Selective inhibition of thymidine transport at low doses of the alkylating agents triethyleneiminobenzoquinone (Trenimon)

Cytotoxic and cytostatic effects of antitumor agents induced at the plasma membrane level

A variety of antitumor agents inhibit cell proliferation by interacting with the plasma membrane. They act as growth factor antagonists, growth factor receptor blockers, interfere with mitogenic signal transduction or exert direct cytotoxic effects. The P-glycoprotein encoded by the MDR1 gene represents a transmembrane protein which catalyzes the efflux of various antitumor agents. This membrane protein is the target of compounds acting as Multi-Drug Resistance (MDR)-modulators. Finally, several established antitumor agents which are considered to represent DNA-targeted drugs, including anthracyclines, platinum complexes and alkylating agents, cause a variety of membrane lesions. Their contribution to the antitumor activity of these drugs is discussed.

Enhanced levels of cyclic AMP, adenosine(5')tetraphospho(5')adenosine and nucleoside 5'-triphosphates in mouse leukemia P388/D1 after treatment with cis-diamminedichloroplatinum(II)

As part of the exploration of the mechanism of platinum(II) complex-induced growth inhibition and/or cytotoxicity, we studied the intracellular levels of several nucleotides during treatment of mouse leukemia P388/D1 at selected concentrations of 1 microM cis-diamminedichloroplatinum(II) (cis-DDP) and 20 microM of its trans-isomer (trans-DDP). The effects and their time-dependences are correlated with those on cell growth parameters previously published (Just G and Holler E, Cancer Res 49: 7072-7078, 1989). The effects of cis-DDP are strong and irreversible, whereas those of trans-DDP are marginal and reversible, in parallel with similar effects on cell growth parameters. Concentrations of nucleoside 5'-di- and 5'-triphosphates increase in parallel with cellular DNA and protein content by three- to four-fold after 60 hr of treatment. The nucleoside monophosphates dAMP, dGMP and dTMP reveal concentration maxima during exponential cell growth that are two- to six-fold higher than in the control cultures. Levels of cyclic AMP, adenosine(5')tetraphospho(5')adenosine (Ap4A) and CDP rise three- to five-fold above those in the control cultures within a few hours of the start of treatment. The level of coenzyme NAD+ falls below that of the control, concomitantly with an arrest of cells in the G2 phase of the cell cycle and with the appearance of giant cells. Due to the high reactivity of cis-DDP and the continuous concentration increase during the treatment, purine nucleoside 5'-triphosphates provide a possibility for the acquisition of resistance to cis-DDP. The correlation of responses of metabolically and regulatory active nucleotides with biological effects suggests their function in antitumorigenesis.

Replication-linked histone acetylation in rat liver tissue is sensitive to alkylating agents

The effect of alkylating agents on histone acetyltransferase (EC 2.3.1.48) activity and thymidine incorporation was investigated in benign and malignant proliferating rat liver tissue and compared with the effect in normal non-proliferating rat liver tissue. In both, benign and malignant proliferating tissue, but not in quiescent tissue, the histone acetylation is depressed by alkylating agents and this depression correlates with the inhibition of the thymidine incorporation. This effect suggests that the depression of the replication associated histone acetylation may be an important factor for the antiproliferative activity of alkylating agents.

Synergistic enhancement of the antiproliferative activity of cis-diamminedichloroplatinum(II) by the ether lipid analogue BM41440, an inhibitor of protein kinase C

The new phospholipid analogue 3-hexadecylmercapto-2-methoxy-methyl-propyl-1-phosphocholine inhibits the phospholipid-calcium-dependent protein kinase, partially purified from Walker carcinoma cells with a Ki value of 0.56 microM. The compound inhibits the phorbol ester stimulated phosphorylation of the ribosomal protein S6 indicating that the depression of Ca2+-phospholipid-dependent protein kinase by the alkyl phospholipid also occurs in intact cells. The dose effect curve for the inhibition of cell proliferation by 3-hexadecylmercapto-2-methoxy-methyl-propyl-1-phosphocholine in Walker cells exhibits a close correlation to the dose effect curve for the depression of Ca2+-phospholipid-dependent protein kinase activity. Although alternative mechanisms cannot be excluded, the data suggest that the growth inhibitory activity of 3-hexadecylmercapto-2-methoxy-methyl-propyl-1-phosphocholine correlates with the inhibition of Ca2+-phospholipid-dependent protein kinase. The antiproliferative activity of 3-hexadecylmercapto-2-methoxy-methyl-propyl-1-phosphocholine is synergistically enhanced by cis-diamminedichloroplatinum(II).

