A role for adenine nucleotides in the sensing mechanism to purine starvation in Leishmania donovani

Purine salvage by Leishmania is an obligatory nutritional process that impacts both cell viability and growth. Previously, we have demonstrated that the removal of purines in culture provokes significant metabolic changes that enable Leishmania to survive prolonged periods of purine starvation. In order to understand how Leishmania sense and respond to changes in their purine environment, we have exploited several purine pathway mutants, some in which adenine and guanine nucleotide metabolism is uncoupled. While wild type parasites grow in any one of a variety of naturally occurring purines, the proliferation of these purine pathway mutants requires specific types or combinations of exogenous purines. By culturing purine pathway mutants in high levels of extracellular purines that are either permissive or non‐permissive for growth and monitoring for previously defined markers of the adaptive response to purine starvation, we determined that adaptation arises from a surveillance of intracellular purine nucleotide pools rather than from a direct sensing of the extracellular purine content of the environment. Specifically, our data suggest that perturbation of intracellular adenine‐containing nucleotide pools provides a crucial signal for inducing the metabolic changes necessary for the long‐term survival of Leishmania in a purine‐scarce environment.     

In situ regulation of mammalian CTP synthetase by allosteric inhibition

The regulatory role of the allosteric site of CTP synthetase on flux through the enzyme in situ and on pyrimidine nucleotide triphosphate (NTP) pool balance was investigated using a mutant mouse T lymphoblast (S49) cell line which contains a CTP synthetase refractory to complete inhibition by CTP. Measurements of [3H]uridine incorporation into cellular pyrimidine NTP pools as a function of time indicated that CTP synthesis in intact wild type cells was markedly inhibited in a cooperative fashion by small increases in CTP pools, whereas flux across the enzyme in mutant cells was much less affected by changes in CTP levels. The cooperativity of the allosteric inhibition of the enzyme was greater in situ than in vitro. Exogenous manipulation of levels of GTP, an activator of the enzyme, indicated that GTP had a moderate effect on enzyme activity in situ, and changes in pools of ATP, a substrate of the enzyme, had small effects on CTP synthetase activity. The consequences of incubation with actinomycin D, cycloheximide, dibutyryl cyclic AMP, and 6-azauridine on the flux across CTP synthetase and on NTP pools differed considerably between wild type and mutant cells. Under conditions of growth arrest, an intact binding site for CTP on CTP synthetase was required to maintain a balance between the CTP and UTP pools in wild type cells. Moreover, wild type cells failed to incorporate H14CO3- into pyrimidine pools following growth arrest. In contrast, mutant cells incorporated the radiolabel at a high rate indicating loss of a regulatory function. These results indicated that uridine nucleotides are important regulators of pyrimidine nucleotide synthesis in mouse S49 cells, and CTP regulates the balance between UTP and CTP pools.     

Incomplete nucleoside transport deficiency with increased hypoxanthine transport capability in mutant T-lymphoblastoid cells.

From a mutagenized population of wild-type mouse (S49) T-lymphoma cells, a clone, 80-5D2, was isolated in a single step by virtue of its ability to survive in 80 nM 5-fluorouridine. Unlike previously isolated nucleoside transport-deficient cell lines (A. Cohen, B. Ullman, and D. W. Martin, Jr., J. Biol. Chem. 254:112-116, 1979), 80-5D2 cells were only slightly less sensitive to growth inhibition by a variety of cytotoxic nucleosides and were capable of proliferating in hypoxanthine-amethopterin-thymidine-containing medium. The molecular basis for the phenotype of 80-5D2 cells was incomplete deficiency in the ability of the mutant cells to translocate nucleosides across the plasma membrane. Interestingly, mutant cells were more capable than wild-type cells of transporting the nucleobase hypoxanthine. Residual transport of adenosine into 80-5D2 cells was just as sensitive to inhibition by nucleosides and more sensitive to inhibition by hypoxanthine than that in wild-type cells, indicating that the phenomena of ligand binding and translocation can be uncoupled genetically. The 80-5D2 cells lacked cell surface binding sites for the potent inhibitor of nucleoside transport p-nitrobenzylthioinosine (NBMPR) and, consequently, were largely resistant to the physiological effects of NBMPR. However, the altered transporter retained its sensitivity to dipyridamole, another inhibitor of nucleoside transport. The biochemical phenotype of the 80-5D2 cell line supports the hypothesis that the determinants that comprise the nucleoside carrier site, the hypoxanthine carrier site, the NBMPR binding site, and the dipyridamole binding site of the nucleoside transport function of mouse S49 cells are genetically distinguishable.     

