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Query: EC:3.4.21.7 (
plasmin
)
9,023
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The activation of canine anionic and cationic trypsinogen by
enterokinase
, trypsin, thrombin,
plasmin
and extracts from canine granulocytes were studied in vitro. Enterokinase activates both trypsinogens about 1000 times faster than trypsin. The
enterokinase
-catalyzed activation is not inhibited by the main serum protease inhibitors, alpha-macroglobulin and alpha 1-antitrypsin. alpha-Macroglobulin cannot inhibit the activation of the trypsinogens by trypsin but this reaction is completely inhibited by alpha 1-antitrypsin. The results are discussed in relation to the pathogenesis of acute pancreatitis.
...
PMID:Studies on the activation of canine trypsinogens in vitro. 9 42
In rats fed control and ethanol-containing Lieber-DeCarli diets for a period of 12 months, the bile did not contain any
enterokinase
, the pancreatic juice did not contain any
plasmin
or thrombin, but in animals fed high fat diet with ethanol, trypsinogen and chymotrypsinogen were significantly increased and trypsin inhibitor decreased. In the tissue, free trypsin and cathepsin B were increased. Composite profile of trypsinogen in gel segments obtained from the pancreatic juice and the tissue showed higher peaks of cationic and anionic variants of trypsinogen in animals fed ethanol. There was no evidence of mesotrypsinogen or of enzyme Y in the juice or the tissue. These studies show that serine proteases and cathepsin B may play a major role in the pathobiology of alcoholic pancreatitis.
...
PMID:Effect of chronic ethanol feeding on factors leading to inappropriate intrapancreatic activation of zymogens in the rat pancreas. 128 69
Proteinase species secreted by 10 human gastric carcinoma cell lines were analyzed by gelatin zymography and immunoblotting. These cell lines were classified into the following three groups with respect to proteinase secretion: cell lines secreting mainly gelatinases A and/or B; those secreting multiple types of serine proteinases; and those scarcely secreting these enzymes. Two cell lines of the second group, STKM-1 and MKN28, hardly secreted metalloproteinases but secreted the following four types of serine proteinases: (a) two trypsin-like enzymes (M(r) 26,000 and 24,000 in proenzyme forms); (b) a tissue kallikrein-like enzyme (M(r) 150,000 in a complex form); (c) a
plasmin
-like enzyme (M(r) 70,000); and (d) a plasminogen activator (urokinase-type, M(r) 57,000, from STKM-1 and tissue-type, M(r) 70,000, from MKN28). The M(r) 70,000
plasmin
-like enzyme was also detected at lower levels in the conditioned media of four other cell lines (MKN1, MKN45, NUGC-3, and KATO III). The M(r) 24,000 proenzyme of the trypsin-like enzyme was purified from the serum-free conditioned medium of STKM-1. The proenzyme was activated by
enterokinase
treatment or autolytically by incubation at neutral pH, decreasing its apparent molecular weight from 24,000 to 23,000 on nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The activated enzyme extensively degraded fibronectin, laminin, and gelatins and to lesser extents type I, III, IV, and V collagens at 30 degrees C. These results suggest that the matrix serine proteinases may play a major role in the matrix degradation by some kinds of human cancer cells.
...
PMID:Multiple secretion of matrix serine proteinases by human gastric carcinoma cell lines. 138 87
Different enzymatic methods for cleavage of recombinant fusion proteins were compared. To find an efficient cleavage method, five different fusion proteins were produced. The fusion proteins differed only in the linker region between the fusion partner and the desired product, human des(1-3)insulin-like growth factor I. A cleavage study was performed with
enterokinase
,
plasmin
, thrombin, urokinase, and recombinant H64A subtilisin. Significant cleavage was obtained using thrombin, H64A subtilisin, and
enterokinase
. Thrombin cleavage was studied on a larger scale and des(1-3)IGF-I was recovered at a final yield of 3 mg/L growth medium. Thrombin and
enterokinase
were also studied as immobilized proteases and they cleaved the fusion proteins with retained activity. To further improve thrombin cleavage, a continuous reactor was constructed, consisting of a closed system with a thrombin column and an ion exchange column in series. Here, the fusion protein circulated while free des(1-3)IGF-I was bound to the ion exchange column after release from the fusion protein. In the reactor, thrombin was as efficient as the free enzyme but gave a diminished rate of product degradation.