The phospholipid- and calcium-dependent protein kinase as a target in tumor chemotherapy

Evidence for a constitutive activation of protein kinase C (EC 2.7.1.37) in Ha-ras transformed 3T3 cells is presented. Several compounds which inhibit protein kinase C in vitro have been studied with regard to their antiproliferative activity in cultured tumor cells. The following agents were investigated: 3-hexadecyl-mercapto-2-methoxy-methyl-propyl-1- phosphocholine (BM 41440); 1-octadecyl-2-methyl-sn-glycero-3-phosphocholine (ET-18-OCH3); quercetin, tamoxifen and staurosporine. All compounds decrease protein kinase C activity in vitro as well as in intact cells and inhibit cell multiplication within the same dose range. The results suggest a causal relation between the antiproliferative effects and the inhibition of protein kinase C. All inhibitors of protein kinase C synergistically enhance the antiproliferative activity of cis-diamminedichloroplatinum(II). Available data suggest that the effects of protein kinase C inhibitors should be exploitable for tumor chemotherapy.

Differential sensitivity of histone acetylation in nitrogen-mustard sensitive and resistant cells. Relation to drug uptake, formation and repair of DNA-interstrand cross-links

Cultivation of Ehrlich-ascites tumor cells in the presence of N-mustard leads to a selection of cells with a defective choline carrier. As N-mustard employs the choline carrier for transport, this results in reduced drug uptake and in a decrease in drug sensitivity which is specific for N-mustard. Walker carcinoma cells with a stable pleiotropic resistance to a variety of alkylating agents and adriamycin exhibit no evidence for an impaired drug transport and show the same frequency of DNA-interstrand cross-links as the sensitive parental line. Both sensitive and resistant Walker cells exhibit equal capacities for repair of N-mustard induced DNA-interstrand cross-links. The inhibition of histone acetylation by N-mustard, however, was found to be significantly lower in the resistant Walker or Ehrlich cells compared to sensitive counterparts. Although the difference between N-mustard concentrations leading to half maximal inhibition of histone acetylation in sensitive and resistant cells is considerably smaller than the difference between N-mustard doses required for half maximal inhibition of cell proliferation the data suggest that--besides DNA-DNA cross-linking--the inhibition of histone acetylation has to be considered as an important alternative mechanism responsible for the cytotoxic activity of alkylating agents. Inhibition of histone acetylation is not due an accelerated deacetylation and is predominantly expressed in chromatin fractions soluble in 0.1 M NaCl after digestion with micrococcal nuclease.

Growth inhibitory activity of atrial natriuretic factor in rat glomerular mesangial cells

Atrial natriuretic factor (ANF) binding sites, or ANF-induced cGMP accumulation, have been shown in numerous tissues that may not be intimately involved in volume homeostasis. In a series of experiments, we found that quiescent rat glomerular mesangial cells in culture could be reactivated to enter the cell cycle, and that ANF had potent inhibitory effects on proliferation of these cells. [3H]Thymidine incorporation increased by fivefold in reactivated compared to quiescent cells, and ANF in physiologic concentrations inhibited this incorporation by 48%. Thus, ANF appears to be a multifunctional peptide, consistent with a number of peptide growth factors.

Enhancement of the antiproliferative effect of cis-diamminedichloroplatinum(II) and nitrogen mustard by inhibitors of protein kinase C

Quercetin (3,3',4',5,7-pentahydroxyflavone) has been shown to inhibit a variety of enzymes including the calcium- and phospholipid-dependent protein kinase (protein kinase C) in vivo and in vitro. We show that this compound synergistically enhances the antiproliferative activity of cis-diamminedichloroplatinum(II) (cis-DDP) and nitrogen mustard. Quercetin does not affect the repair of DNA interstrand cross-links introduced by cis-DDP. Long-term exposure to 12-O-tetradecanoylphorbol-13-acetate (TPA), which reduces total protein kinase C activity, also amplifies the growth-inhibitory effect of cis-DDP and acts synergistically with quercetin. A synergism is also observed if tamoxifen or staurosporine are combined with cis-DDP. For both drugs the dose-effect curves for the inhibition of protein kinase C closely resemble the dose-effect curves for the antiproliferative activities. Although alternative mechanisms cannot be definitively excluded, the effects of quercetin, TPA, tamoxifen and staurosporine may result from the inhibition of protein kinase C.

