A new human breast carcinoma cell line resistant to DNA-damaging drugs

To investigate the phenomenon of active dissociation of the vital dye, Hoechst 33342 (Ho342), from DNA (DNA clearing), a new MCF7HoeR-7 human breast carcinoma cell line was isolated from parent MCF7 cells by step-wise selection with increasing concentrations of Ho342. This cell line possesses an enhanced ability for DNA clearing. The MCF7HoeR-7 line is characterised in detail and compared with the parental MCF7 line and a typical P-glycoprotein-mediated multidrug resistant (MDR) cell line, MCF7/Adr. MCF7HoeR-7 cells have an increased population growth rate, a lower DNA content and a reduced number of chromosomes. Enhanced DNA clearing in MCF7HoeR-7 cells is associated with the high resistance of the cells to the toxic effects of Ho342 and cross-resistance to etoposide, a topoisomerase II inhibitor in clinical use. The MCF7HoeR-7 and parent MCF7 cell lines have similar expression levels of transport proteins. The results obtained confirm that DNA clearing is an atypical MDR mechanism in tumour cells.     

Lactaptin Induces p53-Independent Cell Death Associated with Features of Apoptosis and Autophagy and Delays Growth of Breast Cancer Cells in Mouse Xenografts

Lactaptin, the proteolytic fragment of human milk kappa-casein, induces the death of various cultured cancer cells. The mechanisms leading to cell death after lactaptin treatment have not been well characterized. In this study the in vivo and in vitro effects of a recombinant analogue of lactaptin (RL2) were examined. Following treatment with the recombinant analogue of lactaptin strong caspase -3, -7 activation was detected. As a consequence of caspase activation we observed the appearance of a sub-G1 population of cells with subdiploid DNA content. Dynamic changes in the mRNA and protein levels of apoptosis-related genes were estimated. No statistically reliable differences in p53 mRNA level or protein level were found between control and RL2-treated cells. We observed that RL2 constitutively suppressed bcl-2 mRNA expression and down regulated Bcl-2 protein expression in MDA-MB-231 cells. We demonstrated that RL2 penetrates cancer and non-transformed cells. Identification of the cellular targets of the lactaptin analogue revealed that α/β-tubulin and α-actinin-1 were RL2-bound proteins. As the alteration in cellular viability in response to protein stimulus can be realized not only by way of apoptosis but also by autophagy, we examined the implications of autophagy in RL2-dependent cell death. We also found that RL2 treatment induces LC3-processing, which is a hallmark of autophagy. The autophagy inhibitor chloroquine enhanced RL2 cytotoxicity to MDA-MB-231 cells, indicating the pro-survival effect of RL2-dependent autophagy. The antitumour potential of RL2 was investigated in vivo in mouse xenografts bearing MDA-MB-231 cells. We demonstrated that the recombinant analogue of lactaptin significantly suppressed the growth of solid tumours. Our results indicate that lactaptin could be a new molecule for the development of anticancer drugs.     

Flavonoid–membrane interactions: Involvement of flavonoid–metal complexes in raft signaling

Flavonoids are polyphenolic compounds produced by plants and delivered to the human body through food. Although the epidemiological analyses of large human populations did not reveal a simple correlation between flavonoid consumption and health, laboratory investigations and clinical trials clearly demonstrate the effectiveness of flavonoids in the prevention of cardiovascular, carcinogenic, neurodegenerative and immune diseases, as well as other diseases. At present, the abilities of flavonoids in the regulation of cell metabolism, gene expression, and protection against oxidative stress are well-known, although certain biophysical aspects of their functioning are not yet clear. Most flavonoids are poorly soluble in water and, similar to lipophilic compounds, have a tendency to accumulate in biological membranes, particularly in lipid rafts, where they can interact with different receptors and signal transducers and influence their functioning through modulation of the lipid-phase behavior. In this study, we discuss the enhancement in the lipophilicity and antioxidative activity of flavonoids after their complexation with transient metal cations. We hypothesize that flavonoid–metal complexes are involved in the formation of molecular assemblies due to the facilitation of membrane adhesion and fusion, protein–protein and protein–membrane binding, and other processes responsible for the regulation of cell metabolism and protection against environmental hazards.     