...
PMID:An evaluation of different enzymatic cleavage methods for recombinant fusion proteins, applied on des(1-3)insulin-like growth factor I. 138 67
Zymogen activation is an important biochemical control process and has important physiological and pathological implications. We have simultaneously measured both procarboxypeptidase A, the enzyme precursor, and carboxypeptidase A, its active product, in serum by using an affinity resin and the synthetic peptide substrate N-(2-furanacryloyl)-L-phenylalanyl-L-phenylalanine. Serum procarboxypeptidase A is activated by trypsin, chymotrypsin,
plasmin
, subtilisin, or urokinase but not by thrombin or
enteropeptidase
. The molecular weight of the precursor is approximately 5000-10 000 greater than that of the active product. Both enzyme and precursor increase in serum in the course of pancreatic inflammation, but the degree of activation can vary up to 2000-fold, independent of the amount of precursor present. The existence of this pancreatic proteolytic precursor in serum opens new avenues for the investigation of zymogen activation and its regulation.
...
PMID:Human serum procarboxypeptidase A. 634 78
Thrombokinase of the blood, while resembling
enterokinase
in its role of activator, is more closely analogous to trypsin in its intrinsic origin. It probably arises from a plasma precursor; but it is different from
plasmin
(
fibrinolysin
). Like trypsin, thrombokinase can activate prothrombin without the aid of other factors; however, it is potentiated by platelets plus calcium. Unlike certain tissue "thromboplastins," it does not sediment appreciably in 2 hours at 85,000 g. Like trypsin, it hydrolyzes p-toluenesulfonylarginine methyl ester (TAMe). Chromatography on DEAE-cellulose separated thrombin from thrombokinase. The TAMe esterase associated with the thrombokinase fractions was largely suppressed by soybean trypsin inhibitor, while that associated with the thrombin fractions was not. Highly purified thrombokinase was used as starting material; and thrombokinase was eluted in the last major protein band. Under these conditions stepwise elution was as effective as gradient in leading to further purification. The product of 199 liters of bovine plasma was chromatographed in 1 day; and the specific activity was comparable to that attained previously by repeated electrophoretic fractionations. The assembled data suggest that the thrombokinase protein may be approaching homogeneity.
...
PMID:Thrombokinase of the blood as trypsin-like enzyme. 1403 95
Polyserase-1 (polyserine protease-1)/TMPRSS9 (transmembrane serine protease 9) is a type II transmembrane serine protease (TTSP) that possesses unique three tandem serine protease domains. However, the physiological function of each protease domain remains poorly understood. We discovered a new splice variant of polyserase-1, termed Serase-1B, which contains 34 extra amino acids consisting a SEA module (a domain found in sea urchin sperm protein,
enterokinase
and agrin) adjacent to the transmembrane domain and the first protease domain with a mucin-like box at the C-terminus. The tissue distribution of this enzyme by RT (reverse transcription)-PCR analysis revealed high expression in the liver, small intestine, pancreas, testis and peripheral blood CD14+ and CD8+ cells. To investigate the role of Serase-1B, a full-length form recombinant protein was produced. Interestingly, recombinant Serase-1B was partly secreted as a soluble inactive precursor and it was also activated by trypsin. This activated enzyme selectively cleaved synthetic peptides for trypsin and activated protein C, and it was inhibited by several natural serine protease inhibitors, such as aprotinin, alpha2-antiplasmin and plasminogen activator inhibitor 1. In addition, Serase-1B efficiently converted pro-uPA (urokinase-type plasminogen activator) into active uPA and this activation was strongly inhibited by these natural inhibitors. Furthermore, this activation was also negatively regulated by glycosaminoglycans. Our results indicate that Serase-1B is a novel member of TTSPs that might be involved in uPA/
plasmin
-mediated proteolysis and possibly implicated in biological events such as fibrinolysis and tumour progression.