Cytotoxicities of a linoleic acid hydroperoxide and its related aliphatic aldehydes toward cultured human umbilical vein endothelial cells

An assay method for the quantification of the cytotoxicities of various agents toward cultured human endothelial cells was developed using Earle's solution as an incubation medium. By this method, the cytotoxicities of a linoleic acid hydroperoxide (LOOH) and its related aliphatic aldehydes toward human umbilical vein endothelial cells were investigated. Saturated aldehydes, pentanal, hexanal and 9-oxononanoic acid, are nontoxic; alpha, beta-unsaturated aldehydes, 2-hexenal, 2-heptenal, 2-octenal and 2-nonenal, are toxic only at high concentrations; LOOH and alpha, beta-unsaturated aldehydes with a hydroxy group or an additional double bond, 4-hydroxy-2-nonenal, 2,4-nonadienal and 2,4-decadienal, are highly toxic. In particular, 2,4-decadienal, whose 50% lethal concentration is 9 microM, is the most injurious. The cytotoxicities of LOOH and its related aldehydes were found to be much reduced in growth medium containing serum, growth factors, heparin, amino acids and vitamins.

Events in degenerating cat peripheral nerve: induction of Schwann cell S phase and its relation to nerve fibre degeneration

Severance of a peripheral nerve leads to a characteristic series of events in the distal stump, including the dissolution of axons and myelin and the proliferation of Schwann cells within their basal lamina. This study examines the relationship between the spatial-temporal pattern of the induction of the Schwann cell S phase, loss of the structural and functional properties of axolemma, and the clearance of myelin debris in the cat tibial nerve. Nerve transection stimulated a monophasic increase in [3H]thymidine incorporation that peaked at 4 days post-transection throughout an 80-mm length of distal stump. Light microscope autoradiography revealed prominent incorporation into Schwann cells of myelinated fibres. Treatment of distal stumps with mitomycin C at the time of nerve transection greatly retarded thymidine incorporation and clearance of myelin debris, but not the time course of axonal degeneration, decline in the synthesis of the major myelin glycoprotein, P0, or the onset of ovoid formation. Nerve transection also greatly reduced the specific uptake of [3H]saxitoxin (STX), a ligand which binds to voltage-sensitive sodium channels. Binding in the distal stump fell precipitously to 20% of the normal at 4 days post-transection, concurrent with the peak of thymidine incorporation. This low level of binding was maintained for periods of up to 70 days, demonstrating that some STX binds to structures other than axons in denervated distal stumps. Prior treatment with mitomycin C delayed the loss of specific STX binding. In conclusion, these studies suggest that: Schwann cell DNA replication and/or mitosis regulates other events during Wallerian degeneration, including myelin degeneration, catabolism of P0 and the clearance of sodium channels from nodal axolemma; the decline in P0 synthesis and/or shift to synthesis of less extensively processed P0 is independent of the induction of Schwann cell S phase; and Schwann cells enveloping myelinated axons enter S phase within a 24-h period throughout the entire 80-mm length of distal stump.

Effects of the lipidperoxidation product 4-hydroxynonenal and related aldehydes on proliferation and viability of cultured Ehrlich ascites tumor cells

