Dynamics of modulation of biochemical programs in cancer cells

Down-regulation of increased signal transduction capacity in human cancer cells

Signal transduction capacity in human cancer cells is constitutively up-regulated by the markedly increased steady-state activities of the three synthetic enzymes, PI kinase, PIP kinase and PLC, which catalyze the conversion of PI to the second messengers IP3 and DAG. This evidence is supported by the elevated concentration of IP3 in human colon, ovarian and breast carcinoma samples and rat hepatocellular carcinomas and sarcoma. The decrease in activities of the two specific phosphatases in the degradative pathway of signal transduction provides an amplified capacity for IP3 production. The elevated second messenger concentrations should lead to increased calcium release and protein kinase C activation. These biochemical alterations should confer selective biological advantages to cancer cells. The malignancy-linked rise in the activity of the signal transduction pathway can be down-regulated by drugs (tiazofurin, ribavirin, tamoxifen) or through inhibition of the kinases by flavonoids (quercetin, genistein) which lead to a reduction of IP3 concentration. As a result, carcinoma cells in culture stop proliferating and are destroyed. The stringent linkage of signal transduction with neoplasia provides novel targets for clinical chemotherapy.

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.

Estimation of metabolic flux rates in liver purine catabolism of tumour-bearing mice by computer simulation of radioactive tracer experiments

Mouse hepatocytes from healthy control mice and from Ehrlich ascites tumour-bearing mice were used for tracer-kinetic studies of purine catabolism of liver cells during different periods of tumour growth. The dynamics of the radioactive tracers were modelled mathematically by a system of differential equations. Computer simulations, i.e. direct fitting of numerical solutions of these equations to the observed time-courses of metabolites and specific radioactivities, enables one to estimate unknown kinetic parameters of a simplified model of pathways of hepatic purine catabolism in tumour-bearing mice. There occurred great differences of metabolic flux rates between control hepatocytes, hepatocytes of mice during the proliferating period of tumour growth (6th day after inoculation of the tumour) and hepatocytes of mice during the resting period of tumour growth (12th day after inoculation of the tumour). The final purine degradation of hepatocytes prepared during the proliferating period was lower in comparison with that of control hepatocytes, but it was markedly higher in hepatocytes prepared during the resting period of tumour growth. The changes in hepatocyte purine catabolism during the proliferating period of tumour growth argue for transitions which aim at the maintenance of high purine nucleotide levels in the liver itself rather than for an increased nucleoside and nucleobase supply for the tumour. This suggestion is in accordance with the increased ATP level of the liver during the proliferating phase of tumour growth.(ABSTRACT TRUNCATED AT 250 WORDS)

Reversed-phase high-performance liquid chromatography of purine compounds for investigation of biomedical problems: application to different tissues and body fluids

An overview of high-performance liquid chromatographic separation techniques (reversed-phase and ion-pair reversed-phase) used in the analysis of purine ribonucleotides, ribonucleosides and nucleobases, including procedures for sample preparation, is given. Coverage of the separation techniques is extended to the measurement of specific radioactivities of these compounds in tracer kinetic experiments for metabolic flux rate analyses. This article is focused on the development and adaptation of reversed-phase separation techniques for nucleotides, nucleosides and bases that are used to examine a variety of biomedical problems. The investigation of purine nucleotide metabolic disorders or physiological transitions in the pathomechanisms of different diseases and syndromes or in cell maturation processes, respectively, requires the application of chromatographic separation to a multitude of tissues and body fluids. These samples vary greatly in concentrations of purine compounds with low molecular mass, from ca. 5 mM to ca. 0.5 microM. The advantages and disadvantages of different techniques are critically discussed.

Reversed-phase and ion-pair separations of nucleotides, nucleosides and nucleobases: analysis of biological samples in health and disease

Methods for the assay of nucleotides, nucleosides and nucleobases in biological samples in health and disease are reviewed, with emphasis on reversed-phase and ion-pair reversed-phase techniques for their determination. Modes of extraction from biological samples are discussed with respect of the determination of in vivo concentrations. Advantages and limitations of ion-pair reversed-phase chromatography are discussed with examples from biochemistry and clinical chemistry. The capacity of the high-performance capillary electrophoresis is compared with that of ion-pair reversed-phase chromatography.

