AS1411 derivatives as carriers of G-quadruplex ligands for cervical cancer cells.

Nucleic acid aptamers can specifically bind to target molecules on the cell membrane that mediate their entrance into the cells. Their small size, high binding affinity, specificity, good biocompatibility, stability and low immunogenicity make them ideal drug delivery systems for cancer therapy. These biopharmaceuticals have potential for the delivery of anticancer compounds to diseased tissues, increasing their effectiveness while mitigating the off-target toxicity towards healthy cells. Herein, we have studied two quadruplex-forming DNA sequences derived from the nucleolin-targeted aptamer AS1411 as supramolecular carriers for the cancer-selective delivery of acridine orange derivatives (C3, C5 and C8) in cervical cancer cells. The devised delivery strategy relied on the non-covalent association of the acridine derivatives and the G-quadruplex (G4) structures. This association is done with a high binding strength, as suggested by the obtained KD values in the 10-6-10-7 M range, leading to the thermal stabilization of the G4 structures, particularly for C8. The stability of the resulting supramolecular conjugates was evaluated in fetal bovine serum, which proved their resistance against serum nucleases up to 48 h. Previous studies showed that the tested acridine orange derivatives were cytotoxic towards cervical cancer cells (HeLa) and non-malignant cells. However, when conjugated to AS1411 derivatives, the cytotoxicity of the free ligands towards non-malignant cells was restrained. Furthermore, conjugated C3 showed an enhanced cytotoxicity against HeLa cancer cells. Confocal microscopy indicated that both G4 sequences appear to colocalize with nucleolin, suggesting their ability to recognize and bind nucleolin on the cell surface. Additionally, the results confirmed the internalization of these delivery systems into HeLa cancer cells and their sustained cell trafficking, although being able to dissociate intracellularly to deliver C8 to the nucleoli. Overall, we showed that AS1411-derived G4s can be used as a potential cancer drug delivery system for cervical cancer.

Supramolecular zippers elicit interbilayer adhesion of membranes producing cell death.

BACKGROUND: The fluorescent dye 10-N-nonyl acridine orange (NAO) is widely used as a mitochondrial marker. NAO was reported to have cytotoxic effects in cultured eukaryotic cells when incubated at high concentrations. Although the biochemical response of NAO-induced toxicity has been well identified, the underlying molecular mechanism has not yet been explored in detail. METHODS: We use optical techniques, including fluorescence confocal microscopy and lifetime imaging microscopy (FLIM) both in model membranes built up as giant unilamellar vesicles (GUVs) and cultured cells. These experiments are complemented with computational studies to unravel the molecular mechanism that makes NAO cytotoxic. RESULTS: We have obtained direct evidence that NAO promotes strong membrane adhesion of negatively charged vesicles. The attractive forces are derived from van der Waals interactions between anti-parallel H-dimers of NAO molecules from opposing bilayers. Semi-empirical calculations have confirmed the supramolecular scenario by which anti-parallel NAO molecules form a zipper of bonds at the contact region. The membrane remodeling effect of NAO, as well as the formation of H-dimers, was also confirmed in cultured fibroblasts, as shown by the ultrastructure alteration of the mitochondrial cristae. CONCLUSIONS: We conclude that membrane adhesion induced by NAO stacking accounts for the supramolecular basis of its cytotoxicity. GENERAL SIGNIFICANCE: Mitochondria are a potential target for cancer and gene therapies. The alteration of the mitochondrial structure by membrane remodeling agents able to form supramolecular assemblies via adhesion properties could be envisaged as a new therapeutic strategy.

Evaluation of Acridine Orange Derivatives as DNA-Targeted Radiopharmaceuticals for Auger Therapy: Influence of the Radionuclide and Distance to DNA.

A new family of 99mTc(I)- tricarbonyl complexes and 125I-heteroaromatic compounds bearing an acridine orange (AO) DNA targeting unit was evaluated for Auger therapy. Characterization of the DNA interaction, performed with the non-radioactive Re and 127I congeners, confirmed that all compounds act as DNA intercalators. Both classes of compounds induce double strand breaks (DSB) in plasmid DNA but the extent of DNA damage is strongly dependent on the linker between the Auger emitter (99mTc or 125I) and the AO moiety. The in vitro evaluation was complemented with molecular docking studies and Monte Carlo simulations of the energy deposited at the nanometric scale, which corroborated the experimental data. Two of the tested compounds, 125I-C5 and 99mTc-C3, place the corresponding radionuclide at similar distances to DNA and produce comparable DSB yields in plasmid and cellular DNA. These results provide the first evidence that 99mTc can induce DNA damage with similar efficiency to that of 125I, when both are positioned at comparable distances to the double helix. Furthermore, the high nuclear retention of 99mTc-C3 in tumoral cells suggests that 99mTc-labelled AO derivatives are more promising for the design of Auger-emitting radiopharmaceuticals than the 125I-labelled congeners.

