Lack of adenosine deaminase activity in cultured murine cytotoxic T lymphocytes

The level of adenosine deaminase (ADA) activity was investigated in various populations of IL 2-dependent, cultured cytotoxic T lymphocytes (CTL), from bulk cultures as well as from CTL lines (CTL-A and CTL-B types). The study of C57BL/6 derived, cytotoxic bulk cultures yielded the following mean values of ADA activity: 12,500 U/mg in the cortical, immature region of the thymus, 1500 U/mg in the immunocompetent, cortisone-resistant medullary thymocytes, and 2000 U/mg in the T cell population from the spleen. These results are in agreement with previous studies on separated T lymphocyte populations of known origin and further indicate that a fall in ADA activity accompanies T cell maturation. ADA activity was measured in C57BL/6-derived CTL-A lines obtained from the thymic and splenic bulk cultures. All lines were characterized by a very low level of ADA activity, compared with the T cell bulk cultures freshly initiated from the thymic medulla or from the spleen, and to a variety of T tumor lines established in long term culture. Some showed undetectable ADA activity (less than or equal to 20 units/mg), whereas others maintained significant activity (50 to 500 U/mg). No correlation was found between the residual ADA activity level and the killing activity, at the time of the enzyme assay. Identical properties were observed for CTL-B cloned lines of various genetic backgrounds. These results suggest that the level of ADA activity of the CTL in the mouse is lower than the average value of mature T cells of the thymic medulla, and might constitute a differentiation marker specific to the CTL population. A possibility remains that low ADA activity levels in these CTL lines may be the consequence of an extinction of the ADA gene during in vitro growth, as it is observed for the cytotoxic activity itself. In either case, a low ADA activity level is a remarkable property of IL 2-dependent CTL clones, when compared to various established T tumor lines, which exhibit high and stable ADA levels during long term in vitro growth (5000 to 15,000 U/mg).     

Fine mapping and functional activity of the adenosine deaminase origin in murine embryonic fibroblasts

DNA replication initiates at origins within the genome. The late-firing murine adenosine deaminase (mAdA) origin is located within a 2 kb fragment of DNA, making it difficult to examine by realtime technology. In this study, fine mapping of the mAdA region by measuring the abundance of nascent strand DNA identified two origins, mAdA-1 and mAdA-C, located 397 bp apart from each other. Both origins conferred autonomous replication to plasmids transfected in murine embryonic fibroblasts (MEFs), and exhibited similar activities in vivo and in vitro. Furthermore, both were able to recruit the DNA replication initiator proteins Cdc6 and Ku in vitro, similar to other bona fide replication origins. When tested in a murine Ku80(-/-) cell line, both origins exhibited replication activities comparable to those observed in wildtype cells, as did the hypoxanthine-guanine phosphoribosyltransferase (HPRT) and c-myc origins. This contrasts with previously published studies using Ku80-deficient human cells lines and suggests differences in the mechanism of initiation of DNA replication between the murine and human systems.     

T细胞功能亚群

T细胞是高度异质性的细胞群,可分为不同类别。近年来,T细胞(尤其是CD4+T细胞)功能亚群的研究进展极为迅速。Th1、Th2、nTreg、Th17、Tfh、iTreg、Th9和Th22细胞等陆续被发现,极大扩展了对CD4+T细胞功能亚群的认识。同时,对CD8+T细胞和记忆性T细胞功能亚群的研究也取得进展。     

Changes in adenosine deaminase activity in ageing cultured human cells and the role of zinc

The level of adenosine deaminase (ADA; EC 3.5.4.4) was estimated at different passages in six confluent fibroblast cultures established from forearm skin biopsies of healthy adult normal volunteers. After determination of the zinc concentration in standard growth medium, ADA activity was estimated at different passages of subculture in media with different zinc concentrations. The results indicated that the specific activity of ADA in control confluent skin fibroblast cultures (passage 2) cultivated in standard growth medium containing 15.4 microM zinc (similar to that present in normal human plasma) was equal to 226.6+/-19.64 micromol min(-1) mg(-1) protein. The results showed that there were no significant changes in ADA specific activity in any of the control cultures as the zinc concentration of the medium was increased. To characterize the passage of subculture at which fibroblasts enter the ageing phase, three marker enzymes were assayed namely, phosphofructokinase, lactate dehydrogenase and glycogen phosphorylase. The result showed that the cells enter the ageing phase at passage 20 and beyond. Further investigation showed that ADA activity of serially subcultured confluent cultures cultivated in standard growth medium significantly dropped at passages 20, 25 and 30. ADA activity however was not significantly altered in cells at passage 2, 10 and 15 cultivated in standard growth medium and in the presence of higher zinc levels (23.1, 34.6, 53.8 and 73.1 microM). Furthermore there was significant lowering of ADA activities in cells at passages 20, 25 and 30 when cells were cultured in the presence of 15.4, 23.1 and 34.6 microM zinc. Such lowered activities of ADA were restored to normal when the cells were cultured in the presence of higher zinc concentration equal to 53.8 and 73.1 microM. From the results we concluded that it is possible to restore ADA activity in aged skin fibroblasts to normal levels by raising the zinc concentration in the culture medium to four or five times the control normal plasma zinc level.     

