N-methylation of anthracyclines modulates their cytotoxicity and pharmacokinetic in wild type and multidrug resistant cells

Anthracyclines are the most commonly used classes of anticancer agents in chemotherapy. Development of resistance to these molecules is one of the major reasons for treatment failure. The overexpression of the membrane transporter P-glycoprotein (P-gp) is among the principal mechanisms involved in this phenomenon. This pump, which is responsible for the multidrug resistance (MDR) phenotype, decreases the toxicity of a wide range of unrelated anticancer drugs by increasing their cellular efflux. Structure-activity relationship experiments have shown that the positively charged amino group of the anthracyclines could be responsible for their transport by P-gp. Here, we used three new anthracyclines that shared the same chromophore but differed by the degree of N-methylation of their sugar moiety. Oxaunomycin (OXN) possessed a non-methylated amino group, while LB-1 was monomethylated and beta-clamycin T (BCT) was dimethylated. In sensitive cells (FLC), reduced cytotoxicity was related to the level of N-methylation; whereas in resistant cells (DOX-RFLC(1) and DOX-RFLC(2)) overexpressing different levels of P-gp, increased N-methylation enhanced anthracycline cytotoxicity. Decreased resistance in DOX-RFLCs was associated with an increased drug accumulation due to a reduced cellular efflux. As expected, the MDR modulator verapamil decreased resistance to these anthracyclines by increasing the cellular accumulation. These results suggest that N-methylation of anthracyclines circumvents resistance by diminishing drug transport by P-gp in MDR-positive cells. These observations could be the consequence of the steric hindrance created by the methyl group(s) which may impair the interaction between the positively charged amino group and the active site of P-gp.

ZnCl(2) prevents c-myc repression and apoptosis in serum-deprived Syrian hamster embryo cells

In order to understand the c-myc implication in the apoptotic process better, we investigated the influence of ZnCl(2) on its expression in normal and transformed Syrian hamster embryo (SHE) cells in relation to apoptosis induced by serum withdrawal. Normal primary SHE cells exposed to a serum-free medium undergo rapid apoptosis characterised by a dramatic down-regulation of c-myc transcription. In these normal cells treated with ZnCl(2), c-myc expression is maintained in serum-starved conditions while apoptosis is inhibited. The results shed light on the involvement of c-myc expression in the survival of normal cells in the absence of growth factors. The regulation of c-myc expression appears to be influenced by zinc treatment as an inhibitor of apoptosis, but mechanisms sustaining the level of c-myc transcription remain to be demonstrated. The hypothesis that maintenance of c-myc expression allows cells to escape apoptosis is in accordance with results in transformed SHE cells that underwent low apoptosis and poor down-regulation of c-myc in serum-deprived conditions.

PARP degradation in apoptotic Syrian hamster embryo (SHE) cells compared to HL60 cell line

In this study, we attempted to identify apoptotic Syrian hamster embryo (SHE) cells by detecting the specific cleavage of poly(ADP-ribose)polymerase (PARP). Apoptosis was unequivocally identified in serum-deprived SHE cells. After protein electrophoresis and transfer, the anti-PARP antibody (C-2-10) was applied in order to visualize PARP degradation and the anti-polymer antibody (LP96-10) was used to identify PARP and its expected 89-kDa fragment on the membrane after renaturation and NAD+ addition. Results showed that PARP rapidly disappeared during apoptosis in SHE cells, but the resulting fragment remained undetectable with the anti-PARP antibody and no stable polymerase activity of this fragment was measured using anti-polymer antibody. Serum-starved SHE cells were compared to the etoposide-treated HL60 cell line as a control for typical apoptosis-related PARP cleavage. These results underline the fact that while PARP degradation is a criterion for apoptosis, the diagnosis of apoptosis can not rely exclusively on the appearance of its 89-kDa fragment as this signal may fail to appear in some cell systems.

