EC:3.1.3.5 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.3.5 (5'-nucleotidase)
3,167 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

It is well known that adenine-based purines exert multiple effects on pain transmission. However, less attention has been given to the potential effects of guanine-based purines (GBPs) on pain transmission. The aim of this study was to investigate the effects of intracerebroventricular (i.c.v.) guanosine and GMP on mice pain models. Mice received an i.c.v. injection of vehicle (saline or 10 muM NaOH), guanosine (5 to 400 nmol), or GMP (240 to 960 nmol). Additional groups were also pre-treated with i.c.v. injection of the A(1)/A(2A) antagonist caffeine (15 nmol), the non-selective opioid antagonist naloxone (12.5 nmol), or the 5'-nucleotidase inhibitor AOPCP (1 nmol). Measurements of CSF purine levels and cortical glutamate uptake were performed after treatments. Guanosine and GMP produced dose-dependent antinociceptive effects. Neither caffeine nor naloxone affected guanosine antinociception. Pre-treatment with AOPCP completely prevented GMP antinociception, indicating that conversion of GMP to guanosine is required for its antinociceptive effects. Intracerebroventricular administration of guanosine and GMP induced, respectively, a 180- and 1800-fold increase on CSF guanosine levels. Guanosine was able to prevent the decrease on cortical glutamate uptake induced by intraplantar capsaicin. This study provides new evidence on the mechanism of action of GBPs, with guanosine and GMP presenting antinociceptive effects in mice. This effect seems to be independent of adenosine and opioid receptors; it is, however, at least partially associated with modulation of the glutamatergic system by guanosine.
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PMID:Antinociceptive effects of intracerebroventricular administration of guanine-based purines in mice: evidences for the mechanism of action. 1870 36

The karyotypes of human melanomas exhibit multiple chromosome alterations. Recurrent deletions of 9p, 10q and 14q arms, which carry genes encoding for enzymes of purine metabolism, were also found in human gliomas, another neuroectodermal tumor previously studied for both cytogenetics and nucleotides metabolism. Postulating that this metabolism might also be modified in melanomas, the activities of eleven enzymes involved in catabolic and synthetic pathways of purine metabolism were measured, in addition to two enzymes of the pyrimidine synthesis. Assays were performed on six melanoma mestastases, five nodal and one cutaneous, after transplantation into nude mice. The purine metabolism was characterized by a more active catabolic than synthetic pathway, a possible imbalance between de novo and salvage pathways for adenylates synthesis, rather in favor of the de novo pathway, and a more active adenylate than guanylate synthesis. The skin metastasis exhibited quite different cytogenetic and metabolic patterns, when compared to the nodal metastases. Considering the relationships between cytogenetic and metabolic data, low activities of methylthioadenosine phosphorylase, adenosine kinase, adenosine monophosphate deaminase, nucleoside phosphorylase and 5'-nucleotidase were observed in melanomas, as well as frequent losses of 9p, 10q, Ip, 14q and 6q arms respectively carrying genes encoding for these enzymes, most of these rearrangements were confirmed by chromosome painting. The two enzymes exhibiting the highest activities were adenosine deaminase and adenylosuccinate lyase, encoded by genes mapped on chromosomes 20 and 22 respectively, frequently in excess in melanomas. Thus, for these tumors, the metabolic pattern roughly parallels the cytogenetic profile, even if the absence of case to case correlation suggests that gene dosage effect, if it occurs, is not the only parameter involved. The main enzymatic and cytogenetic difference between melanomas and gliomas, concerns both adenylosuccinate lyase activity and the balance of chromosome 22, high in melanomas and low in gliomas.
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PMID:Nucleotide-metabolism and chromosome alterations in human-malignant melanoma xenografts. 2155 73