Platelet-neutrophil interactions. 12S,20- and 5S,12S-dihydroxyeicosapentaenoic acids: two novel neutrophil metabolites from platelet-derived 12S-hydroxyeicosapentaenoic acid

Dietary marine n-3 polyunsaturated fatty acids have demonstrated an antiinflammatory potential in epidemiologic and intervention studies in humans. Proposed mechanisms, involving only leukocytes, fall short of explaining this potential completely. Enriched by dietary means with eicosapentaenoic acid (EPA), stimulated human platelets release substantial amounts of eicosapentaenoic acid and 12S-hydroxyeicosapentaenoic acid (12S-HEPE) in addition to 12S-hydroxyeicosatetraenoic acid (12S-HETE) derived from arachidonic acid. Human neutrophils metabolize 12S-HETE to 5S,12S-DiHETE when stimulated, whereas unstimulated neutrophils produce 12S,20-DiHETE. This study was undertaken to characterize metabolism of 12S-HEPE in human neutrophils. We demonstrate herein for the first time that 12S-HEPE is metabolized by human neutrophils. In unstimulated neutrophils 20-hydroxylation to 12S,20-DiHEPE occurs, whereas in stimulated neurtrophils 5-lipoxygenation to 5S,12S-DiHEPE takes place. The structures of these metabolites were characterized by their relative retention times on reversed-phase high pressure liquid chromatography, by their UV absorbance spectra, and by gas-liquid chromatography-mass spectrometry. With increasing amounts of 12S-HEPE, stimulated neutrophils produced increasing amounts of 5S,12S-DiHEPE, which is virtually inactive biologically. Concomitantly, production of the potent chemokinetic and chemoattractant arachidonic acid derivative leukotriene B4 decreased. Thus, 12S-HEPE can compete with endogenous arachidonic acid for 5-lipoxygenation in stimulated human neutrophils. 12,20-DiHEPE, LTB5, and 5S,12S-DiHEPE were detectable after coincubating EPA-enriched platelets with unenriched neutrophils, and arachidonic acid-derived 5-lipoxygenase products were decreased. We conclude that 12S-HEPE can participate in platelet-neutrophil interactions in a manner similar to 12S-HETE. By providing competing substrates for neutrophil 5-lipoxygenase, platelets might contribute to the antiinflammatory potential of dietary n-3 fatty acids through platelet-neutrophil interaction.     

Separation and quantitation of perbenzoylated glucocerebroside and galactocerebroside by high-performance liquid chromatography

Procollagens are the major proteins secreted into the conditioned medium of cultured arterial smooth muscle cells. Methods for the isolation and quantification of these macromolecules have traditionally required preliminary salt precipitation of procollagens from the conditioned medium followed by cellulose ion-exchange chromatography. The method described here exploits the elongated conformation of soluble procollagens and allows the direct recovery of procollagens from culture medium by a single gel-filtration chromatographic step under nondissociating conditions. Procollagens are isolated in high yield and show minimal processing by procollagen N- or C-terminal peptidase activity. This method results in rapid recovery of highly purified procollagens, free of most proteoglycans or other products of smooth muscle cell metabolism.     

Adenylate deaminase deficiency in a mutant murine T cell lymphoma cell line

From a population of wild type S49 cells, a clone, DTB6, was isolated in a single step from selective medium containing thymidine and dibutyryl cyclic AMP that exhibited a 60% deficiency in AMP deaminase (AMP-D) activity. The AMP-D deficiency conferred to the DTB6 cells a striking susceptibility to killing by low concentrations of either adenine or adenosine, the latter in the presence of an inhibitor of adenosine deaminase activity. This growth supersensitivity of DTB6 cells toward adenine could be ameliorated by the addition of hypoxanthine to the culture medium. Immunoprecipitation of AMP-D from wild type and mutant cells revealed that the DTB6 cell line contained markedly diminished amounts of the AMP-D isozyme which reacts with antisera to the predominant isoform expressed in adult kidney. The quantities of the AMP-D isozyme immunoprecipitated by antisera raised to the predominant isoform prepared from adult heart were equivalent in the two cell lines. Although Northern blot analyses revealed no alterations in mRNA sizes or levels encoded by either of the AMP-D genes, Southern blots of genomic DNA hybridized to a cDNA specific for the ampd2 gene revealed the presence of a new BamHI restriction fragment in the DNA of DTB6 cells. These data suggested that a point mutation has occurred in the ampd2 gene of DTB6 cells which encodes the AMP-D isozyme recognized by the kidney antisera. The DTB6 cells also possessed a virtual complete deficiency in thymidine kinase activity. The two enzyme deficiencies were distinguishable. The ability to isolate single step mutants with two seemingly independent biochemical abnormalities raises the speculation that there may be some link between cellular functions responsible for purine nucleotide and thymidine metabolism.     

Regulatory T Cells and Human Myeloid Dendritic Cells Promote Tolerance via Programmed Death Ligand-1

Immunotherapy using regulatory T cells (Treg) has been proposed, yet cellular and molecular mechanisms of human Tregs remain incompletely characterized. Here, we demonstrate that human Tregs promote the generation of myeloid dendritic cells (DC) with reduced capacity to stimulate effector T cell responses. In a model of xenogeneic graft-versus-host disease (GVHD), allogeneic human DC conditioned with Tregs suppressed human T cell activation and completely abrogated posttransplant lethality. Tregs induced programmed death ligand-1 (PD-L1) expression on Treg-conditioned DC; subsequently, Treg-conditioned DC induced PD-L1 expression in vivo on effector T cells. PD-L1 blockade reversed Treg-conditioned DC function in vitro and in vivo, thereby demonstrating that human Tregs can promote immune suppression via DC modulation through PD-L1 up-regulation. This identification of a human Treg downstream cellular effector (DC) and molecular mechanism (PD-L1) will facilitate the rational design of clinical trials to modulate alloreactivity.