...
PMID:Serase-1B, a new splice variant of polyserase-1/TMPRSS9, activates urokinase-type plasminogen activator and the proteolytic activation is negatively regulated by glycosaminoglycans. 1687 79
1. Methods for the preparation and partial purification of streptococcal
fibrinolysin
are described. 2. The lysis of fibrin clots in the presence of streptococcal
fibrinolysin
is associated with proteolysis of the fibrin. Digestion is due to an enzyme normally present in serum or plasma in an inactive state, which is activated by
fibrinolysin
. Fibrinolysin alone has no demonstrable proteolytic activity. 3. The lysin factor-
fibrinolysin
system brings about proteolysis of other proteins such as gelatin or casein, in addition to fibrin and fibrinogen. 4. It is suggested that lysin factor exists in serum or plasma as a zymogen, and that it is activated by
fibrinolysin
, a kinase, in a manner similar to the activation of trypsinogen by
enterokinase
or the mold kinase of Kunitz (1938).
...
PMID:STREPTOCOCCAL FIBRINOLYSIS: A PROTEOLYTIC REACTION DUE TO A SERUM ENZYME ACTIVATED BY STREPTOCOCCAL FIBRINOLYSIN. 1987 27
1. Fibrinolysin-activated lysin factor and chloroform-activated serum protease of serum and plasma are one and the same enzyme, differing only in their mode of activation. 2. The enzyme as it normally occurs in serum or plasma is not inactive because of combination with serum inhibitor. It is present as an inactive precursor or zymogen and may be activated from this state by streptococcal
fibrinolysin
. 3. The activation of serum protease by streptococcal
fibrinolysin
is a catalytic reaction, analogous to the kinase activation of trypsinogen by
enterokinase
. Treatment of serum or plasma with chloroform apparently results in removal of serum inhibitor which may allow autocatalytic activation of the serum protease. 4. The serum enzyme differs from trypsin in its pH of optimum activity, in its reactions with specific protease inhibitors, and in its action on casein. 5. A revised nomenclature for the serum enzyme system is suggested which more accurately describes its properties than the terms in current use.
...
PMID:A PROTEOLYTIC ENZYME OF SERUM: CHARACTERIZATION, ACTIVATION, AND REACTION WITH INHIBITORS. 1987 36
Cleavage and activation of hemagglutinin (HA) by trypsin-like proteases in influenza A virus (IAV) are essential prerequisites for its successful infection and spread. In host cells, some transmembrane serine proteases such as TMPRSS2, TMPRSS4 and HAT, along with
plasmin
in the bloodstream, have been reported to cleave the HA precursor (HA
0
) molecule into its active forms, HA
1
and HA
2
. Some trypsinogens can also enhance IAV proliferation in some cell types (e.g., rat cardiomyoblasts). However, the precise activation mechanism for this process is unclear, because the expression level of the physiological activator of the trypsinogens, the TMPRSS15
enterokinase
, is expected to be very low in such cells, with the exception of duodenal cells. Here, we show that at least two variant enterokinases are expressed in various human cell lines, including A549 lung-derived cells. The exogenous expression of these enterokinases was able to enhance the proliferation of IAV in 293T human kidney cells, but the proliferation was reduced by knocking down the endogenous
enterokinase
in A549 cells. The
enterokinase
was able to enhance HA processing in the cells, which activated trypsinogen
in vitro
and in the IAV-infected cells also. Therefore, we conclude that
enterokinase
plays a role in IAV infection and proliferation by activating trypsinogen to process viral HA in human cell lines.
...
PMID:Enterokinase Enhances Influenza A Virus Infection by Activating Trypsinogen in Human Cell Lines. 2962 40
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