The mechanism by which the lipid peroxidation product 4-hydroxynonenal and several other homologous, yet non biogenic aldehydes inhibit proliferation of cultured Ehrlich ascites tumor cells has been studied. Incubation of cells (5 X 10(-4)/ml) in a minimum essential medium supplemented with 10 or 20 microM 4-hydroxynonenal reduces the 36-hr cell count to 65 and 30% of the control value. The reduced growth rate is most likely due to a blockage of the DNA synthesis. Cells labelled by a [3H]-thymidine pulse prior to exposure to 4-hydroxynonenal (20 microM, 8 hr) showed no change of the specific radioactivity of the DNA, indicating that no de novo synthesis occurred in the presence of the aldehyde. In the absence of the aldehyde the specific radioactivity of the DNA decreased by 25%. A 2-hr incubation in the presence of 10 or 20 microM of 4-hydroxynonenal reduced [3H]-thymidine incorporation into the HClO4 insoluble fraction to 85 and 50% of the controls, but had no effect of the [3H]-thymidine and 86Rb uptake. Moreover, examination of the cell cultures by the Trypan Blue exclusion technique revealed that 20 microM 4-hydroxynonenal does not cause cell death. The high reactivity of 4-hydroxynonenal towards sulfhydryl groups suggests that the aldehyde inhibits DNA synthesis by interacting with a functional SH group of DNA polymerase. The specific action on DNA synthesis is abolished at an aldehyde concentration of 50 microM, which leads to 30% (6 hr exposure) and 95% (36 hr exposure) of dead cells. The cytostatic index (CI), i.e. concentration at 50% Trypan Blue positive cells/concentration at 50% inhibition of cell growth deducted from the dose effect curves is 3.0 for 4-hydroxynonenal. The other homologous 4-hydroxyalkenals with chain length of 5, 6, 7, 8, 10 and 11 carbon atoms also inhibit cell growth. The CI varied from 1.20 to 1.94, indicating that these non biogenic 4-hydroxyalkenals have a distinctively lower specific effect on proliferation than the biogenic 4-hydroxynonenal. The Michael adducts of 4-hydroxynonenal with glutathione and cysteine were nearly one order of magnitude less toxic than the free aldehyde, the CI (2.41 cysteine adduct, 2.06 glutathione adduct), however, were not improved since the growth inhibitory action was also reduced.

In vitro and in vivo investigations for the development of cytostatic methylhydrazones

In in vitro short-term (3 h) assays, the beta-chloroethyl-methyl-hydrazones B 1 and B 2 inhibit the uptake of 3H-thymidine by EAC and L 1210 leukemia cells, B 2 being 5 to 10 times more effective than B 1. The growth inhibitory effect of both compounds was also confirmed in long-term (7 days) clonal assays using agar-containing glass capillaries, B 2 again being more effective than B 1. In contrast to these differences in vitro, in vivo both substances showed remission to the same degree in EAC- and complete resistance in L 1210-bearing mice. The diverging in vitro/in vivo sensitivities were thought to result from differences in the affinity of the methylhydrazones to the tumor cells: using short exposure periods (3 h) B 1 was more inhibitory than B 2 on both EAC and L 1210 colony growth; i.e., the more hydrophilic B 2 could more easily be washed off. To further test the idea of different cell membrane affinities, the methylhydrazones ZB 1 and P 1 with increasing lipophilic properties were synthesized. In vitro, after both pulse and continuous exposure ZB 1 and P 1 showed enforced inhibitory effects on colony growth. In vivo, ZB 1 and P 1 reduced the tumor weight of EAC mice, while only P 1 increased the survival time of L 1210 mice. The results suggest that from the combination of in vitro/in vivo assays mechanistic conclusions can be derived that are valuable for further development of these cystostatics.

Nitrogen mustard interference with potassium transport systems in Ehrlich ascites tumor cells

Nitrogen mustard (N-mustard) inhibits the ouabain-sensitive and the furosemide-sensitive Rb uptake of Ehrlich ascites tumor cells, whereas the transport, which is resistant to both inhibitors, is not affected by the alkylating agent. At N-mustard concentrations below 10 microM, the reduction in Rb uptake is predominantly due to an interference with the furosemide-sensitive system. The dose response curve for the inhibition by N-mustard of the furosemide-sensitive Rb uptake closely parallels the dose response curve for the anti-tumor activity of the alkylating drug. This is in contrast to the behaviour of the ouabain-sensitive Rb transport. The inhibition of the furosemide-sensitive Rb uptake is expressed much less in cells which are resistant to N-mustard. The recovery of the furosemide-sensitive transport system after a single exposure to N-mustard is relatively slow and characterized by an initial 4 h lag period, whereas the repair of DNA-interstrand cross-links starts immediately after removal of the drug. At mM concentrations furosemide blocks the multiplication of Ehrlich ascites tumor cells. However, lower concentrations of furosemide which cause a 50% reduction in the furosemide-sensitive Rb uptake do not interfere with cell proliferation. This is in contrast to the behaviour of N-mustard which exerts a clear-cut depression of cell growth at concentrations leading to a 50% inhibition of the furosemide-sensitive Rb transport. It is concluded, therefore, that the inhibition of the furosemide-sensitive system alone is not sufficient to explain the anti-tumor activity of the alkylating agent. The effect is discussed as part of a more extended N-mustard-induced membrane alteration which may be important for the growth inhibitory effect of the alkylating agent.

