UMLS:C0019829 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0019829 (Hodgkin's disease)
30,247 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

L-asparaginase is an enzyme which hydrolyses asparagine. Since the 1960s it has been known that some leukemic cells are deficient in asparagine synthetase and therefore cannot manufacture sufficient quantities of this essential amino acid to maintain cell viability. L-asparaginase is predominantly useful in acute lymphocytic leukemia (ALL) although responses have been noted in patients with acute myeloid leukemia, lymphoma, and rarely other tumors. L-asparaginase has been used in conjunction with methotrexate and ara-C in combination programs in leukemia. The major side-effect limiting the usefulness of L-asparaginase is allergic reactions. In addition, it is probable that neutralizing antibodies develop which shorten the half life of the drug so that the goal of depletion of plasma levels of asparagine cannot be attained or maintained. Polyethylene glycol (M.W. 5000) can be conjugated to L-asparaginase at sites not involving the active site of the enzyme. This enables free access of a small molecule, asparagine, to the active site of the enzyme but prevents uptake by the reticuloendothelial system, greatly decreasing the probability of developing antibodies against the asparaginase and prolongs the circulating half life of the drug. In a phase I/II study conducted at the M.D. Anderson Cancer Center, 37 heavily pretreated patients with refractory hematologic malignancy were treated. The age range from 15 to 73 years, median 49 years. Nineteen patients had ALL, 15 lymphoma, two myeloma, and one Hodgkin's disease. The dose levels of PEG L-asparaginase varied from 250 IU/m2 up to 8000 IU/m2. The pharmacokinetic profile demonstrated a monophasic half life consistent with a one compartment model with a single elimination phase.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:L-asparaginase and PEG asparaginase--past, present, and future. 848 65

A cDNA encoding human bleomycin hydrolase, a member of the cysteine proteinase family of proteins, has been cloned from a human brain cDNA library. The isolated cDNA contains an open reading frame coding for a polypeptide of 456 amino acids that contains all of the structural features characteristic of cysteine proteinases, including the cysteine, histidine, and asparagine residues that are essential for the catalytic properties of these enzymes. The deduced amino acid sequence for human bleomycin hydrolase shows 92, 40, and about 35% of identities with those determined for rabbit bleomycin hydrolase, yeast bleomycin hydrolase, and bacterial aminopeptidase C, respectively. Northern blot analysis of poly(A)+ RNAs isolated from a variety of human tissues demonstrated that human bleomycin hydrolase is expressed in all examined tissues, which is consistent with a putative role of this protein as a proteolytic enzyme involved in norman cellular protein degradation and turnover. Preliminary expression analysis of bleomycin hydrolase in different human tumors showed increased expression of the enzyme in a series of head and neck carcinomas when compared with paired adjacent normal mucosa. We also observed a variable degree of bleomycin hydrolase expression in different types of lymphoma, with low or undetectable levels in Hodgkin's disease samples and higher levels in Burkitt's lymphomas. These results are consistent with a proposed role for human bleomycin hydrolase in resistance of some tumor to bleomycin chemotherapy.
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PMID:Cloning and expression analysis of human bleomycin hydrolase, a cysteine proteinase involved in chemotherapy resistance. 862 Apr 87

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

The channel of the glutamate N-methyl-D-aspartate receptor (NMDAR) transports Ca2+ approximately four times more efficiently than that of Ca2+-permeable alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate receptors (AMPAR). To investigate the basis of this difference in these glutamate receptors (GluRs), we measured the ratio of Cs+ efflux and Ca2+ influx in recombinant NMDAR and Ca2+-permeable AMPAR channels expressed in human embryonic kidney 293 (HEK 293) cells over a wide voltage range. At any one potential, this biionic flux ratio was measured by quantifying the total charge and the charge carried by Ca2+ using whole-cell currents and fluorometric techniques (dye overload) with Cs+ internally and Ca2+ externally (1.8 or 10 mM) as the only permeant ions. In AMPAR channels, composed of either GluR-A(Q) or GluR-B(Q) subunits, the biionic flux ratio had a biionic flux-ratio exponent of 1, consistent with the prediction of the Goldman-Hodgkin-Katz current equation. In contrast, for NMDAR channels composed of NR1 and NR2A subunits, the biionic flux-ratio exponent was approximately 2, indicating a deviation from Goldman-Hodgkin-Katz. Consistent with these results, in NMDAR channels under biionic conditions with high external Ca2+ and Cs+ as the reference ions, Ca2+ permeability (PCa/PCs) was concentration dependent, being highest around physiological concentrations (1-1.8 mM; PCa/PCs approximately 6.1) and reduced at both higher (110 mM; PCa/PCs approximately 2.6) and lower (0.18 mM; PCa/PCs approximately 2.2) concentrations. PCa/PCs in AMPAR channels was not concentration dependent, being around 1.65 in 0.3-110 mM Ca2+. In AMPAR and NMDAR channels, the Q/R/N site is a critical determinant of Ca2+ permeability. However, mutant AMPAR channels, which had an asparagine substituted at the Q/R site, also showed a biionic flux-ratio exponent of 1 and concentration-independent permeability ratios, indicating that the difference in Ca2+ transport is not due to the amino acid residue located at the Q/R/N site. We suggest that the difference in Ca2+ transport properties between the glutamate receptor subtypes reflects that the pore of NMDAR channels has multiple sites for Ca2+, whereas that of AMPAR channels only a single site.
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PMID:Different mechanisms of Ca2+ transport in NMDA and Ca2+-permeable AMPA glutamate receptor channels. 980 70

