Ribonucleotide reductase as one important target of [Tris(1,10-phenanthroline)lanthanum(III)] trithiocyanate (KP772).

KP772 is a new lanthanum complex containing three 1,10-phenathroline molecules. Recently, we have demonstrated that the promising in vitro and in vivo anticancer properties of KP772 are based on p53-independent G(0)G(1) arrest and apoptosis induction. A National Cancer Institute (NCI) screen revealed significant correlation of KP772 activity with that of the ribonucleotide reductase (RR) inhibitor hydroxyurea (HU). Consequently, this study aimed to investigate whether KP772 targets DNA synthesis in tumor cells by RR inhibition. Indeed, KP772 treatment led to significant reduction of cytidine incorporation paralleled by a decrease of deoxynucleoside triphosphate (dNTP) pools. This strongly indicates disruption of RR activity. Moreover, KP772 protected against oxidative stress, suggesting that this drug might interfere with RR by interaction with the tyrosyl radical in subunit R2. Additionally, several observations (e.g. increase of transferrin receptor expression and protective effect of iron preloading) indicate that KP772 interferes with cellular iron homeostasis. Accordingly, co-incubation of Fe(II) with KP772 led to generation of a coloured iron complex (Fe-KP772) in cell free systems. In electron paramagnetic resonance (EPR) measurements of mouse R2 subunits, KP772 disrupted the tyrosyl radical while Fe-KP772 had no significant effects. Moreover, coincubation of KP772 with iron-loaded R2 led to formation of Fe-KP772 suggesting chelation of RR-bound Fe(II). Summarizing, our data prove that KP772 inhibits RR by targeting the iron centre of the R2 subunit. As also Fe-KP772 as well as free lanthanum exert significant -though less pronounced- cytotoxic/static activities, additional mechanisms are likely to synergise with RR inhibition in the promising anticancer activity of KP772.

Vaults and the major vault protein: novel roles in signal pathway regulation and immunity.

The unique and evolutionary highly conserved major vault protein (MVP) is the main component of ubiquitous, large cellular ribonucleoparticles termed vaults. The 100 kDa MVP represents more than 70% of the vault mass which contains two additional proteins, the vault poly (ADP-ribose) polymerase (vPARP) and the telomerase-associated protein 1 (TEP1), as well as several short untranslated RNAs (vRNA). Vaults are almost ubiquitously expressed and, besides chemotherapy resistance, have been implicated in the regulation of several cellular processes including transport mechanisms, signal transmissions and immune responses. Despite a growing amount of data from diverse species and systems, the definition of precise vault functions is still highly complex and challenging. Here we review the current knowledge on MVP and vaults with focus on regulatory functions in intracellular signal transduction and immune defence.

Multidrug-resistant cancer cells are preferential targets of the new antineoplastic lanthanum compound KP772 (FFC24).

Recently, we have introduced [tris(1,10-phenanthroline)lanthanum(III)] trithiocyanate (KP772, FFC24) as a new lanthanum compound which has promising anticancer properties in vivo and in vitro. Aim of this study was to investigate the impact of ABC transporter-mediated multidrug resistance (MDR) on the anticancer activity of KP772. Here, we demonstrate that all MDR cell models investigated, overexpressing ABCB1 (P-glycoprotein), ABCC1 (multidrug resistance protein 1), or ABCG2 (breast cancer resistance protein) either due to drug selection or gene transfection, were significantly hypersensitive against KP772. Using ABCB1-overexpressing KBC-1 cells as MDR model, KP772 hypersensitivity was demonstrated to be based on stronger apoptosis induction and/or cell cycle arrest at unaltered cellular drug accumulation. KP772 did neither stimulate ABCB1 ATPase activity nor alter rhodamine 123 accumulation arguing against a direct interaction with ABCB1. Accordingly, several drug resistance modulators did not sensitize but rather protect MDR cells against KP772-induced cytotoxicity. Moreover, long-term KP772 treatment of KBC-1 cells at subtoxic concentrations led within 20 passages to a complete loss of drug resistance based on blocked MDR1 gene expression. When exposing parental KB-3-1 cells to subtoxic, stepwise increasing KP772 concentrations, we observed, in contrast to several other metallo-drugs, no acquisition of KP772 resistance. Summarizing, our data demonstrate that KP772 is hyperactive in MDR cells and might have chemosensitizing properties by blocking ABCB1 expression. Together with the disability of tumor cells to acquire KP772 resistance, our data suggest that KP772 should be especially active against notoriously drug-resistant tumor types and as second line treatment after standard chemotherapy failure.