Regulation of deoxycytidine kinase activity and inhibition by DFDC

(1) Deoxycytidine kinase activity increased in a transformation- and progression-linked fashion in rat hepatomas of different proliferation rates. The activity also increased and was growth rate-linked in a series of tissue culture cell lines of human and animal tumors. (2) Deoxycytidine kinase activity was stringently linked with expression of the neoplastic proliferative program as it sharply increased in log phase in tissue culture cells of hepatoma 3924A and several human carcinoma strains. (3) Deoxycytidine kinase is subject to nutritional and hormonal regulation. On starvation the activity in liver decreased and on refeeding it returned to normal. Steroid hormone increased liver enzymic activity. Deoxycytidine kinase is substrate-inducible, since deoxycytidine injections in rat led to a 2- to 3-fold increase in hepatic enzyme activity. (4) Actinomycin or cycloheximide treatment blocked the increase in liver deoxycytidine kinase activity induced by steroid or deoxycytidine treatment. Therefore, it is assumed that the rise in deoxycytidine kinase activity requires new RNA and protein synthesis. (5) Cycloheximide treatment of rats carrying hepatomas yielded a t1/2 = 3.4 hr in the tumor for deoxycytidine kinase activity which was the shortest among the examined enzymes of purine and pyrimidine biosynthesis. (6) Actinomycin treatment of rats carrying hepatomas yielded a t1/2 of 5.8 hr for deoxycytidine kinase activity in the tumor which was one of the shortest in the examined enzymes of purine and pyrimidine biosynthesis. (7) Difluorodeoxycytidine (DFDC) is a competitive inhibitor (Ki = 7-28 microM) of deoxycytidine kinase from rat hepatoma and from human pancreatic carcinoma and ovarian carcinoma cells in culture.

Reciprocal alterations of GMP reductase and IMP dehydrogenase activities during differentiation in HL-60 leukemia cells

The study was undertaken to elucidate the regulatory roles of GMP reductase (GMPR) and IMP dehydrogenase (IMPDH) on purine interconversion during differentiation. Treatment of HL-60 cells with retinoic acid (1 microM) induced granulocytic differentiation which was accompanied with a 2.4-fold increase in GMPR and 55% decrease in IMPDH activities. Maturation induced by 12-O-tetradecanoylphorbol 13-acetate or dimethylsulfoxide was also associated with similar reciprocal alterations. Incubation with guanosine (200 microM), which expands the guanine nucleotide pool, elevated GMPR (1.9-fold) and decreased IMPDH (73%) activities. The synchronous and opposing alterations in GMPR and IMPDH activities should amplify the metabolic response due to differentiation or guanylate pool expansion.

Changes of nucleotide patterns in liver, muscle and blood during the growth of Ehrlich ascites cells: application of the reversed-phase and ion-pair reversed-phase high-performance liquid chromatography with radial compression column

The pool of purine compounds was analysed in liver, skeletal muscle and blood of mice during the growth of Ehrlich ascites tumour cells. Three fast isocratic high-performance liquid chromatographic methods were used. (1) Determination of nucleotides by an isocratic ion-pair reversed-phase chromatography with a 10 mM ammonium phosphate buffer containing acetonitrile and tetrabutylammonium phosphate. (2) Separation of nucleosides and nucleobases in cell extracts by a reversed-phase system with methanol and 50 mM potassium phosphate buffer as eluent. (3) Nucleosides and nucleobases in body fluids were analysed by a reversed-phase system with 10 mM potassium phosphate containing methanol. These methods allow the rapid determination of purine compounds in small biological samples from various cell types and body fluids, with high accuracy and sensitivity. The pool of cellular nucleotides increased during the exponential phase of tumour growth. Adenosine accumulated significantly in all tissues in the stationary phase of tumour growth.

Effects of deoxyadenosine on ribonucleotide reductase in adenosine deaminase-deficient lymphocytes

To explore the relationship between ribonucleotide reductase and immunodysfunction in adenosine deaminase deficiency, the effects of deoxyadenosine on ribonucleotide reductase in ADA-deficient lymphocytes was investigated. An assay system for ribonucleotide reductase in intact permeabilized lymphocytes was developed to approximate physiological conditions. The activity of cytidine diphosphate (CDP) reductase in resting but not in proliferating lymphocytes in culture was inhibited by 1 to 10 mumol/L deoxyadenosine. The resting cells were protected from the toxicity of 1 mumol/L deoxyadenosine by 5 mmol/L nicotinamide or 30 mumol/L deoxycytidine and from that of 10 mumol/L deoxyadenosine by 30 mumol/L deoxycytidine. These findings suggest that depletion of nicotinamide adenine dinucleotide might be the principal cause of death in resting lymphocytes with ADA deficiency. It is concluded that the mechanism of deoxyadenosine toxicity on non-replicating lymphocytes, which may not be mediated by ribonucleotide reductase inhibition, is closely related to the mechanism of immunodysfunction in patients with ADA deficiency.

Expression of key enzymes of purine and pyrimidine metabolism in a hepatocyte-derived cell line at different phases of the growth cycle

The effect of growth phase on enzymatic activities of the de novo and salvage pathways for purine and pyrimidine nucleotide synthesis was studied in a hepatocyte-derived cell line from the rat. The cells were in lag phase after plating for 36 h; log phase started at 48 h and persisted up to 120 h of culture. Then the cells stopped growing and entered into plateau phase (144 h). In non-proliferating cells (144 h of culture) the basal activities of the enzymes of purine de novo biosynthesis were 1.7- to 6.8-fold higher than in normal rat liver, those of pyrimidine de novo synthesis showed 0.6- to 30-fold increase in activity. The purine salvage enzymes were unchanged, and the pyrimidine salvage enzymes were 3.1- to 7.4-fold higher compared to normal liver. During the growth cycle all enzymes except the purine salvage enzymes, which did not change, showed a peak in activity at 72 h of culture (log phase). The increase in activity in log phase compared to plateau phase was 1.3- to 2.4-fold for purine de novo synthetic enzymes, 1.1- to 2.4-fold for pyrimidine de novo enzymes, and 1.4- to 4.7-fold for pyrimidine salvage enzymes. The specific activities of the enzymes in exponentially growing cells were comparable either to that in 24-h regenerating liver, or to that in hepatomas of low or medium growth rate. It was concluded that the enzymatic pattern and metabolic state of the cells shared some features with regenerating liver, others with tumors, although they were not tumorigenic after transplantation into athymic nude mice.

