Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.5.1.1 (asparaginase)
 2,695 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The resistance of certain tumor cells to the chemotherapeutic agent L-asparaginase has often been found to be associated with the presence of asparagine synthetase activity. In an attempt to study the translational regulation of the asparagine synthetase gene, the 5'-untranslated region of human asparagine synthetase cDNA was mapped by antisense oligonucleotide-mediated hybrid arrest translation in reticulocyte lysate. Three consecutive cis-acting regulatory elements, spanning from -60 to -120 bases from the initiation codon, in the 5'-untranslated region of the asparagine synthetase gene, were identified. T1 RNase footprinting analysis showed that those regulatory elements can be protected from T1 digestion when incubated with reticulocyte lysate. A 46-kDa trans-acting protein factor that interacts with the cis-acting regulatory element of asparagine synthetase mRNA was detected. This 46-kDa protein factor is most likely to be the eucaryotic peptide chain initiation factor eIF-4A as determined by immunoprecipitation experiments using a monoclonal antibody raised against reticulocyte eIF-4A.
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PMID:Interaction of the eucaryotic peptide chain initiation factor eIF-4A with the specific elements at the 5'-untranslated sequence of human asparagine synthetase mRNA. 809 51

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

Complete amino acid deprivation in mammalian cells causes a significant enhancement in gene expression for a number of important cellular activities; among these is asparagine synthetase (AS). The data presented demonstrate that, in both nonleukemic (rat Fao hepatoma cells) and human leukemia cells (MOLT-4, NALL-1, and BALL-1), AS mRNA levels, protein content, and enzymatic activity are induced after incubation in an otherwise complete tissue culture medium that is deficient in a single amino acid or in medium that has been depleted of the amino acid asparagine by the addition of asparaginase. Complete amino acid deprivation results in a concerted increase in AS mRNA, protein, and enzymatic activity, which, in conjunction with previously published research, suggests that the mechanism of this cellular response involves transcriptional control of the AS gene. Asparaginase treatment is a standard component of acute lymphoblastic leukemia therapy for which the effectiveness is related to the inability of these cells to upregulate AS activity to a sufficient level. With regard to the asparaginase sensitivity of the three human leukemia cell lines, there was a trend toward an inverse relation to the degree of AS expression. Selection for asparaginase-resistant MOLT-4 sublines resulted in enhanced AS mRNA and protein content regardless of whether the cells had been selected by asparaginase treatment directly or asparagine was removed from the culture medium. Collectively, the data illustrate that further advances in asparaginase therapy will require additional knowledge of amino acid-dependent regulation of AS gene expression and, conversely, that asparaginase resistance represents a model system for investigating metabolite control in a clinically relevant setting.
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PMID:Amino acid control of asparagine synthetase: relation to asparaginase resistance in human leukemia cells. 957 15

The L-asparaginase of Escherichia coli (ASNase) is currently used in combination with antineoplastic drugs to treat various lymphoblastic leukaemias. However, its use is limited by severe immunological reactions and the short serum half-life associated with the enzyme. Immobilization of ASNase into a biocompatible matrix can greatly decrease the immunogenicity of the enzyme, increase its half-life in vivo and its therapeutic index. Thus the E. coli ASNase was immobilized in a biocompatible hydrogel made of rat serum albumin and poly(ethylene glycol) (PEG; molecular mass 10 kDa). The effectiveness of this enzymic bioreactor to deplete serum L-asparagine was evaluated after its peritoneal implantation in rats. Seven units of immobilized ASNase/rat depleted serum asparagine to an undetectable level (< 1 microM) during 6 days, while 5 units of immobilized ASNase/rat decreased the level of serum asparagine by 85-90% during at least 2 days. Under both conditions asparagine levels returned to normal about 10 days after surgery, and hydrogels still retained 80% of their enzymic activity when assayed in vitro. After 10-14 days in vivo, hydrogels became opaque and surrounded by a fibrotic capsule with a few inflammatory sites. Nevertheless, the enzymic hydrogel showed great stability in vivo, and, after 4 months of implantation, 12% of the initial ASNase activity was still present. At 6 months, histological analysis showed stabilization of the fibrotic capsule thickness. Assays on the levels of ASNase and asparagine synthetase indicated an induction of the latter activity, mainly in the pancreas when compared with the level observed in spleen or liver. ELISA tests at 28 days and 120 days showed the presence of anti-ASNase (and, in lower amounts, anti-PEG) antibodies in sera of implanted rats. As observed with other enzyme-immobilization systems used in vivo, the formation of fibroblast-like cell layers around the implant, which block the translocation of the substrate into the enzymic matrix, is the major factor affecting the performance and longevity of the bioreactor.
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PMID:Immobilization of L-asparaginase into a biocompatible poly(ethylene glycol)-albumin hydrogel: evaluation of performance in vivo. 942 58

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

Lack of sufficient cellular activity of asparagine synthetase (AS) in blast cells compared with normal tissue is thought to be the basis of the antileukaemic effect of L-asparaginase in acute lymphoblastic leukaemia (ALL). Although L-asparaginase is routinely used in ALL, its role and value in the treatment of acute myelogenous leukaemia (AML) is still being discussed. To evaluate the pharmacological basis for L-asparaginase treatment, we established pretreatment monitoring of the intracellular AS activity in blast cells of patients with AML and ALL. There was no general difference in AS activity between ALL and AML samples. Significantly lower AS activity, however, was found in the B-lineage ALL subgroups as well as AML-M5.
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PMID:Asparagine synthetase activity in paediatric acute leukaemias: AML-M5 subtype shows lowest activity. 1084 36

