMID:A sensitive method for differential determination of kininase I, II and neutral endopeptidase (NEP) in human urine. 255 8

Recently, the existence of neutral endopeptidase (NEP) as a new kininase in the kidney has been reported. In this study, the localization of NEP in the nephron was investigated and compared with other components of the renal kallikrein-kinin (K-K) system by using a stop-flow method in dog kidneys. The stop-flow method was performed according to the procedures previously reported by Scicli et al and Malvin et al. Five mongrel dogs (weighing 15-20 kg) were used in this study. Kininase I, II and NEP were measured by the modified procedure of Ura et al. Kallikrein and kinin were found in the distal tubules, and kininase I and II were observed in both the distal and proximal tubules. NEP was localized mainly in the proximal tubules. A small peak was also recognized in the distal tubules. From these results, it was suggested that, not only kininase I and II but also NEP existing in the proximal tubules may destroy kinin filtered from the glomeruli, and these kininases existing in the distal tubules may play an important role in connection with kinin producing enzymes on the regulation of activity in the renal kallikrein-kinin system.
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PMID:Localization of neutral endopeptidase in the kidney determined by the stop-flow method. 255 9

Tissue kallikrein and low molecular weight kininogen are localized in the particular cells of the connecting tubules, indicating that kinin is immediately generated in the lumina of the lower nephrons. The role of the renal kallikreinkinin system was studied using mutant kininogen-deficient Brown NorwayKatholiek (BN-Ka) rats, and compared with that in normal BN-Kitasato rats of the same strain. Mutant BN-Ka rats showed no visible changes, but they were very sensitive to excess sodium ingestion and to the tendency of sodium to accumulate in the body by aldosterone released by angiotensin II, so that sodium was accumulated in erythrocytes and cerebrospinal fluid in BN-Ka rats and hypertension was induced. After four days infusion of 0.3 M NaCl solution to conscious and unrestrained mutant BN-Ka rats, the sensitivity of the vascular smooth muscle to norepinephrine and angiotensin II increased 30-fold and 10-fold, respectively. Bradykinin was degraded by neutral endopeptidase (NEP) and carboxypeptidase Y-like exopeptidase (CPY) in rat and human urine. Daily oral administration of a selective inhibitor of CPY, ebelactone B, or that of NEP, BP1O2, prevented development of deoxycorticosterone acetate-salt hypertension in Sprague-Dawley rats. These results indicate that: 1) the renal kallikrein-kinin system allows excretion of excess sodium in the body, 2) decreased sodium excretion due to reduced excretion of urinary kallikrein in patients with essential hypertension or in genetically hypertensive rats may cause hypertension, and 3) urine kininase inhibitors such as ebelactone B may emerge as a new antihypertensive drug.
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PMID:Crucial suppressive role of renal kallikrein-kinin system in development of salt-sensitive hypertension. 983 May 1

A reduction of renal kallikrein has been found in non-insulin-treated diabetic individuals, suggesting that an impaired renal kallikrein-kinin system (KKS) contributes to the development of diabetic nephropathy. We analyzed relevant components of the renal KKS in non-insulin-treated streptozotocin (STZ)-induced diabetic rats. Twelve weeks after a single injection of STZ, rats were normotensive and displayed hyperglycemia, polyuria, proteinuria, and reduced glomerular filtration rate. Blood bradykinin (BK) levels and prekallikrein activity were significantly increased compared with controls. Renal kallikrein activity was reduced by 70%, whereas urinary BK levels were increased up to threefold. Renal kininases were decreased as indicated by a 3-fold reduction in renal angiotensin-converting enzyme activity and a 1.8-fold reduction in renal expression of neutral endopeptidase 24.11. Renal cortical expression of kininogen and B2 receptors was enhanced to 1.4 and 1. 8-fold, respectively. Our data suggest that increased urinary BK levels found in severely hyperglycemic STZ-diabetic rats are related to increased filtration of components of the plasma KKS and/or renal kininogen synthesis in combination with decreased renal kinin-degrading activity. Thus, despite reduced renal kallikrein synthesis, renal KKS is activated in the advanced stage of diabetic nephropathy.
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PMID:Functional, biochemical, and molecular investigations of renal kallikrein-kinin system in diabetic rats. 1060 Aug 53

The present study examined non-insulin-treated streptozotocin (STZ)-induced diabetic rats to determine the role of kinins in diabetic nephropathy. Their involvement in the renoprotective effect of the angiotensin-converting enzyme inhibitor (ACEI) ramipril was investigated using the bradykinin (BK) B(2)-receptor antagonist, icatibant (HOE 140), or a combination of the two drugs.Although, none of the treatments prevented the decline of the glomerular filtration rate (GFR) in diabetic rats, ramipril (3 mg/kg/day), but not icatibant (HOE 140; 500 microg/kg/day), prevented proteinuria in these animals. However, the antiproteinuric effect of ramipril was reduced by 45% when combined with icatibant. To explore whether the renal kallikrein-kinin system (KKS) belongs to the underlying mechanisms of these findings, we also determined urinary BK levels, renal kallikrein (KLK) and angiotensin-converting enzyme (ACE) activity as well as renal cortical mRNA levels of neutral endopeptidase 24.11 (NEP) and low-molecular weight (LMW) kininogen. STZ led to a reduction of renal KLK and ACE activity and NEP expression and to a three-fold increase of urinary BK excretion and renal kininogen expression. Icatibant given alone had no effect on these parameters. In contrast, ramipril treatment normalized urinary protein and BK excretion as well as kininogen mRNA expression without affecting NEP mRNA expression or KLK and ACE activity. Our data demonstrate that renal BK is increased in severe STZ-induced diabetes mellitus, but may affect glomerular regulation only to a minor degree under this condition. However, kinins are partly involved in the antiproteinuric action of ACEI at this stage of diabetic nephropathy.
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PMID:Kinins are involved in the antiproteinuric effect of angiotensin-converting enzyme inhibition in experimental diabetic nephropathy. 1263 11

It is widely accepted that a high sodium intake triggers blood pressure rise. However, only one-third of the normotensive subjects were reported to show salt-sensitivity in their blood pressure. Many factors have been proposed as causes of salt-sensitive hypertension, but none of them provides a satisfactory explanation. We propose, on the basis of accumulated data, that the reduced activity of the kallikrein-kinin system in the kidney may provide this link. Renal kallikrein is secreted by the distal connecting tubular cells and all kallikrein-kinin system components are distributed along the collecting ducts in the distal nephron. Bradykinin generated is immediately destroyed by carboxypeptidase Y-like exopeptidase and neutral endopeptidase, both quite independent from the kininases in plasma, such as angiotensin converting enzyme. The salt-sensitivity of the blood pressure depends largely upon ethnicity and potassium intake. Interestingly, potassium and ATP-sensitive potassium (K(ATP)) channel blockers accelerate renal kallikrein secretion and suppress blood pressure rises in animal hypertension models. Measurement of urinary kallikrein may become necessary in salt-sensitive normotensive and hypertensive subjects. Furthermore, pharmaceutical development of renal kallikrein releasers, such as K(ATP) channel blockers, and renal kininase inhibitors, such as ebelactone B, may lead to the development of novel antihypertensive drugs.
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PMID:A missing link between a high salt intake and blood pressure increase. 1665 1


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