Effects of nitrogen mustard on potassium transport systems and membrane structure of Ehrlich ascites tumor cells

By Ehrlich ascites tumor cells 86Rb+ has been shown to be a suitable tracer for K+-transport. Sixty percent of the total 86Rb-uptake into these cells is ouabain-inhibitable, 30% is sensitive to furosemide and 10% enters the cells by ouabain and furosemide-insensitive systems. N-Mustard inhibits both the ouabain-sensitive and the furosemide-inhibitable systems. The uptake which is resistant to both inhibitors is not affected by the alkylating drug. At N-mustard concentrations below 10 microM, the reduction of the Rb-uptake is predominantly due to the inhibition of the furosemide-sensitive transport. Higher concentrations are required before a significant inhibition of the ouabain-sensitive transport can be observed. The dose response curve of the furosemide-sensitive transport--not, however, of the ouabain inhibitable pump--corresponds to the dose response curve for the antiproliferative activity of N-mustard. The recovery of the furosemide-sensitive transport after a single exposure to N-mustard is relatively slow and--in contrast to the repair of DNA cross-links--is characterized by an initial 4-hr lag period. Furosemide alone does not interfere with cell multiplication. The inhibition of the transport system alone does, therefore, not explain the antitumor activity of N-mustard. The effect is discussed as a marker for membrane lesions after exposure to alkylating agents. In order to investigate the influence of N-mustard on membrane structure, membranes were labelled with diiodofluoresceiniodoacetamide. Anisotropy curves obtained from time-dependent depolarization of delayed fluorescence indicated a mustard induced immobilization of membrane constituents. Lateral diffusion of lipophilic probes was determined by following the quenching of fluorescence of pyrene by cetylpyridinium. The latter studies yielded no evidence for a change in membrane lipid fluidity. The data are interpreted as the results of cross-links of membrane proteins by the bifunctional alkylating agent.

Plasma membrane as target of alkylating agents

N mustard resistant Walker cells exhibit the same frequency of DNA interstrand cross-links and the same rate of cross-link removal as the sensitive parental line. Employing cytostatically active concentrations of chlorambucil covalently bound to polyethyleneimine, the extent of DNA cross-linking is reduced to levels observed in the presence of nontoxic concentrations of free chlorambucil. It is concluded, therefore, that DNA cross-links alone are not sufficient to explain the inhibition of cell multiplication by alkylating agents and that additional mechanisms have to be considered. Evidence for an interference of alkylating agents with several enzymes of the plasma membrane is presented. An inhibition by N mustard of the furosemide-sensitive Na+/K+/Cl- -cotransport and the Na+/H+-antiport is described in greater detail. Considering the fact that the enzymes which are affected by alkylating agents are controlled by growth factors it was investigated whether a synergism between inhibitors of early growth-factor-controlled reactions and alkylating agents is to be seen. It is demonstrated that mepacrine, an inhibitor of phospholipase C, and the calmodulin binding drugs, chlorpromazine and flunarizine, amplify the action of N mustard.

Interactions of cytostatic unsaturated ketonucleosides with sulfhydryl containing cell constituents

The cytostatic unsaturated ketonucleosides, 1, 2, 3 and 4 are highly reactive sulfhydryl blocking agents. Kinetics of their reactions with reduced glutathione (GSH) were measured and their reactivity was compared to that of N-ethylmaleimide (NEM), acrylonitrile and chloroacetamide. Their reaction products with N-acetyl-L-cysteine (AcCys) were prepared and characterized by chemical analysis and nuclear magnetic resonance (NMR) spectroscopy. Compounds 1, 2 and 3 gave Michael type 1:1 addition products. Compound 4 reacted with AcCys by a three step mechanism; the primary addition product 8 underwent an unusual elimination reaction giving the unsaturated compound 9, which yielded the addition product 10 with AcCys. In the reaction with GSH, compound 4 behaved like a bifunctional SH alkylating agent. Compounds 1, 2, 3 and 4 also reacted with protein thiols as shown by their ability to inhibit lactate dehydrogenase (LDH). Unsaturated ketonucleosides had diversified effect on L1210 leukemia cells. While the most potent cytostatics, compounds 1 and 3, reduced considerably the membrane surface SH level, they were without effect on soluble intracellular protein thiols. In contrast, nucleosides 2 and 4, less active than the former, only slightly affected the membrane surface sulfhydryls and considerably depleted the intracellular soluble protein thiols. Only slight differences were found between the reactions of the four nucleosides with non-protein SH (NPSH). The correlation found between in vivo biological activity and cell membrane impairment suggests that selective alkylation of certain key membrane thiols by unsaturated ketonucleosides might be an important event in their biological effect.