Cellular functions of vaults and their involvement in multidrug resistance.

Vaults are evolutionary highly conserved ribonucleoprotein (RNP) particles with a hollow barrel-like structure. They are 41 x 73 nm in size and are composed of multiple copies of three proteins and small untranslated RNA (vRNA). The main component of vaults represents the 110 kDa major vault protein (MVP), whereas the two minor vault proteins comprise the 193 kDa vault poly(ADP-ribose) polymerase (VPARP) and the 240 kDa telomerase-associated protein-1 (TEP1). Vaults are abundantly present in the cytoplasm of eukaryotic cells and they were found to be associated with cytoskeletal elements as well as occasionally with the nuclear envelope. Vaults and MVP have been associated with several cellular processes which are also involved in cancer development like cell motility and differentiation. Due to the over-expression of MVP (also termed lung resistance-related protein or LRP) in several P-glycoprotein (P-gp)-negative chemoresistant cancer cell lines, vaults have been linked to multidrug resistance (MDR). Accordingly, high levels of MVP were found in tissues chronically exposed to xenobiotics. In addition, the expression of MVP correlated with the degree of malignancy in certain cancer types, suggesting a direct involvement in tumor development and/or progression. Based on the finding that MVP binds several phosphatases and kinases including PTEN, SHP-2 as well as Erk, evidence is accumulating that MVP might be involved in the regulation of important cell signalling pathways including the PI3K/Akt and the MAPK pathways. In this review we summarize the current knowledge concerning the vault particle and discuss its possible cellular functions, focusing on the role of vaults in chemotherapy resistance.

Anticancer effects of zoledronic acid against human osteosarcoma cells.

Based on neoadjuvant chemotherapy, the prognosis of osteosarcoma patients has improved dramatically. However, due to therapy resistance in patient subgroups, the development of new treatment strategies is still of utmost importance. The aim of our study was to test the effects of the nitrogen-containing bisphosphonate zoledronic acid (ZOL) on osteosarcoma cell lines (N = 9). Exposure to ZOL at low micromolar concentrations induced a dose- and time-dependent block of DNA synthesis and cell cycle progression followed by microfilament breakdown and apoptosis induction. The ZOL-induced cell cycle accumulation in S phase was accompanied by significant changes in the expression of cyclins and cyclin-dependent kinase inhibitors with a prominent loss of cyclin E and D1. ZOL not only inhibited growth but also migration of osteosarcoma cells. The mevalonate pathway intermediary geranyl-geraniol (GGOH) but not farnesol (FOH) significantly inhibited the anticancer effects of ZOL against osteosarcoma cells. Correspondingly, ZOL sensitivity correlated with the blockade of protein geranylgeranylation indicated by unprenylated Rap1. Overexpression of even high levels of P-glycoprotein, as frequently present in therapy-resistant osteosarcomas, did not impair the anticancer activity of ZOL. Summarizing, our data suggest that ZOL, which selectively accumulates in the bone, represents a promising agent to improve osteosarcoma therapy.

Methods for the detection of antioxidants which prevent age related diseases: a critical review with particular emphasis on human intervention studies.

