Activation of ADP-ribosyltransferase in polyamine-depleted mammalian cells

Effects of cyclosporin A and a non-immunosuppressive analogue, O-acetyl cyclosporin A, upon the growth of parent and multidrug resistant human lung cancer cells in vitro

We have studied the ability of cyclosporin A (CsA) and a non-immunosuppressive analogue, O-acetyl cyclosporin A (OACsA, B3-243) to inhibit the growth of human lung cancer cells in vitro. Using continuous drug exposure and the MTT colorimetric assay to determine cell growth we found that CsA produced partial growth inhibition at doses ranging from 0.5 to 3.0 micrograms ml-1 (0.4-2.4 microM). At progressively higher doses, complete growth inhibition and in situ cell lysis were seen. The P-glycoprotein expressing multidrug resistant (MDR) variant H69/LX4 of the small cell line H69/P was less sensitive to cyclosporins than the parent line, but this was not true of the non-P-glycoprotein expressing MDR variants of large cell line COR-L23 or adenocarcinoma line MOR. Sensitivity to OACsA was approximately 2-fold higher than that to CsA in most of the lines although not in the most sensitive line, COR-L88. Even in COR-L88, exposed to CsA or OACsA for 24 h, clonogenic cell survival was reduced only to 50%. There was no reduction in polyamine content of COR-L23 or COR-L88 cells following 48 h of exposure to CsA or OACsA. The effects on cell growth could not be inhibited by the addition of exogenous putrescine, nor could they be enhanced by the addition of alpha-difluoromethylorthinine. It does not appear therefore that inhibition of polyamine synthesis is the basis of the observed growth inhibition.

Effects of cyclosporin A on growth and polyamine metabolism of MOLT-4 T-lymphoblastic leukaemia cells

We have examined the effects of Cyclosporin A (CsA) on growth and polyamine metabolism of MOLT-4, human T lymphoblastic leukaemia cells to ascertain the role of the polyamine biosynthetic pathway in the antitumour action of CsA. We observed that CsA had a dose-dependent inhibitory effect on growth of the cells in vitro, decreasing protein content, cell number and the rate of incorporation of 3H-thymidine into the cells. However, CsA treatment had no significant effect on intracellular polyamine levels in the cells. Contrary to previous reports, simultaneous addition of the diamine, putrescine, with CsA did not block or lessen the growth inhibitory effects of CsA. On the other hand, ornithine decarboxylase activity, the rate limiting enzyme of polyamine biosynthesis which converts ornithine to putrescine, was decreased by CsA treatment. This decrease appeared to be reversible and contrasts with the inhibition by alpha-difluoromethyl-ornithine, which is irreversible and can be overcome by addition of putrescine. This suppression of ornithine decarboxylase by CsA is more likely to occur by indirect effects on translation and/or transcription rather than a direct effect on the enzyme. It may be a contributory factor in the overall antiproliferative effects of CsA but is more likely to be a response to these growth inhibitory effects rather than a direct effect of the drug.

Mitochondrial effects of the guanidino group-containing cytostatic drugs, m-iodobenzylguanidine and methylglyoxal bis (guanylhydrazone)

The involvement of mitochondrial damage in the antiproliferative effects of m-iodobenzylguanidine [MIBG] and methylglyoxal bis (guanylhydrazone) [methylGAG] was studied in human neuroblastoma SK-N-SH, mouse neuroblastoma N1E115 and mouse lymphosarcoma S49 cells. Proliferation of SK-N-SH cells was insensitive to MIBG (100 microM gave 15% inhibition), but sensitive to methylGAG (IC50 = 50 microM). MIBG and methylGAG were approximately equitoxic to N1E115 cells (IC50 of 92 and 87 microM, respectively). S49 cells were most sensitive to both MIBG (IC50 = 11 microM) and methylGAG (IC50 = 5 microM). In isolated sonicated mitochondria, MIBG inhibited respiration a complex I of the respiratory chain (EC50 = 0.5 mM), whereas methylGAG was much less effective (EC50 greater than 15 mM). In intact cells, MIBG at 31 microM impaired mitochondrial respiration and stimulated the glycolytic flux. In contrast, equimolar concentrations of methylGAG had no effect on oxygen consumption, ATP content, glucose consumption and lactate production. MethylGAG significantly increased putrescine levels in N1E115 and S49 cells within 12 hr via inhibition of S-adenosylmethionine decarboxylase. No such effects were seen in SK-N-SH cells for up to 48 hr. Equimolar concentrations of MIBG had no effect on the putrescine levels in the various cell lines, suggesting that MIBG did not inhibit S-adenosylmethionine decarboxylase. It is concluded that the antiproliferative mechanisms of the guanidino compounds are essentially different. MIBG inhibited mitochondrial respiration at complex I with concomitant stimulation of the glycolytic flux but was essentially without effect on polyamine levels. On the other hand, cytotoxicity of methylGAG was not associated with mitochondrial dysfunction.