Different functions of subsets of effector T cells in murine influenza virus infection

Enriched preparations of secondary effector T cells to influenza virus were tested for their in vivo biological function by adoptive transfer to mice 24 hr after an intranasal inoculation of infectious influenza virus. One class of cells which were Lyt 1⁺2^?3^?, I region-restricted, and could mediate DTH reaction failed to reduce lung virus titers 5 days after transfer and caused a higher mortality rate in the recipient mice than in the controls. A second class of cells which were Lyt 1^?2⁺3⁺, K,D region-restricted, and were cytotoxic and could mediate DTH activity substantially reduced lung virus titers 5 days after transfer. The influx of mononuclear cells to the lungs after adoptive cell transfer was measured by injection of [¹²⁵I]UdR 24 hr prior to harvest of lung cells, using both infected CBA and athymic BALB/ c nude (nu/nu) mice as recipients. I region-restricted cells caused increased cellular infiltration which was very marked in athymic mice. It was concluded that this reaction significantly contributed to the observed immunopathology in infected mice. Transfer of K,D region-restricted cells reduced the cellular infiltration in infected CBA mice and caused only a slight increase in infected athymic mice. The evidence supported the concept that the second class of cells exerted their protective (antiviral) effect in vivo by direct lysis of virus-infected cells rather than by liberation of lymphokines.     

Identification of functional murine adenosine deaminase cDNA clones by complementation in Escherichia coli

Total poly(A+) RNA derived from a mouse cell line with amplified adenosine deaminase genes was used as template to synthesize double-stranded cDNA. The cDNAs were inserted into the PstI site of the beta-lactamase gene in plasmid pBR322 following G-C tailing. After transformation into adenosine deaminase-deficient Escherichia coli hosts, recombinant plasmids containing functional murine adenosine deaminase cDNAs were identified by selecting for functional complementation. Analysis of plasmids containing functional adenosine deaminase cDNA sequences strongly suggested that adenosine deaminase expression resulted mainly from beta-lactamase/adenosine deaminase fusion proteins even when the adenosine deaminase codons were out-of-frame with respect to the beta-lactamase gene codons upstream. The nucleotide sequence of a 1.65-kilobase pair cDNA insert in one of the functional recombinant clones was determined and found to contain a 1056-nucleotide open reading frame. When this 1056-nucleotide open reading frame was inserted into a mammalian expression vector and introduced into monkey kidney cells, a high level of authentic mouse adenosine deaminase was produced. Nucleic acid blot analysis using a full-length adenosine deaminase cDNA clone as probe revealed that the mouse adenosine deaminase structural gene was at least 21 kilobase pairs in size and encoded three polyadenylated mRNAs. Analysis of the cDNA library from which the functional clones were isolated suggested that this approach of cloning functional mammalian adenosine deaminase cDNA clones by genetic complementation of enzyme-deficient bacteria could be accomplished even if the abundance of the adenosine deaminase mRNA sequences were as low as approximately 0.001%.     

Sequence, genomic organization and functional expression of the murine tRNA-specific adenosine deaminase ADAT1

We have recently identified the first mammalian tRNA-specific adenosine deaminase human ADAT1, a member of the ADAR family of RNA editing enzymes. This protein is responsible for the first step of the unique A(37) to m(1)I(37) modification in eukaryotic tRNA(Ala). Here, we present the genomic structure of murine ADAT1 and the functional expression of mADAT1 cDNA. In mouse, as well as in human, ADAT1 is expressed from a single copy gene. The coding region of the mADAT1 gene is spread over nine exons, covering approximately 30kb of genomic DNA and encodes a protein of 499 amino acids. Overall, mADAT1 shares 81% nucleotide homology and 87.5% protein homology with the human ortholog. The recombinant mouse protein is active specifically and with a high efficiency on human tRNA(Ala) in vitro. Its genomic organization is compared to the structures of the sequence-related, pre-mRNA specific adenosine deaminases ADAR1 and ADAR2.     

Preliminary X-ray analysis of crystals of murine adenosine deaminase

We have obtained single crystals of a cloned mammalian adenosine deaminase (Mr = 41,000), a key enzyme in purine degradation and in normal development of the immune system, that are suitable for high-resolution structural analysis. The crystals belong to the space group C2 with unit cell parameters a = 101.68 A (1 A = 0.1 nm), b = 94.38 A, c = 85.51 A, and beta = 96.54 degrees. The asymmetric unit contains two enzyme molecules.     