It is well documented that reactive oxygen species (ROS) are involved in the aetiology of age related diseases. Over the last decades, strong efforts have been made to identify antioxidants in human foods and numerous promising compounds have been detected which are used for the production of supplements and functional foods. The present paper describes the advantages and limitations of methods which are currently used for the identification of antioxidants. Numerous in vitro methods are available which are easy to perform and largely used in screening trials. However, the results of such tests are only partly relevant for humans as certain active compounds (e.g. those with large molecular configuration) are only poorly absorbed in the gastrointestinal tract and/or may undergo metabolic degradation. Therefore experimental models are required which provide information if protective effects take place in humans under realistic conditions. Over the last years, several methods have been developed which are increasingly used in human intervention trials. The most widely used techniques are chemical determinations of oxidised guanosine in peripheral blood cells or urine and single cell gel electrophoresis (comet) assays with lymphocytes which are based on the measurement of DNA migration in an electric field. By using of DNA-restriction enzymes (formamidopyrimidine DNA glycosylase and endonuclease III) it is possible to monitor the endogenous formation of oxidised purines and pyrimidines; recently also protocols have been developed which enable to monitor alterations in the repair of oxidised DNA. Alternatively, also the frequency of micronucleated cells can be monitored with the cytokinesis block method in peripheral human blood cells before and after intervention with putative antioxidants. To obtain information on alterations of the sensitivity towards oxidative damage, the cells can be treated ex vivo with ROS (H(2)O(2) exposure, radiation). The evaluation of currently available human studies shows that in approximately half of them protective effects of dietary factors towards oxidative DNA-damage were observed. Earlier studies focused predominantly on the effects of vitamins (A, C, E) and carotenoids, more recently also the effects of fruit juices (from grapes, kiwi) and beverages (soy milk, tea, coffee), vegetables (tomato products, berries, Brussels sprouts) and other components of the human diet (coenzyme Q(10), polyunsaturated fatty acids) were investigated. On the basis of the results of these studies it was possible to identify dietary compounds which are highly active (e.g. gallic acid). At present, strong efforts are made to elucidate whether the different parameters of oxidative DNA-damage correlates with life span, cancer and other age related diseases. The new techniques are highly useful tools which provide valuable information if dietary components cause antioxidant effects in humans and can be used to identify individual protective compounds and also to develop nutritional strategies to reduce the adverse health effects of ROS.

Multidrug resistance markers P-glycoprotein, multidrug resistance protein 1, and lung resistance protein in non-small cell lung cancer: prognostic implications.

PURPOSE: The aim of this retrospective study was to comparatively investigate the expression of the three drug-resistance genes P-glycoprotein (P-gp), multidrug-resistance protein 1 (MRP1), and lung resistance protein (LRP), in non-small cell lung cancer (NSCLC) tissues, and to assess possible associations with clinicopathologic features. METHODS: Tumor specimens from 126 patients were analyzed by immunohistochemistry and, in selected cases, by reverse transcriptase polymerase chain reaction (RT-PCR), and data were statistically analyzed by SPSS. RESULTS: The mean expression levels of tumor tissues in the case of P-gp and LRP did not exceed the one of normal epithelia, while MRP1 was significantly enhanced in NSCLC. A weak association was observed between higher grading and P-glycoprotein expression (p <0.08) as well as lower grading and MRP1 expression in the case of adenocarcinoma (p <0.05). MRP1 levels were highest in TNM stage I and declined with advanced stage (p <0.03). A significant association was found between high MRP1 levels and longer overall survival (N =115, p <0.04), which was highly significant in the patient group never treated with chemotherapy (N =77; p <0.007). P-gp expression was enhanced in those patients who had received chemotherapy before surgery (p <0.05). CONCLUSIONS: Our data point towards a major role of MRP1 in the intrinsic treatment resistance of NSCLC and suggest, in addition, a significant activation of P-gp expression during chemotherapy.

Intrinsic and acquired forms of resistance against the anticancer ruthenium compound KP1019 [indazolium trans-[tetrachlorobis(1H-indazole)ruthenate (III)] (FFC14A).

