Deoxynucleoside overproduction in deoxyadenosine-resistant, adenosine deaminase-deficient human histiocytic lymphoma cells

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.     

An approach to a selection system for adenosine-deaminase-positive (ADA+) cells and detection of rat ADA+ "revertants"

We have substituted deoxyadenosine or adenosine for hypoxanthine in the standard HAT selection system in an attempt to select for ADA-normal (ADA+) cells. ADA- human lymphoid line cells could not utilize deoxyadenosine as an alternative to hypoxanthine as a purine source (DAT) and failed to grow but were only somewhat inhibited in growth when adenosine was substituted for hypoxanthine (AAT). In contrast, ADA+ cells utilized adenosine or deoxyadenosine as efficiently as hypoxanthine as a purine source. Growth in DAT, but not in HAT, of an artificial mixture of one ADA+ human lymphoid cells in 1,000 ADA- cells resulted in enrichment of ADA+ cells to 25-86% of total cells. When we grew a rat ADA- cell line in two variations of the DAT system, we detected at least three electrophoretically different ADA+ patterns, one of which corresponded to normal rat ADA. These could represent "revertants."     

Structure-Activity Relationships of Adenosine Deaminase Inhibitors

Abstract

Adenosine deaminase (ADA) is an important catabolic enzyme which converts adenosine and deoxyadenosine to inosine and deoxyinosine, respectively. ADA exists in two different isoenzymes, namely ADA1 and ADA2, whose balance in monocytes-macrophages seems to guarantee the homeostasis of adenine nucleosides. Modifications of the purine moiety or/and substitution of the sugar moiety of adenosine with aliphatic chains led to derivatives which are good ADA inhibitors.     

Introduction of sequences encoding functional human adenosine deaminase into mouse cells using a retroviral shuttle system

A retroviral packaging system was used to generate a murine virus carrying sequences encoding human adenosine deaminase (ADA). To this end, human ADA cDNA was inserted into the retroviral shuttle vector pZIP-NeoSV(X)1. This vector provides all of the cis-acting sequences necessary for the efficient packaging and transmission of the viral genome as well as a selectable gene for G418 resistance. Transfection of this recombinant plasmid into cells that provide essential virus products (psi-2 cells) yielded cell lines that stably produced virions carrying the coding sequence of human ADA. We have used these virions to infect NIH3T3 cells, which after 48 h synthesized catalytically active human ADA. Furthermore, G418-resistant cell lines were obtained from the virus-infected NIH3T3 cells that stably produced the human ADA enzyme.     

Expression of a functional human adenosine deaminase in transgenic tobacco plants

An inherited disorder, adenosine deaminase deficiency is a form of severe combined immunodeficiency, which is ultimately caused by an absence of adenosine deaminase (ADA), a key enzyme of the purine salvage pathway. The absence of ADA-activity in sufferers eventually results in a dysfunctional immune system due to the build-up of toxic metabolites. To date, this has been treated with mixed success, using PEG-ADA, made from purified bovine ADA coupled to polyethylene glycol. It is likely, however, that an enzyme replacement therapy protocol based on recombinant human ADA would be a more effective treatment for this disease. Therefore, as a preliminary step to produce biologically active human ADA in transgenic tobacco plants a human ADA cDNA has been inserted into a plant expression vector under the control of the CaMV 35S promoter and both human and TMV 5′ UTR control regions. Plant vector expression constructs have been used to transform tobacco plants via Agrobacterium-mediated transformation. Genomic DNA, RNA and protein blot analyses have demonstrated the integration of the cDNA construct into the plant nuclear genome and the expression of recombinant ADA mRNA and protein in transgenic tobacco leaves. Western blot analysis has also revealed that human and recombinant ADA have a similar size of approximately 41 kDa. ADA-specific activities of between 0.001 and 0.003 units per mg total soluble protein were measured in crude extracts isolated from transformed tobacco plant leaves.     

Correct splicing despite mutation of the invariant first nucleotide of a 5' splice site: a possible basis for disparate clinical phenotypes in siblings with adenosine deaminase deficiency.

