Interaction of an amphiphilic squalenoyl prodrug of gemcitabine with cellular membranes.

We have designed an amphiphilic prodrug of the anticancer agent gemcitabine (dFdC), by covalent coupling to squalene. This bioconjugate, which self-assembled into nanoparticles (NPs) in water, was previously found to display an impressive anticancer activity both in vitro and in vivo. The present study aims to investigate the impact of SQdFdC nanoparticles on cellular membranes. MTT assays showed that, in the nanomolar range, squalenoyl gemcitabine (SQdFdC) was slightly less active than dFdC on a panel of human cancer cell lines, in vitro. However, above 10 µmol L(-1) SQdFdC was considerably more cytotoxic than dFdC. Contrarily to its parent drug, SQdFdC also induced cell lysis in a few hours, as evidenced by LDH release assays. Erythrocytes were used as an experimental model insensitive to the antimetabolic activity of dFdC to further investigate the putative membrane-related cytotoxic activity of SQdFdC. The bioconjugate also induced hemolysis in a time- and dose-dependent fashion, unlike squalene or dFdC, which clearly proved that SQdFdC could permeabilize cellular membranes. Structural X-ray diffraction and calorimetry studies were conducted in order to elucidate the mechanism accounting for these observations. They confirmed that SQdFdC could be transferred from NPs to phospholipid bilayers and that the insertion of the prodrug within model membranes resulted in the formation of nonlamellar structures, which are known to promote membrane leakage. As a whole, our results suggested that due to its amphiphilic nature, the cell uptake of SQdFdC resulted in its insertion into cellular membranes, which could lead to the formation of nonlamellar structures and to membrane permeation. Whether this mechanism could be the source of toxicity in vivo, however, remains to be established, since preclinical studies have clearly proven that squalenoyl gemcitabine displayed a good toxicity profile.

Cytotoxicity and cellular uptake of newly synthesized fucoidan-coated nanoparticles.

The aim was to synthesize and characterize fucoidan-coated poly(isobutylcyanoacrylate) nanoparticles. The nanoparticles were prepared by anionic emulsion polymerization (AEP) and by redox radical emulsion polymerization (RREP) of isobutylcyanoacrylate using fucoidan as a new coating material. The nanoparticles were characterized, and their cytotoxicity was evaluated in vitro on J774 macrophage and NIH-3T3 fibroblast cell lines. Cellular uptake of labeled nanoparticles was investigated by confocal fluorescence microscopy. Results showed that both methods were suitable to prepare stable formulations of fucoidan-coated PIBCA nanoparticles. Stable dispersions of nanoparticles were obtained by AEP with up to 100% fucoidan as coating material. By the RREP method, stable suspensions of nanoparticles were obtained with only up to 25% fucoidan in a blend of polysaccharide composed of dextran and fucoidan. The zeta potential of fucoidan-coated nanoparticles was decreased depending on the percentage of fucoidan. It reached the value of -44 mV for nanoparticles prepared by AEP with 100% of fucoidan. Nanoparticles made by AEP appeared more than four times more cytotoxic (IC(50) below 2 µg/mL) on macrophages J774 than nanoparticles made by RREP (IC(50) above 9 µg/mL). In contrast, no significant difference in cytotoxicity was highlighted by incubation of the nanoparticles with a fibroblast cell line. On fibroblasts, both types of nanoparticles showed similar cytotoxicity. Confocal fluorescence microscopy observations revealed that all types of nanoparticles were taken up by both cell lines. The distribution of the fluorescence in the cells varied greatly with the type of nanoparticles.

Transmembrane diffusion of gemcitabine by a nanoparticulate squalenoyl prodrug: an original drug delivery pathway.