Glucose 6-phosphate plays a central role in the regulation of glycogen synthesis in a glycogen-storing liver cell line

Two substrains of the epithelial liver cell line C1I, one storing large amounts of glycogen, the other one being very poor in glycogen were used as a model for studying glycogen synthesis. The glycogen content of glycogen-rich cells doubled during the proliferative phase and remained high in plateau phase although glycogen synthase I activity was not significantly altered during growth cycle and was too low to account for the increase in glycogen. However, the activity of the glucose 6-phosphate (Glc6-P)-dependent synthase rose continuously during growth cycle, and intracellular Glc6-P-concentration increased about 10-fold in log phase cells to 0.72 mumol g-1 wet weight. A0.5 of synthase for Glc6-P was 0.79 mM. It was also found that in contrast to the enzyme from normal liver, glycogen phosphorylase a from C1I cells was inhibited by Glc6-P, the apparent Ki being 0.45 mM. It was concluded that glycogen accumulation in C1I cells was due to stimulation of synthase and inhibition of phosphorylase by Glc6-P. Findings from the glycogen-poor cell line which revealed similar specific activities of synthase and phosphorylase but only low Glc6-P (0.056 mumol g-1 wet weight) supported this conclusion. Addition of glucose to starved cells resulted in a transient activation of synthase in both cell lines. Net glycogen synthesis, was, however, only observed in the cells with a high Glc6-P-content. Thus, modulation of synthase and phosphorylase by Glc6-P and not activation/inactivation of the enzymes seems to play a predominant role in glycogen accumulation in this cell line.

Pyrimidine base degradation in cultured murine C-1300 neuroblastoma cells and in situ tumors

Dihydropyrimidine dehydrogenase (DPD), the initial, rate-limiting step in pyrimidine degradation, was studied in two cell lines of murine neuroblastoma (MNB-T1 and MNB-T2) that were derived from C-1300 MNB tumor carried in A/J mice. The MNB-T2 (low malignancy) cell line was originally derived from the in situ tumor and carried in tissue culture for more than 100 passages; the MNB-T1 (high malignancy) line consisted of a new sub-culture that was also established from the in situ MNB tumor. DPD activity was determined in cytosolic preparations of MNB utilizing high performance liquid chromatography to separate the radiolabeled substrate ([2-14C]thymine) from [2-14C]dihydrothymine. The apparent affinity of DPD for NADPH in MNB cells (Km approximately 0.08 mM) was identical to that of A/J mouse brain and liver. The DPD activity of the high malignancy (MNB-T1) cell line was 14.3% of that observed in the low malignancy (MNB-T2) line. In situ tumors formed after implantation of high malignancy (MNB-T1) cells into A/J mice had only 25.2% of the DPD activity observed in tumors derived from low malignancy (MNB-T2) cells. When MNB-T2 cells were injected into naive A/J mice, tumors developed in only 68% of animals, the tumor growth rate was slow and a mortality of 20% was observed. In contrast, tumors derived from injected MNB-T1 cells showed a faster growth rate and 100% mortality. Most MNB-T2 derived tumors were not lethal and ultimately resolved while the MNB-T1 derived tumors were invariably lethal. These studies support the concept that the levels of DPD activity in neoplastic cells are inversely related to their malignant expression and also provide a model to study differences between neuroblastoma cell lines derived from the same in situ tumor but which manifest different neoplastic behavior.

Enzyme-pattern-targeted chemotherapy with tiazofurin and allopurinol in human leukemia

