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1.
We have established long term cell lines from a patient with adenosine deaminase (ADA)-deficient severe combined immunodeficiency by stimulation of blood and bone marrow cells with PHA and IL-2 followed by transformation of the activated cells with the human retrovirus HTLV-I. Despite the absence of detectable T cells in the patients blood, cell lines grew that carried the phenotype of mature activated T cells. TJF-2, the line established from blood, was characterized in detail. The concentration of ADA in TJF-2 cells was less than 1% of normal (3.2 U vs 413.0 U). Studies with pharmacologic inhibitors of ADA suggest that the residual adenosine deaminating activity of TJF-2 is from an enzyme distinct from true ADA, a nonspecific aminohydrolyase. Growth of TJF-2 cells was hypersensitive to inhibition by 2'-deoxyadenosine compared to normal T cells (ID50, 55 microM vs greater than 1000 microM). Analysis of 2'-deoxyadenosine-challenged cells showed that TJF-2 cells accumulated significant levels of deoxyadenosine triphosphate, whereas normal T cells did not unless they were also incubated with the ADA inhibitor deoxycoformycin. Southern and Northern blot analysis of these cells revealed a grossly intact ADA gene that produced a normal size ADA mRNA. Yet, despite ADA deficiency, cells of the TJF-2 line were otherwise indistinguishable from HTLV-I-transformed T cells derived from normal donors with respect to dependence on exogenous IL-2 for growth, clonal rearrangement patterns of TCR beta-chain genes, response to PHA, and rapid restoration of cellular volume after hypotonic challenge. The TJF-2 line thus represents a unique HTLV-I-transformed human T cell line exhibiting ADA deficiency and its expected metabolic consequences.  相似文献   

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A protein which specifically complexes with adenosine deaminase (complexing protein) has been purified to homogeneity from human plasma. This protein was compared with complexing protein isolated from human kidney. The two proteins produce electrophoretically different forms of high molecular weight adenosine deaminase when combined with the Mr = 36,000 enzyme monomer from erythrocytes. This difference may, at least in part, be due to the greater sialic acid content of complexing protein from plasma. By other criteria, including amino acid composition, total carbohydrate content, and subunit structure, the two proteins are quite similar. In addition, plasma complexing protein shows complete cross-reactivity with anti-kidney complexing protein serum. These results suggest that plasma and kidney complexing proteins are products of the same gene.  相似文献   

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Human gamma-glutamyltransferase (GGT) belongs to a multigenic family and at least three mRNAs are transcribed from the gene that codes for an active enzyme. Four human tumour cell lines (HepG2, LNCap, HeLa and U937) with different GGT levels were used to investigate how GGT activity, total GGT mRNA and each individual GGT mRNA subtype responded to tumour necrosis factor-alpha (TNF-alpha), 12-O-tetradecanoylphorbol 13-acetate (TPA) or sodium butyrate treatment. Butyrate reduced the GGT activity in HepG2 cells, and the level of total GGT mRNA accordingly, whereas TNF-alpha and TPA did not alter these parameters. In LNCap cells, TNF-alpha, TPA, and butyrate reduced the activity as well as the level of GGT total mRNA. In HeLa cells no significant changes were observed either in activity or in mRNA level whereas TPA induced both GGT activity and mRNA levels in U937 cells. The distribution of each GGT mRNA subtype (A, B and C) was found to be cell specific: type B mRNA was the major form in HepG2 cells, while type A was the major form in LNCap and HeLa, type A and type C were expressed almost at the same level in U937 cells. The GGT mRNA subtypes were also differently modulated in these cells after TNF-alpha, TPA or butyrate treatment, suggesting that they are regulated by distinct and cell type specific mechanisms.  相似文献   

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A severe genetic deficiency of adenosine deaminase is causally associated with an autosomal recessive form of severe combined immunodeficiency disease, while subjects with absent erythrocyte but partial lymphocyte enzyme activity remain immunocompetent. The genetic expression of adenosine deaminase in B-lymphoblast cell lines derived from four unrelated subjects with the "partial" enzyme deficiency was examined. Enzymatic activity among these cell lines ranged from 5 to 50% of normal with the level of immunoreactive adenosine deaminase protein either proportional to enzyme activity or elevated in two of the cases. Northern blot analysis using a cDNA probe showed that adenosine deaminase mRNA in each of these cell lines was of normal expected size (1.6-1.8 kilobases) and was present in normal to above normal amounts. Rates of enzyme synthesis varied from 165 to 15% of normal. Adenosine deaminase protein degradation rates in these cell lines were 1.5 to almost 3 times faster than normal, consistent with the observed absence of the enzyme in erythrocytes. From these analyses apparent abnormalities in mRNA regulation, translation, and protein degradation can be identified among the partially adenosine deaminase-deficient cell lines studied. Ultimately, it will be essential to determine the nature of the protein mutation and the gene defect to define the structural alterations and functional abnormalities of enzyme variants isolated from subjects with partial adenosine deaminase deficiency.  相似文献   

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Normal and mutant human adenosine deaminase genes   总被引:2,自引:0,他引:2  
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Adenosine deaminase 1 (ADA1) was purified from human and chicken liver. The purified enzyme had a molecular weight of approximately 42,000 Da on SDS-PAGE. In humans, ADA1 was mainly purified concomitant with ADA-binding protein, dipeptidyl peptidase IV (DPP IV)/CD26; however, in chickens, only ADA1 without DPP IV was purified. Both human and chicken ADA1s showed similar properties on substrate specificities, sensitivities on inhibitors, and pH profile. However, they had different affinities with adenosine-Sepharose and IgG anti-ADA1-Sepharose. Human ADA1 was not adsorbed in adenosine-Sepharose column, but chicken ADA1 was adsorbed. As for IgG anti-ADA1-Sepharose column, the results were converse. Furthermore, human ADA1 could bind to DPP IV whereas chicken ADA1 could not.  相似文献   

