Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.4 (trypsin)
 42,187 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The lysosomal cysteine protease cathepsin B is thought to play a central role in intrapancreatic trypsinogen activation and the onset of experimental pancreatitis. Recent in vitro studies have suggested that this mechanism might be of pathophysiological relevance in hereditary pancreatitis, a human inborn disorder associated with mutations in the cationic trypsinogen gene. In the present study evidence is presented that cathepsin B is abundantly present in the secretory compartment of the human exocrine pancreas, as judged by immunogold electron microscopy. Moreover, pro-cathepsin B and mature cathepsin B are both secreted together with trypsinogen and active trypsin into the pancreatic juice of patients with sporadic pancreatitis or hereditary pancreatitis. Finally, cathepsin B- catalyzed activation of recombinant human cationic trypsinogen with hereditary pancreatitis-associated mutations N29I, N29T, or R122H were characterized. In contrast to a previous report, cathepsin B-mediated activation of wild type and all three mutant trypsinogen forms was essentially identical under a wide range of experimental conditions. These observations confirm the presence of active cathepsin B in the human pancreatic secretory pathway and are consistent with the notion that cathepsin B-mediated trypsinogen activation might play a pathogenic role in human pancreatitis. On the other hand, the results clearly demonstrate that hereditary pancreatitis-associated mutations do not lead to increased or decreased trypsinogen activation by cathepsin B. Therefore, mutation-dependent alterations in cathepsin B-induced trypsinogen activation are not the cause of hereditary pancreatitis.
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PMID:Presence of cathepsin B in the human pancreatic secretory pathway and its role in trypsinogen activation during hereditary pancreatitis. 1193 57

Hereditary pancreatitis is an autosomal dominant condition, which results in recurrent attacks of acute pancreatitis, progressing to chronic pancreatitis often at a young age. The majority of patients with hereditary pancreatitis express one of two mutations (R122H or N29I) in the cationic trypsinogen gene (PRSS1 gene). It has been hypothesised that one of these mutations, the R122H mutation causes pancreatitis by altering a trypsin recognition site so preventing deactivation of trypsin within the pancreas and prolonging its action, resulting in autodigestion. Families with these two mutations have been identified in many countries and there are also other rarer mutations, which have also been linked to hereditary pancreatitis. Patients with hereditary pancreatitis present in the same way as those with sporadic pancreatitis but at an earlier age. It is common for patients to remain undiagnosed for many years, particularly if they present with non-specific symptoms. Hereditary pancreatitis should always be considered in patients who present with recurrent pancreatitis with a family history of pancreatic disease. If patients with the 2 common mutations are compared, those with the R122H mutation are more likely to present at a younger age and are more likely to require surgical intervention than those with N29I. Hereditary pancreatitis carries a 40 % lifetime risk of pancreatic cancer with those patients aged between 50 to 70 being most at risk in whom screening tests may become important.
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PMID:Hereditary pancreatitis. 1250 40

Neonatal hypertrypsinaemia with normal sweat chloride detected during CF screening may be related to trypsin activation. We have looked for mutations of the cationic trypsinogen (PRSS1) and pancreatic secretory trypsin inhibitor (PSTI) genes in 50 hypertrypsinaemic neonates with known CFTR genotypes and negative sweat test. No mutations were found in either gene. Two silent polymorphisms were detected in the PRSS1 gene. A polymorphism in the promoter region and an intronic polymorphism of the PSTI gene were found. No difference was observed in the frequency of PRSS1 or PSTI polymorphisms in neonates carrying or not carrying CF mutations. These results do not provide an indication for an increased frequency of mutations in the PRSS1 and PSTI genes in this group of neonates with transient hypertrypsinaemia.
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PMID:Cationic trypsinogen and pancreatic secretory trypsin inhibitor gene mutations in neonatal hypertrypsinaemia. 1252 13

Human pancreatic secretions contain two major trypsinogen isoforms, cationic and anionic trypsinogen, normally at a ratio of 2 : 1. Pancreatitis, pancreatic cancer and chronic alcoholism lead to a characteristic reversal of the isoform ratio, and anionic trypsinogen becomes the predominant zymogen secreted. To understand the biochemical consequences of these alterations, we recombinantly expressed and purified both human trypsinogens and documented characteristics of autoactivation, autocatalytic degradation and Ca2+-dependence. Even though the two trypsinogens are approximately 90% identical in their primary structure, we found that human anionic trypsinogen and trypsin exhibited a significantly increased (10-20-fold) propensity for autocatalytic degradation, relative to cationic trypsinogen and trypsin. Furthermore, in contrast to the characteristic stimulation of the cationic proenzyme, acidic pH inhibited autoactivation of anionic trypsinogen. In mixtures of cationic and anionic trypsinogen, an increase in the proportion of the anionic proenzyme had no significant effect on the levels of trypsin generated by autoactivation or by enterokinase at pH 8.0 in 1 mm Ca2+- conditions that were characteristic of the pancreatic juice. In contrast, rates of trypsinogen activation were markedly reduced with increasing ratios of anionic trypsinogen under conditions that were typical of potential sites of pathological intra-acinar trypsinogen activation. Thus, at low Ca2+ concentrations at pH 8.0, selective degradation of anionic trypsinogen and trypsin caused diminished trypsin production; while at pH 5.0, inhibition of anionic trypsinogen activation resulted in lower trypsin yields. Taken together, the observations indicate that up-regulation of anionic trypsinogen in pancreatic diseases does not affect physiological trypsinogen activation, but significantly limits trypsin generation under potential pathological conditions.
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PMID:Human anionic trypsinogen: properties of autocatalytic activation and degradation and implications in pancreatic diseases. 1270 65