The dependence of Protein Kinase A (PKA) activity on cAMP levels is an important facet of the dimorphic switch between budding and filamentous growth as well as for pathogenicity in some fungi. To better understand these processes in the pathogenic fungus Ustilago maydis, we characterized the structure and biochemical functions of two phosphodiesterase (PDE) genes. Phosphodiesterases are enzymes involved in cAMP turnover and thus, contribute to the regulation of the cAMP-PKA signaling pathway. Two predicted homologs of PDEs were identified in the genome of U. maydis and hypothesized to be involved in cAMP turnover, thus regulating activity of the PKA catalytic subunit. Both umpde1 and umpde2 genes contain domains associated with phosphodiesterase activity predicted by InterPro analysis. Biochemical characterization of recombinantly produced UmPde1 (U. maydis Phosphodiesterase I) and UmPde2 demonstrated that both enzymes have phosphodiesterase activity in vitro, yet neither was inhibited by the phosphodiesterase inhibitor IBMX. Moreover, UmPde1 is specific for cAMP, while UmPde2 has broader substrate specificity, utilizing cAMP and cGMP as substrates. In addition, UmPde2 was also found to have nucleotide phosphatase activity that was higher with GMP compared to AMP. These results demonstrate that UmPde1 is a bona fide phosphodiesterase, while UmPde2 has more general activity as a cyclic nucleotide phosphodiesterase and/or GMP/AMP phosphatase. Thus, UmPde1 and UmPde2 likely have important roles in cell morphology and development and share some characteristics with a variety of non-fungal phosphodiesterases.
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PMID:Two phosphodiesterases from ustilago maydis share structural and biochemical properties with non-fungal phosphodiesterases. 2168 62

Ethanol is a widely consumed drug that acts on the central nervous system (CNS), modifying several signal transduction pathways activated by hormones and neurotransmitters. The zebrafish is an experimental model for the study of human diseases and the use of this species in biochemical and behavioral studies on alcoholism and alcohol-dependence has increased recently. However, there are no data concerning the effects of chronic ethanol exposure on the purinergic system, where extracellular nucleotides act as signaling molecules. Purinergic signaling is controlled by a group of enzymes named ectonucleotidases, which include NTPDases and ecto-5'-nucleotidase already characterized in zebrafish brain. The aim of this study was to evaluate nucleotide hydrolysis by NTPDases and ecto-5'-nucleotidase after long-term ethanol exposure. Additionally, the gene expression patterns of NTPDases1-3 and 5'-nucleotidase were determined. Animals were exposed to 0.5% ethanol for 7, 14, and 28 days. There were no significant changes in ATP and GTP hydrolysis after all treatments. However, a decrease in ADP (46% and 34%) and GDP (48% and 36%) hydrolysis was verified after 7 and 14 days, respectively. After 7 and 14 days of ethanol exposure, a significant decrease in AMP hydrolysis (48% and 36%) was also observed, whereas GMP hydrolysis was inhibited only after 7 days (46%). NTPDase2_mv and NTPDase3 mRNA transcript levels decreased after 7 and 14 days, respectively. In contrast, ethanol increased NTPDase1, NTPDase2_mq, and NTPDase3 transcript levels after 28 days of exposure. NTPDase2_mg and 5'-nucleotidase gene expression was not altered. Therefore, the ectonucleotidase pathway may be a target of chronic ethanol toxicity and the regulation of purinergic system could play a key role in the neurochemical mechanisms underlying the effects of ethanol on the CNS.
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PMID:Chronic ethanol treatment alters purine nucleotide hydrolysis and nucleotidase gene expression pattern in zebrafish brain. 2170 70

IMP preferring cytosolic 5'-nucleotidase II (cN-II) is a widespread enzyme whose amino acid sequence is highly conserved among vertebrates. Fluctuations of its activity have been reported in some pathological conditions and its mRNA levels have been proposed as a prognostic factor for poor outcome in patients with adult acute myeloid leukemia. As a member of the oxypurine cycle, cN-II is involved in the regulation of intracellular concentration of 5'-inosine monophosphate (IMP), 5'-guanosine monophosphate (GMP), and also 5-phosphoribose 1-pyrophosphate (PRPP) and is therefore involved in the regulation of purine and pyrimidine de novo and salvage synthesis. In addition, several studies demonstrated the involvement of cN-II in pro-drug metabolism. Notwithstanding some publications indicating that cN-II is essential for the survival of several cell types, its role in cell metabolism remains uncertain. To address this issue, we built two eucaryotic cellular models characterized by different cN-II expression levels: a constitutive cN-II knockdown in the astrocytoma cell line (ADF) by short hairpin RNA (shRNA) strategy and a cN-II expression in the diploid strain RS112 of Saccharomyces cerevisiae. Preliminary results suggest that cN-II is essential for cell viability, probably because it is directly involved in the regulation of nucleotide pools. These two experimental approaches could be very useful for the design of a personalized chemotherapy.
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PMID:Initial studies to define the physiologic role of cN-II. 2213 70