Adenosine deaminase (ADA) deficiency usually causes severe combined immune deficiency in infancy. Milder phenotypes, with delayed or late onset and gradual decline in immune function, also occur and are associated with less severely impaired deoxyadenosine (dAdo) catabolism. We have characterized the mutations responsible for ADA deficiency in siblings with striking disparity in clinical phenotype. Erythrocyte dAdo nucleotide pool size, which reflects total residual ADA activity, was lower in the older, more mildly affected sib (RG) than in her younger, more severely affected sister (EG). Cultured T cells, fibroblasts, and B lymphoblasts of RG had detectable residual ADA activity, while cells of EG did not. ADA mRNA was undetectable by northern analysis in these cells of both patients. Both sibs were found to be compound heterozygotes for the following novel splicing defects: (1) a G+1-->A substitution at the 5' splice site of IVS 2 and (2) a complex 17-bp rearrangement of the 3' splice site of IVS 8, which inserted a run of seven purines into the polypyrimidine tract and altered the reading frame of exon 9. PCR-amplified ADA cDNA clones with premature translation stop codons arising from aberrant pre-mRNA splicing were identified, which were consistent with these mutations. However, some cDNA clones from T cells of both patients and from fibroblasts and Epstein-Barr virus (EBV)-transformed B cells of RG, were normally spliced at both the exon 2/3 and exon 8/9 junctions. A normal coding sequence was documented for clones from both sibs. The normal cDNA clones did not appear to arise from either contamination or PCR artifact, and mosaicism seems unlikely to have been involved. These findings suggest (1) that a low level of normal pre-mRNA splicing may occur despite mutation of the invariant first nucleotide of the 5' splice donor sequence and (2) that differences in efficiency of such splicing may account for the difference in residual ADA activity, immune dysfunction, and clinical severity in these siblings.     

The effects of an induced adenosine deaminase deficiency on T-cell differentiation in the rat

Inherited deficiency of the enzyme adenosine deaminase (ADA) has been found in a significant proportion of patients with severe combined immunodeficiency disease and inherited defect generally characterized by a deficiency of both B and T cells. Two questions are central to understanding the pathophysiology of this disease: (1) at what stage or stages in lymphocyte development are the effects of the enzyme deficiency manifested; (2) what are the biochemical mechanisms responsible for the selective pathogenicity of the lymphoid system. We have examined the stage or stages of rat T-cell development in vivo which are affected by an induced adenosine deaminase deficiency using the ADA inhibitors, erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA) and 2'-deoxycoformycin (DCF). In normal rats given daily administration of an ADA inhibitor, cortical thymocytes were markedly depleted; peripheral lymphocytes and pluripotent hemopoietic stem cells (CFU-S) all were relatively unaffected. Since a deficiency of ADA affects lymphocyte development, the regeneration of cortical and medullary thymocytes and their precursors after sublethal irradiation was used as a model of lymphoid development. By Day 5 after irradiation the thymus was reduced to 0.10-0.5% of its normal size; whereas at Days 9 and 14 the thymus was 20-40% and 60-80% regenerated, respectively. When irradiated rats were given daily parenteral injections of the ADA inhibitor plus adenosine or deoxyadenosine, thymus regeneration at Days 9 and 14 was markedly inhibited, whereas the regeneration of thymocyte precursors was essentially unaffected. Thymus regeneration was at least 40-fold lower than in rats given adenosine or deoxyadenosine alone. Virtually identical results were obtained with both ADA inhibitors, EHNA and DCF. The majority of thymocytes present at Day 9 and at Day 14 in inhibitor-treated rats had the characteristics of subcapsular cortical thymocytes which are probably the most ancestral of the thymocytes. Thus, an induced ADA deficiency blocked the proliferation and differentiation of subcapsular cortical thymocytes which are the precursors of cortical and medullary thymocytes.     

Deoxyadenosine metabolism and cytotoxicity in cultured mouse T lymphoma cells: a model for immunodeficiency disease.