A Versatile Cell Death Screening Assay Using Dye-Stained Cells and Multivariate Image Analysis.

A novel dye-based method for measuring cell death in image-based screens is presented. Unlike conventional high- and medium-throughput cell death assays that measure only one form of cell death accurately, using multivariate analysis of micrographs of cells stained with the inexpensive mix, red dye nonyl acridine orange, and a nuclear stain, it was possible to quantify cell death induced by a variety of different agonists even without a positive control. Surprisingly, using a single known cytotoxic agent as a positive control for training a multivariate classifier allowed accurate quantification of cytotoxicity for mechanistically unrelated compounds enabling generation of dose-response curves. Comparison with low throughput biochemical methods suggested that cell death was accurately distinguished from cell stress induced by low concentrations of the bioactive compounds Tunicamycin and Brefeldin A. High-throughput image-based format analyses of more than 300 kinase inhibitors correctly identified 11 as cytotoxic with only 1 false positive. The simplicity and robustness of this dye-based assay makes it particularly suited to live cell screening for toxic compounds.

Observations on the viability of C6-glioma cells after sonoporation with low-intensity ultrasound and microbubbles.

Ultrasound (US) and microbubbles can be used to facilitate cellular uptake of drugs through a cavitationinduced enhancement of cell membrane permeability. The mechanism is, however, still incompletely understood. A direct contact between microbubbles and cell membrane is thought to be essential to create membrane perturbations lasting from seconds to minutes after US exposure of the cells. A recent study showed that the effect may even last up to 8 h after cavitation (with residual permeability up to 24 h after cavitation). In view of possible membrane damage, the purpose of this study was to further investigate the evolution of cell viability in the range of the 24-h temporal window. Furthermore, a description of the functional changes in tumor cells after US exposure was initiated to obtain a better understanding of the mechanism of membrane perturbation after sonication with microbubbles. Our results suggest that US does not reduce cell viability up to 24 h post-exposure. However, a perturbation of the entire cell population exposed to US was observed in terms of enzymatic activity and characteristics of the mitochondrial membrane. Furthermore, we demonstrated that US cavitation induces a transient loss of cell membrane asymmetry, resulting in phosphatidylserine exposure in the outer leaflet of the cell membrane.

Targeting of mitochondria by 10-N-alkyl acridine orange analogues: role of alkyl chain length in determining cellular uptake and localization.

10-N-Nonyl acridine orange (NAO) is used as a mitochondrial probe because of its high affinity for cardiolipin (CL). Targeting of NAO may also depend on mitochondrial membrane potential. As the nonyl group has been considered essential for targeting, a systematic study of alkyl chain length was undertaken; three analogues (10-methyl-, 10-hexyl-, and 10-hexadecyl-acridine orange) were synthesized and their properties studied in phospholipid monolayers and breast cancer cells. The shortest and longest alkyl chains reduced targeting, whereas the hexyl group was superior to the nonyl group, allowing very clear and specific targeting to mitochondria at concentrations of 20-100 nM, where no evidence of toxicity was apparent. Additional studies in wild-type and cardiolipin-deficient yeast cells suggested that cellular binding was not absolutely dependent upon cardiolipin.

Analysis of mitochondrial activity related to cell death after PDT with AlPCS(4).

OBJECTIVE: The aim of this study was to report that photodynamic therapy (PDT) with mitochondria-associated chloroaluminum phthalocyanine tetrasulfonate (AlPcS(4)) leads to significant alterations in this organelle. BACKGROUND DATA: PDT is a viable treatment modality for a variety of tumors, as well as for some non-oncologic diseases. The procedure submits cells or tissue to a photosensitizing drug followed by light irradiation of appropriate wavelength, usually in the red area or close to infrared, and compatible with the drug absorption spectrum, inducing the apoptotic process. However, the precise mechanism of PDT-induced apoptosis is not well characterized. Several cellular organelles can be postulated as the target for PDT with different photosensitizers such as plasmatic membrane, nucleus, mitochondria, endoplasmic reticulum, Golgi complex, and others. The mitochondrion is the main target in PDT because it is the main organelle involved in apoptosis. One of the main agents is cytochrome c, a proapoptotic factor that preferentially links itself to the mitochondrial cardiolipin. METHODS: The photosensitizing effects of AlPcS(4) were studied in the mitochondria. Cells were irradiated with a diode laser (670 nm, energy density of 4.5 J/cm(2), and power density of 45 mW/cm(2)). RESULTS: The fluorescent analyses of the mitochondria were performed with MitoTracker and nonyl acridine orange (NAO), and electron microscopy demonstrated that PDT with AlPcS(4) leads to significant alterations in mitochondria, causing membrane potential loss, alteration in cardiolipin distribution and cell death. CONCLUSION: The labels with Mitotracker and NAO demonstrated mitochondrial migration to the perinuclear region, confirmed through electron microscopy, suggesting that intact mitochondria were solicited for possible DNA fragmentation.