Among the members of the 5'-nucleotidase family, there is only one membrane-bound ectosolic isoenzyme. This esterase prefers AMP as substrate but can hydrolyze a number of purine and pyrimidine phosphorylated compounds, indicating that no evolutive pressure to develop a more restricted specificity was exerted on this enzyme. On the contrary, five cytosolic isoforms have been evolved, probably by convergent evolution, showing different and restricted substrate specificity. The different isoforms have different level of expression and distribution in organs of vertebrates. The cytosolic nucleotidase specific for IMP and GMP (cN-II), is an enzyme allosterically regulated, structurally strongly conserved and expressed at a low but constant level in all organs and tissues in vertebrates. As far as we know, alteration of cN-II expression is limited to pathological conditions. In this review, we report the results of the modulation of cN-II specific activity exerted by silencing or hyperexpression in different cell types, in the attempt to better understand its role and implications in pathology and therapy.
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PMID:On the physiological role of cytosolic 5'-nucleotidase II (cN-II): pathological and therapeutical implications. 2399 10

Cytosolic 5'-nucleotidase II (cN-II) is an intracellular 5'-nucleotidase characterized by substrate specificity. It preferentially hydrolyzes 6-hydroxypurine nucleotides such as IMP and GMP over AMP or UMP. cN-II is allosterically activated by ATP and inhibited by inorganic phosphate. It also has phosphotransferase activity and transfers phosphate moieties from IMP or GMP to nonphysiological nucleoside analogues used to treat some viral infections or malignancies. The cN-II gene has a strikingly conserved primary structure from humans to nematodes and its activity has been detected in various animals including snails. Its activity is highest in the livers of birds, crocodiles, lizards and snakes. The activity in chicken liver increases 2-fold by feeding a high-protein diet. These results suggest that cN-II participates, through IMP dephosphorylation, in production of uric acid as the main end product of aminonitrogen in these animals. Some studies suggest that cN-II participates in dephosphorylation of IMP accumulated in cells of some tissues to diffusible inosine for reutilization by other tissues. It has also been proposed that cN-II, together with purine nucleoside phosphorylase and hypoxanthine-guanine phosphoribosyltransferase, constitutes the "oxypurine cycle", thus regulating intracellular phosphoribosyl pyrophosphate (PRPP) concentrations. As for intracellular dephosphorylation of AMP, another intracellular 5'-nucleotidase, cN-I, is supposed to participate, because it hydrolyzes AMP more preferentially than IMP or GMP. However, for the tissues, in which the expression of cN-I is very low or undetectable, e.g. liver or brain tissues, results have been obtained that suggest the participation of cN-II in intracellular dephosphorylation of AMP.
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PMID:Enzymatic properties and physiological roles of cytosolic 5'-nucleotidase II. 2399 15