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Deoxyadenosine toxicity toward lymphocytes may produce immune dysfunction in patients with adenosine deaminase (adenosine aminohydrolase, EC 3.5.4.4) deficiency. The relationship between endogenous deoxynucleoside synthesis in adenosine deaminase-deficient cells and sensitivity to adenosine and deoxyadenosine toxicity is unclear. The human histiocytic lymphoma cell line (DHL-9) naturally lacks adenosine deaminase, and has minimal levels of thymidine kinase. Dividing DHL-9 cells excrete deoxyadenosine and thymidine into the extracellular space. The present experiments have analyzed nucleoside synthesis and excretion in a mutagenized clone of DHL-9 cells, selected for increased resistance to deoxyadenosine toxicity. The deoxyadenosine-resistant cells excreted both deoxyadenosine and thymidine at a 6-7-fold higher rate than wild-type lymphoma cells. The deoxyadenosine overproduction was accompanied by a reduced ability to form dATP from exogenous deoxyadenosine, and a 2.5-fold increase in ribonucleotide reductase activity. The pace of adenosine excretion, the growth rate, and the levels of multiple other enzymes involved in deoxyadenosine and adenosine metabolism were equivalent in the two cell types. These results suggest that the excretion of deoxyadenosine and thymidine, but not adenosine, is exquisitely sensitive to alterations in the rate of endogenous deoxynucleotide synthesis. Apparently, small changes in deoxynucleotide synthesis can significantly influence cellular sensitivity to deoxyadenosine toxicity.  相似文献   

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Summary Adenosine deaminase is found primarily in the cytoplasm of many cell types. In the human erythrocyte, about 30 per cent of the total adenosine deaminase activity is membrane associated, and about two-thirds of this is inactivated by treatment of intact erythrocytes with the nonpenetrating reagent diazotized sulfanilic acid, without affecting lactate dehydrogenase, a soluble cytoplasmic enzyme. This indicates that within the cell membranes, the catalytic site of about two-thirds of the adenosine deaminase faces the external medium, i.e., ecto adenosine deaminase. Localization of adenosine deaminase activity at the cell membrane is demonstrated directly by electron microscopy by use of the substrate 6-Chloropurine ribonucleoside, which is dechlorinated by adenosine deaminase to produce Cl, which is precipitated at its locus of formation by added Ag+, and the precipitated AgCl converted into the electron dense Ag0 upon exposure to light.From the Hydropathic Profile of the amino acid sequence of adenosine deaminase it is evident that there are two hydrophobic domains of sufficient length to span a biological membrane, and it is proposed that these domains could function to anchor the enzyme to the membrane.The importance of adenosine deaminase is indicated by the fatal immuno-deficiency which results from untreated genetic adenosine deaminase deficiency. It may be important to determine whether the amount of ecto adenosine deaminase activity is better suited to assess the clinical status of adenosine deaminase deficient patients that the currently used total cellular enzyme activity.Abbreviations ADA Adenosine Deaminase - LDH Lactate Dehydrogenase - HEPES N-2-Hydroxyethylpiperazine-N-2-ethanesulfonic acid - CPR 6-Chloropurine Ribonucleoside - SDS Sodium Dodecyl Sulfate - NAD -Nicotinamide Adenine Dinucleotide - HBSS Hank's Balanced Salt Solution - DASA Diazotized Sulfanilic Acid  相似文献   

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DNA ligase activity was studied in several untransformed or virus-transformed human cell lines from normal donors and from Bloom's syndrome (BS) patients. This proneness genetic disease is characterized by several cytological abnormalities and cancer proneness and, recently, some transformed cell lines from these patients were described to present a reduced activity of DNA ligase I. Results presented in this work indicate that: (i) the total DNA ligase activity in crude extract from untransformed or transformed cell lines from several BS patients was significantly higher than in control cells; (ii) the partial purification of the enzyme after gel filtration on fast protein liquid chromatography of crude extracts from lymphoblastoid BS cells showed that the enzyme activity was eluted in a major 180 kDa form in which activity was higher than in control cells; (iii) the activity gel analysis of these enzyme fractions revealed that DNA ligase of human cells was correlated to a major 130 kDa polypeptide and, in BS cells, the extent of the activity of this band was equal or higher than that in control untransformed or transformed cells.  相似文献   

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Evidence for the presence of an insoluble form of adenosine deaminase complexing protein in human kidney has been obtained. An initial study demonstrated that binding of monomeric adenosine deaminase to particulate material from kidney was saturable and could be blocked by preincubating the enzyme with soluble complexing protein. Treatment of particulate material with deoxycholate, followed by immunoassay of the detergent extract, confirmed the presence of an insoluble form of complexing protein in the kidney. Several other human organs examined by this technique contained smaller amounts of insoluble complexing protein. Complexing protein isolated from the soluble and particulate fractions of kidney homogenates were found to be structurally similar. The proteins had the same subunit Mr and showed complete crossreactivity with antiserum to soluble complexing protein. Indirect immunoperoxidase staining of renal cortical tissue revealed that complexing protein was concentrated in the brush border of the proximal tubules. These results indicate that (a) the soluble and insoluble forms of complexing protein from human kidney may be products of the same gene(s) and (b) a portion of the complexing protein in human kidney is bound to the brush border membranes of cells lining the proximal tubules.  相似文献   

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P P Trotta 《Biochemistry》1982,21(17):4014-4023
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