Analysis of mitochondria isolated from single cells.

Bulk studies are not suitable to describe and study cell-to-cell variation, which is of high importance in biological processes such as embryogenesis, tissue differentiation, and disease. Previously, capillary electrophoresis with laser-induced fluorescence detection (CE-LIF) was used to measure the properties of organelles isolated from millions of cells. As such, these bulk measurements reported average properties for the organelles of cell populations. Similar measurements for organelles released from single cells would be highly relevant to describe the subcellular variations among cells. Toward this goal, here we introduce an approach to analyze the mitochondria released from single mammalian cells. Osteosarcoma 143B cells are labeled with either the fluorescent mitochondrion-specific 10-N-nonyl acridine orange (NAO) or via expression of the fluorescent protein DsRed2. Subsequently, a single cell is introduced into the CE-LIF capillary where the organelles are released by a combined treatment of digitonin and trypsin. After this treatment, an electric field is applied and the released organelles electromigrate toward the LIF detector. From an electropherogram, the number of detected events per cell, their individual electrophoretic mobilities, and their individual fluorescence intensities are calculated. The results obtained from DsRed2 labeling, which is retained in intact mitochondria, and NAO labeling, which labels all mitochondria, are the basis for discussion of the strengths and limitations of this single-cell approach.

Fluorescence resonance energy transfer reveals a binding site of a photosensitizer for photodynamic therapy.

Phthalocyanine (Pc) 4, like many photosensitizers for photodynamic therapy (PDT), localizes to intracellular membranes, especially mitochondria. Pc 4-PDT photodamages Bcl-2 and Bcl-xL, antiapoptotic proteins interacting with the permeability transition pore complex that forms at contact sites between the inner and outer mitochondrial membranes. These complexes and the inner membrane are unique in containing the phospholipid cardiolipin. Nonyl-acridine orange (NAO) is a specific probe of cardiolipin. Here we show evidence for fluorescence resonance energy transfer from NAO to Pc 4, defining a binding site for the photosensitizer. This observation establishes an innovative tool for exploring the localization of other photosensitizers and additional fluorescent, mitochondrion-localizing drugs having appropriate spectral properties.

Impact of proliferative activity and tumorigenic conversion on mitochondrial function of fibroblasts in 2D and 3D culture.

The purpose of the present study was to examine mitochondrial function in differently transformed cells relative to their tumorigenic state and proliferative activity in vitro. An established two-step carcinogenesis model consisting of immortal and tumorigenic rat embryo fibroblasts that can be cultured as monolayers and multicellular spheroids was investigated. Flow cytometric measurements were carried out using the two mitochondrial-specific fluorochromes rhodamine 123 (Rh123) and 10-N-nonyl acridine orange (NAO), in combination with the DNA dye Hoechst 33342 for simultaneous cell cycle analysis. Since the accumulation of Rh123 depends on mitochondrial membrane potential, Rh123 fluorescence intensity gives an estimate of mitochondrial activity per cell, as determined by both overall mitochondrial function and mass. In contrast, NAO uptake reflects mitochondrial mass only, as it binds to cardiolipin in the inner mitochondrial membrane independently of membrane potential. Aliquots of cell suspensions derived from exponential monolayer, confluent monolayer, and a range of sizes of multicellular spheroids were stained with either Rh123 or NAO and Hoechst 33342, then mitochondrial mass and activity per unit cell volume and cellular DNA content were measured by flow cytometry. Differences in the average mitochondrial activity per cell in different cell lines and culture conditions were primarily due to alterations in cell volume. Importantly, tumorigenic conversion by ras-transfection did not consistently change mitochondrial activity per unit cell volume. The mitochondrial mass per unit cell volume increased for all cells when cellular quiescence was induced, either in monolayers or spheroids. However, mitochondrial function (activity/mass) decreased when cells became quiescent, resulting in a positive correlation between mitochondrial function and S-phase fraction, independent of transformation status or culture condition. We conclude that mitochondrial function reflects proliferative activity rather than tumorigenic conversion.

