Increased activity, amount, and altered kinetic properties of IMP dehydrogenase from mycophenolic acid-resistant neuroblastoma cells

The Intracellular Formation of a Mononucleotide of the Anti-Influenza Agent 1,3,4-thiadiazol-2-ylcyanamide (LY217896)

LY217896 is a substituted thiadiazole compound with anti-influenza activity in vitro and in the mouse model of infection. LY297336 is a ribosylated (N-4) derivative of LY217896. A highly polar intracellular metabolite of LY217896 was isolated by HPLC, and mass spectral analysis and treatment of the metabolite with alkaline phosphatase showed that it was a monophosphate (LY307987) derived from LY217896. The formation of LY307987 was inhibited by 43 and 63% when 10 μm of LY217896 was incubated with 100 μM of 8-aminoguanosine (8AGuo) and guanine (Gua), respectively, whereas inosine (Ino) and hypoxanthine (Hx) had no effect on the formation of LY307987. LY217896 inhibited the incorporation of [14C]-Hx into nucleic acids in cells which metabolize LY217896; however, LY217896 did not inhibit the formation of inosine 5′-monophosphate (IMP) from Hx in a cell-free HGPRT (hypoxanthine-guanine phosphoribosyltransferase)-catalysed reaction. Incubation of MDCK cells with 10 μm of LY217896 resulted in an 8-fold increase in the level of intracellular IMP. At 100 μm, neither LY217896 nor LY297336 inhibited inosine 5′-monophosphate dehydrogenase (IMPDH) and only cellular extracts which contained intracellular metabolites of LY217896 inhibited IMPDH. Quantification of the 5-phosphorylribose pyrophosphate (PRPP) levels in BS-C-1, MDCK, and MCN cells showed a positive correlation between PRPP concentration and cellular metabolism of LY217896. Combination studies of LY217896 with 2′,3′-dideoxyinosine (ddlno) or 2′,3′-dideoxyguanosine (ddGuo) showed that LY217896 enhanced the antiretroviral activities of these dideoxynucleosides, which is consistent with an inhibitory effect on IMPDH.

Defects in purine nucleotide metabolism lead to substantial incorporation of xanthine and hypoxanthine into DNA and RNA

Deamination of nucleobases in DNA and RNA results in the formation of xanthine (X), hypoxanthine (I), oxanine, and uracil, all of which are miscoding and mutagenic in DNA and can interfere with RNA editing and function. Among many forms of nucleic acid damage, deamination arises from several unrelated mechanisms, including hydrolysis, nitrosative chemistry, and deaminase enzymes. Here we present a fourth mechanism contributing to the burden of nucleobase deamination: incorporation of hypoxanthine and xanthine into DNA and RNA caused by defects in purine nucleotide metabolism. Using Escherichia coli and Saccharomyces cerevisiae with defined mutations in purine metabolism in conjunction with analytical methods for quantifying deaminated nucleobases in DNA and RNA, we observed large increases (up to 600-fold) in hypoxanthine in both DNA and RNA in cells unable to convert IMP to XMP or AMP (IMP dehydrogenase, guaB; adenylosuccinate synthetase, purA, and ADE12), and unable to remove dITP/ITP and dXTP/XTP from the nucleotide pool (dITP/XTP pyrophosphohydrolase, rdgB and HAM1). Conversely, modest changes in xanthine levels were observed in RNA (but not DNA) from E. coli lacking purA and rdgB and the enzyme converting XMP to GMP (GMP synthetase, guaA). These observations suggest that disturbances in purine metabolism caused by known genetic polymorphisms could increase the burden of mutagenic deaminated nucleobases in DNA and interfere with gene expression and RNA function, a situation possibly exacerbated by the nitrosative stress of concurrent inflammation. The results also suggest a mechanistic basis for the pathophysiology of human inborn errors of purine nucleotide metabolism.

