UMLS:C0030305 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0030305 (pancreatitis)
16,014 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This report describes a new monoclonal antibody (MAb) designated 47D10 which was produced by immunizing mice against a human lung adenocarcinoma line, A549. The MAb 47D10 reacts with a surface antigen found in 95% of adenocarcinomas of the pancreas as well as on high percentages of adenocarcinomas from colon, breast, lung, and bile duct. The antigen was not detected in normal pancreas, in pancreatitis, or in a variety of normal tissues with the exception of colon and mature granulocytes. Lymphocytes and erythrocytes were also negative. The binding of 47D10 to tumor cells was unaffected by treatment of cells with neuraminidase. Immunoprecipitation followed by polyacrylamide gel electrophoresis showed that 47D10 MAb recognized a group of glycoproteins ranging in molecular weight from 67,000-98,000 on A549 lung carcinoma cells. Pulse-chase labeling showed two precursor proteins with molecular weights of 69,000 and 67,000 which were processed to the larger polypeptides in 1.5 h. At least part of the carbohydrates associated with the 47D10 antigen was asparagine linked because the antigen was sensitive to endoglycosidases, and tunicamycin inhibited the biosynthesis of 47D10 antigen. The 47D10 antigen was expressed on the cell surface because it could be detected on live A549 cells by enzyme-linked immunosorbant assays as well as by immunofluorescent staining. Furthermore, 47D10 antigens on tumor cell lines and granulocytes were vectorially labeled with 125I. The antigen found on granulocytes showed a higher molecular weight of 150,000-180,000, which was digested by endoglycosidase F to polypeptides with molecular weights ranging from 23,000-27,000. In contrast, the degradation product of the A549 antigen was a Mr 39,000 polypeptide after treatment with endoglycosidase F. The immunochemical characteristics of 47D10 antigen suggest that it is distinct from other antigens associated with pancreatic tumors, such as carcinoembryonic antigen, 19-9, and Du-PAN-2. By virtue of its broad range of tumor cell reactivity and low activity on normal cells, the 47D10 MAb may represent an important immunological reagent for differential diagnosis, especially of pancreatic carcinoma.
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PMID:Tissue distribution, immunochemical characterization, and biosynthesis of 47D10, a tumor-associated surface glycoprotein. 353 19

The polyethylene glycol (PEG) adduct of Escherichia coli L-asparaginase was administered intravenously to 4 patients with chemotherapy refractory cancers. The PEG-enzyme in plasma exhibited a half-life of 16-25 days. Doses of 250IU/m2 or greater reduced plasma asparagine to undetectable levels for as long as enzyme was detectable in plasma. All doses of enzyme administered (250-1000 IU/m2) caused similar increases in plasma aspartate, i.e. no dose-response relationship. Pleural fluid and ascites contained detectable enzyme but at a value 10-15% of simultaneously drawn plasma levels. Toxicity in this small group of patients was minimal; nausea and transient fever predominated. There were no clinical signs of PEG-asparaginase-induced pancreatitis, renal dysfunction, hypocalcemia and hyperglycemia. No patient developed evidence of a PEG-asparaginase allergic reaction; no patient formed antibodies to asparaginase or PEG-asparaginase. Two patients with large cell lymphoma showed a partial response to treatment.
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PMID:Pharmacology of Escherichia coli-L-asparaginase polyethylene glycol adduct. 704 23