Lack of mitochondrial anionic phospholipids causes an inhibition of translation of protein components of the electron transport chain. A yeast genetic model system for the study of anionic phospholipid function in mitochondria.

Reduction of mitochondrial cardiolipin (CL) levels has been postulated to compromise directly the function of several essential enzymes and processes of the mitochondria. There is limited genetic evidence for the critical roles with which CL and its precursor phosphatidylglycerol (PG) have been associated. A null allele of the PGS1 gene from Saccharomyces cerevisiae, which encodes the enzyme responsible for the synthesis of the CL precursor PG phosphate, was created in a yeast strain in which PGS1 expression is exogenously regulated by doxycycline. The addition of increasing concentrations of doxycycline to the growth medium causes a proportional decrease to undetectable levels of PGS1 transcript, PG phosphate synthase activity, and PG plus CL. The doubling time of this strain with increasing doxycycline increases to senescence in non-fermentable carbon sources or at high temperatures, conditions that do not support growth of the pgs1Delta strain. Doxycycline addition also causes mitochondrial abnormalities as observed by fluorescence microscopy. Products of four mitochondrial encoded genes (COX1, COX2, COX3, and COB) and one nuclear encoded gene (COX4) associated with the mitochondrial inner membrane are not present when PGS1 expression is fully repressed. No translation of these proteins can be detected in cells lacking the PGS1 gene product, although transcription and splicing appear unaffected. Protein import of other nuclear encoded proteins remains unaffected. The remaining proteins encoded by mitochondrial DNA are expressed and translated normally. Thus, the molecular basis for the lack of mitochondrial function in pgs1Delta cells is the failure to translate gene products essential to the electron transport chain.

Mitochondrial phospholipid hydroperoxide glutathione peroxidase inhibits the release of cytochrome c from mitochondria by suppressing the peroxidation of cardiolipin in hypoglycaemia-induced apoptosis.

Cytochrome c (cyt. c) is a proapoptotic factor that binds preferentially to cardiolipin (CL), a mitochondrial lipid, but not to cardiolipin hydroperoxide (CL-OOH). Cyt. c that had bound to CL liposomes was liberated on peroxidation of the liposomes by a radical. The generation of CL-OOH in mitochondria occurred before the release of cyt. c in rat basophile leukaemia (RBL)2H3 cells that had been induced to undergo apoptosis by exposure to hypoglycaemia with 2-deoxyglucose (2DG). The amount of cyt. c bound to CL prepared from the mitochondria of 2DG-treated cells was lower than that of untreated cells. The release of cyt. c was completely suppressed when the production of CL-OOH in mitochondria was inhibited by the overexpression of mitochondrial phospholipid hydroperoxide glutathione peroxidase (PHGPx). The fluorescence from CL-labelling dye (10-N-nonyl Acridine Orange) decreased on the induction of apoptosis by 2DG. However, no decrease in fluorescence was observed in PHGPx-overexpressing cells. Cyt. c was released from mitochondria that had been isolated from control cells on peroxidation by t-butylhydroperoxide, but no similar liberation of cyt. c from mitochondria isolated from mitochondrial PHGPx-overexpressing cells was observed. These findings suggest that the generation of CL-OOH in mitochondria might be a primary event that triggers the release of cyt. c from mitochondria in the apoptotic process in which mitochondrial PHGPx participates as an anti-apoptotic factor by preventing the formation of CL-OOH.

Changes in intramitochondrial cardiolipin distribution in apoptosis-resistant HCW-2 cells, derived from the human promyelocytic leukemia HL-60.

Using a cytofluorimetric approach, we studied intramitochondrial cardiolipin (CL) distribution in HCW-2 cells, an apoptosis-resistant clone of human HL-60 cells. In HL-60, about 50% of total CL is distributed in the outer leaflet of mitochondrial inner membrane, while in HCW-2 a significantly higher amount of CL (about 65%) is in that site. In basal conditions, HSW-2 cells also show a reduced mitochondrial membrane potential even if they are able to proliferate as the parental line. Taking into account the complex functions that CL plays in the regulation of mitochondrial activity, it is likely that HCW-2 could produce ATP utilizing more glycolytic pathways rather than mitochondrial respiratory chain.

Mitochondrial function in oncogene-transfected rat fibroblasts isolated from multicellular spheroids.