The effects of nitrogen mustard (HN2) on activities of the plasma membrane of PC6A mouse plasmacytoma cells

Nitrogen mustard, HN2 (10(-5) M), inhibited the transport of the potassium congener 86rubidium into PC6A mouse plasmacytoma cells by 45% after a 4 hr incubation at 37 degree in vitro. HN2 (10(-3) M) had a rapid effect on the profile of 86rubidium transport into PC6A cells when added simultaneously with the 86rubidium whereas a monofunctional analogue of HN2((2-chloroethyl)dimethylamine) had no effect at 10(-3) M. The transport of the amino acid analogues alpha-aminoisobutyric acid and cycloleucine into PC6A cells was inhibited by 19% and 5% respectively after a 4 hr incubation with 10(-5) M HN2. The results suggest that the activity of plasma membrane Na+K+-ATPase may be affected by HN2. This enzyme may play a pivotal role in controlling cell growth and division. Crude cell membrane preparations from PC6A cells had variable Na+K+-ATPase activity which was possibly due to contamination with mitochondrial Mg2+-ATPase. Incubation of a crude cell membrane preparation in the presence of 40 nM dicyclohexylcarbodiimide gave constant Na+K+-ATPase activity which was inhibited by 44% on incubation with HN2 (10(-3) M) for 0.5 hr. The monofunctional analogue of HN2 inhibited this preparation by only 7% under the same conditions. It is suggested that inhibition of Na+K+-ATPase by HN2 may be an important facet of its cytotoxic activity.

On interactions of cytostatic benzylidine hydrazines with SH-groups

The cytostatic and mutagenic compound N'-methyl-N'-cyano-(p-chloro)-benzaldehyde hydrazone (CyB4) has been found to be a strong SH-blocking agent since it reacts with the thiol groups of glutathione and of the cell membrane of Ehrlich ascites carcinoma cells (EAC). Furthermore, it decreases the intracellular, non-proteinogenic SH(NPSH)-level of tumor cells. CyB4 is not able to alkylate 4-(p-nitrobenzyl)-pyridine (NBP) by a nucleophilic substitution reaction, but it could be shown that the reactivity of CyB4 with thiol groups is due to a Michael-addition-type reaction of SH-groups with the cyano-group of CyB4. On the other hand, cytostatic beta-chloroethyl hydrazones showed a negligible reactivity against glutathione and led even to an increase of thiol groups, detectable by the 5,5'-dithiobis-2-nitrobenzoic acid (DTNB)-method, at the cell membrane of EAC when incubated in the presence of beta-chloroethyl hydrazones N-benzylidene-N'-methyl-N'-(2-chloroethyl) hydrazine (B1) and N-(4-dimethylaminobenzylidene)-N'-methyl-N'-(2-chloroethyl) hydrazine (B2). Therefore, it is concluded that the cytostatic efficiency of CyB4 is due to its SH-blocking while that of the beta-chloroethyl hydrazones is due to a rearrangement of the tumor cell membrane, as indicated by the increased level of reactive SH-groups.

Potential pitfalls of [3H]thymidine techniques to measure cell proliferation

Pitfalls and artifacts in the use of [3H]thymidine in the measurement of cell proliferation kinetics in vitro and in vivo are reviewed. These pitfalls are of particular significance for the study of inhibitors of cell proliferation including chalones.