Lentiviral vector conferring resistance to mycophenolate mofetil and sensitivity to ganciclovir for in vivo T-cell selection

Several clinical studies of gene-modified T cells have shown limited in vivo function of the cells, immunogenicity of the transgene, and lack of a selective advantage for gene-modified T cells. To address these problems, we developed a lentiviral vector (LV) that provides a selectable, proliferative advantage and potentially decreases immunogenicity for transduced T cells. The bicistronic vector expressed two genes linked with an internal ribosomal entry site. One gene is a variant of the inosine monophosphate dehydrogenase 2, inosine monophosphate dehydrogenase (IMPDH(IY)), conferring resistance to the immunosuppressive drug mycophenolate mofetil (MMF). The other is a suicide gene, herpes simplex virus thymidine kinase (HSV-TK), rendering proliferating cells sensitive to ablation with ganciclovir, fused to the selectable transmembrane marker DeltaCD34 (DeltaCD34/TK). Cells transduced with LV-DeltaCD34/TK.IMPDH(IY) were efficiently enriched by immunomagnetic selection for CD34, proliferated in 0.5-5 microM MMF, and were killed by 0.5-25 microg ml(-1) ganciclovir. We demonstrate efficient selection and killing of gene-modified cells and suggest LV-DeltaCD34/TK.IMPDH(IY)-transduced T cells could be used to facilitate allogeneic hematopoietic cell engraftment. The expression of IMPDH(IY) would allow in vivo selection with MMF, and DeltaCD34/TK expression would allow rapid and safe elimination of transduced T cells if graft-versus-host disease developed.

Inosine-5'-monophosphate dehydrogenase is required for mitogenic competence of transformed pancreatic beta cells

The relation of inosine-5'-monophosphate dehydrogenase (IMPDH; the rate-limiting enzyme in GTP synthesis) to mitogenesis was studied by enzymatic assay, immunoblots, and RT-PCR in several dissimilar transformed pancreatic ss-cell lines, using intact cells. Both of the two isoforms of IMPDH (constitutive type 1 and inducible type 2) were identified using RT-PCR in transformed beta cells or in intact islets. IMPDH 2 messenger RNA (mRNA) and IMPDH protein were both regulated reciprocally by changes in levels of their end-products. Flux through IMPDH was greatest in rapidly growing cells, due mostly to increased uptake of precursor. Glucose (but not 3-0-methylglucose, L-glucose, or fructose) further augmented substrate uptake and also increased IMPDH enzymatic activity after either 4 or 21 h of stimulation. Serum or ketoisocaproate also increased IMPDH activity (but not uptake). Two selective IMPDH inhibitors (mycophenolic acid and mizoribine) reduced IMPDH activity in all cell lines, and, with virtually identical concentration-response curves, inhibited DNA synthesis (assessed as bromodeoxyuridine incorporation) in response to glucose, serum, or ketoisocaproate. Inhibition of DNA synthesis was reversible, completely prevented by repletion of cellular guanine (but not adenine) nucleotides, and could not be attributed to toxic effects. Despite the fact that modulation of IMPDH expression by guanine nucleotides was readily detectable, glucose and/or serum failed to alter IMPDH mRNA or protein, indicating that their effects on IMPDH activity were largely at the enzyme level. Precursors of guanine nucleotides failed, by themselves, to induce mitogenesis. Thus, adequate IMPDH activity (and thereby, availability of GTP) is a critical requirement for beta-cell proliferation. Although it is unlikely that further increases in GTP can, by themselves, initiate DNA synthesis, such increments may be needed to sustain mitogenesis.

Inosine-5'-monophosphate dehydrogenase: regulation of expression and role in cellular proliferation and T lymphocyte activation

Guanine nucleotide synthesis is essential for the maintenance of normal cell growth and function, as well as for cellular transformation and immune responses. The expression of two genes encoding human inosine-5'-monophosphate dehyrogenase (IMPDH) type I and type II results in the translation of catalytically indistinguishable enzymes that control the rate-limiting step in the de novo synthesis of guanine nucleotides. Cellular IMPDH activity is increased more than 10-fold in activated peripheral blood T lymphocytes and is attributable to the increased expression of both the type I and type II enzymes. In contrast, abrogation of cellular IMPDH activity by selective inhibitors prevents T lymphocyte activation and establishes a requirement for elevated IMPDH activity in T lymphocytic responses. In order to assess the molecular mechanisms governing the expression of the IMPDH type I and type II genes in resting and activated peripheral blood T lymphocytes, we have cloned the human IMPDH type I and type II genes and characterized their genomic organization and their respective 5'-flanking regions. Both genes contain 14 highly conserved exons that vary in size from 49 to 207 base pairs. However, the intron structures are completely divergent, resulting in disparities in gene length (18 kilobases for type I and 5.8 kilobases for type II). In addition, the 5'-regulatory sequences are highly divergent; expression of the IMPDH type I gene is controlled by three distinct promoters in a tissue specific manner while the type II gene is regulated by a single promoter and closely flanked in the 5' region by a gene of unknown function. The conservation of the IMPDH type I and type II coding sequence in the presence of highly divergent 5'-regulatory sequences points to a multifactorial control of enzyme expression and suggests that tissue-specific and/or developmentally specific regulation of expression may be important. Delineation of these regulatory mechanisms will aid in the elucidation of the signaling events that ultimately lead to the synthesis of guanine nucleotides required for cellular entry into S phase and the initiation of DNA replication.