Familial lipoprotein lipase (LPL) deficiency is an inherited disorder of lipoprotein metabolism characterized by hypertriglyceridemia and recurrent episodes of abdominal pain and pancreatitis. We have studied the genetic basis of LPL deficiency in a 62-year-old black male with undetectable pre- and post-heparin plasma LPL mass and activity, DNA sequence analysis of the patient's LPL cDNA and gene as well as digestion with Bcl I and Asu I revealed that the proband is a homozygote for two separate gene defects. One mutation changed a G to an A, resulting in the conversion of amino acid 9 of the mature protein, aspartic acid (GAC), to asparagine (AAC). The second substitution, a C for a T, replaced tyrosine (TAC) at residue 262 with histidine (CAC). Northern blot analysis of monocyte-derived macrophage RNA demonstrated the presence of LPL mRNA of approximately normal size and quantity when compared to control. Expression of both mutations separately (pCMV-9 and pCMV-262) or in combination (pCMV-9+262) in human embryonal kidney-293 cells demonstrated that LPL-9 had approximately 80% the specific activity of wild type LPL, but LPL-262 and LPL-9+262 had no enzymic activity, thus establishing the functional significance of the LPL-262 defect. Despite an absolute deficiency of LPL mass and activity demonstrated by analysis of patient post-heparin plasma, in vitro expression of both LPL mutants was normal, suggesting that the absence of LPL in patient post-heparin plasma was a result of altered in vivo processing. Analysis of the heparin binding properties of the mutant enzymes by heparin-Sepharose affinity chromatography indicated that most of the LPL-262 mass was present in an inactive peak, which like the normal LPL monomer, eluted at 0.8 M NaCl. Thus, the Tyr262 --> His mutation may alter the stability of the LPL dimer, leading to the formation of inactive LPL-262 monomer which exhibits reduced heparin affinity. Based on these results, we propose that, in vivo, enhanced formation of LPL-9+262 monomer leads to abnormal binding of the mutant lipase to endothelial glycosaminoglycans ultimately resulting in enhanced catabolism of the mutant enzyme and lower enzyme mass in post-heparin plasma.
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PMID:Homozygosity for two point mutations in the lipoprotein lipase (LPL) gene in a patient with familial LPL deficiency: LPL(Asp9-->Asn, Tyr262-->His). 872 26

The removal of amino acids during continuous renal replacement therapies induces clinical problems. Previous studies on animals have shown nephroprotective (glycine, alanine) or negative effects (lysine) on renal function in occurrence of acute renal failure. Disturbed metabolism in acute renal failure needs adequate parenteral nutrition. On the other hand, experience with continuous renal replacement therapies of metabolic crises in inborn errors of metabolism indicate a good control of disturbed amino acid metabolism. The aim of our study was to find amino acids, that might play an important role in the pathogenesis, prognosis and detection of acute renal failure and severe illness, so far only estimated by lactic acid. Thirty-three probes (serum and hemofiltrate) were taken from patients, suffering with acute renal failure caused by septic shock, severe pancreatitis and hepatorenal syndrome, one hour after the beginning of extracorporal circulation, the conditions of treatment were standardized. The material was deproteinized and studied by the amino acid analyzer LBK 4251 Apha Plus (Pharmacia, Stockholm, Sweden), while the lactic acid concentration was determined in a standard laboratory. Proline, glycine, alanine, methionine and histidine showed a close relationship to the lactic acid levels, but these amino acids were an essential part of parenteral nutrition. A statistical relationship was also established in (amino acids with amide groups) asparagine, glutamine, citrulline, cystathionine and phosphoethanolamine. The mean values of most of the amino acids were higher than normal, but standard deviations were increased. The presence of these amino acids in hemofiltrate and the good sieving coefficients could mean that the better prognosis of critically ill patients in continuous renal replacement therapies may also be due to continuous control of amino acid levels (especially with amide groups).
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PMID:Which amino-acids do serum and hemofiltrate of critically ill patients with acute renal failure contain? 925 6