Adenosine- and uridine-cytidine kinases, purine-nucleoside phosphorylase, hypoxanthine-guanine phosphoribosyl transferase, and several related enzymes, are components of the salvage pathways which reduce the loss of intracellular purine and pyrimidine rings. Although this could explain the role of these enzymes, it poses a problem of the role of the cytosolic 5'-nucleotidase. Why are nucleosides produced from nucleoside-monophosphates, only to be converted back to the same compounds? To date, it is well established that a cross talk exists between the extracellular and intracellular nucleoside metabolism. In districts, such as brain, which are dependent on salvage nucleotide synthesis, nucleosides are produced through the action of the ecto-5'-nucleotidase, the last component of a series of plasma-membrane bound enzyme proteins, catalyzing the successive dephosphorylation of released nucleoside-triphosphates. Both nucleosidetriphosphates (mainly ATP and UTP) and nucleosides (mainly adenosine), act as extracellular signals. Once transported into cell cytosol, all nucleosides are salvaged back to nucleoside-triphosphates, with the exception of inosine, whose salvage is limited to IMP. Intracellular balance of nucleosides is maintained by the action of several enzymes, such as adenosine deaminase, uridine phosphorylase and cytidine deaminase, and by at least three 5'-nucleotidases, the ADP activated AMP preferring cN-IA, the ATP-ADP activated IMP-GMP preferring cN-II, and the UMP-CMP preferring cN-III. Here we are reviewing the mechanisms whereby cytosolic 5'-nucleotidases control changes in nucleoside and nucleotide concentration, with the aim to provide a common basis for the study of the relationship between biochemistry and other related disciplines, such as physiology and pharmacology.
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PMID:The functional logic of cytosolic 5'-nucleotidases. 2399 16

For several years the IMP/GMP-preferring cytosolic 5'-nucleotidase II (cN-II) has been considered as a therapeutic target in oncology. Indeed, various reports have indicated associations between cN-II expression level and resistance to anticancer agents in several cancer cell lines and in patients affected with neoplasia, mainly by hematologic malignancies. In this paper we present evidence showing that, among the commonly used cytotoxic nucleoside analogs, fludarabine can act as a cN-II inhibitor. In vitro studies using the wild type recombinant cN-II demonstrated that fludarabine inhibited enzymatic activity in a mixed manner (Ki 0.5 mM and Ki' 9 mM), whereas no inhibition was observed with clofarabine and cladribine. Additional experiments with mutant recombinant proteins and an in silico molecular docking indicated that this inhibition is due to an interaction with a regulatory site of cN-II known to interact with adenylic compounds. Moreover, synergy experiments between fludarabine and 6-mercaptopurine in human follicular lymphoma (RL) and human acute promyelocytic leukemia (HL-60) cells transfected with control or cN-II-targeting shRNA-encoding plasmids, showed synergy in control cells and antagonism in cells with decreased cN-II expression. This is in line with the hypothesis that fludarabine acts as a cN-II inhibitor and supports the idea of using cN-II inhibitors in association with other drugs to increase their therapeutic effect and decrease their resistance.
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PMID:The purine analog fludarabine acts as a cytosolic 5'-nucleotidase II inhibitor. 2565

IMP/GMP preferring cytosolic 5'-nucleotidase II (cN-II) is a bifunctional enzyme whose activities and expression play crucial roles in nucleotide pool maintenance, nucleotide-dependent pathways and programmed cell death. Alignment of primary amino acid sequences of cN-II from human and other organisms show a strong conservation throughout the entire vertebrata taxon suggesting a fundamental role in eukaryotic cells. With the aim to investigate the potential role of this homology in protein-protein interactions, a two hybrid system screening of cN-II interactors was performed in S. cerevisiae. Among the X positive hits, the Leucin Rich Repeat (LRR) domain of Ipaf was found to interact with cN-II. Recombinant Ipaf isoform B (lacking the Nucleotide Binding Domain) was used in an in vitro affinity chromatography assay confirming the interaction obtained in the screening. Moreover, co-immunoprecipitation with proteins from wild type Human Embryonic Kidney 293 T cells demonstrated that endogenous cN-II co-immunoprecipitated both with wild type Ipaf and its LRR domain after transfection with corresponding expression vectors, but not with Ipaf lacking the LRR domain. These results suggest that the interaction takes place through the LRR domain of Ipaf. In addition, a proximity ligation assay was performed in A549 lung carcinoma cells and in MDA-MB-231 breast cancer cells and showed a positive cytosolic signal, confirming that this interaction occurs in human cells. This is the first report of a protein-protein interaction involving cN-II, suggesting either novel functions or an additional level of regulation of this complex enzyme.
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PMID:Cytosolic 5'-nucleotidase II interacts with the leucin rich repeat of NLR family member Ipaf. 2581 92

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