The human pancreas secretes two major trypsinogen isoforms, cationic and anionic trypsinogen. To date, 19 genetic variants have been identified in the cationic trypsinogen gene (PRSS1) of patients with hereditary, familial, or sporadic chronic pancreatitis. A common feature of cationic trypsinogen mutants studied so far is an increased propensity for autocatalytic activation (autoactivation). This is thought to lead to premature intrapancreatic digestive protease activation. In contrast, no pancreatitis-associated mutations have been found in the anionic trypsinogen gene (PRSS2), suggesting that this isoform might play a relatively unimportant role in pancreatitis. To challenge this notion, here we describe the unique properties of the E79K cationic trypsinogen mutation (c.235G>A), which was identified in three European families affected by sporadic or familial pancreatitis cases. In vitro analysis of recombinant wild-type and mutant enzymes revealed that catalytic activity of E79K trypsin was normal, and its inhibition by pancreatic secretory trypsin inhibitor was unaffected. Although the E79K mutation introduces a potential new tryptic cleavage site, autocatalytic degradation (autolysis) of E79K-trypsin was also unchanged. Furthermore, in contrast to previously characterized disease-causing mutations, E79K markedly inhibited autoactivation of cationic trypsinogen. Remarkably, however, E79K trypsin activated anionic trypsinogen two-fold better than wild-type cationic trypsin did, while the common pancreatitis-associated mutants R122H or N29I had no such effect. The observations not only suggest a novel mechanism of action for pancreatitis-associated trypsinogen mutations, but also highlight the importance of interactions between the two major trypsinogen isoforms in the development of genetically determined chronic pancreatitis.
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PMID:Interaction between trypsinogen isoforms in genetically determined pancreatitis: mutation E79K in cationic trypsin (PRSS1) causes increased transactivation of anionic trypsinogen (PRSS2). 1469 29

The classical feature of hereditary pancreatitis (HP) is characterized by recurrent episodes of acute pancreatitis or a priori chronic pancreatitis in several members of one family. In 1996, the identification of the first HP-associated mutation in the cationic trypsinogen gene provided a breakthrough in our understanding of the pathogenesis of chronic pancreatitis. In the following years, several different mutations in the same gene have been found in a large number of investigated families. Most intriguing, HP patients have a more than 50-fold increased risk of pancreatic ductal cancer in comparison with expected pancreatic cancers in the general population. Variants of the major intrapancreatic trypsin antagonist SPINK1 have implications for more common forms of chronic pancreatitis. Research has focussed on the SPINK1-N34S-mutation, which is closely associated with tropical, alcoholic, or "idiopathic" chronic pancreatitis. Chronic pancreatitis represents a variable part of the cystic fibrosis syndrome, which is caused by mutations in the gene coding for the cystic fibrosis transmembrane conductance regulator (CFTR). Several groups have reported an increased prevalence of CFTR mutations in patients with chronic pancreatitis of different etiology. In this review, we summarize interesting clinical and biochemical features of genetic variants in these genes which are associated with chronic pancreatitis.
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PMID:Genetic aspects of chronic pancreatitis. 1556 96

Hereditary pancreatitis is a rare autosomal dominant inherited disease with 80% penetration rate. The disease is characterized by recurrent episodes of pancreatitis often beginning in childhood, positive family history with at least two other affected members and no known precipitating factors. Most forms of hereditary pancreatitis are caused by one of two commoner mutations, R122H in exon 3 and N29I in exon 2 of the cationic trypsinogen (CT) (PRSS1) gene, located on chromosome 7. These genetic defects are speculated to cause excessive trypsin activity or to prevent inactivation of prematurely activated trypsin, resulting in pancreatitis. We performed mutation analysis of a Korean family with two members having clinically suspicious hereditary pancreatitis. We analyzed the CT gene in DNA samples extracted from peripheral blood of five family members. First of all, polymerase chain reaction and restriction enzyme digestion were performed in exon 3 of the CT gene. And then DNA products were purified and sequenced. We found out that three members of the family, the mother and two daughters, had a R122H mutation of the CT gene. We report the first family of hereditary pancreatitis associated with the CT gene mutation, an arginine to histidine amino acid substitution at residue 122, in Korea.
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PMID:[A case of R122H mutation of cationic trypsinogen gene in a pediatric patient with hereditary pancreatitis complicated by pseudocyst and hemosuccus pancreaticus]. 1572 20