Effect of polyamine depletion on DNA damage and repair following UV irradiation of HeLa cells

Treatment of HeLa cells with the polyamine biosynthesis inhibitors, methylglyoxal bis(guanylhydrazone) (MGBG), difluoromethylornithine (DFMO) or a combination of the two, resulted in reduction in cellular polyamine levels. Analysis of UV light-induced DNA damage and repair in these polyamine depleted cells revealed distinct differences in the repair process relative to that seen in cells possessing a normal polyamine complement. Initial yield of thymine dimers and rate of removal of these lesions from cellular DNA appeared normal in polyamine-depleted cells. However, depleted cells exhibited retarded sealing of DNA strand breaks resulting from cellular repair processes, reduced repair synthesis and an increased sensitivity to UV killing. Incision at damaged sites was not affected since ara-C repair-dependent breaks accumulated in a normal fashion. Molecular analysis of inhibited repair sites by exonuclease III and T4 DNA ligase probes suggest that the strand interruptions consist of gaps rather than ligatable nicks, consistent with an interpretation of the repair defect being at the gap-filling stage rather than the ligation step. Observed patterns of differential polyamine depletion by DFMO and MGBG, and partial reversal of repair inhibition by polyamine supplementation, suggests that polyamine depletion per se, rather than some secondary effect of inhibitor treatment, is responsible for the inhibition of repair.

Influence of cyclosporin A and alpha-difluoromethylornithine, an inhibitor of polyamine biosynthesis, on two rodent T-cell cancers in vivo

We have examined the influence of cyclosporin A (CsA), administered together with the polyamine antimetabolite, alpha-difluoromethylornithine (DFMO), on growth of the Roser acute T-cell leukaemia in PVG rats and on growth of the EL4 lymphoma in C57BL/6 mice. CsA or DFMO alone, administered from the time of tumour injection, markedly reduced numbers of circulating lymphoblasts in leukaemic rats, although survival was prolonged only in those animals given DFMO. Drug combination further reduced blood-borne tumour cells, but had no additional effects on tumour growth within organs or on host survival, compared to that achieved with DFMO treatment alone. Neither CsA nor DFMO, administered from the time of tumour-cell injection, nor both drugs in combination, affected peritoneal growth of the EL4 lymphoma or organ infiltration. Host survival was prolonged by DFMO. As anticipated, DFMO inhibited polyamine synthesis in vivo, but the observed anti-tumour effect of CsA was not accompanied by an alteration in polyamine biosynthesis. By reducing polyamine synthesis, however, DFMO may enhance the vulnerability of those malignant T cells which are susceptible to the as yet unexplained selective inhibitory action of CsA in vivo.

Poly(ADP-ribose) catabolism in mammalian cells exposed to DNA-damaging agents

DNA damage inflicted by the alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine, or by UV254nm, stimulated the catabolism of protein-bound poly(ADP-ribose) in the chromatin of cultured hepatocytes. The stimulation was highest at the largest doses of DNA-damaging treatment. As a consequence, the half-life of ADP-ribosyl polymers may drop to less than 41 s. This rapid turnover contrasts with the slow catabolism of a constitutive fraction of polymers exhibiting a half-life of 7.7 h. Our data suggest that post-incisional stimulation of poly(ADP-ribose) biosynthesis in DNA-excision repair is coupled with an adaptation of poly(ADP-ribose) catabolism in mammalian cells.

Inhibition of X-ray-induced DNA strand break repair in polyamine-depleted HeLa cells

Treatment of HeLa cells with the polyamine biosynthesis inhibitors, alpha-difluoromethylornithine (DFMO) or methylglyoxal bis(guanylhydrazone) (MGBG), results in, depending on the conditions, partial or complete depletion of the cellular polyamines: putrescine, spermidine and spermine. In this compromised state cells exhibited a distinct deficiency in repair of X-ray-induced DNA strand breaks. The half-time for return of normal DNA sedimentation following 1.6 Gy was 9.5 min for untreated control cells and 22, 32 and 50 min for cells treated with MGBG, DFMO + MGBG and DFMO, respectively. Normal repair kinetics were restored to these cells upon a short incubation in media containing all three polyamines. The rapid early phase of repair following higher X-ray doses (16 Gy) was also delayed in polyamine-depleted cells but later repair occurring 1-4 h post-irradiation, representing chromatin reconstitution, was apparently normal.