Inosine-5'-monophosphate dehydrogenase is a rate-determining factor for p53-dependent growth regulation

We have proposed that reduced activity of inosine-5'-monophosphate dehydrogenase (IMPD; IMP:NAD oxidoreductase, EC 1.2.1.14), the rate-limiting enzyme for guanine nucleotide biosynthesis, in response to wild-type p53 expression, is essential for p53-dependent growth suppression. A gene transfer strategy was used to demonstrate that under physiological conditions constitutive IMPD expression prevents p53-dependent growth suppression. In these studies, expression of bax and waf1, genes implicated in p53-dependent growth suppression in response to DNA damage, remains elevated in response to p53. These findings indicate that under physiological conditions IMPD is a rate-determining factor for p53-dependent growth regulation. In addition, they suggest that the impd gene may be epistatic to bax and waf1 in growth suppression. Because of the role of IMPD in the production and balance of GTP and ATP, essential nucleotides for signal transduction, these results suggest that p53 controls cell division signals by regulating purine ribonucleotide metabolism.

Structure and mechanism of inosine monophosphate dehydrogenase in complex with the immunosuppressant mycophenolic acid

The structure of inosine-5'-monophosphate dehydrogenase (IMPDH) in complex with IMP and mycophenolic acid (MPA) has been determined by X-ray diffraction. IMPDH plays a central role in B and T lymphocyte replication. MPA is a potent IMPDH inhibitor and the active metabolite of an immunosuppressive drug recently approved for the treatment of allograft rejection. IMPDH comprises two domains: a core domain, which is an alpha/beta barrel and contains the active site, and a flanking domain. The complex, in combination with mutagenesis and kinetic data, provides a structural basis for understanding the mechanism of IMPDH activity and indicates that MPA inhibits IMPDH by acting as a replacement for the nicotinamide portion of the nicotinamide adenine dinucleotide cofactor and a catalytic water molecule.

Cytosolic biosynthesis of GTP and ATP in normal rat pancreatic islets

GTP and ATP are necessary for glucose-induced insulin secretion; however, the biosynthetic pathways of purine nucleotides have not been studied in pancreatic islets. The present work examines the cytosolic pathways of purine nucleotide synthesis using intact rat islets cultured overnight in RPMI 1640 medium containing either [14C]glycine (to label the de novo pathway) or [3H]hypoxanthine (to mark the salvage pathway), with or without mycophenolic acid or L-alanosine (selective inhibitors of cytosolic GTP and ATP synthesis, respectively). Addition of mycophenolic acid decreased total GTP content (mass) by 73-81%; although the incorporation of labeled hypoxanthine into GTP also fell by 87%, the incorporation of glycine did not change. Similarly, L-alanosine decreased ATP mass by 26-33% in the presence of either label; whereas the incorporation of hypoxanthine into ATP fell 59%, the incorporation of glycine was again not significantly decreased. Thus, both the de novo and salvage purine nucleotide biosynthetic pathways are present in rat islets; however, the salvage pathway appears to be quantitatively the more important source of nucleotides. This conclusion was supported by additional studies of the effects on nucleotide content and insulin secretion of various site-specific inhibitors of purine synthesis. These findings have potential relevance to the processes of mitogenesis, cell proliferation and differentiation of islet cells, as well as for the control of insulin secretion.