Detection of apoptosis induced by topoisomerase inhibitors and serum deprivation in syrian hamster embryo cells

The sensitivity of normal diploid Syrian hamster embryo (SHE) cells to apoptosis was tested after treatment with the topoisomerase inhibitors camptothecin and etoposide and after serum withdrawal. Programmed cell death (PCD) was identified through morphological, biochemical, and molecular changes and compared with that of HL60 cell line. The results showed that topoisomerase inhibitors, which were shown to be potent PCD inducers in the HL60 cell line, induced a weaker apoptotic response in SHE cells than after growth factor deprivation. In addition, serum-free medium, which rapidly induced apoptosis in SHE cells, did not affect the HL60 cell line. In both cell types, PCD was expressed by condensed chromatin, fragmented nuclei, and DNA laddering on electrophoretic gels, an indisputable sign of apoptosis. In apoptotic HL60 cells, the cleavage of 113-kDa poly(ADP-ribose)polymerase (PARP) resulted in the so-called apoptotic 89-kDa fragment and was associated with increased caspase-3 activity. In apoptotic SHE cells, PARP degraded early but the degradation profile was not characterized by the appearance of an 89-kDa fragment. Moreover, no activation of caspase-3 was noted. ZnCl(2), which is known to prevent protease activity responsible for apoptosis features, inhibited PARP cleavage and nuclear modifications induced by apoptotic stimuli in both cell types, but with a higher sensitivity in SHE cells. Apoptosis induced by serum deprivation was linked with c-myc negative regulation in SHE cells, but not with p53 protein accumulation, while topoisomerase inhibitors led to p53 stabilization without any change in c-myc expression. Serum-free medium and topoisomerase inhibitors did not modify c-myc expression in the HL60 cell line. The overall results demonstrated that apoptosis, which is a carefully regulated process of cell death, may proceed through mechanisms varying according to cell type or apoptosis inducer. In addition, markers which are generally considered hallmarks of apoptosis may fail to appear in some cell types.

Epigenetic events during the process of cell transformation induced by carcinogens (review)

Recent studies clearly demonstrate that several environmental carcinogens lack the ability to initially induce genetic damage. In that view, multistage chemical carcinogenesis may be processed under the control of a variety of epigenetic events in addition to genotoxic impacts. The understanding of this mechanism as reviewed in this report requires knowledge of early changes induced by carcinogens in target cells, biochemical, biological and molecular reactions closely related to both sides of the growth equation: cell proliferation and programmed death. Among several cell transformation models, the most suitable for carcinogen detection and mechanistic study is the Syrian hamster embryo (SHE) cell transformation assay. This closely mimics the multistage carcinogenesis and we can examine, in a relatively short time (8 days), the mechanisms by which genotoxic and non-genotoxic agents may increase the frequency of cell transformation as a preneoplastic end-point. The mode of action of hundred of compounds, carcinogens and non-carcinogens, has been explored so far using one-stage and two-stage treatment protocols. In general, with the two-stage protocol, all carcinogens, irrespective of their genotoxic or non-genotoxic potential, give unambiguous positive results. Since perturbations of cell proliferation and death are considered essential events in the process of carcinogenesis, studies have been conducted on the dysregulation of two specific parameters, the induction of ornithine decarboxylase (ODC) an enzyme related to cell proliferation, and the apoptosis rate, when SHE cells are exposed to carcinogens. In one-stage treatment (5 h-24 h), only the promoter TPA induces ODC activity, while other carcinogens do not increase this activity. Using the two-stage exposure protocol (1 h xenobiotic/5 h TPA), all carcinogens both genotoxic and non-genotoxic, are able to stimulate ODC activity above the level obtained with TPA alone. Based on the two-stage treatment with carcinogens a close relationship can be obtained between the ODC superinduction and the increase of morphological cell transformation frequency. In cancer development, it is postulated that the inhibition of apoptosis may help altered cells to escape cell death and acquire a tumorigenic phenotype. Two-stage treatment carcinogen/TPA, effectively decreases the apoptotic rate. This is accompanied by an upregulation of the Bcl-2 oncoprotein, a well-known apoptotic inhibitor. However, treatment with a non-carcinogen phthalic anhydride, also inhibits apoptosis while it does not superinduce ODC activity. Although inhibition of apoptosis is not specific to the carcinogenic compound, both superinduction of ODC activity and inhibition of apoptosis via Bcl-2 upregulation may cooperate during the early stages of the carcinogenic process. In a long-term stage transformation assay, the rate of transformed colonies is relatively low (2-8%) bringing about the slow evolution of tumoral disease in humans and tumoral induction in rodents. This could be the consequence of the activation of various cellular repair mechanisms during the exposure time. Experimental data reported so far point out that genotoxic and non-genotoxic carcinogens, thought to be more active in the initiation or in the promotion stage, must share the same stage pathway leading to cancer development.