Owing to the high efficacy of L-asparaginase in the treatment of acute lymphatic leukaemia the enzyme was introduced into the chemotherapy schedules for remission induction of this disease shortly after results of large-scale clinical trials had become available. Since asparaginase monotherapy was associated with a high response rate but short remission duration, the enzyme is currently employed within the framework of combination chemotherapy schedules which achieve treatment response in about 90% and long-term remissions in the majority of patients. Recently initiated clinical trials have still confirmed the eminent value of asparaginase in the combination chemotherapy of acute lymphatic leukaemia and of some subtypes of non-Hodgkin lymphoma, and its important role as an essential component of multimodal treatment protocols. Despite the unique mechanism of action of this cytotoxic substance which shows relative selectivity with regard to the metabolism of malignant cells, some patients experience toxic effects during asparaginase therapy. Immunological reactions toward the foreign protein include enzyme inactivation without any clinical manifestations as well as anaphylactic shock. Severe functional disorders of organ systems result from the impaired homeostasis of the amino acids asparagine and glutamine. The changes affecting the proteins of the coagulation system have considerable clinical impact as they may induce bleeding as well as thromboembolic events and may be associated with life-threatening complications when the central nervous system is involved. Risk factors predisposing to thromboembolic complications are hereditary resistance against activated protein C and any other hereditary thrombophilia. Other organ systems potentially affected by relevant functional disorders are the central nervous system, the liver, and the pancreas, with patients who have a history of pancreatic disorders carrying an especially high risk of developing pancreatitis. Studies on the mechanisms of action and the occurrence of resistance phenomena have shown that a treatment response may only be expected if the malignant cells are unable to increase their asparagine synthetase activity to an extent providing enough asparagine to the cell; one may thus conclude that the enzyme-induced asparagine depletion of the serum constitutes the decisive cytotoxic mechanism. Independent of the asparagine depletion related cytotoxicity however, there are other mechanisms of clinical relevance like induction of apoptosis. Besides this, further influences on signal transduction cannot be excluded. Only few publications have dealt with the question of minimum trough activities to be ensured before each subsequent asparaginase dose in order to maintain uninterrupted asparagine depletion under treatment, and answers to this problem are not definitive. Clinical studies using enzymes from E. coli strains indicate that a trough activity of 100 U/l will suffice for complete asparagine depletion of the fluid body compartments with the preparations studied. These findings have been transferred to enzymes from other E. coli strains as well as those isolated from Erwinia chrysanthemi and to the PEG-conjugated E. coli asparaginases. It might be desirable to countercheck the results for confirmation or correction. The dosage and administration schedule of the various enzyme preparations required for complete asparagine depletion over a period of time have been insufficiently defined. While pharmacokinetic studies showed clinically relevant differences in biological activity and activity half-lives for enzymes from different biological sources, the findings of recently published clinical trials indicate that the therapeutic efficacy is affected when different asparaginase preparations are given by identical therapy schedules. (ABSTRACT TRUNCATED)
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PMID:Use of L-asparaginase in childhood ALL. 976 45

Hereditary, chronic pancreatitis is an autosomal dominant genetic disorder, frequently associated with two point mutations in the cationic trypsinogen gene. The mutations result in characteristic changes in the amino-acid sequence of trypsinogen: an arginine residue at position 117 is changed to histidine (Arg117-->His) or an asparagine residue at position 21 is replaced by isoleucine (Asn21-->Ile). Current opinion on the pathogenesis of hereditary pancreatitis suggests that the mutations lead to increased trypsin activity in the pancreatic tissue as a result of enhanced autoactivation of trypsinogen or decreased autocatalytic degradation (autolysis) of trypsin. To investigate the relationship between the altered properties of mutant trypsinogens and the pathomechanism of pancreatitis, wild-type and two mutant forms of recombinant human cationic trypsinogen were produced and autoactivation of trypsinogens and autolysis of trypsins were studied. The results indicate that trypsin stabilization (i.e. decreased autolysis) caused by the Arg117-->His mutation may contribute to the development of pancreatitis, however, the Asn21-->Ile mutation has no such effect. In contrast, enhanced autoactivation of mutant trypsinogens may contribute to the pathogenesis of both forms of hereditary pancreatitis. This notion is strongly supported by the clear correlation between the autoactivation rates of mutant trypsinogens and the severity of clinical symptoms.
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PMID:[Significance of trypsinogen gene mutations in the etiology of hereditary pancreatitis]. 1132 17