Acetylation of spermidine and methylglyoxal bis(guanylhydrazone) in baby-hamster kidney cells (BHK-21/C13)

Treatment of BHK-21/C13 cells with methylglyoxal bis(guanylhydrazone) (MGBG) induced the cytosolic form of spermidine N1-acetyltransferase. It stabilized the enzyme against proteolytic degradation, but the drug did not affect the enzyme activity in vitro. MGBG was itself acetylated by BHK-21/C13 cells, but at only one-tenth the rate at which spermidine was acetylated. Acetylation occurred almost exclusively in the nuclear fraction. The product was identified as N-acetyl-MGBG by h.p.l.c., by using [3H]acetyl-CoA and [14C]MGBG as co-substrates. The results suggest that the acetylation of MGBG by BHK-21/C13 cells occurs by a different acetyltransferase enzyme from that which acetylates spermidine.

Alterations in amounts and covalent modifications of low-molecular-weight chromosomal proteins in Chinese hamster ovary cells during polyamine depletion

The effect of polyamine depletion on phosphorylation and ADP-ribosylation of low-Mr chromosomal proteins was studied in intact, mutant Chinese hamster ovary cells (CHO-P22) devoid of ornithine decarboxylase activity. When starved of polyamines for 6 days, severe polyamine deficiency develops and the cells gradually stop growing. The rate of DNA synthesis was retarded to 16% of the control value and to 29% in density-inhibited cells. The synthesis of high-mobility-group (HMG) proteins was decreased by 65% in polyamine-depleted cells and by 40% in density-inhibited cells. The synthesis of core histones was decreased by 40% both in polyamine-depleted and density-inhibited cells. In polyamine-depleted cells the molar ratio of the higher-Mr HMG proteins (HMG 1 + 2) to the lower-Mr HMG proteins (HMG 14 + P) was about one-half of that found in cells grown in the presence of putrescine or in density-inhibited cells. In contrast to HMG proteins, no major differences were found in the content of core histones in these cell populations. In the perchloric acid-soluble fraction of nuclear proteins, 32P was incorporated mainly into histone H1, HMG P and a protein migrating more slowly than HMG 1 (protein P1). Specific changes in the 32P-labeling and migration of a number of protein bands, including histone H1, was observed in polyamine-depleted cells as compared to cells grown in the presence of putrescine or to density-inhibited cells. ADP-ribosylation experiments using [3H]adenosine showed a different pattern of label distribution; the higher-Mr HMG proteins from polyamine-depleted cells contained about one-half the amount of label found in the proteins from control cells. The lower-Mr HMG proteins and histone H1 were the preferentially labeled proteins in polyamine-depleted cells. Labeling of core histones with [32P]orthophosphate or [3H]adenosine did not differ markedly in the two cell populations. The results obtained using intact polyamine auxotrophic cells indicated that polyamine depletion is connected with more severe alterations in amounts and covalent modifications (phosphorylation and ADP-ribosylation) of HMG chromosomal proteins and histone H1 than core histones.

Degradation of (ADP-ribose)n in permeabilized HeLa cells

Determination of (ADP-ribose)n degradation rates in permeabilized HeLa cells, measured as loss of acid-insoluble radioactivity from permeabilized cells previously incubated with [3H]NAD+, showed bi-phasic kinetics. The majority of label was lost within 20 min at pH 6.0 and 37 degrees C and has a half-life of about 12-15 min. The minor ADP-ribose component was either removed very slowly, or appeared to be stable over an 80 min incubation. The degradation rate of the labile component was directly proportional to the initial amount of ADP-ribose present, and was independent of the experimental conditions used to create various elevated levels. The degradation rates of monomeric and oligo/polymeric ADP-ribose were the same, surprising since different enzymes catalyse the respective reactions. The more stable ADP-ribose component could be more inaccessible to degrading enzymes and/or might represent a different linkage to protein, the cleavage of which is slow.

Chilling followed by incubation at 37 degrees C causes a reduction in NAD+ levels which can be prevented by the poly(ADP-ribose)transferase inhibitor 3-aminobenzamide

The exposure of cells for 60 min to a serum free medium at ice temperature followed by a return to normal culture conditions (30 min at 37 degrees C) caused a dramatic decrease in NAD+ levels. This decrease in NAD+ was prevented by 3-aminobenzamide. Alkaline elution analysis of DNA from cultures that were sisters to the ones utilized for measuring cellular NAD+ content revealed an absence of DNA breakage. These data suggest that poly(ADP-ribose)transferase may be induced in conditions not involving DNA fragmentation. The induction of this enzyme could therefore represent a cellular emergency reaction and not just a response to DNA damage.