The inherited absence of either adenosine deaminase (ADA) or purine nucleoside phosphorylase is associated with severe immunological impairment. We have developed a cell culture model using a mouse T cell lymphoma to simulate ADA deficiency and to study the relationship between purine salvage enzymes and immune function. 2′-deoxyadenosine triphosphate (deoxyATP) levels have been shown to be greatly elevated in erythrocytes of immunodeficient, ADA-deficient patients, suggesting that deoxyadenosine is the potentially toxic substrate in ADA deficiency. Using a potent ADA inhibitor, we have demonstrated that deoxyadenosine is growth-inhibitory and cytotoxic to S49 cells, and that deoxyATP accumulates in these cells. Cell variants, unable to transport or phosphorylate deoxyadenosine, are much less sensitive to deoxyadenosine, indicating that intracellular phosphorylation of deoxyadenosine is required for the lethal effects.We have partially reversed the cytotoxic effects of deoxyadenosine with deoxycytidine in wild-type cells, but we cannot show any reversal in cell lines lacking deoxycytidine kinase. Adenosine (ado) kinase-deficient cells are extremely resistant to deoxyadenosine in the presence of deoxycytidine. This deoxycytidine reversal of deoxyadenosine toxicity is consistent with an inhibition of ribonucleotide reductase by deoxyATP, and we have shown that incubation of S49 cells with deoxyadenosine markedly reduces intracellular levels of deoxyCTP, deoxyGTP and TTP.Kinetics data in wild-type cells and in cell variants are consistent with the presence of two deoxyadenosine-phosphorylating activities — one associated with ado kinase and another associated with deoxycytidine kinase.The S49 cells appear to be a valid model for the simulation of ADA deficiency in cell culture, and from our results, we can suggest administration of deoxycytidine as a pharmacological regimen to circumvent the clinicopathologic symptoms in ADA deficiency.     

The emerging role of adenosine deaminases in insects

Adenosine deaminases catalyze the deamination of adenosine and deoxyadenosine into their respective inosine nucleosides. Recent sequencing of the genomes of several model organisms and human reveal that Metazoa usually have more than one adenosine deaminase gene. A deficiency in the gene encoding the major enzyme is lethal in mouse and Drosophila and leads to severe combined deficiency (SCID) in human. In these organisms, enzyme deficiency causes increased adenosine/deoxyadenosine concentration in body fluids and some organs. Elevated levels of adenosine and deoxyadenosine are toxic to certain mammalian and insect cells, and it was shown for human and mouse that it is a primary cause of pathophysiological effects. Data suggest that the major role of adenosine deaminases in various taxa is the protection of tissues against increased levels of adenosine and deoxyadenosine. This review also discusses potential roles of adenosine deaminases in Drosophila metamorphosis and the employment of a Drosophila model to study the cell-specific toxicity of elevated nucleoside levels.     

The potential importance of soluble deoxynucleotidase activity in mediating deoxyadenosine toxicity in human lymphoblasts

Deoxyadenosine and its nucleotides have been implicated in the pathogenesis of the immune dysfunction associated with a genetic deficiency of adenosine deaminase (ADA). We have previously shown that when ADA is blocked with a synthetic inhibitor, human T lymphoblastoid cell lines are more sensitive to deoxyadenosine toxicity, dephosphorylate deoxyadenosine nucleotides at a slower rate, and have much lower levels of ecto-5'-nucleotidase than most B cell lines. It seemed unlikely, however, that an enzyme on the outer surface of the lymphocyte plasma membrane could regulate intracellular deoxynucleotide catabolism. We now report that human lymphoblasts also contain a soluble deoxynucleotidase activity that is distinguishable from the plasma membrane enzyme by several criteria. In multiple human lymphoblastoid cell lines of varying origin and phenotype. soluble deoxynucleotidase correlated significantly (rs = 0.80, p < 0.001) with sensitivity to deoxyadenosine toxicity.     

A Role for Adenosine Deaminase in Drosophila Larval Development

Adenosine deaminase (ADA) is an enzyme present in all organisms that catalyzes the irreversible deamination of adenosine and deoxyadenosine to inosine and deoxyinosine. Both adenosine and deoxyadenosine are biologically active purines that can have a deep impact on cellular physiology; notably, ADA deficiency in humans causes severe combined immunodeficiency. We have established a Drosophila model to study the effects of altered adenosine levels in vivo by genetic elimination of adenosine deaminase-related growth factor-A (ADGF-A), which has ADA activity and is expressed in the gut and hematopoietic organ. Here we show that the hemocytes (blood cells) are the main regulator of adenosine in the Drosophila larva, as was speculated previously for mammals. The elevated level of adenosine in the hemolymph due to lack of ADGF-A leads to apparently inconsistent phenotypic effects: precocious metamorphic changes including differentiation of macrophage-like cells and fat body disintegration on one hand, and delay of development with block of pupariation on the other. The block of pupariation appears to involve signaling through the adenosine receptor (AdoR), but fat body disintegration, which is promoted by action of the hemocytes, seems to be independent of the AdoR. The existence of such an independent mechanism has also been suggested in mammals.     