We have designed an amphiphilic prodrug of gemcitabine (dFdC) by its covalent coupling to a derivative of squalene, a natural lipid. The resulting bioconjugate self-assembled spontaneously in water as nanoparticles that displayed a promising in vivo anticancer activity. The aim of the present study was to provide further insight into the in vitro subcellular localization and on the metabolization pathway of the prodrug. Cells treated with radiolabelled squalenoyl gemcitabine (SQdFdC) were studied by differential detergent permeation, and microautography coupled to fluorescent immunolabeling and confocal microscopy. This revealed that the bioconjugate accumulated within cellular membranes, especially in those of the endoplasmic reticulum. Radio-chromatography analysis proved that SQdFdC delivered dFdC directly in the cell cytoplasm. Mass spectrometry studies confirmed that gemcitabine was then either converted into its biologically active triphosphate metabolite or exported from the cells through membrane transporters. To our knowledge, this is the first description of such an intracellular drug delivery pathway. In vitro cytotoxicity assays revealed that SQdFdC was more active than dFdC on a transporter-deficient human resistant leukemia model, which was explained by the subcellular distribution of the drugs and their metabolites. The squalenoylation drug delivery strategy might, therefore, dramatically improve the efficacy of gemcitabine on transporter-deficient resistant cancer in the clinical context.

Cyclodextrin complexed insulin encapsulated hydrogel microparticles: An oral delivery system for insulin.

An oral insulin delivery system based on methyl-ß-cyclodextrin (MCD) complexed insulin encapsulated polymethacrylic acid (PMAA) hydrogel microparticles was evaluated in this investigation. Poly(methacrylic acid)-chitosan-polyethylene glycol (PCP) microparticles were prepared by ionic gelation method. The insulin-MCD (IC) complex prepared was characterized by fluorescence spectroscopic and isothermal titration micro-calorimeteric (ITC) methods. MCD complexed insulin was encapsulated onto PCP microparticles by diffusion filling method. Loading and release properties of the complexed insulin from microparticles were evaluated under in vitro conditions. The effect of MCD complexation on the permeability of insulin was studied using Caco 2 cell monolayers and excised intestinal tissue with an Ussing chamber set-up. In vivo experiments were carried on streptozotocin induced diabetic rats to evaluate the efficacy of MCD complexed insulin encapsulated PCP microparticles to deliver insulin by the oral route. IC complex formation was established by fluorescence and ITC investigations. Insulin loading and release properties from the hydrogel matrix was rather unaffected by the MCD complexation. However MCD complexation was effective in enhancing insulin transport across Caco 2 cell monolayers, when applied in combination with the PMAA hydrogel system. Both insulin and MCD complexed insulin encapsulated PCP microparticles were effective in reducing blood glucose level in diabetic animal models. Cyclodextrin complexed insulin encapsulated hydrogel microparticles appear to be an interesting candidate for oral delivery of insulin.

Thermal enhancement of oxaliplatin-induced inhibition of cell proliferation and cell cycle progression in human carcinoma cell lines.

Hyperthermia is used to treat intraperitoneal colorectal carcinomatosis. In this setting, the molecular effects of oxaliplatin and hyperthermia, in combination and alone, were deciphered in ovarian and colon cancer cells. The combined antiproliferative effects of hyperthermia and oxaliplatin (Eloxatine) on human IGROV-1 ovarian carcinoma, Caco-2 and HT-29 colon carcinoma cell lines were investigated by cell viability test, cell cycle analysis and modulation of expression of cell cycle-related proteins. Oxaliplatin inhibited growth of all cell lines in a dose-dependent manner. The efficacy of the drug was markedly enhanced by concurrent exposure to mild heat shock (1 h, 42 degree C). In IGROV-1 cells, a low concentration (15 microg/ml) of oxaliplatin in combination with hyperthermia induced a transient G2/M arrest. In both colon carcinoma cell lines, a G1/S arrest with a reduction of the G0/G1 population occurred. In IGROV-1 and Caco-2 cells, growth arrest was accompanied by apoptosis as suggested by the appearance of sub-G1 population. Time-course changes of cell cycle regulatory proteins levels revealed accumulation of cyclins A and B as well as of cdc2 and cdk2 upon exposure of IGROV-1 cells to hyperthermia and oxaliplatin. In this cell line, p53 appeared to be implicated in both G2/M arrest and apoptosis. G1/S arrest of HT-29 cells was linked to up-regulation of cyclin E and p27(Kip1) and accumulation of the hypophosphorylated form of pRB, whereas in Caco-2 cells only the hyperphosphorylated form was detected as well as a down-regulation of the proto-oncogene c-myc. Taken together, the results of these in vitro studies suggest that hyperthermia and oxaliplatin might elicit antiproliferative effects by modulating the expression of cell cycle regulatory proteins through different signalling pathways.