We examined the types of Epstein-Barr virus-associated nuclear antigen-1 (EBNA-1) gene carboxy (C)-terminal mutations occurring in Hodgkin's disease (HD) and reactive tissues from two different geographic regions. Previously reported EBNA-1 C-terminal region amino acid sequence variants, based on the amino acid at codon 487, include Prototype (P)-ala, which is found in the B95.8-derived prototype virus, P-thr, Variant (V)-leu, V-val, and V-pro. Using polymerase chain reaction (PCR) to amplify portions of the EBNA-1 gene, followed by DNA sequencing, we found a single EBNA-1 gene sequence variant in each tissue, whether reactive or neoplastic and whether from Brazil or the United States. Variant EBNA-1 gene sequences were more common in both neoplastic and non-neoplastic tissues from different geographic areas than the so-called prototype sequence. In the 17 Brazilian HD cases, 4 cases had P-thr variants and 13 had V-leu variants. In the six reactive tissues from Brazil, one had a P-ala variant, two had P-thr variants, and three had V-leu variants. In the 12 American HD cases, 2 had P-ala variants, 6 had P-thr variants, and 4 had V-leu variants. The 11 American reactive tissues included 2 P-ala variants, 5 P-thr variants, and 4 V-leu variants. In both countries, there were similar variant EBNA-1 sequences present in normal tissues and HD cases. Compared with the P-ala and P-thr cases, the V-leu cases were more likely to have the 30-bp latent membrane protein 1 (LMP1) gene deletion (P = 0.0075). In addition, cases of HD with the V-leu were statistically associated with a substitution of asparagine for glutamine at codon 322 of the C-terminal portion of the LMP1 gene. Our results suggest that any variation in EBNA-1 gene sequence is caused by a polymorphism present in pre-existing viral strains in the underlying population, and not a mutation occurring during oncogenesis.
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PMID:EBNA-1 gene sequences in Brazilian and American patients with Hodgkin's disease. 1038 19

Veltuzumab is a humanized anti-CD20 monoclonal antibody with complementarity-determining regions (CDRs) identical to rituximab, except for one residue at the 101st position (Kabat numbering) in CDR3 of the variable heavy chain (V(H)), having aspartic acid (Asp) instead of asparagine (Asn), with framework regions of epratuzumab, a humanized anti-CD22 antibody. When compared with rituximab, veltuzumab has significantly reduced off-rates in 3 human lymphoma cell lines tested, as well as increased complement-dependent cytotoxicity in 1 of 3 cell lines, but no other in vitro differences. Mutation studies confirmed that the differentiation of the off-rate between veltuzumab and rituximab is related to the single amino acid change in CDR3-V(H). Studies of intraperitoneal and subcutaneous doses in mouse models of human lymphoma and in normal cynomolgus monkeys disclosed that low doses of veltuzumab control tumor growth or deplete circulating or sessile B cells. Low- and high-dose veltuzumab were significantly more effective in vivo than rituximab in 3 lymphoma models. These findings are consistent with activity in patients with non-Hodgkin lymphoma given low intravenous or subcutaneous doses of veltuzumab. Thus, changing Asn(101) to Asp(101) in CDR3-V(H) of rituximab is responsible for veltuzumab's lower off-rate and apparent improved potency in preclinical models that could translate into advantages in patients.
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PMID:Properties and structure-function relationships of veltuzumab (hA20), a humanized anti-CD20 monoclonal antibody. 1894 Nov 14