KP1019 [indazolium trans-[tetrachlorobis(1H-indazole)ruthenate (III)] (FFC14A) is a metal complex with promising anticancer activity. Since chemoresistance is a major obstacle in chemotherapy, this study investigated the influence of several drug resistance mechanisms on the anticancer activity of KP1019. Here we demonstrate that the cytotoxic effects of KP1019 are neither substantially hampered by overexpression of the drug resistance proteins multidrug resistance-related protein 1, breast cancer resistance protein, and lung resistance protein nor the transferrin receptor and only marginally by the cellular p53 status. In contrast, P-glycoprotein overexpression weakly but significantly (up to 2-fold) reduced KP1019 activity. P-glycoprotein-related resistance was based on reduced intracellular KP1019 accumulation and reversible by known P-glycoprotein modulators. KP1019 dose dependently inhibited ATPase activity of P-glycoprotein with a K(i) of approximately 31 microM. Furthermore, it potently blocked P-glycoprotein-mediated rhodamine 123 efflux under serum-free conditions (EC(50), approximately 8 microM), however, with reduced activity at increased serum concentrations (EC(50) at 10% serum, approximately 35 microM). Moreover, P-glycoprotein-mediated daunomycin resistance could only be marginally restored by KP1019 in serum-containing medium, also indicating an influence of serum proteins on the interaction between KP1019 and P-glycoprotein. Acquired KP1019 resistance was investigated by selecting KB-3-1 cells against KP1019 for more than 1 year. Only an approximately 2-fold KP1019 resistance could be induced, which unexpectedly was not due to overexpression of P-glycoprotein or other efflux pumps. Accordingly, KP1019-resistant cells did not display reduced drug accumulation. Their unique cross-resistance pattern confirmed an ABC transporter-independent resistance phenotype. In summary, the likeliness of acquiring insensitivity to KP1019 during therapy is expected to be low, and resistance should not be based on overexpression of drug efflux transporters.

Overexpression of the human major vault protein in astrocytic brain tumor cells.

Evidence has shown that the major human vault protein (MVP), which is identical to lung resistance-related protein (LRP), may be causally involved in a special type of multidrug resistance (MDR). The purpose of this study was to investigate the expression and cellular localization of MVP in cells derived from brain tumors and other tumors of neuroectodermal origin. Using both established cell lines (n = 22) and primary explants (n = 30), we show that a distinct overexpression of the MVP gene at the mRNA (RT-PCR) and protein (Western blot) levels is a characteristic feature of cells derived from astrocytic brain tumors. Primary cultures obtained from meningioma specimens also expressed high MVP levels, in contrast to neuroblastoma and medulloblastoma cells, which rarely contained detectable amounts of MVP. Normal human astrocytes cultured in vitro expressed MVP, although at low amounts compared with most malignant cell types. Basal MVP expression correlated with resistance against diverse antineoplastic drugs including anthracyclins, cisplatin and etoposide. By Western blot, MVP was also detected in all tumor samples taken from 7 glioma and 3 meningioma patients. Taken together, these data suggest overexpression of MVP as one explanation for the low efficacy of chemotherapeutic treatment of astrocytic brain tumors.

A small upstream open reading frame causes inhibition of human major vault protein expression from a ubiquitous mRNA splice variant.

Overexpression of the major vault protein (MVP) has been linked to a multidrug resistance (MDR) phenotype. We describe a ubiquitously expressed MVP mRNA splice variant (long (L)-MVP) differing from the regular isoform (short (S)-MVP) within the 5'-leader. Only L-MVP mRNA contains a small upstream open reading frame which was proven to inhibit in vitro and in vivo MVP expression in cis. L-MVP represented an almost constant portion of total MVP mRNA in diverse normal tissues, but was more variable in malignant cell types. MDR sublines with altered MVP expression displayed changed S-MVP/L-MVP ratios as compared to their drug-sensitive counterparts. Our results suggest alternative splicing as one mechanism for regulation of MVP expression.

Expression of the major vault protein LRP in human non-small-cell lung cancer cells: activation by short-term exposure to antineoplastic drugs.

Non-small-cell lung cancer (NSCLC) cells are characterised by resistance to the toxic impact of antineoplastic drugs both in vivo and in vitro. The lung resistance-related protein (LRP), identical with the human major vault protein, is over-expressed in a variety of tumour cells characterised by intrinsic or acquired chemoresistance. We investigated the expression and cellular localisation of LRP in 16 unselected NSCLC cell lines, immortalised bronchial epithelial cells and embryonic lung fibroblasts. All cell lines analysed expressed LRP mRNA, while protein expression ranged from undetectable up to high levels. Cell fractionation and immunofluorescence staining in selected cell lines localised LRP almost exclusively to the cytoplasm. LRP was contained in the 100, 000 g pellet and absent in the soluble, cytosolic fraction and nuclei. A small proportion of LRP, however, was shown to be loosely associated with the outside of the nuclei. Sucrose gradient equilibrium centrifugation revealed presence of LRP exclusively in the fraction known to accumulate purified vault particles. Short-term exposure (16 hr) to subtoxic daunomycin (DM)-, and bleomycin (BM)-concentrations significantly (up to 4-fold) enhanced LRP expression in 2/4 cell lines tested. Cisplatin (CDDP) had a minor effect while vinblastine (VBL) was ineffective. At cytotoxic conditions all drugs rather decreased than increased LRP expression. When basic LRP expression was compared with chemosensitivity, a significant correlation was detected for resistance to CDDP but not DM, doxorubicin (DOX), etoposide (VP-16), VBL and BM. Summing up, our data suggest a role of vaults both in basic CDDP resistance and, additionally, in an short-term defensive response of NSCLC cells against several other drugs.