Since the identification in 1996 of a "gain of function" missense mutation, R122H, in the cationic trypsinogen gene (PRSS1) as a cause of hereditary pancreatitis, continued screening of this gene in both hereditary and sporadic pancreatitis has found more disease-associated missense mutations than expected. In addition, functional analysis has yielded interesting findings regarding their underlying mechanisms resulting in a gain of trypsin. A critical review of these data, in the context of the complicated biogenesis and complex autoactivation and autolysis of trypsin(ogen), highlights that PRSS1 mutations cause the disease by various mechanisms depending on which biochemical process they affect. The discovery of these mutations also modifies the classical perception of the disease and, more importantly, reveals fascinating new aspects of the molecular evolution and normal physiology of trypsinogen. First, activation peptide of trypsinogen is under strong selection pressure to minimize autoactivation in higher vertebrates. Second, the R122 primary autolysis site has further evolved in mammalian trypsinogens. Third, evolutionary divergence from threonine to asparagine at residue 29 in human cationic trypsinogen provides additional advantage. Accordingly, we tentatively assign, in human cationic trypsinogen, the strongly selected activation peptide as the first-line and the R122 autolysis site as the second-line of the built-in defensive mechanisms against premature trypsin activation within the pancreas, respectively, and the positively selected asparagine at residue 29 as an "amplifier" to the R122 "fail-safe" mechanism.
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PMID:Molecular pathology and evolutionary and physiological implications of pancreatitis-associated cationic trypsinogen mutations. 1170 3

In contrast to that in children, pharmacokinetic, pharmacodynamic, and safety information on pegaspargase in adults is very limited. We administered a single intravenous dose of pegaspargase (2000 IU/m2) as part of a standard frontline induction regimen to 25 adults with newly diagnosed acute lymphoblastic leukemia (ALL), and obtained serum samples on several time points. The population mean peak serum concentration of asparaginase enzymatic activity was 1 IU/mL, the elimination half-life was 7 days, and the volume of distribution was 2.43 L/m2. After the single dose, asparagine deamination was complete in all patients after 2 hours, and in 100%, 81%, and 44% on days 14, 21, and 28, respectively. A pharmocodynamic correlation model showed minimal enzymatic activity of 0.2 IU/mL for optimal asparagine depletion. The kinetic posthoc analyses demonstrated enzymatic activity for 3 weeks or more. One patient developed neutralizing antiasparaginase antibodies on day 22 after administration. Pegaspargase was well tolerated, with few grade 3/4 side effects. No allergic reactions or pancreatitis were observed. In adults aged 55 years or younger, pegaspargase produces a long duration of asparagine depletion and can be given intravenously, with a safety profile that is similar to equivalent multiple doses of intramuscular Escherichia coli asparaginase.
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PMID:Pharmacodynamics and safety of intravenous pegaspargase during remission induction in adults aged 55 years or younger with newly diagnosed acute lymphoblastic leukemia. 1713 21