Poly(ADP-ribosyl)ation studies in situ

We have studied the poly(ADP-ribosyl)ation of nuclear proteins in situ by examining the incorporation of [3H]NAD-derived ADP-ribose into polymers. We have devised a way to deliver [3H]NAD to cells growing in vitro, and we have determined the kinetics of uptake and incorporation into nuclear proteins using this delivery system. Incorporation into the histone fraction, known acceptors of poly(ADP-ribose), was examined and shown to be sensitive to the poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide. Polyacrylamide gel electrophoresis of 3H-labeled proteins revealed radioactivity associated with known poly(ADP-ribose)-accepting proteins such as poly(ADP-ribose) polymerase and histones. These results were confirmed when we immunoreacted gel-separated proteins with anti-(ADP-ribose) generated in our laboratory.

Increased protein ADPribosylation in HeLa cells exposed to the anti-cancer drug methotrexate

DNA single-strand breaks (about 200-300 per genome) were transiently detected during the first hour when HeLa cells were incubated for up to 24 h with 100 microM methotrexate. There was an expected increase in ADPribosyltransferase activity, which reached a maximum 2-3-fold stimulation at 3 h but which was still greater than in control cells after 24 h. When hypoxanthine (25 microM) was present in the incubations together with the methotrexate the transferase was no longer activated, although basal, control levels of activity were still present. DNA strand breaks were reduced in number but were still just detectable under these conditions. Cellular NAD+ levels were mostly unaffected by the various drug treatments, except for a small transient decrease after 1 h, possibly as a result of the transferase activation. Methotrexate did not cause an increase in the rate of ADPribose degradation. Degradation of ADPribose residues labelled in a preincubation period in permeabilized cells was more extensive at pH 6.0 was a 50% loss of acid-insoluble radioactivity in 30 min at 26 degrees C. At pH 8.0 the loss did not exceed 30-35% even after 90 min incubation. The activation of the transferase is reflected in a general increase in protein ADPribosylation detected by autoradiography of 32P-labelled proteins in 6.25-18.25%T gradient acrylamide gels. There were three major acceptors with molecular masses of 17, 100 and over 100 kDa, which could be respectively a histone, a transferase-derived peptide fragment and the transferase itself. When ADPribosyltransferase was inhibited with 3-amino-benzamide DNA single-strand breaks were no longer detected. However, this had no observably signficant effect on the kinetics of loss of cell viability (from Trypan blue uptake), cell number or colony-forming ability. Similar results are observed in most cases when the activation of the transferase, resulting from the incubation of cells with methotrexate, is inhibited by hypoxanthine. We conclude from such observations that the enhanced protein ADPribosylation seen in the cells exposed to methotrexate is a direct consequence of drug-exposure, but does not have any significant influence over the course of events leading ultimately to cell death.

A gel-electrophoretic analysis of protein ADP-ribosylation in polyoma virus-transformed and non-transformed BHK-21/C13 fibroblasts

We have examined a variety of conditions for solubilizing and electrophoresing cell proteins in order to define optimum conditions for studying proteins modified by ADP-ribosylation. We have identified conditions in which proteins can be quantitatively extracted from cells in an undegraded form with the protein-ADPribose linkages intact. Effective measures include boiling cells briefly (4 min) in the presence of 2% SDS and 2 M urea at pH 6.8. Both SDS and urea were present in the 6-18% gradient polyacrylamide gel matrix used for electrophoresis. Under these conditions good resolution of proteins of a wide molecular-weight range is obtained. This system has been used to compare protein ADP-ribosylation in non-transformed and polyma virus-transformed baby hamster kidney (BHK) fibroblasts, since the latter cells have a greater NAD+ ADP-ribosyltransferase activity (measured in isolated nuclei and permeabilized cells). Addition of DNAase to permeabilized BHK cells over the range 10-150 micrograms led to a progressively greater activation of transferase compared with controls. When PyY cells were used, however, maximum activation was achieved with only 10 micrograms of DNAase, further additions producing a successively smaller activation relative to control cells without added nuclease. There were also differences between these cells in response to salt. Addition of NaCl (to about 0.3 M) to BHK cells resulted in various extents of transferase activation, whereas any addition of NaCl to the incubate of permeabilized PyY cells decreased transferase activity. These different enzyme activities between this transformed and non-transformed cell line are for the most part not reflected in the protein modification profiles seen on autoradiograms of acrylamide gels after electrophoresis 32P-labelled proteins. A variety of proteins are modified and their molecular weights depend on the NA concentration in the permeabilized cell incubation. At 0.5 microM NAD+ there were two major acceptors with Mr values of 14 kDa and 30 kDa, and at 100 microM NAD+, three major acceptors, with Mr values of 19 kDa. 45 kDa and greater than 170 kDa. NAD concentrations of between 1 microM and 100 microM had no further effect on protein ADP-ribosylation profiles, except for the protein(s) of Mr greater than 170 kDa, pointing to a critical difference around 0.5-1.0 microM substrate. In some experiments, however, a difference was observed in the intensity of radioactivity in two bands. This may represent two different proteins, or a single protein modified to different extents.(ABSTRACT TRUNCATED AT 400 WORDS)