A novel bioassay for P-glycoprotein functionality using cytochalasin D.

The functional contribution of both P-glycoprotein (P-gp) and the multidrug resistance-associated protein (MRP) to multidrug resistance (MDR) in tumor cells is commonly determined by drug cytotoxicity and/or accumulation/efflux tests. We report on a bioassay developed for the specific detection of functional P-gp levels and the efficacy of related chemosensitizers (CD-P-gp-assay). The assay is based on the flow cytometric measurement of changes in the > or = G2M cell cycle compartment which are due to the induction of polykaryons after exposure of proliferating cells to three defined cytochalasin D (CD) concentrations with and without verapamil. As demonstrated in 13 well-characterized MDR cell models (20 resistant sublines), there is a significant correlation between cytokinesis-blocking CD doses, as well as responsiveness to chemosensitizers and MDR1 gene expression (mRNA and P-gp) allowing discrimination between different levels of P-gp-MDR. CD-P-gp-assay specificity was assessed by testing 23 compounds: 19 known as potent inhibitors of P-gp-MDR, some of them, though to a lesser extent, also of MRP-MDR; 1 inhibiting MRP-but not P-gp-MDR; 3 inactive in both types of MDR. A modulation of CD activity was confined exclusively to both P-gp-expressing cell lines and P-gp chemosensitizers. CD cytoskeletal activity measured by FACS is a specific and sensitive tool with which to detect functional P-gp and related chemosensitizers.

Expression of the multidrug resistance-associated protein (MRP) and chemoresistance of human non-small-cell lung cancer cells.

Human non-small-cell lung cancer (NSCLC) is considered to be a chemotherapy-refractory malignancy. The underlying mechanisms remain rather obscure. The multidrug resistance-associated protein (MRP), mediating a multidrug resistance (MDR) phenotype, has been reported to be overexpressed in several drug-selected lung cancer cell lines. A few previous studies have described intrinsic MRP expression in both NSCLC and normal lung tissues. However, the drug-transporting activity as well as the correlation with chemoresistance is unclear. Using 15 unselected cell lines, we show that MRP (mRNA and protein as detected by reverse transcriptase polymerase chain reaction and immunoblot) is frequently expressed intrinsically, with markedly varying intensity, in NSCLC. Two cell lines expressed high MRP levels, one comparable to the drug-selected controls (GLC4/ADR, HL-60/AR) without, however, amplification of the MRP gene (Southern hybridization). Using 3H-daunomycin (3H-DM) and calcein as MRP substrates and probenecid (PRO), genistein (GEN), benzbromarone (BB), N-ethylmaleimide (NEM) and verapamil (VP) as MRP modulators, drug accumulation studies revealed a transporting activity of MRP that correlated significantly with the gene expression data. Moreover, a significant correlation between MRP expression and chemoresistance against daunomycin (DM), doxorubicin (DOX), etoposide (VP-16) and vinblastine (VBL), but not cisplatin (CDDP) and bleomycin (Bleo) (MTT-based survival assay), was detected. Correlations mainly rested on the pronounced chemoresistance of 2 highly MRP-expressing cell lines and did not reach significance when these cell lines were excluded.

Possible role of the multidrug resistance-associated protein (MRP) in chemoresistance of human melanoma cells.