A novel endonuclease IV post-PCR genotyping system

Here we describe a novel endonuclease IV (Endo IV) based assay utilizing a substrate that mimics the abasic lesions that normally occur in double-stranded DNA. The three component substrate is characterized by single-stranded DNA target, an oligonucleotide probe, separated from a helper oligonucleotide by a one base gap. The oligonucleotide probe contains a non-fluorescent quencher at the 5′ end and fluorophore attached to the 3′ end through a special rigid linker. Fluorescence of the oligonucleotide probe is efficiently quenched by the interaction of terminal dye and quencher when not hybridized. Upon hybridization of the oligonucleotide probe and helper probe to their complementary target, the phosphodiester linkage between the rigid linker and the 3′ end of the probe is efficiently cleaved, generating a fluorescent signal. In this study, the use of the Endo IV assay as a post-PCR amplification detection system is demonstrated. High sensitivity and specificity are illustrated using single nucleotide polymorphism detection.     

Saccharides of seven Pseudomonas aeruginosa immunotypes

Abstract The structures of O-specific polysaccharides obtained by mild acid degredation of lipopolysaccharides (LPS) from seven Pseudomonas aeruginosa Fisher's immunotypes have been studied. The polysaccharides consist mainly of monoamino and diamino sugars, frequently also carrying acidic functions. Some of the sugars were detected in nature for the O-specific polysaccharides of the immunotypes 2, 3, 4, 5 and 6 are identical to those of the polysaccharides of the 011; 0(2a)2c; 01; 010a, 10b and 07a, 7d Lányi-Bergan serological subgroups respectively, whereas no analogues have been found for the immunotypes 1 and 7. Some cross-reactions between the LPS of different immunotypes were observed in passive haemagglutination tests; the results of inhibition of passive haemagglutination and agar gel immunoprecipitation point, however, to a specificity of the LPS. Many of the LPS of the seven Pseudomonas aeruginosa immunotypes manifest rather a high cross-protective activity in active immunization tests in mice. The nature of the cross-protective activity of the LPS is discussed.     

Relationship of DNA damage and embryotoxicity induced by 4-hydroperoxydechlorocyclophosphamide in postimplantation rat embryos

4-Hydroperoxydechlorocyclophosphamide (4-OOHdeCl-CP) is a preactivated analogue of cyclophosphamide (CP) that undergoes an elimination reaction to yield acrolein and the nonalkylating derivative of phosphoramide mustard (PM), i.e., dechlorophosphoramide mustard. We used this analogue to assess the role of acrolein in CP-induced embryotoxicity. Embryotoxicity was assessed using day 10 rat embryos cultured in vitro. 4-OOHdeC1-CP was embryotoxic over a concentration range of approximately 75-150 microM and produced complete embryolethality at concentrations of 175 microM and above. This analogue induced abnormal development characterized by tail defects at low drug concentrations and microencephaly or prosencephalic hypoplasia at high concentrations. Using the technique of alkaline elution, we also assessed DNA damage induced by embryotoxic concentrations of drug. When embryos were cultured in serum-containing medium during drug exposure, no DNA damage was detected, even at embryolethal drug concentrations. However, if cellular glutathione (GSH) was depleted with buthionine sulfoximine (BSO) before drug exposure and embryos were cultured in serum-free medium during drug exposure, DNA damage, primarily DNA single-strand breaks, was detected, but only at embryolethal concentrations. Using radiolabeled CP, we showed that acrolein does reach the embryo; however, more acrolein is incorporated into the yolk sac. Binding studies revealed that acrolein binds preferentially to cellular protein, whereas PM binds preferentially to DNA. These results suggest that, unlike the case with PM, the embryotoxic target for acrolein is protein and not DNA. Furthermore, our results indicate that acrolein may mediate its effects on the embryo via the yolk sac.     