Apoptosis inhibition and ornithine decarboxylase superinduction as early epigenetic events in morphological transformation of Syrian hamster embryo cells exposed to 2-methoxyacetaldehyde, a metabolite of 2-methoxyethanol

We have conducted a study to determine the carcinogenic potential of ethylene glycol monomethyl ether (EGME), a member of the glycol ether family, as compared to its reactive metabolite 2-methoxy-acetaldehyde (MALD). Since disruption of equilibrium between cell proliferation and cell death is thought to play a key role in multistage carcinogenesis, we investigated, in Syrian hamster embryo (SHE) cells exposed to various doses of EGME and MALD, impairment in apoptosis rate and in ornithine decarboxylase (ODC) metabolism. The activity of this rate-limiting enzyme of polyamine biosynthesis is closely related to cell proliferation and cell transformation. At the end-point, comparative action of the two products on SHE cell morphological transformation frequency was evaluated. One-stage exposure of SHE cells to 2 mM EGME and 200 microM MALD for 5 h did not change basal apoptotic level, whereas 0.16 microM phorbol ester (TPA) decreased it. Using two-stage exposure protocol (1 h xenobiotic followed by 5 h TPA), MALD strongly inhibited apoptosis more than did TPA alone; the parent compound EGME did not have any effect on TPA inhibiting action. Western blotting analysis showed that sequential treatment (MALD/TPA) increased Bcl-2 oncoprotein expression, whereas Bcl-XL and Bax proteins were not changed. The same staged exposure of SHE cells to MALD/TPA strongly induced ODC activity, and the rate was higher than that obtained with TPA alone: this was accompanied by an increase of ODC protein level. This ODC superinduction was not observed with EGME/TPA treatment. In long-term SHE-cell morphological transformation assay, staged exposure to MALD (800 microM or 1 mM for 24 h) followed by TPA applications increased the number of transformed colonies at the seventh day. Such early cooperative events as apoptosis inhibition and ODC superinduction, followed by the increase of SHE-cell transformation frequency, are highly indicative of a carcinogenic potential for the metabolite, MALD.

Two-stage exposure of Syrian-hamster-embryo cells to environmental carcinogens: superinduction of ornithine decarboxylase correlates with increase of morphological-transformation frequency

As part of environmental toxicology, it is important to assess both the carcinogenic potential of xenobiotics and their mode of action on target cells. Since dysregulation of ornithine decarboxylase (ODC), a rate-limiting enzyme of polyamine biosynthesis, is considered as an early and essential component in the process of multistage carcinogenesis, we have studied the mode of ODC induction in Syrian-hamster-embryo(SHE) cells stage-exposed to carcinogens and to non-carcinogens. One-stage (5 hr) treatment of SHE cells with 50 microM clofibrate (CLF), a non-genotoxic carcinogen, or with 0.4 microM benzo(a)pyrene (BaP), a genotoxic carcinogen, slightly decreased basal ODC activity. Using the 2-stage exposure, 1 hr to carcinogen, then replacement by TPA for 5 hr, the ODC activity was higher than that obtained with TPA alone. This ODC superinduction was not observed when SHE cells were similarly pre-treated with non-carcinogenic compounds. Several environmental chemicals, pesticides, solvents, oxidizers and drugs were investigated with this SHE cell model. With one-stage exposure, some xenobiotics decreased basal ODC activity, while for others ODC changes were not noticeable. With 2-stage exposure (chemical followed by TPA), all carcinogens amplified the TPA-inducing effect, resulting in ODC superinduction. Comparative studies of the action of carcinogens and of non-carcinogens, using 2-stage exposure protocols, clearly show a close relationship between ODC induction rate and morphological transformation frequency.