The hypothesis was tested that the increased IMP dehydrogenase activity in human myelocytic leukemic cells, and along with it guanylate biosynthesis, might be a sensitive target to chemotherapy by tiazofurin. 1. IMP dehydrogenase activity in normal leukocytes was 3.1 +/- 0.5 (means +/- S.E.) nmol/hr/mg protein and in leukemic cells it was elevated 15- to 41-fold. The activity of guanine phosphoribosyltransferase in normal leukocytes was 389 +/- 27 nmol/hr/mg protein and in the leukemic cells it increased 2.8- to 6.8-fold. 2. IMP dehydrogenase was purified 4,900-fold to homogeneity from rat hepatoma 3924A with a yield of 30%. The kinetic properties of the hepatoma enzyme were similar to those of the enzyme in human myelocytic leukemic blast cells because of the similarity of the Km's for IMP (23 microM), NAD (44 and 65 microM); the Ki for TAD was 0.1 microM in both enzymes. 3. There was a selectivity of the in vitro response to tiazofurin in human normal and leukemic leukocytes. When labeled tiazofurin was incubated with leukocytes from normal, healthy volunteers and from leukemic patients, the leukemic leukocytes made 20- to 30-fold more TAD and the GTP content decreased as compared to normal leukocytes. This procedure proved to be a suitable predictive test in a clinical setting because patients with positive tests responded to tiazofurin whereas those with negative ones did not. 4. The National Cancer Institute approved a chemotherapeutic phase I/II trial which concentrates on treatment of refractory acute myelocytic leukemia. Tiazofurin is infused in a 60-minute period with a pump to insure uniform delivery. A novel aspect of the trial was that it was directed primarily by the biochemical impact of tiazofurin on IMP dehydrogenase activity and GTP concentration and the tiazofurin doses were to be adjusted accordingly. Patients received allopurinol as a routine precaution against possible accumulation of uric acid in the kidney. 5. In the first eight patients, there was one complete remission, two entered the chronic phase, two entered into partial remission, one did not respond, and two were not evaluable. In the five patients who responded, there was a rapid, profound decrease in IMP dehydrogenase activity of the blast cells and a gradual decline in GTP concentrations. The blast cell count followed the decrease in the GTP concentration. The white blood cell count was largely preserved. 6. Bone marrow aspirates and peripheral blood samples showed that with tiazofurin treatment there was an induced differentiation of the myelocytes.(ABSTRACT TRUNCATED AT 400 WORDS)

The modulation of serine metabolism in hepatoma 3924A during different phases of cellular proliferation in culture

The activities of 3-phosphoglycerate dehydrogenase and serine hydroxymethyltransferase increased markedly during the transition of hepatoma cells from a resting non-proliferating culture into the proliferating growth phase. Activities declined as cells reached confluency and entered the plateau growth phase. This pattern was paralleled by changes in [14C]serine incorporation into nucleic acids. The experiments support the hypothesis that the biosynthesis of serine is metabolically coupled to its utilization for nucleotide precursor formation in cancer cells.

Salvage pathways as targets of chemotherapy

This paper discussed the significance of the activities of purine and pyrimidine salvage enzymes in cancer cells and the targeting against them of chemotherapy. 1. The activities of salvage enzymes in the rat liver were orders of magnitude higher than those of the rate-limiting enzymes of de novo biosynthesis. A similar relationship was observed in rat hepatomas of different growth rates and in primary colon carcinoma in human. 2. The concentrations of nucleosides and nucleobases were measured in plasma, liver and hepatoma 3924A in the rat. The freeze-clamp method was required to determine the concentrations of these precursors in rat liver and hepatoma in a reliable and precise fashion because ischemia markedly altered the concentrations of nucleosides, nucleobases and, as shown earlier, nucleotides in these tissues. The results indicated that the liver markedly concentrated the purine precursors, hypoxanthine, guanine and adenine, but not thymidine, which was one-third that of the plasma. Uridine and deoxycytidine occurred in the same concentration as in plasma, but cytidine was 3-fold higher in liver. In the hepatoma in comparison to the liver the concentrations of the nucleosides and bases were altered and for some of the changes the enzymic differences between liver and hepatoma appeared to be accountable. 3. Kinetic parameters for purine and pyrimidine synthetic enzymes and for the substrates and co-factors were determined in liver and hepatoma 3924A. When enzymic activities were calculated at the tissue steady-state concentrations of the various ligands, the activities of the salvage enzymes were markedly higher than those of the rate-limiting enzymes. 4. Hepatoma cells were highly sensitive to the action of the transport inhibitor, dipyridamole, in lag and log phases. However, plateau phase cells lost their sensitivity to dipyridamole. 5. Amphotericin B rendered plateau phase cells sensitive to the inhibitory action of dipyridamole for the incorporation of thymidine. 6. Amphotericin B enhanced cytotoxicity of dipyridamole in hepatoma and human colon cancer HT-29 cells. 7. In these studies we discovered the decreased responsiveness to dipyridamole of plateau phase cells and the ability of amphotericin B to restore the sensitivity. Moreover, dipyridamole and amphotericin B were synergistic in their cytotoxic action in rat hepatoma cells and human colon cancer cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Could the loss of regulation of genetic expression in cancer cells be used to cause their necrosis?

In cancer cells the control over the genetic message involved in the induction of mitosis is irreversibly lost. This fact is indicated by certain phenomena displayed by cancer cells under restricted nutritional conditions. Cells transformed by DNA viruses (which stabilize "p53") keep on cycling and die. In starving cells at the inside of tumors the synthesis of pre-rRNA still proceeds while all other anabolic processes are already at a standstill. The reason is that glutamine, glycine and aspartate are channelled into the enzymatic pathways for the synthesis of nucleosides: thus, protein synthesis is denied those aminoacids. Such situations might be imitated through the administration of excess nucleosides and (within limits) the simultaneous restriction of some selected aminoacids. DNA replication depends on the stabilization of p53, but an accumulation of pre-rRNA might occur, which ultimately might be harmful for cancer cells. Several ways to improve this rationale might be tested on cultured cells and on research animals. They include the destruction of methionine with bacterial enzymes, or the addition of ornithine, a precursor of putrescine, which is an important factor of DNA and pre-rRNA synthesis.