Secondary loss of deoxyguanosine kinase activity in purine nucleoside phosphorylase deficient mice

The T-cell immunodeficiency associated with purine nucleoside phosphorylase (PNP) deficiency in man is believed to be due to the accumulation of dGTP which may be preferentially formed from deoxyguanosine in T-lymphocytes or their precursor cells. We found no evidence for dGTP accumulation in thymocytes or spleen leucocytes, < 1 nmol/10(9) cells, nor in erythrocytes, < 0.05 nmol/10(9) cells, of the B6-NPE- or B6-NPF PNP-deficient mice strains. There were no changes in purine or pyrimidine ribonucleotide pools. As these mice had been previously shown to excrete PNP nucleoside substrates, we examined the metabolism of deoxyguanosine. Deoxyguanosine kinase activity as compared to control mice was 6 to 52% for the B6-NPE mutant, 2 to 22% for the B6-NPF mutant. Fractionation of erythrocyte and liver lysates from the F mutation and the background strain, C57BL/6J, by anion exchange chromatography confirmed the secondary deficiency of deoxyguanosine kinase and demonstrated that this activity was distinct from adenosine kinase and two major peaks of deoxycytidine kinase activity. Mouse PNP, expressed and purified as a fusion protein, did not show evidence of being bifunctional and having deoxyguanosine kinase activity. Metabolic modelling revealed that the ratio of deoxyguanosine phosphorylation versus phosphorolysis was < 0.06 in control mice, and < or = 0.3 in lymphocytes of PNP-deficient mice. Were deoxyguanosine kinase not reduced in the PNP-deficient mice, all tissues of the B6-NPF mutant would preferentially phosphorylate deoxyguanosine at low substrate concentrations.

The interaction of immunosuppressive compounds in tandem stimulated peripheral human lymphocytes

We have developed an in vitro system to model the interactions of drugs used to treat transplant rejection. This system consists of stimulation of human lymphocytes with a primary mitogen (anti-T-cell receptor complex antibodies (OKT3 or wt31)) and treatment with a primary immunosuppressive drug (ISD) (Cyclosporine A (CsA) or FK-506)). This is later followed by stimulation with a secondary mitogen (Interleukin-2 or anti-CD28), and treatment with a second ISD. This system allows a variety of concentrations and compounds to be rapidly tested. We have used this system to study the effect of various compounds when used as either primary or secondary ISDs. Our results show that when CsA is used as the primary ISD, further proliferation can be inhibited by rapamycin, mycophenolic acid, or suramin. When FK-506 is the primary ISD, inhibition of proliferation by rapamycin is variable depending on the primary and secondary mitogens. If rapamycin is the primary ISD, both CsA and FK-506 show antagonistic interactions. These results suggest that the order in which combinations of ISDs are administered in transplantation may have significant effects on the clinical outcome.

Gene amplification and dual point mutations of mouse IMP dehydrogenase associated with cellular resistance to mycophenolic acid

Mouse neuroblastoma cells (NB) selected for 10,000-fold increased resistance to mycophenolic acid (NB-Myco) showed a 200-500-fold increase in IMP dehydrogenase protein, and the enzyme (IMP: NAD+ oxidoreductase, EC 1.1.1.205) also exhibited a 2400-fold increased ki for mycophenolic acid and reduced catalytic efficiency (Hodges, S.D., Fung, E., McKay, D.J., Renaux, B.S., and Snyder, F.F. (1989) J. Biol. Chem. 264, 18137-18141). The molecular basis of these changes is the subject of the present study. The nucleotide sequence of IMP dehydrogenase cDNA from NB-Myco cells revealed four nucleotide changes. One of these changes did not result in a codon change, and a second one corresponding to methionine-483 was present in the parental NB mouse line. The remaining two nucleotide substitutions and deduced residue changes are: the C to T transition at base 998 relative to initiation of translation, altering threonine-333 to isoleucine; and the C to A transversion at base 1052, altering serine-351 to tyrosine. Evidence was also obtained for IMP dehydrogenase having undergone gene amplification. IMP dehydrogenase mRNA levels were 500-fold increased in NB-Myco cells as compared to parental NB cells. DNA dot blot analysis showed a 25-fold increase in IMP dehydrogenase gene copy number and restriction enzyme analysis revealed similar gene structure for NB and NB-myco cells.

Inhibition of IMP dehydrogenase by mycophenolic acid in Molt F4 human malignant lymphoblasts

The effects of inhibition of inosine monophosphate dehydrogenase (IMPDH), the rate-limiting enzyme in guanine nucleotide de novo synthesis, on cell growth, cell viability, endogenous nucleotide concentrations and concentrations of extracellular nucleosides and bases were studied in Molt F4 human malignant lymphoblasts. Mycophenolic acid (MPA) was used as a specific inhibitor of the enzyme activity. IMPDH activity was maximally inhibited with 0.5 microM MPA. After a 2 h exposure of the cells to 0.5 microM MPA, guanine nucleotides were depleted to approximately 50% of control values, whereas 5-phosphoribosyl-1-pyrophosphate levels increased to approximately 200%. Under these conditions, cytotoxicity became obvious after 24 h. Depletion of guanine nucleotides and cytotoxicity were prevented by addition of guanosine to MPA treatment. Daily supplements of guanosine were required to prevent MPA cytotoxicity during the entire incubation period of 72 h. We conclude that depletion of guanine nucleotides, induced by treatment with MPA, induces a severe and rapid cytotoxicity in Molt F4 cells.