On July 24, 2006, the U.S. Food and Drug Administration granted approval to pegaspargase (Oncaspar; Enzon Pharmaceuticals, Inc., Bridgewater, NJ; hereafter, O) for the first-line treatment of patients with acute lymphoblastic leukemia (ALL) as a component of a multiagent chemotherapy regimen. O was previously approved in February 1994 for the treatment of patients with ALL who were hypersensitive to native forms of L-asparaginase. The trial supporting this new indication was an open label, randomized, multicenter clinical trial that enrolled 118 children (age, 1-9 years) with previously untreated, standard risk ALL. Patients received either native Escherichia coli asparaginase (Elspar; Merck, Whitehouse Station, NJ; hereafter, E) or O along with multiagent chemotherapy during remission induction and delayed intensification (DI) phases of treatment. O, at a dose of 2,500 IU/m(2), was administered i.m. on day 3 of the 4-week induction phase and on day 3 of each of two 8-week DI phases. E, at a dose of 6,000 IU/m(2), was administered i.m. three times weekly for nine doses during induction and for six doses during each DI phase. This study allowed direct comparison of O and E for asparagine depletion, asparaginase activity, and development of asparaginase antibodies. An unplanned comparison of event-free survival (EFS) was conducted to rule out a deleterious O efficacy effect. Following induction and DI treatment there was complete (</=1 microM) or moderate (1-10 microM) depletion of serum asparagine levels in the large majority of samples tested over the 4-week period in both O-treated and E-treated subjects. Similarly, depletion of cerebrospinal fluid asparagine levels during induction was similar between O-treated and E-treated subjects. The number of days asparaginase activity exceeded >0.03 IU/ml in O-treated subjects was greater than the number of days in E-treated subjects during both the induction and DI phases of treatment. There was no correlation, however, between asparaginase activity and serum asparagine levels, making the former determination less clinically relevant. Using the protocol-prespecified threshold for a positive result of >2.5 times the control, 7 of 56 (12%) O subjects tested at any time during the study demonstrated antiasparaginase antibodies and 16 of 57 (28%) E subjects tested at any time during the study had antiasparaginase antibodies. In both study arms EFS was in the range of 80% at 3 years. The most serious, sometimes fatal, O toxicities were anaphylaxis, other serious allergic reactions, thrombosis (including sagittal sinus thrombosis), pancreatitis, glucose intolerance, and coagulopathy. The most common adverse events were allergic reactions (including anaphylaxis), hyperglycemia, pancreatitis, central nervous system thrombosis, coagulopathy, hyperbilirubinemia, and elevated transaminases. Disclosure of potential conflicts of interest is found at the end of this article.
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PMID:FDA drug approval summary: pegaspargase (oncaspar) for the first-line treatment of children with acute lymphoblastic leukemia (ALL). 1776 59

The cure rate for children with acute lymphoblastic leukaemia (ALL) has increased to approximately 70%, in part related to the use of the protein synthesis inhibitor drug asparaginase in multiagent chemotherapy regimens. Its lack of haematological toxicity allows its incorporation into phases of therapy in which myelosuppression would be expected either from the disease itself (induction therapy) or secondary to other chemotherapeutic agents (consolidation, intensification or reinduction phases of therapy). Its antileukaemic effect is related to the degree and duration of asparagine depletion. The 2 native forms of L-asparaginase are derived from Escherichia coli and Erwinia chrysanthemi. The half-lives (t((1/2))) of these forms are approximately 1.2 and 0.6 days, respectively. In order to increase the biological t((1/2)), pegaspargase was synthesised by the covalent attachment of monomethoxypolyethylene glycol (PEG) to native E. coli L-asparaginase: it has a t((1/2)) of approximately 5.7 days. The duration of asparagine depletion, the substrate amino acid of the drug, is directly related to asparaginase t((1/2)). Asparaginase is associated with several unique toxicities, including hyperglycaemia, hypolipoproteinaemia, hypoalbuminaemia, coagulation factor deficiencies, hepatotoxicity and pancreatitis. Since asparaginase is a protein, it may induce hypersensitivity reactions. The incidence of these reactions increases with use. In addition, silent hypersensitivity, i.e. the development of IgG antibodies without clinical reactions, results in a decreased t((1/2)) of asparaginase, shortened duration of asparagine depletion, and probably decreased efficacy. The use of pegaspargase allows continued treatment with asparaginase in patients with clinical hypersensitivity reactions. In addition, its use in patients with silent hypersensitivity may maintain the efficacy of asparaginase. So far, the optimal use of the 3 forms of asparaginase has not been determined in children with ALL, partly due to the lack of appropriate pharmacokinetic monitoring methods. As the technology has become available, it has been demonstrated that there is little rationale for the dosage and administration schedules presently in use. Studies are required to determine appropriate dosages and administration methods (intravenous or intramuscular) and schedules for each form of asparaginase, based upon pharmacokinetic parameters. The incidence and time to onset of hypersensitivity (clinical or silent) reactions and the appropriate means of continuing asparaginase therapy with therapeutic effect needs to be evaluated. Pharmacokinetic studies are now available as a research tool. These will allow further investigation to determine if failure to maintain asparagine depletion is a remediable cause of treatment failure.
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PMID:Acute lymphoblastic leukaemia: a guide to asparaginase and pegaspargase therapy. 1803 Oct 78

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