One of ostrich (Struthio camelus) trypsinogen genes was cloned from pancreatic cDNA. Its amino acid sequence compared to known trypsin sequences from other species shows high identity and suggests that it is a member of the phylogenetically anionic trypsinogen I subfamily. After cytoplasmic over expression in Escherichia coli and renaturation, the activation properties of ostrich trypsinogen were studied and compared to those of human trypsinogen 1 (also called as human cationic trypsinogen). Ostrich trypsinogen undergoes bovine enterokinase activation and autoactivation much faster than human trypsinogen 1 and exhibits on a synthetic substrate a somewhat higher enzymatic activity than the latter one. The most interesting property of ostrich trypsin is its relatively fast autolysis that can be explained via a mechanism different from the common mechanism for rat and human 1 trypsins. The latter proteases have a site, Arg117-Val118, where the autolysis starts and then goes on in a zipper-like fashion. This is absent from ostrich trypsin. Instead it has a couple of cleavage sites within regions 67-98, including two unusual ones, Arg76-Glu77 and Arg83-Ser84. These appear to be hydrolysed fast in a non-consecutive manner. Such an autolysis mechanism could not be inhibited by a single-site mutation which in humans is proposed to lead to pancreatitis.
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PMID:Cloning and expression of ostrich trypsinogen: an avian trypsin with a highly sensitive autolysis site. 1575 90

The activation peptide of vertebrate trypsinogens contains a highly conserved tetra-aspartate sequence (Asp(19-22) in humans) preceding the Lys-Ile scissile bond. A large body of research has defined the primary role of this acidic motif as a specific recognition site for enteropeptidase, the physiological activator of trypsinogen. In addition, the acidic stretch was shown to contribute to the suppression of autoactivation. In the present study, we determined the relative importance of these two activation peptide functions in human cationic trypsinogen. Individual Ala replacements of Asp(19-22) had minimal or no effect on trypsinogen activation catalyzed by human enteropeptidase. Strikingly, a tetra-Ala(19-22) trypsinogen mutant devoid of acidic residues in the activation peptide was still a highly specific substrate for human, but not for bovine, enteropeptidase. In contrast, an intact Asp(19-22) motif was critical for autoactivation control. Thus, single Ala mutations of Asp(19), Asp(20) and Asp(21) resulted in 2-3-fold increased autoactivation, whereas the Asp(22) --> Ala mutant autoactivated at a 66-fold increased rate. These effects were multiplicative in the tri-Ala(19-21) and tetra-Ala(19-22) mutants. Structural modeling revealed that the conserved hydrophobic S2 subsite of trypsin and the unique Asp(218), which forms part of the S3-S4 subsite, participate in distinct inhibitory interactions with the activation peptide. Finally, mutagenesis studies confirmed the significance of the negative charge of Asp(218) in autoactivation control. The results demonstrate that in human cationic trypsinogen the Asp(19-22) motif per se is not required for enteropeptidase recognition, whereas it is essential for maximal suppression of autoactivation. The evolutionary selection of Asp(218), which is absent in the large majority of vertebrate trypsins, provides an additional mechanism of autoactivation control in the human pancreas.
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PMID:The tetra-aspartate motif in the activation peptide of human cationic trypsinogen is essential for autoactivation control but not for enteropeptidase recognition. 1597 May 97

Mutations in the human cationic trypsinogen are associated with hereditary pancreatitis. The cDNA coding for human cationic trypsinogen was subcloned into the expression vector pcDNA3. The mutations R122H, N29I, A16V, D22G, and K23R were introduced by site directed mutagenesis. We constructed an expression vector coding for active trypsin by subcloning the cDNA of trypsin lacking the coding region for the trypsin activating peptide behind an appropriate signal peptide. Expression of protein was verified by Western blot and measurement of enzymatic activity. AR4-2J cells were transiently transfected with the different expression vectors and cell viability and intracellular caspase-3 activity were quantified. In contrast to wild-type trypsinogen, expression of active trypsin and mutated trypsinogens reduced cell viability of AR4-2J cells. Expression of trypsin and R122H trypsinogen induced caspase-3 activity. Acinar cells might react to intracellular trypsin activity by triggering apoptosis.
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PMID:Expression of mutated cationic trypsinogen reduces cellular viability in AR4-2J cells. 1603 33


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