RU49953: a non-hormonal steroid derivative that potently inhibits P-glycoprotein and reverts cellular multidrug resistance.

Progesterone and the antiprogestin RU38486 have been reported as non-transported modulators of P-glycoprotein-mediated drug efflux. However, their hormonal properties limit their potential for clinical trials. The present work shows that some derivatives from either progesterone/RU38486 or estradiol, displaying differential interaction with hormone receptors, bind to P-glycoprotein and chemosensitize the growth of MDR1-transfected cells to vinblastine more strongly than does RU38486. Structure comparison of the compounds indicates that the highly hydrophobic estradiol derivative RU49953, which does not interact with any hormone receptor, inhibits P-glycoprotein-mediated drug efflux very efficiently, as monitored by flow cytometry, and prevents drug site photoaffinity labeling by azidopine. It induces a much higher chemosensitization than the well-known P-glycoprotein modulator verapamil, which is itself more efficient than RU38486. RU49953 therefore constitutes a promising new lead for steroid-type modulators of multidrug resistance.

Tamoxifen encapsulation within polyethylene glycol-coated nanospheres. A new antiestrogen formulation.

When dealing with solid tumors in vivo, pegylated long-circulating carrier systems show, after intravenous administration, an attractive extravasation profile with an enhanced localization in the tumoral interstitium. These systems could be of help for the delivery of cancer fighting drugs, such as Tamoxifen, a well known antiestrogen used in breast cancer therapy that possesses an extended biodistribution in vivo. This work aimed at encapsulating Tamoxifen in long-circulating poly(MePEGcyanoacrylate-co-hexadecylcyanoacrylate) 1:4 nanospheres. Tamoxifen-loaded poly(MePEGcyanoacrylate-co-hexadecylcyanoacrylate) nanospheres were successfully synthesized and characterized in terms of hydrophilicity/hydrophobicity by a model made up from near infrared spectra using principal component analysis. Zeta potential, drug loading, encapsulation efficiency, as well as biological effect, in vitro release and nanospheres integrity were also investigated. Even though near infrared spectroscopy could not detect Tamoxifen, it revealed that Pluronic F68 was associated with the pegylated nanospheres. HPLC measurements demonstrated that Tamoxifen was encapsulated in the pegylated nanospheres following a partition equilibrium between the polymeric and the aqueous phases. The Tamoxifen encapsulated in the nanospheres still showed a transcription inhibitory activity in ex vivo experiments. However, zeta potential and in vitro release suggested that Tamoxifen was essentially localized at the nanoparticles surface, resulting in an important and immediate drug release.

Chromatin structure and dynamics: functional implications.

In eucaryotes, DNA packaging into nucleosomes and its organization in a chromatin fiber generate constraints for all processes involving DNA, such as DNA-replication, -repair, -recombination, and -transcription. Transient changes in chromatin structure allow overcoming these constraints with different requirements in regions where processes described above are initiated. Mechanisms involved in chromatin dynamics are complex. Multiprotein complexes which can contain histone-acetyltransferase, -deacetylase, -methyltransferase or -kinase activities are targeted by regulatory factors to precise regions of the genome. These enzymes have been shown to modify histone-tails within specific nucleosomes. Post-translational modifications of histone-tails constitute a code that is thought to contribute to the nucleosome or to the chromatin fiber remodeling, either directly, or through the recruitment of other proteins. Other multiprotein complexes, such as ATP-dependent remodeling complexes, play an essential role in chromatin fiber dynamics allowing nucleosome sliding and redistribution on the DNA. We will focus here on the chromatin structure and its consequences for DNA damaging, replication, repair, and transcription and we will discuss the mechanisms of chromatin remodeling.