Ribonucleotide reductase activity during the senescence of normal human diploid fibroblasts in culture

Changes in ribonucleotide reductase occur during the senescence of normal human diploid fibroblasts in culture. Enzyme activity is significantly lower in cells and extracts at high mean population doublings (MPD) as compared to fibroblasts at low MPD. Although many of the kinetic properties of the enzyme remain unaltered in cells at high MPD, changes in the extent and kinetic mechanism of inhibition of CDP and ADP reductase activity by dATP, the overall negative effector of ribonucleotide reductase, were observed. These results and a previous observation that the four deoxyribonucleotide pools are markedly altered during in vitro senescence of human diploid fibroblasts, provide evidence for a link between ribonucleotide reduction, deoxyribonucleotide pools, and the establishment of the non-proliferative or senescent state.

Biochemical mechanisms of resistance to tiazofurin

The purpose of this investigation was to examine factors which regulate the reprogramming of gene expression in tumors responsible for resistance to tiazofurin. To study the resistance phenomenon drug-induced tumor lines were selected and examined for the mechanism of resistance. A comparison of the biochemical expression of resistance to tiazofurin in drug-induced resistant lines of hepatoma 3924A, leukemias L1210 and P388 revealed that the 3 lines expressed similar genetic alterations related to reduced TAD content, decreased NAD pyrophosphorylase activity and increased synthesis of guanylates from salvaging preformed guanine indicating that these 3 factors play an important role in the resistance to tiazofurin. Resistance was stable in the leukemia lines and did not require drug to maintain resistance. Hepatoma 3924A resistant line reverted to sensitive state in the absence of drug selection pressure. NAD pyrophosphorylase activity was substantially deleted in the tiazofurin resistant leukemia lines, but was only significantly decreased in the hepatoma resistant line. Extensive biochemical alterations including enhanced activity of IMP dehydrogenase, increased inosinate and guanylate pools, and reduced uptake of tiazofurin were found in the hepatoma line resistant to tiazofurin. To examine the applicability of these results to naturally sensitive and spontaneously resistant tumors, murine tumors were examined. In murine tumors, TAD accumulation, ratios of enzyme activities responsible for the synthesis and degradation of TAD, and the ratios of perturbation of inosinate and guanylate pools following tiazofurin challenge demonstrated significant correlation with the sensitive or resistant nature of the tumors. To extrapolate these observations to human tumor systems, cytotoxicity of tiazofurin and its metabolic effects were compared in 6 human lung cancer cell lines derived from cancer patients with small cell lung cancer (4 lines) and lung adenocarcinoma (2 lines). Cell lines exhibiting greater sensitivity to tiazofurin accumulated significantly larger amounts of TAD and showed significant reduction of guanylate pools following tiazofurin incubation. The activity of the enzyme responsible for the formation of TAD, NAD pyrophosphorylase, did not correlate with responsiveness to tiazofurin but the enzyme which hydrolyzes TAD, TADase, correlated positively with the status of resistance.(ABSTRACT TRUNCATED AT 400 WORDS)

Potentiation of antimetabolite action by dibromodulcitol in cell culture

The postulation that the activity of key enzymes that reveal marked increases should be potential targets for anticancer chemotherapy (47) was supported by new evidence on the alterations of CDP reductase, CTP synthetase and OMP decarboxylase in hepatoma 3924A cell cultures. Inhibitors of these enzymes (VF-122, acivicin, pyrazofurin) and that of IMP dehydrogenase (tiazofurin) efficiently killed hepatoma 3924A cells in culture, as demonstrated by the clonogenic assay. Acivicin, pyrazofurin, tiazofurin and VF-122 were lethal against tumor cells in the exponential phase of growth with IC50 of 1.5, 5, 10 and 4.5 microM, respectively. All these antimetabolites exhibited cytotoxicity preponderantly against exponential-phase cultures, indicating that all the four drugs belong to Class II (phase-specific agents) in the Kinetic Classification of Anticancer Agents (38). Dibromodulcitol, a bifunctional alkylating agent, revealed cycle-specific cytotoxicity (Class III agent) against hepatoma 3924A, yielding IC50 values of 2.3 and 5.5 microM for exponentially and stationary growing cells, respectively. Using isobologram analysis on the survival data of 3924A cells, synergistic interaction was observed when DBD in combination with acivicin, pyrazofurin and tiazofurin was examined. DBD in combination with VF-122 exhibited additive lethality against hepatoma cells in culture. The synergistic and additive cytotoxicity in combinations of DBD with these antimetabolites was accompanied by the concurrent depletion of ribonucleotide and/or deoxyribonucleotide pools. The synergistic biological results of drug combinations of acivicin with DBD can be accounted for by the action of acivicin in inhibiting CTP synthetase, resulting in a synergistic decrease in CTP content, and by inhibition of DNA synthesis caused by DBD. The synergistic and additive depletion of UTP, CTP, dTTP and dCTP pools in the combinations of DBD with pyrazofurin may be responsible for the synergistic lethality of these combinations. Synergism, in terms of pool depletion, was observed for GTP and dCTP; summation was detected for dGTP when DBD and tiazofurin were given concurrently. The synergistic cytotoxicity of this drug combination may be a consequence of these alterations. The additive lethality of DBD-VF-122 drug combinations was reflected in the additive elevations of the ribonucleoside diphosphate concentrations. These observations indicate that treatments based on the Kinetic Classification and on the biochemical targeting of the drug should have an impact on the design of in vivo chemotherapy.