Effect of alkali metal salts on Sarcoma I in A/J mice

The chloride salts of lithium (Li+) and cesium (Cs+) were evaluated for their ability to influence the growth of Sarcoma I implants in A/J mice. The administration of daily doses of either 1 or 3 mEq/kg CsCl to these mice reduced the incidence and size of tumor implants. This effect was not apparent in animals receiving a smaller dose (0.5 mEq/kg) of the same drug. At the time of sacrifice the serum level of Cs+ in this latter group was approximately half that recorded in animals receiving the higher doses of CsCl. No effect on tumor incidence or rate of growth was observed in animals receiving different doses of LiCl. Because of the similarities that existed between cesium and potassium, it was postulated that the effect of cesium was due to alterations in the intracellular composition of the tumor cells. Also, the possible role of cytotoxic agents in potentiating the inhibitory effect of cesium on tumors was discussed.

Comparison of cytostatic sensitivities of L 1210 cells and human stimulated lymphocytes in three cell proliferation assays

Three methods of measuring cell proliferation, viz., cellular H-thymidine uptake, counting of cells in suspension, and counting of colonies of cells grown in agar contained in glass capillaries, were compared by studying cell growth kinetics using the L 1210 cell line. We found the agar colony culture method to be most suitable and methodologically most advantageous. Using these cytokinetic models, we investigated the differential sensitivities of exponential and stationary phase L 1210 cells and normal, human, PHA-stimulated, peripheral T-lymphocytes to methotrexate, cytosine arabinoside, azathioprine, and a partially purified lymphocyte chalone preparation. L 1210 cells in exponential growth showed a higher drug sensitivity to all the agents tested than those in stationary growth. Normal, human T-lymphocytes exhibited less sensitivity to the tested agents. We found the agar culture to be more than twice as sensitive as the suspension culture and up to 8-fold more sensitive than the 3H-thymidine uptake method.

ADP-ribosylation of nuclear proteins in normal lymphocytes and in low-grade malignant non-Hodgkin lymphoma cells

Normal lymphocytes and lymphocytes from patients with low-grade malignant non-Hodgkin lymphoma were isolated from blood by a Percoll gradient procedure. Absence of cell proliferation in both cell types was indicated by very low [3H]thymidine incorporation rates. Determination of endogenous protein-bound single ADP-ribose residues by a radioimmunoassay revealed that the leukemic cells had 2.5-times lower levels of the NH2OH-sensitive and a 4-fold lower amount of NH2OH-resistant ADP-ribose . protein conjugate subfractions, respectively, than normal lymphocytes. By contrast, "total" ADP-ribose transferase activity, as measured in homogenates or permeabilized cells in the presence of DNase, was two-times higher in leukemic cells, whereas activity determined in permeabilized cells in the absence of added DNase was practically identical in both cell types. The apparent discrepancy between ADP-ribose transferase activity and endogenous levels of protein-bound single ADP-ribose residues may be explained in part by an enzyme inhibitor present in normal human lymphocytes. NAD + NADH levels were decreased 2.5-fold in the leukemic cells. This decrease, however, does not explain the reduced levels of mono(ADP-ribose) . protein conjugates since the ratio of protein-bound single ADP-ribose residues to NAD is distinctly different in leukemic lymphocytes compared to normal lymphocytes.

[The influence of cytostatic and immunosuppressive methyl hydrazones on myelo- and lymphopoiesis in vitro (author's transl)]

The cytostatic and immunosuppressive N'-methyl-N'-beta-chloroethylbenzaldehyde hydrazones B1 and B2 inhibit the colony growth of mouse bone marrow cells and PHA-stimulated human lymphocytes in vitro in a dose-dependent manner. In the presence of B1, however, in contrast to B2, the inhibition of 3H-thymidine (3H-Tdr) uptake by the bone marrow cells and lymphocytes is insignificant. Two further benzaldehydrazones CyB4 and EB4 show little or no influence both on clony growth and nucleoside uptake. On the other hand, CyB4 inhibits the 3H-Tdr uptake by ConA- or LPS-stimulated mouse spleen cells to a gretaer degree than does B1 or B2, although CyB4 unlike B1 or B2 does not display any immunosuppressive effects in the mouse. These findings demonstrate that the 3H-Tdr method is less sensitive than the colony assays and is hence only of limited value as a measure of the vitro proliferation of mammalian cells treated with cytostatics.