Inosine-5'-monophosphate dehydrogenase activity is maintained in immortalized murine cells growth-arrested by serum deprivation

We have examined properties of IMPD activity in soluble extracts from immortalized murine epithelial and fibroblastic cells. The absence of significant xanthine oxidase activity in these extracts allowed the use of a spectrophotometric assay to study the enzyme activity. The observed enzymatic activity had subcellular localization and kinetic properties similar to those of previously described mammalian IMPD from other sources. Analysis of IMPD activity in extracts from cells in different states of growth related to serum concentration gave a surprising result. Extracts from exponentially growing cells exhibited a level of IMPD activity similar to that of extracts from quiescent cells arrested by serum-deprivation. In previous studies, the cellular variable designated to account for changes in IMPD activity was proliferative rate. Our findings suggest that either proliferative rate is not the functionally significant variable related to IMPD regulation or that there are other factors that can supersede it in certain contexts. Given the role of the enzyme in regulating the synthesis of guanine nucleotides, which are key regulatory molecules for many cellular processes, this may indeed be the case. Using immortalized cell lines growth-arrested by serum deprivation, we have experimentally isolated the enzyme activity from the previously assigned variable of growth rate. Based on our findings we propose that regulation of IMPD activity is more appropriately related to proliferative capacity as opposed to proliferative rate.

Assay for expression of methotrexate-resistant dihydrofolate reductase activity in the presence of drug-sensitive enzyme

A simple, continuous spectrophotometric assay for dihydrofolate reductase (DHFR) activity was adapted for determination of drug-resistant enzyme activity expressed from transfected genes in cells containing drug-sensitive enzyme. Methotrexate inhibition characteristics in this assay system were assessed for the murine wild-type (WT) enzyme as well as variant genes encoding amino acid substitutions at codon positions 22 (arg22) or 31 (trp31) expressed in DHFR-deficient Chinese hamster ovary (CHO) cells and in mouse 3T3 cells. Methotrexate concentrations were thus identified which maximized inhibition of the wild-type enzyme while maintaining substantial arg22 or trp31 activity. Mixing experiments were conducted to determine the minimum amount of drug-resistant enzyme distinguishable from a constant amount of wild-type enzyme in the presence of methotrexate. Mixtures of enzymes from a variety of sources (WT, arg22, or trp31 expressed in CHO or 3T3 cells) demonstrated a detection limit of 0.03 to 0.06 nmol/min. Assay of methotrexate-resistant arg22 DHFR appeared to be limited by the low level of activity associated with this enzyme variant, whereas assay of the trp31 variant was limited by enzyme inhibition at lower concentrations of methotrexate. The assay was thus applicable to two quite diverse DHFR variants and may be useful for assaying the expression of other drug-resistant DHFR genes as well after introduction into cells containing drug-sensitive enzyme.

Comparison of the in vitro and biophysical effects of cyclosporine A, FK-506, and mycophenolic acid on human peripheral blood lymphocytes

The immunosuppressive drugs FK-506 and mycophenolic acid (MPA) have recently been described, but their mode(s) of action are not well understood. We have compared them to cyclosporine A (CsA) in several assays. We have shown that CsA (1 microgram/ml), MPA (0.1 microgram/ml), and FK-506 (0.5 microgram/ml) all induce a state of unresponsiveness to anti-CD3 stimulation as measured by [3H]-thymidine uptake. This suggests that the target of these drugs may be present only after mitogenic stimulation. These drugs also cause a hyperpolarization of the plasma membrane of lymphocytes. This effect is blocked by quinine or verapamil. All three immunosuppressors only slightly modulate the increase in intracellular Ca++ caused by Con-A or by anti-CD3 stimulation but do not affect Ca++ levels alone. They also decrease expression of IL-2 receptors on alpha CD3-stimulated lymphocytes. Similarities in their modes of action, as measured by these biophysical and cell biological tests, indicate the possibility that these three drugs will show similarities in their clinical performance.