Dysregulation of ornithine decarboxylase activity, apoptosis and Bcl-2 oncoprotein in Syrian hamster embryo cells stage-exposed to di(2-ethylhexyl)phthalate and tetradecanoylphorbol acetate

Perturbations of cell proliferation and death are considered as essential events in the process of carcinogenesis. Thus, two parameters, ornithine decarboxylase (ODC), an enzyme closely related to cell proliferation and transformation, and apoptotic phenomenon are profoundly modified. Using Syrian hamster embryo (SHE) cells, we have examined in the framework of two-stage carcinogenesis (initiation-promotion) the effects of a non-genotoxic [diethylhexylphthalate (DEHP)] or genotoxic [benzo[a]pyrene (BaP)] carcinogen or a non-carcinogenic compound [phthalic anhydride (AP)] on these parameters. Immunoreactive Bcl-2 and Bcl-xL proteins were also investigated following two-stage exposures. Whereas exposures to BaP, DEHP or AP alone did not provoke any modification of ODC activity, the phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), strongly increased it. Using two-stage exposure protocol (xenobiotics first, then replacement by TPA-promoter), the ODC activity was higher than that obtained with TPA alone. This superinduction of ODC activity was observed only with the carcinogenic compounds DEHP and BaP. Following the same exposure protocol, spontaneous cellular apoptosis was decreased. Furthermore, Bcl-2 oncoprotein was also upregulated approximately 8- and 11-fold for BaP and DEHP respectively; meanwhile Bcl-xL protein rate did not change. The non-carcinogenic compound AP slightly inhibited spontaneous SHE cell death without ODC superinduction. Exogenous polyamines, putrescine, spermidine and spermine diluted in the medium did not inhibit spontaneous apoptosis. Although inhibition of apoptosis was not specific of carcinogenic compound, both superinduction of ODC activity and inhibition of apoptosis via Bcl-2 upregulation, may cooperate during early stages of the carcinogenic process.

Comparative effects of clofibrate and methyl clofenapate on morphological transformation and intercellular communication of Syrian hamster embryo cells

The Syrian hamster embryo (SHE) cell system was used to evaluate the ability of two hepatocarcinogenic structurally related peroxisome proliferators (PPs) to induce morphological transformation (MT) of SHE colonies and to inhibit gap junctional intercellular communication (GJIC). Clofibrate and methyl clofenapate (MCP), which was shown to be a more active PP and a more potent carcinogen in vivo than clofibrate, were compared. MCP appeared slightly more active in vitro than clofibrate in affecting MT and GJIC of SHE cells. The morphological transformation of SHE colonies was induced by 50 microM MCP, against 100 microM clofibrate. Moreover, 50 microM MCP potentiated the transforming effects of both benzo[a]pyrene and 12-O-tetradecanoylphorbol-13-acetate. The inhibition of GJIC, measured by transfer of lucifer yellow, was transient and occurred at concentrations inducing morphological transformation. MCP inhibited dye transfer at 50 microM and the inhibition lasted up to 24 h at 100 microM. Inhibition of communication lasted only 4 h with clofibrate and occurred at a higher concentration (175 microM). This study showed that both the SHE cell transformation and dye transfer assays were able to display the different activities of the two PPs, even though the difference in potency observed was smaller than in vivo. It also revealed interactions between non-genotoxic carcinogens and the ability of the SHE cell transformation assay to detect these combined effects.

Nongenotoxic carcinogens: development of detection methods based on mechanisms: a European project