Human malignant melanoma is characterised by unresponsiveness to conventional chemotherapy. Melanoma-derived cell lines are often markedly chemoresistant, suggesting that cellular mechanisms mediate the multidrug resistance (MDR) phenotype. The multidrug resistance-associated protein (MRP) is a drug transporter protein associated with resistance to a broad spectrum of lipophilic drugs. To investigate whether MRP is involved in intrinsic drug resistance of human melanoma, we analysed expression and functional activity of MRP as well as its impact on chemoresistance in 40 melanoma cell lines (35 established by us from primary and metastatic lesions and 5 obtained from international sources), as well as in one dysplastic naevus-derived cell line and in normal melanocytes. By reverse transcriptase-polymerase chain reaction various levels of MRP mRNA were detected in all melanoma cell lines, and by immunoblot the corresponding protein in a high percentage of them. Functional activity of MRP was assayed by analysing cellular accumulation of 3H-daunomycin (3H-DM) and calcein in response to MRP-modulators by beta-spectrometric and fluorescence-activated cell sorter analysis, respectively. Probenecid (PRO), N-ethylmaleimide (NEM) and benzbromarone (BB) moderately (< or = 1.43-fold) but significantly enhanced intracellular accumulation of MRP substrate probes corresponding to MRP expression. Moreover, the sensitivity of melanoma cell lines to daunomycin (DM) and doxorubicin (DOX), but not to vinblastine (VBL), etoposide (VP-16) and cisplatin (CDDP), analysed by an MTT-based survival assay, were inversely correlated with MRP-gene expression. Our results imply that MRP may be a component of the intrinsic chemoresistance phenotype characteristic of human malignant melanoma.

Effects of multidrug resistance-related ATP-binding-cassette transporter proteins on the cytoskeletal activity of cytochalasins.

Cytochalasins are microfilament-active mould metabolites, widely utilized to study the involvement of the actin cytoskeleton in cellular processes as well as in genotoxicity and cell kinetic research. In this study we have investigated whether multidrug-resistance phenotypes, caused by overexpression of the ATP-binding-cassette transporter proteins P-glycoprotein (P-gp) or multidrug-resistance-associated protein (MRP), influence the microfilament-depolymerizing effect of cytochalasins. Using four well-characterized multidrug-resistance cell models, we have shown that both the microfilament-disrupting (phalloidine staining) and the cytotoxic (MTT-assay) activity of cytochalasins are reduced in parallel with increased P-gp expression and restorable by P-gp-modulating agents. This also applied to the cytochalasin D-mediated induction of polykaryons (microscopic evaluation) which arise as a consequence of impaired cytokinesis but unaffected karyokinesis. The reduced cellular activity of cytochalasins in P-gp-positive cell lines was correlated with decreased intracellular accumulation ([3H]cytochalasin B accumulation) which was also restorable by P-gp modulators. Moreover, the dose-dependent inhibition of P-gp photoaffinity labeling ([3H]-azidopine) suggested cytochalasins as P-gp-binding agents. In contrast, MRP overexpression had no effect on either cytochalasin microfilament activity or cytotoxicity. In conclusion, data indicate that the microfilament-destructive effects of cytochalasins are impaired due to a reduction of the intracellular cytochalasin accumulation by P-gp but not by MRP. Results are discussed with regard to P-gp as a resistance factor when cytochalasins are utilized to study microfilament dynamics, cell cycle kinetics or chromosomal damage. Moreover, the polykaryon-inducing activity of cytochalasin D is suggested as a specific indicator for a P-gp-mediated multidrug-resistance phenotype and the reversing potency of chemosensitizers.

Intrinsic MDR-1 gene and P-glycoprotein expression in human melanoma cell lines.

Metastatic malignant melanoma is considered a chemotherapy-refractory malignancy. A few previous studies have delivered contradictory results regarding the presence and functionality of P-glycoprotein (P-gp), a transmembranous protein associated with the classical multidrug resistance (cMDR), in malignant melanoma. Therefore we have investigated this issue on 33 cell lines established from primary and metastatic lesions of human malignant melanoma, comparing different cMDR detection methods. Immunocytochemically 33% of the cell lines stained positive for P-gp. The data correlated with those of a P-gp-radioimmunometric (antibody-binding) assay. When RT-PCR was used for MDR-1 mRNA determination, 76% of the melanoma cell lines scored positive. Slot-blot analysis was seen to be less sensitive than RT-PCR. Results from the functional P-gp assays, using daunomycin (DM) as MDR-substrate, showed no influence of P-gp expression on drug accumulation and cytotoxicity. However, the cMDR-modifier verapamil (VP) significantly increased both parameters in those melanoma cells with the highest P-gp levels. We conclude that cMDR is apparently not the decisive but probably a complementary protective mechanism against toxic agents in malignant melanoma.