Targets and markers of selective action of tiazofurin

The molecular correlation concept proposed that IMP dehydrogenase activity should be a sensitive target of chemotherapy. This hypothesis received support from an array of evidence. IMP dehydrogenase has the lowest activity in purine biosynthesis; it is the rate-limiting enzyme in GTP production; the enzymic activity is transformation-and progression-linked; it is elevated in all examined animal and human neoplastic cells. The activity of GMP synthetase and the concentrations of GMP and dGTP were increased in cancer cells. Whereas guanine salvage has a high potential activity, the low guanine content may well curtail actual salvage capacity. Ribonucleotide reductase activity was two orders of magnitude lower than that of IMP dehydrogenase. Tiazofurin, a C-nucleoside, had marked cytotoxicity on hepatoma cells in vitro and was the first drug that as a single agent profoundly inhibited the proliferation of the subcutaneously inoculated solid hepatoma 3924A in the rat. The impact of tiazofurin administration in hepatoma cells was revealed in a cascade of biochemical alterations involving primary, secondary and tertiary targets and markers of this drug action. The primary target was IMP dehydrogenase where the active metabolite of tiazofurin, TAD, was thought to be absorbed to the NADH site of the enzyme. As a consequence, the enzymic activity declined rapidly to about 30-40% and returned to normal range by 36 to 48 hr after injection. The secondary targets and markers are the profoundly decreased pools of guanylates (GMP, GDP, GTP). Concurrently, the concentrations of IMP and PRPP were increased 8- to 15-fold. The elevated IMP pools were attributed to the de-inhibition of the AMP deaminase activity subsequent to the decline in GTP concentration. The rise in PRPP pools was attributed to the selective inhibition of GPRT and HPRT activities by the high IMP pool which did not affect APRT activity. This interpretation is supported by the 6- to 8-fold increase in the concentrations of guanine and hypoxanthine and the lack of change in the adenine pools inthe hepatomas after tiazofurin administration. The marked drop in NAD concentration which was drug dose- and time-dependent is attributed to the competition for NAD pyrophosphorylase activity by the precursors of NAD and tiazofurin monophosphate. The tertiary targets were dominated by the profound alterations in the concentrations of the dNTPs. This was characterized by a rapid and persistent drop (for 3 days) of the dGTP pool. The concentrations of dATP and dCTP also declined, but these alterations were less pronounced and the pools returned to normal after 2 days.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of purine and pyrimidine metabolism by insulin and by resistance to tiazofurin

The purpose of this investigation was to elucidate the factors that regulate the pattern of gene expression in purine and pyrimidine metabolism in normal liver and hepatoma. For this purpose, the action of a hormone, insulin, and the development of resistance to a chemotherapeutic agent, tiazofurin, were studied. This investigation brought detailed evidence showing that in the rat insulin exerted a profound effect on liver purine and pyrimidine metabolism by regulating the concentrations of nucleotides through controlling the activities of strategic enzymes involved in their biosynthesis. When rats were made diabetic by alloxan treatment, in the average liver cell concentrations of ATP, GTP, UTP and CTP decreased to 66, 62, 54 and 63%, respectively, of those of normal liver. Administration of insulin for 2 days returned the hepatic nucleotide concentrations to normal range; further insulin treatment for an additional 5 days raised the concentrations of ATP, GTP, UTP and CTP to 197, 352, 412 and 792% of values observed in the liver of diabetic rats. In diabetic rats the hepatic activities of OMP decarboxylase, orotate phosphoribosyltransferase, uridine phosphorylase, uridine-cytidine kinase and uracil phosphoribosyltransferase decreased to 44, 48, 70, 36 and 41% of the activities of normal liver. Insulin treatment for 2 days returned activities to normal range. Continued insulin treatment for an additional 5 days increased the enzymic activities to 3.9- to 5.3-fold of those of the liver of the diabetic rats. The regulation by insulin treatment of the activities of enzymes of de novo and salvage synthesis of UMP should explain, in part at least, the decline and increase of the uridylate pool in diabetes and after insulin treatment. In the diabetic rat hepatic CTP synthetase, the rate-limiting enzyme of CTP biosynthesis, decreased to 53% and insulin administration for 2 days restored activity to normal range. Insulin treatment for an additional 5 days increased the synthetase activity to 4-fold of the values of the diabetic liver. Thus, the behavior of liver CTP synthetase activity is tightly linked with that of the CTP pool. In the diabetic rat liver, the activity of IMP dehydrogenase, the rate-limiting enzyme of GTP biosynthesis, decreased to 24% of that of the normal liver. Insulin administration for 2 days returned the activity to normal range, yielding a 4.5-fold increase in the activity from the diabetic to the insulin-treated state.(ABSTRACT TRUNCATED AT 400 WORDS)