A 66-year-old Japanese woman was referred to us because of severe anemia and fever and presented at our hospital. She was eventually diagnosed as having acute myeloblastic leukemia (AML; M0) with non-Hodgkin lymphoma (NHL). We investigated the therapeutic efficacy of L-asparaginase (L-Asp), vincristine and prednisolone for both her AML and NHL. Asparagine synthetase (AS) activity in her AML blast cells was undetectable. A lymph node biopsy specimen revealed NHL of the marginal zone B cell type. Complete remission (CR) of AML and NHL was achieved. CR of the AML lasted for 18 months without further consolidation therapy. We conclude that L-Asp can be an effective drug for the treatment of AML in which blasts are negative for AS.
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PMID:Effect of L-asparaginase combined with vincristine and prednisolone on acute myeloblastic leukemia (M0) associated with non-Hodgkin lymphoma. 1981 10

L-asparaginase (L-ASP) is one of the cornerstones of the treatment of acute lymphoblastic leukemia and non-Hodgkin lymphoma. It is an enzyme of bacterial origin capable of transforming L-asparagine to aspartic acid. The extracellular depletion of L-asparagine inhibits protein synthesis in lymphoblasts, inducing their apoptosis. Numerous studies have demonstrated that treatment with L-ASP improves survival of patients, but there are clear differences in the characteristics of the three currently available formulations. This article reviews the dosage, activity and side effects of the two L-ASP derived from Escherichia coli (native and pegylated), and the one derived from Erwinia chrysanthemi (Erwinia ASP). Despite its indisputable indication over the past50 years, there are still many points of contention, and its use is still marked by the side effects of the inhibition of protein synthesis. The short half-life of native forms, and the most frequently used parenteral administration by intramuscular injections, affects the quality of life of the patients. Therefore, recent studies claim to evaluate alternatives, such as the formulation of longer half-life pegylated L-ASP, and the use of intravenous formulations. There are encouraging results to date with both preparations. Still, further studies are needed to establish which should be the formulation and frontline indicated route of administration, optimal dosing, and management of adverse effects.
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PMID:[Update on L-asparaginase treatment in paediatrics]. 2372 26

l-asparaginase (EC 3.5.1.1) is an enzyme that catalysis mainly the asparagine hydrolysis in l-aspartic acid and ammonium. This enzyme is presented in different organisms, such as microorganisms, vegetal, and some animals, including certain rodent's serum, but not unveiled in humans. It can be used as important chemotherapeutic agent for the treatment of a variety of lymphoproliferative disorders and lymphomas (particularly acute lymphoblastic leukemia (ALL) and Hodgkin's lymphoma), and has been a pivotal agent in chemotherapy protocols from around 30 years. Also, other important application is in food industry, by using the properties of this enzyme to reduce acrylamide levels in commercial fried foods, maintaining their characteristics (color, flavor, texture, security, etc.) Actually, l-asparaginase catalyzes the hydrolysis of l-asparagine, not allowing the reaction of reducing sugars with this aminoacid for the generation of acrylamide. Currently, production of l-asparaginase is mainly based in biotechnological production by using some bacteria. However, industrial production also needs research work aiming to obtain better production yields, as well as novel process by applying different microorganisms to increase the range of applications of the produced enzyme. Within this context, this mini-review presents l-asparaginase applications, production by different microorganisms and some limitations, current investigations, as well as some challenges to be achieved for profitable industrial production.
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PMID:Current applications and different approaches for microbial l-asparaginase production. 2786 36

This note highlights our understanding and thinking about the feasibility of l-asparaginase as therapeutics for multiple diseases. l-asparaginase enzyme (l-asparagine amidohydrolase, EC 3.5.1.1) is prominently known for its chemotherapeutic application. It is primarily used in the treatment of acute lymphoblastic leukemia in children. It is also used in the treatment of other forms of cancer Hodgkin disease, lymphosarcoma, acute myelomonocytic leukemia, acute myelogenous leukemia, chronic lymphocytic leukemia, reticulosarcoma and melanosarcoma (Lopes et al. Crit Rev Biotechnol 23:1-18, 2015). It deaminates l-asparagine present in the plasma pool causing the demise of tumor cell due to nutritional starvation. The anti-tumorigenic property of this enzyme has been exploited for over four decades and evidenced as a boon for the cancer patients. Presently, the medical application of l-asparaginase is limited only in curing various forms of cancer.
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PMID:l-Asparaginase: a feasible therapeutic molecule for multiple diseases. 2987 9

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