Childhood acute lymphoblastic leukaemia (ALL) is treated by combination chemotherapy with a number of drugs, always including the enzyme L-asparaginase (ASNase). Although the initial remission rate is quite high, relapse and associated drug resistance are a significant problem. In vitro studies have demonstrated increased asparagine synthetase (AS) expression in ASNase-resistant cells, which has led to the hypothesis that elevated AS activity permits drug-resistant survival. The data presented show that not only is elevated AS expression a property of ASNase-resistant MOLT-4 human leukaemia cells, but that short-term (12 h) treatment of the cells with ASNase causes a relatively rapid induction of AS expression. The results also document that the elevated expression of AS in ASNase-resistant cells is not fully reversible, even 6 weeks after ASNase removal from the culture medium. Furthermore, ASNase resistance, assessed as both drug-insensitive cell growth rates and decreased drug-induced apoptosis, parallels this irreversible AS expression. Mimicking the elevated AS activity in ASNase-resistant cells by overexpression of the human AS protein by stable retroviral transformation of parental MOLT4 cells is sufficient to induce the ASNase-resistance phenotype. These data document that ASNase resistance in ALL cells is a consequence of elevated AS expression and that although other drug-induced metabolic changes occur, they are secondary to the increased asparagine biosynthetic rate.
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PMID:Asparagine synthetase expression alone is sufficient to induce l-asparaginase resistance in MOLT-4 human leukaemia cells. 1141 66

Childhood acute lymphoblastic leukaemia is treated by combination chemotherapy with a number of drugs, almost always including the enzyme L-asparaginase (ASNase). Although the initial remission rate is quite high, relapse and associated drug resistance remain a problem. In vitro studies have demonstrated an adaptive increase in asparagine synthetase (AS) expression in ASNase-resistant cells, which is believed to permit ASNase-resistant human leukaemia cells to survive in vivo. The present results, obtained with ASNase-sensitive and -resistant human MOLT-4 leukaemia cell lines, illustrate that several other adaptive processes occur to provide sufficient amounts of the AS substrates, aspartate and glutamine, required to support this increased enzymic activity. In both cell populations, aspartate is derived almost exclusively from intracellular sources, whereas the necessary glutamine arises from both intracellular and extracellular sources. Transport of glutamine into ASNase-resistant cells is significantly enhanced compared with the parental cells, whereas amino acid efflux (e.g. asparagine) is reduced. Most of the adaptive change for the amino acid transporters, Systems A, ASC and L, is rapidly (12 h) reversed following ASNase removal. The enzymic activity of glutamine synthetase is also enhanced in ASNase-resistant cells by a post-transcriptional mechanism. The results demonstrate that there are several sites of metabolic adaptation in ASNase-treated leukaemia cells that serve to promote the replenishment of both glutamine and asparagine.
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PMID:Multiple adaptive mechanisms affect asparagine synthetase substrate availability in asparaginase-resistant MOLT-4 human leukaemia cells. 1148 52

We have sequenced the promoter region of the murine asparagine synthetase gene and examined its methylation profile in the CpG islands of L-asparaginase-sensitive 6C3HED cells (asparagine auxotrophs) and resistant variants (prototrophs). In the former, complete methylation of the CpG island is correlated with failure of expression of mRNA: cells of the latter possess both methylated and unmethylated alleles, as do cells of the intrinsically asparagine-independent lines L1210 and EL4. A similar phenomenon was seen in normal splenic cells of adult mice. This was age related: no methylation was found in weanlings, but up to 45% of gene copies in animals 18 weeks or older were methylated. It was also tissue related, with methylation occurring rarely in liver cells. The relationship of these changes to oncogenesis is considered.
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PMID:Hypermethylation of CpG islands in the mouse asparagine synthetase gene: relationship to asparaginase sensitivity in lymphoma cells. Partial methylation in normal cells. 1155 48

With 35,000 genes and hundreds of thousands of protein states to identify, correlate, and understand, it no longer suffices to rely on studies of one gene, gene product, or process at a time. We have entered the "omic" era in biology. But large-scale omic studies of cellular molecules in aggregate rarely can answer interesting questions without the assistance of information from traditional hypothesis-driven research. The two types of science are synergistic. A case in point is the set of pharmacogenomic studies that we and our collaborators have done with the 60 human cancer cell lines of the National Cancer Institute's drug discovery program. Those cells (the NCI-60) have been characterized pharmacologically with respect to their sensitivity to >70,000 chemical compounds. We are further characterizing them at the DNA, RNA, protein, and functional levels. Our major aim is to identify pharmacogenomic markers that can aid in drug discovery and design, as well as in individualization of cancer therapy. The bioinformatic and chemoinformatic challenges of this study have demanded novel methods for analysis and visualization of high-dimensional data. Included are the color-coded "clustered image map" and also the MedMiner program package, which captures and organizes the biomedical literature on gene-gene and gene-drug relationships. Microarray transcript expression studies of the 60 cell lines reveal, for example, a gene-drug correlation with potential clinical implications--that between the asparagine synthetase gene and the enzyme-drug L-asparaginase in ovarian cancer cells.
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PMID:Searching for pharmacogenomic markers: the synergy between omic and hypothesis-driven research. 1167 54


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