Human diploid fibroblasts with alterations in ribonucleotide reductase activity, deoxyribonucleotide pools and in vitro lifespan

Three drug resistant human diploid fibroblast clones were isolated which contained elevated levels of ribonucleotide reductase activity when compared to wild type fibroblasts. The drug resistant cells do not appear to possess an enzyme with altered affinity for hydroxyurea. The increase in enzyme activity can entirely account for cellular drug resistance. In keeping with the observed changes in reductase activity in drug resistant fibroblasts, deoxyribonucleotide pools were also found to be altered. Most significantly, there was a 1.8-fold expansion of the dCTP pool size, suggesting that elevation in intracellular dCTP concentrations plays an important role in cellular resistance. Furthermore, the drug resistant fibroblasts exhibited substantial reductions in their replicative abilities, suggesting that the regulation of ribonucleotide reductase and the accompanying deoxyribonucleotide pools in human diploid cells is involved in aspects of cellular senescence.

Involvement of ribonucleotide reductase in cellular differentiation

L6 and L8 rat myoblast cell lines have been selected for resistance to hydroxyurea, an antineoplastic agent whose intracellular target is the rate-limiting enzyme activity of DNA synthesis, ribonucleotide reductase. In contrast to the differentiation-competent parental lines from which they were selected, the drug-resistant lines exhibit a grossly altered or absent myogenic capacity. Independent selections have revealed a strong correlation between changes in ribonucleotide reductase, as determined by velocity levels and product pool analyses, and altered myogenic potential. These results provide the first indication that alterations in this key enzyme activity and its accompanying deoxyribonucleoside triphosphate pools can affect cellular differentiation.

Control of enzymic programs and nucleotide pattern in cancer cells by acivicin and tiazofurin

The mechanism of action of acivicin and tiazofurin was compared in hepatoma 3924A. The results were evaluated by assessing the impact of these drugs on primary targets, the activities of key enzymes, and on secondary and tertiary targets, the concentrations of pools of ribonucleotides and deoxyribonucleotides. The action of acivicin entails inhibition and inactivation of the key enzymes of glutamine utilization in the biosynthesis of purines and pyrimidines. As a result, the GTP and CTP pools were markedly depleted, whereas those of ATP and UTP were unaffected. Acivicin also markedly decreased the concentrations of all 4 deoxynucleoside triphosphates. The nucleotide pools returned to normal or near normal range within 2 to 3 days after a single acivicin injection. The pharmacologic targets of acivicin in anticancer chemotherapy include prominently the activities of glutamine-utilizing enzymes and the pools of GTP and CTP and all 4 dNTP's. These biochemical targets also serve as indicators of acivicin action in cancer cells. The action of tiazofurin in hepatoma cells entails the primary target, IMP dehydrogenase. The subsequent effects include marked enlargement of IMP and PRPP pools and depletion of the pools of GDP and GTP. The increased IMP concentration selectively inhibited the activities of hypoxanthine-guanine phosphoribosyltransferase, but did not affect that of adenine phosphoribosyltransferase. The markedly decreased GTP pool de-inhibited the activity of AMP deaminase which permitted the channeling of AMP to IMP. An important indicator of tiazofurin action is the prolonged depletion of dGTP pools and similar but less pronounced declines in the pools of dCTP and dATP. In contrast, dTTP pools were increased. The crucial biochemical targets and indicators of tiazofurin action in sensitive cancer cells include inhibition of IMP dehydrogenase, a decrease in the concentrations of GDP, GTP, dGTP, dCTP, dATP and marked rise in the pools of IMP, PRPP and dTTP. Measurements of the molecular targets and indicators of drug action should be helpful in identifying cancer cells and tissues sensitive or resistant to the action of acivicin or tiazofurin. Identification of the targets and indicators should also be helpful in the design of frequency of administration of the drugs in combatting animal and human neoplasia.

Effects of biochemical modulation of drug combinations directed at the ribonucleotide reductase site on leukemia L1210 cell growth in culture

Ribonucleotide reductase from tumor cells consists of two non-identical components which can be specifically and independently inhibited. Combinations of agents directed at the individual components gave synergistic inhibition of L1210 cell growth in culture. Utilizing hydroxyurea and deoxyadenosine or IMPY and deoxyadenosine as the parent combinations, modulators were used to potentiate the effects of each of these drugs. EHNA was used to prevent the deamination of deoxyadenosine while Desferal was utilized to increase the effects of hydroxyurea and IMPY. Combinations consisting of deoxyadenosine/EHNA plus IMPY/Desferal and deoxyadenosine/EHNA plus hydroxyurea/Desferal gave synergistic inhibition of L1210 cell growth. Utilizing these combination chemotherapies, the concentrations of each of the agents could be kept to minimal, essentially non-inhibitory levels and yet still achieve complete inhibition of L1210 cell growth with the specifically generated four-drug combinations.