Dexamethasone and triamcinolone acetonide accumulation in mouse fibroblasts is differently modulated by the immunosuppressants cyclosporin A, FK506, rapamycin and their analogues, as well as by other P-glycoprotein ligands.

In mouse fibroblasts (LMCAT cells) stably transfected with the reporter gene chloramphenicol acetyl transferase under the control of the mouse mammary tumor virus promoter (MMTV-CAT), cyclosporin A (CsA), FK506, and rapamycin (Rap) at micromolar concentrations potentiate dexamethasone- (Dex) induced CAT gene activity in a dose-dependent way (Renoir J.-M., Mercier-Bodard C., Hoffmann K., Le Bihan S., Ning Y. M., Sanchez E. R., Handschumacher R. E. and Baulieu E. E., Proc. Natl. Acad. Sci. U.S.A., 92, 1995, 4977-4981). In this work, we used LMCAT and 1471.1 cells, another mouse fibroblast cell line stably transfected with the MMTV-CAT construct, and found that exposure to immunosuppressants affected steroid-induced transcription differently. Indeed, all immunosuppressants, including inactive analogues, potentiated not only Dex- but also TA-induced CAT gene expression in LMCAT cells. The extent of this potentiation was 3 times lower for TA than for Dex. These immunosuppressants have no effect in 1471.1 cells. In addition, no difference of glucocorticosteroid affinity for the GR was observed in 1471.1 cells, in contrast to LMCAT cells. In both cell lines, the drugs tested increased [3H] Dex and [3H] TA (although to a lesser extent) accumulation. Since it is known that immunosuppressants can reverse the membrane Phospho-glycoprotein (P-gp) activity responsible for an active efflux of small hydrophobic molecules from numerous cell types, we therefore measured the relative efficiency of other P-gp ligands (including vinca alkaloids and the inactive CsA analogue, PSC833), on [3H] Dex and [3H] TA accumulation. In both cell lines, and depending on the drugs, reversal of Dex export was more pronounced than that of TA export (approximately 11 times in LMCAT and approximately 2 times in 1471.1 cells). However, the antiprogestin/antiglucocorticosteroid RU 38 486 and its 17beta derivatives RU 49 953 which does not bind to GR, both identified as strong reversal molecules of P-gp activity, had respectively, no and a strong inhibiting effect on steroid accumulation in both cell lines. These results suggest that a mechanism resembling but different from P-gp can modulate steroid entry into these mouse fibroblasts. This is confirmed by the failure to demonstrate the presence of P-gp by immunoprecipitation and Western blot experiments in membrane preparations from both cell lines. From these data, we conclude: (i) that the two synthetic GR ligands do not accumulate similarly in mouse fibroblasts, (ii) that RU 49 953 increases steroid efflux, in contrast to other agents known to reverse P-gp activity (iii) that cellular entry and export of Dex and TA can be modulated by membrane efflux mechanism(s), different from P-gp, and (iiii) that immunosuppressant potentiation of Dex- and TA-induced CAT activity involves such a mechanism in LMCAT cells. In 1471.1 cells, the lack of any enhancing effect upon steroid-induced transcription of all the drugs tested, although they all increase steroid accumulation, suggests involvement of immunosuppressant-influenced factor(s) acting downstream from steroid entry, in the hormone receptor-mediated transcription pathway(s).

Calcium/calmodulin kinase inhibitors and immunosuppressant macrolides rapamycin and FK506 inhibit progestin- and glucocorticosteroid receptor-mediated transcription in human breast cancer T47D cells.