A role for adenosine deaminase in Drosophila larval development

Adenosine deaminase (ADA) is an enzyme present in all organisms that catalyzes the irreversible deamination of adenosine and deoxyadenosine to inosine and deoxyinosine. Both adenosine and deoxyadenosine are biologically active purines that can have a deep impact on cellular physiology; notably, ADA deficiency in humans causes severe combined immunodeficiency. We have established a Drosophila model to study the effects of altered adenosine levels in vivo by genetic elimination of adenosine deaminase-related growth factor-A (ADGF-A), which has ADA activity and is expressed in the gut and hematopoietic organ. Here we show that the hemocytes (blood cells) are the main regulator of adenosine in the Drosophila larva, as was speculated previously for mammals. The elevated level of adenosine in the hemolymph due to lack of ADGF-A leads to apparently inconsistent phenotypic effects: precocious metamorphic changes including differentiation of macrophage-like cells and fat body disintegration on one hand, and delay of development with block of pupariation on the other. The block of pupariation appears to involve signaling through the adenosine receptor (AdoR), but fat body disintegration, which is promoted by action of the hemocytes, seems to be independent of the AdoR. The existence of such an independent mechanism has also been suggested in mammals.     

Establishment and characterization of adenosine deaminase-deficient human T cell lines

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.     

Enhanced antibody response in the presence of partial adenosine deaminase inhibition

The enzyme adenosine deaminase (ADA) catalyzes the conversion of adenosine and 2'-deoxyadenosine to inosine and 2'-deoxyinosine, respectively. In the absence of ADA activity, 2'-deoxyadenosine is phosphorylated to deoxyadenosine triphosphate. This study concerned the effects of the ADA inhibitor 2'-deoxycoformycin on the murine in vitro immune response to sheep red blood cells (Mishell-Dutton cultures). In the presence of 10(-7) M 2'-deoxycoformycin or 1 mM 2'-deoxyadenosine, there was a significant increase in the plaque-forming cell response when calculated as plaques per 10(6) viable cells recovered. Cultures containing 10(-7) M 2'-deoxycoformycin retained approximately 10% of residual ADA activity of control cultures. Partial ADA deficiency was not preferentially toxic for cells capable of suppressing plaque cell generation. However, there was a decrease of recovered viable cells in all ADA-deficient cultures. There was no change in the percentage of recovered cells which were L3T4+ or Lyt 2+. A significant decrease was observed in a population of cells expressing surface immunoglobulins. The number of plaque-forming cells/10(3) recovered B cells increased significantly. We conclude that partial ADA deficiency results in selective toxicity to a population of non-antigen-specific B cells. Further studies with antigen-specific cells are necessary to determine the possible mechanism(s) by which cellular activation may prevent susceptibility to the toxic effects of ADA deficiency.     

Cloning and expression of a human ATP-citrate lyase cDNA.

A full-length cDNA clone of 4.3 kb encoding the human ATP-citrate lyase enzyme has been isolated by screening a human cDNA library with the recently isolated rat ATP-citrate lyase cDNA clone [Elshourbagy et al. (1990) J. Biol. Chem. 265, 1430]. Nucleic-acid sequence data indicate that the cDNA contains the complete coding region for the enzyme, which is 1105 amino acids in length with a calculated molecular mass of 121,419 Da. Comparison of the human and rat ATP-citrate lyase cDNA sequences reveals 96.3% amino acid identity throughout the entire sequence. Further sequence analysis identified the His765 catalytic phosphorylation site, the ATP-binding site, as well as the CoA binding site. The human ATP-citrate lyase cDNA clone was subcloned into a mammalian expression vector for expression in African green monkey kidney cells (COS) and Chinese hamster ovary cells (CHO) cells. Transfected COS cells expressed detectable levels of an enzymatically active recombinant ATP-citrate lyase enzyme. Stable, amplified expression of ATP-citrate lyase in CHO cells as achieved by using coamplification with dihydrofolate reductase. Resistant cells expressed high levels of enzymatically active ATP-citrate lyase (3 pg/cell/d). Site-specific mutagenesis of His765----Ala diminishes the catalytic activity of the expressed ATP-citrate lyase protein. Since catalysis of ATP-citrate lyase is postulated to involve the formation of phosphohistidine, these results are consistent with the pattern of earlier observations of the significance of the histidine residue in catalysis of the human ATP-citrate lyase.