Salvage capacity of hepatoma 3924A and action of dipyridamole

The role and behavior of the salvage enzymes in the biosynthesis of purines (adenine and hypoxanthine-guanine phosphoribosyltransferases) and pyrimidines (uridine-cytidine, deoxycytidine and thymidine kinases) were elucidated. In liver purine metabolism the transferase activities were orders of magnitude higher than the activities of the enzymes of de novo biosynthesis. In both purine and pyrimidine biosynthesis the activities of the enzymes of the de novo pathways were low (23 pmol to 70 nmol/hr/mg protein), whereas those of salvage synthetic pathways ranged from 0.8 to 1,470 nmol/hr/mg protein. In purine metabolism the salvage enzymes had markedly higher affinity to the shared substrate PRPP (4 to 40 microM) than the rate-limiting enzyme of de novo synthesis, amidophosphoribosyltransferase (900 microM). In rapidly growing hepatoma 3924A the activities of the enzymes of de novo purine biosynthesis increased, whereas those of the salvage pathway changed little. However, the activities of the enzymes of the salvage pathways remained much higher than those of the enzymes of de novo purine production. In pyrimidine production in the hepatomas the activities of both de novo and salvage enzymes markedly increased. However, the activities of the salvage enzymes far outstripped those of the enzymes of the de novo pathways. To inhibit the operation of the salvage pathways, the action of the transport inhibitor, dipyridamole, was examined. In tissue culture, dipyridamole inhibited the transport of purine and pyrimidine nucleosides with an IC50 of 10(-6) or 10(-7) M. As measured by colony-forming assay, dipyridamole killed hepatoma cells with an IC50 of 20 microM. Dipyridamole markedly depressed the pools of ATP, GTP, CTP and UTP; in combination chemotherapy with acivicin, an anti-glutamine agent, synergistic action was observed on the pools of nucleotides in hepatoma 3924A in vivo. These investigations emphasize the importance of the capacity to utilize precursors by the salvage enzymes and may explain, in part at least, the failure of inhibitors of the de novo pathways to yield lasting chemotherapeutic results. Combination chemotherapy of inhibitors of the de novo pathways with an inhibitor of the salvage pathways (dipyridamole) should impact on our understanding of the contribution of salvage pathways and provide a rational basis for successful combination chemotherapy of neoplastic diseases.

Multi-enzyme-targeted chemotherapy by acivicin and actinomycin

On the basis of our observation of the increased specific activities of glutamine-utilizing enzymes in purine and pyrimidine metabolism in hepatoma 3924A, and because the concentration of glutamine is ten times lower in the hepatomas than in the liver, the biochemical pharmacology of the anti-glutamine agent, acivicin, was examined. (1) Acivicin competitively inhibited the activities of amidophosphoribosyl-transferase, CTP synthetase and carbamoyl-phosphate synthetase II from extracts of liver and hepatoma 3924A. (2) In addition to the competitive inhibition exerted by acivicin, evidence was obtained that this drug also irreversibly inactivated in vitro the glutamine-utilizing enzymes. It is particularly relevant for the selectivity of acivicin that the activity of aspartate carbamoyltransferase, an enzyme present in the same complex as carbamoyl-phosphate synthetase II, was not affected by the anti-glutamine agent. (3) Acivicin in vivo brought down the activities of glutamine-utilizing enzymes in a period of 10 min to 1 hr after injection. CTP synthetase activity declined to less than 10% of that observed in the uninjected rats. The decreases were not reversible by various in vitro methods, but in vivo the activities returned to normal range in 72 hr. (4) The activity of aspartate carbamoyltransferase, which exists as a multi-enzyme complex with synthetase II, was not altered by acivicin injection. Similar results were observed in transplantable sarcoma in the rat. (5) The acivicin-induced decrease in enzymic activities could not be restored by purification of the enzymes. (6) In vitro studies indicated that addition of acivicin to liver or hepatoma extracts or purified enzymes rapidly decreased enzymic activities; the activities could not be restored. These results are consistent with an interpretation that acivicin acts either as a tight-binding inhibitor or as an inactivator through alkylation of the enzymes of glutamine utilization. (7) Acivicin in combination with actinomycin provided a synergistic kill of hepatoma cells in tissue culture and also inhibited the growth of transplantable solid hepatoma 3924A in the rat. (8) The synergistic biological results of combination chemotherapy with acivicin and actinomycin can be accounted for by the action of acivicin in inhibiting GMP and CTP synthetases, resulting in a decrease in GTP and CTP content, and by the actinomycin-caused inhibition of RNA polymerase in selectively blocking the utilization of GTP and CTP.