While the accumulation of genetic changes in a somatic cell is considered essential for the genesis of a cancer, it has become clear that not all carcinogens are genotoxic, suggesting that some carcinogens indirectly participate in the generation of genetic changes during carcinogenesis. A European project funded by the European Community was thus conceived to study mechanisms of nongenotoxic aspects of carcinogenesis. Two main strategical approaches were adapted: (i) to study whether and how Syrian hamster embryo (SHE), Syrian hamster dermal (SHD) and BALB/c 3T3 cell transformation systems simulate in vivo carcinogenesis, and to examine whether they can detect nongenotoxic carcinogens; (ii) to study, refine and validate mechanisms-based end-points for detection of nongenotoxic carcinogens. For mechanisms-based research, the proposed end-points included gap junctional intercellular communication (GJIC) inhibition, altered expression of critical genes, immortalization and aberrant cell proliferation. We also selected model compounds commonly usable for various endpoints. Our major results can be summarized as follows: (1) SHE and BALB/c 3T3 transformation systems reflect both genotoxic and nongenotoxic carcinogenic events; they detect not only genotoxic but also many although not all, nongenotoxic carcinogens. This is further supported by the fact that both genotoxic and nongenotoxic carcinogens were able to immortalize SHD cells. (2) Many nongenotoxic carcinogens, although not all, inhibit GJIC in vitro as well as in vivo. Mechanistic studies suggest an important role of blocked GJIC in carcinogenesis and that different mechanisms are involved in inhibition of the communication by different agents used. However, inhibition of GJIC is not a prerequisite for the enhancement (or induction) of transformation of SHE or BALB/c 3T3 cells. (3) Among compounds examined, there was a good correlation between induction of micronuclei and cell transformation in SHE cells while no such correlation was found between the induction of cell transformation and ornithine decarboxylase activity. (4) Two transgenic mouse mutation assays (lacI and lacZ) were established and validated. The genotoxin dimethylnitrosamine was shown to be mutagenic to the liver in both assays. Ortho-anisidine, a bladder-specific carcinogen that was inactive in standard rodent genetic toxicity assays was uniquely mutagenic to the bladder of the transgenic mice. The peroxisome proliferator methyl clofenipate was established as nonmutagenic to the liver of both transgenic mice. That eliminated DNA damage as a cause of the liver tumours produced by this chemical and weakened the idea that induced cell division leads to mutation induction. (5) With an in vitro DNA replication model, it was found that DNA damage induced by genotoxic agents can be responsible for inhibition of DNA replication, while certain nongenotoxic agents such as phorbol esters increase DNA replication. (6) An attempt to use structure-activity relationship for subfamilies of nongenotoxic carcinogens, e.g., receptor-mediated carcinogens, has been initiated with some promising results. Our results support the idea that there are multiple nongenotoxic mechanisms in carcinogenesis, and that working hypothesis-oriented approaches are encouraged rather than simple screening of chemicals in developing test systems for the detection of nongenotoxic carcinogens.

Synergistic effects of chlordane and TPA in multistage morphological transformation of SHE cells

The cyclodiene pesticide chlordane has been reported to be a non-genotoxic carcinogen in rodents. The effects of chlordane on SHE cell transformation were investigated in this study. It appeared that chlordane exhibited a weak transforming activity when applied repeatedly at 8 micrograms/ml. No effect resulted from the combination of benzo[a]pyrene-chlordane. In contrast, chlordane in the range 5-20 micrograms/ml and 12-O-tetradecanoylphorbol-13-acetate (TPA) (0.1 micrograms/ml) highly potentiated each other when applied sequentially. The synergistic effects could be inhibited by dexamethasone. These results led us to study the genotoxicity of chlordane on SHE cells: no DNA adduct formation could be detected in SHE cells treated with chlordane at a concentration potentiating the transforming effect of TPA. We also confirmed that this pesticide markedly inhibited intercellular communication between SHE as well as V79 cells. These results support literature data on the non-genotoxicity of chlordane. Overall, this study highlights the fact that interaction between-non genotoxic carcinogens may enhance the transformation frequency of SHE cells. Thus, combined effects must be taken into account in the evaluation of carcinogenic risk.

Modulatory effect of dexamethasone on ornithine decarboxylase activity and gene expression: a possible post-transcriptional regulation by a neutral metalloprotease