Increased adenosine deaminase synthesis and messenger RNA activity in deoxycoformycin-resistant cells

The basis for the increased adenosine deaminase activity in deoxycoformycin-resistant rat hepatoma cells was investigated. Three variant cell lines with different levels of adenosine deaminase activity showed increases in the relative rate of synthesis of the enzyme in vivo. No difference in the rate of degradation of the enzyme was seen between the parental cell line and one variant cell line which exhibits a 180-fold increase in adenosine deaminase activity. Polysomal RNA isolated from this variant exhibited a 175-fold increase in the ability to direct the synthesis of adenosine deaminase in vitro.     

Function of murine adenosine deaminase in the gastrointestinal tract

Adenosine deaminase (ADA) deficiency in humans leads to a combined immunodeficiency characterized by severe T and B cell lymphopenia. ADA-deficient humans also display defective development of gut-associated lymphoid tissues (GALT). They lack lymphoid cells, and the Peyer's patches are without germinal centers. In mice, ADA-deficient fetuses die perinatally due to liver damage, but they also exhibit pathology in the thymus, spleen, and the small intestine. The GI phenotype associated with ADA-deficient humans prompted us to examine the effect of ADA-deficiency on mouse small intestine tissue. The work presented here focuses on understanding the physiological role of ADA in the GI tract, using ADA-deficient mice rescued from perinatal lethality by restoring Ada expression to trophoblast cells. Histologically and immunologically, the GALT was compromised at all sites in ADA-/- mice, with the most dramatic changes seen in the Peyer's patches. Profound disturbances in purine metabolism were detected in all the gastrointestinal tissues. In particular, adenosine and deoxyadenosine, the ADA substrates, increased markedly while the product inosine decreased. The activity of S-adenosylhomocysteine hydrolase decreased throughout the GI tract, indicating a possible disruption of cellular transmethylation and activation of apoptotic pathways. There were also disturbances in the purine metabolic pathway with a decrease in the production of downstream nucleosides hypoxanthine and xanthine.     

ECTO-enzyme activity of human erythrocyte adenosine deaminase

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     

Antigenicity of UV radiation-induced murine tumors correlates positively with the level of adenosine deaminase activity

Summary The specific activities of adenosine deaminase (ADA) in 16 murine tumor cell lines derived from seven UV light-induced neoplasms (melanoma and fibrosarcoma) were determined. In each case, the specific activity of ADA correlated positively with the antigenicity of the tumor cells. Highly antigenic cell lines that regress upon introduction into syngeneic hosts had on average 4- to 6-fold higher ADA specific activities than cell lines of low antigenicity that grow progressively in syngeneic hosts. The antigenic differences are probably not related to intracellular cAMP levels, as the level of cAMP differed only 2-fold between the two groups of cell lines.     

High levels of adenosine deaminase on dendritic cells promote autoreactive T cell activation and diabetes in nonobese diabetic mice

Adenosine has been established as an important regulator of immune activation. It signals through P1 adenosine receptors to suppress activation of T cells and professional APCs. Adenosine deaminase (ADA) counters this effect by catabolizing adenosine. This regulatory mechanism has not been tested in a disease model in vivo. Questions also remain as to which cell types are most sensitive to this regulation and whether its dysregulation contributes to any autoimmune conditions. We approached this issue using the NOD model. We report that ADA is upregulated in NOD dendritic cells, which results in their exuberant and spontaneous activation. This, in turn, triggers autoimmune T cell activation. NOD DCs deficient in ADA expression have a greatly reduced capacity to trigger type I diabetes. We also provide evidence that although many cell types, particularly T cells, have been implicated as the suppression targets by adenosine in an in vitro setting, DCs also seem to be affected by this regulatory mechanism. Therefore, this report illustrates a role of ADA in autoimmunity and suggests a potential target for therapeutic intervention.     

Adenosine deaminase of cultured brain cells

Two types of adenosine deaminase (EC 3.5.4.4) were found in cultured cells of central-nervous-system origin. The predominant and more active enzyme was obtained in soluble form from the cytosol of mouse neuroblastoma (N-18), neonatal hamster astrocytes (NN), human oligodendroglioma (HOL) and human astrocytoma (Cox Clone). Particulate adenosine deaminase was probably associated with the plasma membrane. When radioactive adenosine was added to superfusates of monolayer cultures it was rapidly converted into inosine and hypoxanthine. The metabolic conversion required adenosine uptake by the cells, a probable transition through the intracellular ATP pool(s) and a rapid excretion into the superfusate of the catabolic products. We discuss the evidence that points to adenosine and its derivatives as neurohumoral modulators of central-nervous-system function.