Trenimon: biochemical, physiological and genetic effects on cells and organisms

The trifunctional alkylating mutagen Trenimon interferes with the genetic material of a variety of organisms and test systems with respect to the induction of point and chromosomal mutations, sister-chromatid exchanges, recombination phenomena and phage induction. Beneath these mutagenic effects several biochemical and cell physiological aspects have been investigated. In this review we discuss chemical and cell physiological effects of Trenimon, aspects of cancer therapy with Trenimon and genetic effects induced by Trenimon. The available data on mutagenic effects of Trenimon are presented according to organisms or test systems. A short discussion on a possible genetic load by therapy with Trenimon in man concludes this review. DNA damage, especially the induction of cross-linkings, seems to represent the common reason for most of the described effects of Trenimon on cells and organisms.

Thymidine metabolism and DNA synthesis in Newcastle disease virus-infected cells

The inhibition of thymidine incorporation into DNA in Newcastle disease virus-infected cells has been studied. At 6 h after infection of L-929 cells at high multiplicity, transport of exogenous thymidine across the cell membrane was inhibited. The kinetics of this inhibition, decreased Vmax with no change in Km, suggest that there are fewer sites available for transport in infected cells. The conversion of thymidine to dTTP was not inhibited. Equilibrium of exogenous thymidine with the acid-soluble pool occurred more slowly and at a lower level of radioactivity than in uninfected cells, and there was a reduction in the rate of incorporation of exogenous thymidine into DNA. The reduction of incorporation into the pool and into DNA was proportionate. The size of total cellular dTTP pools was changed very little in infected cells. DNA synthesized in infected cells in the presence of [3H]BrdUrd had reduced incorporation of tritium but similar buoyant density to that from uninfected cells. The results show that Newcastle disease virus inhibits DNA synthesis directly and, in addition, decreases thymidine transport. Together these account for the overall decrease in thymidine incorporation into DNA of infected cells.

Evaluation of a short term in vitro test for granulocyte chalone activity

A short term in vitro test for granulocyte chalone activity eas examined for its specificity and reliability. The test used the inhibition, by granulocyte extracts, of 3H-thymidine (3H-Tdr) uptake in to the acid-insoluble material by rat bone marrow cells in vitro to measure possible chalone activity. Among the many possible 3H-Tdr artifacts pool size dilution by Tdr contained in the extracts was excluded using an E. coli mutant requiring thymine. Several amino acids and biogenic amines do not affect the test. However, continuous and pulse labelling of bone marrow cells with 3H-Tdr, viability tests and micro flow fluorometric measurements of the cell cycle distribution following colcemid treatment strongly suggests that the cells do not proliferate in vitro during short term incubation, since practically no cells enter the S-phase, cells in the S-phase die and few if any cells proceed through G2 and mitosis. Moreover, the test cannot exclude cytotoxicity. Thus, the in vitro test may only sceem for an unspecific S-phase inhibitor and must hence be supplemented by another assay to prove the chalone nature of an extract or fraction. The test per se fails to meet most of the requirements of a valid granulocyte chalone assay.

A study of the change in DNA synthesis of S phase cells treated with N-methyl-N-nitrosourethane: a study using Amoeba proteus as a single cell model

The present experiments using Amoeba proteus as a single cell model show that DNA synthesis continues during and after exposure of S phase cell to N-methyl-N'-nitrosourethane (MNU). At sublethal dose levels which caused long division delays, division and growth abnormalities and mutations, the amount of [3h] thymidine ([3h]Tdr) incorporated was decreased by 20-30%; at dose levels which killed all S phase cells it was inhibited by up to 90%. There was a direct correlation between the dose of MNU used and the degree of inhibition of [3H]Tdr incorporated. The effect was rapid, mainly taking place within 20 min of treatment. Amoeba heterokaryons (HKs) were used to examine the rate of DNA synthesis of treated and untreated nuclei in the same cytoplasm, i.e. where the nuclei would have the same [h]tdr intake, the same thymidine kinase (TK) activity and the same endogenous precursor pools. Direct comparison of the nuclear DNA synthetic activity in this way revealed less difference between treated and untreated nuclei than comparisons made using the nuclear grain counts from treated and untreated amoebae. This suggested that much of the decrease in [3H]Tdr incorporation by MNU-treated S phase cells was due to a change in the cytoplasm and/or the cell membrane, rather than to nuclear damage. Thus MNU-treated nuclei were able to synthesize DNA at a near normal rate when they could draw on the resources of untreated cytoplasm, while the rate of DNA synthesis of control nuclei decreased when they occupied cytoplasm which had been exposed to high doses of MNU. These studies suggest that nuclear sites of damage were only involved when lethal doses of MNU had been used.