Embryotoxicity of the intercalating agents m-AMSA and o-AMSA and the epipodophyllotoxin VP-16 in postimplantation rat embryos in vitro

The intercalating agent, m-AMSA, and the epipodophyllotoxin, VP-16, both topoisomerase II-reactive anticancer agents, are also embryotoxic agents in rat embryos cultured in vitro. Quantifying the embryotoxic effects of these drugs revealed that the no observed adverse effect level (NOAEL) for m-AMSA is 10 nM, the embryotoxic concentration range is 50-500 nM, and complete lethality is observed at 1 microM. In contrast, the NOAEL for o-AMSA, an inactive isomer of m-AMSA, is 1.0 microM, the embryotoxic concentration range is 10-100 microM, and complete lethality occurs at 200 microM. Based upon the concentrations of drugs required to produce 50% embryotoxicity or 50% malformed embryos, m-AMSA exhibits a 200-500-fold-higher embryotoxicity compared to o-AMSA. VP-16 exhibits a NOAEL of 1.0 microM, an embryotoxic concentration range of 2-5 microM, and complete lethality at 10 microM. Compared to m-AMSA, VP-16 is approximately 10-fold less embryotoxic. At appropriate concentrations, all three drugs were dysmorphogenic resulting in embryos that were characterized by hypoplasia of the prosencephalon with associated microopthalmia and dilation of the rhombencephalon. and dilation of the rhombencephalon. As a prelude to future studies focusing on the mechanism of drug-induced embryotoxicity, we have used established biochemical and immunologic methods to identify and quantify topoisomerase II in rat embryos. In addition, we have demonstrated that the embryo topoisomerase II can be inhibited by both m-AMSA and VP-16. Finally, we have used a human cDNA probe to detect topoisomerase II mRNA in the rat embryo. Thus, the combination of the in vitro whole embryo culture and these biochemical/molecular assays should allow us to explore the role of a specific nuclear target, i.e., topoisomerase II, in the teratogenic effects of some commonly employed chemotherapeutic agents.     

Role of 2-oxoglutarate dehydrogenase in brain pathologies involving glutamate neurotoxicity

Decreased activity of the mitochondrial thiamin-dependent 2-oxoglutarate dehydrogenase complex (OGDHC) is associated with a number of inborn and acquired neuropathologies. We hypothesized that perturbation in flux through the complex influences brain development and function, in particular, because the OGDHC reaction is linked to the synthesis/degradation of neurotransmitters glutamate and GABA. Developmental impact of this metabolic knot was studied by characterizing the brain OGDHC activity in offspring of rats exposed to acute hypobaric hypoxia at a critical organogenesis period of pregnancy. In this model, we detected the hypoxia-induced changes in the brain OGDHC activity and in certain physiologic and morphometric parameters. The changes were mostly abrogated by application of specific effector of cellular OGDHC, the phosphonate analog of 2-oxoglutarate (succinyl phosphonate), shortly before hypoxia. The glutamate excitotoxicity known to greatly contribute to hypoxic damage was alleviated by succinyl phosphonate in situ. That is, the delayed calcium deregulation, mitochondrial depolarization and reactive oxygen species (ROS) production became less pronounced in cultivated neurons loaded with succinyl phosphonate. In vitro, succinyl phosphonate protected OGDHC from the catalysis-induced inactivation. Thus, the protective effects of the phosphonate upon hypoxic insult in vivo may result from the preservation of mitochondrial function and Ca²⁺ homeostasis due to the phosphonate inhibition of both the OGDHC-dependent ROS production and associated OGDHC inactivation. As a result, we showed for the first time that the hypoxia- and glutamate-induced cerebral damage is linked to the function of OGDHC, introducing the phosphonate analogs of 2-oxoglutarate as promising diagnostic tools to reveal the role of OGDHC in brain function and development.