P-glycoprotein regulates chemosensitivity in early developmental stages of the mouse.

The multidrug resistance (MDR) P-glycoprotein (P-gp) is an active transporter associated with chemoresistance of tumor cells. A fundamental aspect not yet entirely clarified is the physiological role of MDR-P-gp in normal mammalian tissues. In this paper we report that multidrug (chemo)resistance is already present in mouse oocytes and early cleavage embryos. Expression of MDR-specific P-gp is detectable by antibody (C219) staining from the primary oocyte onward to the eight-cell embryo. MDR-mRNA is demonstrated in mature oocytes using an Mdr1-specific cDNA probe. Functional activity of P-gp is shown by the efficacy of MDR reversers (verapamil or quinidine) in enhancement of: 1) drug accumulation (daunomycin) in all stages investigated, 2) drug cytotoxicity (daunomycin or mitomycin c-induced developmental impairment) in two-cell embryos cultured for 24 h, and 3) drug cytokinesis-blocking activity (cytochalasin D; our recent findings demonstrate cytochalasins to be substrates for P-gp and to indicate the presence of MDR by their microfilament-disrupting action on cycling cells) in four- and eight-cell embryos cultured for 24 h. Furthermore, functional involvement of P-gp in vivo is demonstrated. Concurrent administration of verapamil increases doxorubicin-induced developmental impairment in the zygote stage during the first cleavage cycle in pregnant females. Results provide evidence that MDR-P-gp has an efficient protective function in early reproduction.

Persistence of SCE-inducing damage in mouse embryos and fetuses following superovulation.

The frequency of sister-chromatid exchange (SCE) was analyzed in postimplantation embryos of superovulated Swiss and C57BL/6J Han mice. 12- and 16-day-old embryos, analyzed for SCE in vitro as whole embryo primary cell cultures, displayed an average increase in SCE of about 50%. Although an increased frequency of SCE cannot be used for the prediction of specific effects on the health of an individual, damage and possible repair of DNA which provide opportunities for modification of chromosomal structure and function may be present.

In vitro SCE discrepancy between embryonic and extraembryonic mouse tissues.

In vitro sister-chromatid exchange (SCE) background levels and cytokinetics were compared in embryonic (whole embryo cell suspensions) and extraembryonic (yolk sac and amnion, placenta) cells of inbred and outbred strains at various gestational stages (days 12-17). Results indicate a tissue origin (embryonal, extraembryonal) related variation in the formation of baseline SCE frequencies and cytokinetics. The significant higher SCE levels in extraembryonic tissues (maximum increase of 2 X the background values of the embryo cells) were independent of mouse strain and gestational stage. An average of 4-5 SCEs/cell in embryo cells is contrasted by 7-9 SCEs/cell in extraembryo cells. Mitotic index was generally lower and average generation time longer (by 2-3 h) in extraembryonic tissue cells. No significant differences in SCE frequencies and no changes in cytokinetics were detected at the BrdU concentrations used (1.2-4.8 micrograms/ml). The reason for the inter-tissue differences in baseline SCE is still not clear.

Abnormal development and transport and increased sister-chromatid exchange in preimplantation embryos following superovulation in mice.

Both sister-chromatid exchange (SCE) response and embryonic development and transport in preimplantation embryos were evaluated on day 3 of gestation (vaginal plug = 1) of superovulated Swiss mice. Superovulation was found to have significant effects on number of preimplantation embryos (increase), embryo localization (accelerated transport), cleavage rate (advanced development) and abnormality rate (misshaped, fragmented, dead embryos). Superovulated 4- and 8-cell embryos collected from oviducts and uteri and incubated in vitro with 5-bromodeoxyuridine (BrdU) displayed up to 4 times higher SCE frequency than spontaneously ovulated embryos. This increase is independent of stage of development and location at the time of embryo collection. The results indicate that superovulated embryos may have induced DNA lesions.