The effects of immunosuppressants and inhibitors of specific calcium/calmodulin kinase (CaMK) of types II and IV on progestin/glucocorticosteroid-induced transcription were studied in two human stably transfected breast cancer T47D cell lines. The lines contain the chloramphenicol acetyl transferase (CAT) gene under control either of the mouse mammary tumor virus promoter (T47D-MMTV-CAT), or the minimal promoter containing five glucocorticosteroid/progestin hormone response elements [T47D-(GRE)5-CAT]. Progestin- and triamcinolone acetonide (TA)-induced CAT gene expression was inhibited in a dose-dependent manner in both lines by preincubation with rapamycin (Rap) and, to a lesser extent, with FK506, but not with cyclosporin A. CaMK II and/or IV inhibitors KN62 and KN93 also inhibited progestin- and TA-stimulated transcription in both lines. None of these drugs had any effect on basal transcription. The antagonist RU486 inhibited all the effects of both progestin and TA, suggesting that progesterone receptor (PR)-, as well as glucocorticosteroid receptor (GR)- mediated transactivation are targets of immunosuppressants and CaMKs in T47D cells. Indeed, Northern analysis showed that Rap, KN62, and, to a lesser degree, FK506 inhibited progestin stimulation of Cyclin D1 mRNA levels, but not those of the non-steroid-regulated glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene. Addition of Rap or KN62 after exposure of cells to progesterone agonist Org 2058 had no effect on induction of CAT activity. Taken together, these data indicate that Rap and FK506, as well as CaMK inhibitors, inhibit steroid-induced activities of exogenous, as well as of some endogenous, steroid receptor-regulated genes by a mechanism preceding hormone-induced receptor activation. Rap appeared to stabilize a 9S form of [3H]Org 2058-PR complexes isolated from T47D (GRE)5CAT cell nuclei. By contrast, the progesterone receptor (PR) was isolated from cells treated with KN62 as a 5S entity, undistinguishable from the 5S PR species extracted from cells treated with progestin only. The nuclear 9S-[3H]Org2058-PR resulting from cells exposed to Rap, contained, in addition to the heat shock proteins of 90 kDa and 70 kDa (hsp90 and hsp70), the FK506-binding immunophilin FKBP52 but not FKBP51, although the latter was part of unliganded PR heterocomplex associated with hsp90. These results suggest that Rap and KN62 act upon the PR by distinct mechanisms, with only Rap impeding progestin-induced PR transformation. FKBP51 appeared to dissociate from the receptor heterocomplex, but not from hsp90, after hormone binding to PR in vitro and in vivo, whether in the presence or not of Rap and KN62. Immunoprecipitation experiments distinguished two PR- and glucocorticosteroid (GR)-associated molecular chaperone complexes, containing hsp90 and hsp70 and FKBP52 or FKBP51. Another complex identified in T47D cytosol contained hsp90 and the cyclosporin A-binding cyclophilin of 40 kDa, CYP40, but not hsp70, PR, or GR. These observations support the concept that FKBP51 and FKBP52 can act as regulators of Rap and FK506 activity upon PR and GR-mediated transcription, a mechanism that could be also regulated by type II and/or type IV CaMKs.

Spironolactone, an aldosterone antagonist, acts as an antiglucocorticosteroid on the mouse mammary tumor virus promoter.

The ability of the glucocorticosteroid receptor to bind mineralocorticosteroids suggests that spironolactone, a potent aldosterone antagonist, may also interact with the glucocorticosteroid receptor, resulting in an agonist or antagonist glucocorticosteroid activity. We have investigated the effect of this drug on the activity of the glucocorticosteroid-regulated mouse mammary tumor virus (MMTV) promoter. For these studies we used the mouse fibroblast cell line 1471.1. It contains about 200 copies of a permanently established chimeric DNA construct comprising a transcription unit [MMTV long terminal repeat (LTR)] driving the reporter gene chloramphenicol acetyltransferase linked to the 69% transforming fragment of the bovine papilloma virus genome. This cell line has a high level of glucocorticosteroid receptor (1200 fmol/mg protein) and no detectable mineralocorticosteroid receptor. Competition experiments showed a binding of spironolactone to glucocorticosteroid receptor, with an affinity 50-fold lower than that of dexamethasone. In these cells, spironolactone behaves as an antiglucocorticosteroid, inhibiting in a dose-dependent fashion dexamethasone-induced chloramphenicol acetyltransferase activity, with an ED50 of 8 microM. The absence of agonist activity, even at a high concentration of this compound (10 microM), demonstrates that spironolactone is a pure antiglucocorticosteroid in this cell line. MMTV LTR DNase-I hypersensitivity studies demonstrated that spironolactone, when administered in combination with dexamethasone, inhibits formation of the hormone-induced hypersensitive site located about 160 basepairs up-stream of the MMTV cap site. Furthermore, spironolactone alone failed to induce this DNase-I-hypersensitive site, suggesting that the antagonist-receptor complex does not interact productively with MMTV LTR chromatin.