The intracellular effect of dexamethasone (DXME) on the activity and gene expression of ornithine decarboxylase (ODC) was studied in Syrian hamster embryo cells (SHE). The ODC activity (expressed as nmoles decarboxylated ornithine mg-1 protein h-1) was 4.61 +/- 0.14 in untreated cells, whereas it increased to 14.38 +/- 0.26 after 5 h treatment with 1.6 x 10(-7) M TPA. In contrast, DXME (2.5 x 10(-5) M) reduced the ODC activity by 50 per cent to 2.35 +/- 0.22. In cells co-treated for 5 h with TPA and DXME, ODC activity decreased to the level of the untreated cells. However, when DXME was added 3 h after TPA treatment for 2 h, in the continuous presence of TPA, the ODC activity unexpectedly increased further to 16.44 +/- 1.05. The modulation of ODC activity correlated partly with the level of ODC mRNA. Thus when cells were treated with TPA, the ODC mRNA increased threefold, whereas it decreased by 30 per cent when the cells were exposed to DXME. In TPA-DXME co-treated cells, as in TPA pretreated cells followed by DXME for 2 h, a decrease (31.25 per cent and 12.5 per cent respectively) was observed in ODC mRNA. In turnover studies, DXME was found to increase the stability of ODC; the discrepancy between ODC activity and ODC mRNA levels could result from an inhibitory effect of the corticoid on proteolysis of ODC. Studies of lysosomal protease showed that the activities of cathepsins L, B and H decreased following TPA treatment. DXME also inhibited cathepsin L and B activities, but stimulated cathepsin H.(ABSTRACT TRUNCATED AT 250 WORDS)

Cross resistance relevance of the chemical structure of different anthracyclines in multidrug resistant cells

Positively charged doxorubicin (DOX) and non-positively charged anthracyclines, aclarubicin (ACR) and morpholino-carminomycin (KRN 8602), have been investigated with respect to pharmacological parameters, cytotoxicity, DNA damage and repair in DOX-sensitive and -resistant murine and human cells. Friend leukemia cells (FLC) resistant to high concentrations of doxorubicin (DOX-RFLC3) or daunorubicin (DNR-RFLC3) (1771 and 1543 fold resistance respectively) express less than 10 fold resistance to aclarubicin (ACR). In these cells, the intracellular accumulation of ACR is similar in sensitive and resistant cells. Resistance to ACR was not observed in either DOX-RFLC1 or DNR1 with a lower level of resistance (27 fold). Increased expression of a 170,000-dalton surface antigen (gp-170) was found to be correlated with the level of resistance. However, when the selective agent in ACR, despite the low level of resistance (2.8 fold) both high expression of gp 170 and resistance to DOX (77 fold) or DNR (62 fold) are observed. It is assumed therefore that induction of multidrug resistance phenotype can be achieved by compounds which do not display cross resistance with DOX or DNR. Reduced levels or absence of cross-resistance can be related to the electrical charge of the compound. This assumption is supported by further studies on DOX-sensitive or -resistant human K562 cells exposed to another non-positively charged anthracycline, KRN 8602. In the continuous presence of drug, K562/DOX were less resistant to KRN 8602 (2.9 fold) than to DOX (31 fold). After short time exposure followed by growth in drug-free medium, absence of cross-resistance to KRN 8602 has been observed in K562/DOX. Furthermore, accumulation experiments showed that high intracellular drug concentrations were rapidly achieved (within 15 min) in both DOX-sensitive and -resistant cells. In cells exposed to DOX, DNA single-strand break (DNA-SSBs) frequencies were related to time and drug concentration while those produced by KRN 8602 or ACR were maximal after short time incubation. DNA-SSBs produced by these anthracyclines are not repaired when cells are incubated in drug free medium. In DOX resistant cells, DNA-SSBs produced by DOX were repaired whereas those produced by ACR or KRN 8602 were not. It is suggested, therefore, that absence of cross resistance to various anthracyclines is related to differences in the chemical electrical charge, which may influence drug accumulation and DNA repair in resistant cells.

Epidermal cell proliferation and modulation of the protective potency of dexamethasone against phorbol ester-induced ornithine decarboxylase activity

Treating mouse skin with dexamethasone (DXME, 1 mumol) after a single TPA (3.25 nmol) application, inhibited both the dermal inflammatory reaction and the induction of epidermal ornithine decarboxylase (ODC) activity. At the hyperplastic stage, DXME was active against inflammation, though inhibited weakly the induction of ODC. In DXME-protected skin, the hyperplastic stage was delayed; unexpectedly, before that stage, 12-O-tetradecanoyl-phorbol-13-acetate (TPA) induced strongly ODC activity in the epidermal cell layer. Provided that the proliferation process was induced, epidermal cells were increasingly sensitive toward TPA action; they may have been less dependent on inflammatory factors which may modulate the induction of ODC.