The transcriptionally-active MMTV promoter is depleted of histone H1.

We have used an ultraviolet light cross-linking and immunoadsorption assay to demonstrate that histones H1 and H2B are bound to the repressed MMTV promoter. Hormone activation results in reduced H1 content with little or no change in H2B. High resolution analysis of the glucocorticoid-inducible DNaseI hypersensitive region demonstrates an NF-1 footprint as well as specific sites of enhanced cleavage on nucleosome B and in the nucleosome B/nucleosome A linker. These results are consistent with a model in which binding of the glucocorticoid receptor to glucocorticoid regulatory elements on the surface of nucleosome B induces a chromatin transition that is necessary for transcription factor (NF-1 and TFIID) recruitment to the MMTV promoter. We hypothesize that association of histone H1 with important cis-elements on the promoter masks these sites, and glucocorticoid-induced displacement of H1 is necessary to expose factor binding sites at the 3' edge of nucleosome B, in the nucleosome B/nucleosome A linker and at the 5' edge of nucleosome A.

Chromatin structure of hormono-dependent promoters.

Transient transfections of mutated MMTV LTRs, driving the luciferase reporter gene, have shown the presence of at least one cis-acting element cooperating with the GREs. Studies of the chromatin structure of two glucocorticoid-regulated promoters, the mouse mammary tumor virus (MMTV) long terminal repeat (LTR), a retroviral promoter, and the rat tyrosine aminotransferase (TAT) promoter, demonstrate that both DNAs are organized into precisely positioned nucleosomes. Hormonal activation of transcription is accompanied by structural changes of one (MMTV LTR) or two (TAT promoter) nucleosomes associated with the hormone-response elements (HREs). These changes can be visualized by the appearance of DNasel hypersensitive sites. Association of the hormone-receptor complex with the nucleus is necessary to induce the DNasel hypersensitive site and to maintain transcription, but is not necessary to maintain DNasel hypersensitivity. Anti-hormones, even when able to promote a strong binding of the receptor to the nucleus, are unable to induce the chromatin structural change. Using cell lines containing approx. 200 copies of a MMTV LTR/Hv-ras chimeric construct, we have demonstrated a strong, hormono-independent nuclear matrix interaction of sequences located just upstream and downstream of the ras coding sequences.

Role of chromatin structure in transcriptional regulation of MMTV LTR hormone-dependent promoter.

Studies of chromatin structure were performed in mouse fibroblast cell lines containing Bovine Papilloma Virus (BPV) based artificial minichromosomes containing Mouse Mammary Tumor Virus (MMTV) Long Terminal Repeat (LTR), a retroviral promoter regulated by glucocorticoids, driving the transcription of v-Ha-ras. These minichromosomes fractionate with the "active chromatin", indicating an association of the minichromosomes with components of the "nuclear matrix". Two regions of the minichromosomes upstream and downstream of v-Ha-ras are involved in this interaction. MMTV LTR promoter is associated with nucleosomes precisely positioned on the DNA sequences. Hormonal activation is accompanied by a structural change of the nucleosome associated with the hormone response elements (HREs). This structural change can be visualized by the appearance of a hormono-dependent DNaseI hypersensitive site. Anti-hormones, even when able to promote a strong binding of the receptor to the nucleus, are unable to induce the chromatin structural change. The strong association of the hormone-receptor complex with the nucleus is necessary to induce the DNaseI hypersensitive site and to maintain the transcription, but is not necessary for DNaseI hypersensitivity maintenance. This suggests a double role for the hormone-receptor complex: 1) induction of a chromatin rearrangement and 2) transcriptional transactivation.