Two mitochondrion-specific fluorochromes, 10-N-nonyl acridine orange (NAO) and rhodamine 123 (Rh123), were used to determine the mechanism responsible for alterations in energy metabolism of transformed rat embryo fibroblast cells isolated from different locations within multicellular spheroids. Accumulation of Rh123 depends on intact mitochondrial membrane potential, whereas NAO is taken up by mitochondria independently of their function and thus represents mitochondrial distribution only. A reproducible selective dissociation procedure was used to isolate cells from different locations within the spheroids. After isolation, cells were simultaneously stained with one mitochondrial stain and the DNA dye Hoechst 33342, and several parameters, including cell volume, were monitored via multilaser-multiparameter flow cytometry. Our data clearly show a decrease in the uptake of Rh123 in cells from the periphery to the inner regions of the tumor spheroids, reflecting a persistent alteration in mitochondrial function. However, NAO staining experiments showed no reduction in the total mitochondrial mass per unit cell volume. Because cells were exposed to stain under uniform conditions after isolation from the spheroid, these data indicate the downregulation of mitochondrial function is associated with cell quiescence rather than a transient effect of reduced nutrient availability. This result, which is in accordance with data from two other cell lines (EMT6 and 9L), might reflect a general phenomenon in multicellular spheroids, supporting the hypothesis that quiescent cells in the innermost viable spheroid layer stably reduce their mitochondrial function, presumably to compensate for lower nutrient supply and/or decreased energy demand.

Changes of mitochondrial mass in the hemopoietic stem cell line FDCP-mix after treatment with etoposide: a correlative study by multiparameter flow cytometry and confocal and electron microscopy.

FDCP-Mix, a pluripotent murine hemopoietic stem cell line which undergoes typical internucleosomal cleavage of DNA when induced to apoptosis by either drugs or withdrawal of growth factor (interleukin-3) was studied after treatment with the topoisomerase II inhibitor etoposide (0.5-4 microM). An increase in autolytic activity was the major early morphological change within the cytoplasm, with mitochondria as the main target for autolytic digestion. Despite this macroautophagy, thin sections showed a high number of mitochondria, suggesting mitochondrial proliferation as a result of drug treatment. This observation of an increase in the number of mitochondria was confirmed by flow cytometric studies of mitochondrial overall mass. Multiparameter flow cytometry of cells double stained with propidium iodide and nonyl-acridine orange gave an accurate assay for mitochondrial mass in relation to cell cycle stages. The increase in mitochondrial mass was found in all cell cycle stages. The results suggest a drug-induced proliferation of mitochondria separate from the processes involved in the doubling of mitochondrial mass during the cell cycle and a decline of mitochondria in the later stages of apoptosis.

The impairment of mitochondrial membrane potential and mass in proliferating lymphocytes from vitamin E deficient animals is recovered by glutathione.

The time-dependent changes of mitochondrial membrane potential and mass have been investigated on splenocytes from control and vit. E deficient rats, stimulated to proliferate with Concanavalin A, in the presence and absence of reduced glutathione (GSH, 5 mM). Rhodamine-123 (Rh-123) and nonyl acridine orange (NAO) were used as specific probes to monitor the membrane potential and mass of mitochondria, respectively, by means of flow cytometry. Rh-123 uptake was high in an increasing number of cells from normally fed animals during the three-day culture period. On the contrary, splenocytes from vitamin E deficient rats showed a biphasic pattern. The number of cells showing a high uptake of Rh-123 increased after 24 hrs. from mitogenic stimulation, then it decreased at the other two time points considered. In parallel, a continuous increase of the number of cells with depolarized organelles (up to 60% by 72 hrs.) has been observed in vit. E deficiency. This impairment was fully prevented by GSH supplementation to the culture medium. In the presence of the thiol, about 80-85% of cells showed activated mitochondria, whereas the number of splenocytes with depolarized organelles did not exceed 17%, irrespective of the diet applied to the animals. The same pattern was observed considering the changes of mitochondrial mass, measured using NAO as a probe. Present results support that GSH may substitute vitamin E in protecting mitochondria from peroxidative damage.

Direct analysis and significance of cardiolipin transverse distribution in mitochondrial inner membranes.

The distribution of cardiolipin across the inner mitochondrial membrane was directly determined by using the ability of the fluorescent dye 10-N-nonyl-3,6-bis(dimethylamino)acridine (10-N-nonyl acridine orange) to form dimers when it interacts with the diacidic phospholipid. Two independent methods were employed: (a) a spectrophotometric measurement of 10-N-nonyl acridine orange binding to isolated rat liver mitochondria, mitoplasts and inside-out submitochondrial particles, and (b) a flow-cytometric analysis of specific red fluorescence, emitted when two dye molecules are bound to one membrane cardiolipin; the stoichiometry of 10-N-nonyl acridine orange binding to phosphatidylserine and phosphatidylinositol, 1 mol dye/mol phospholipid, prevented dye dimerisation and subsequent red-fluorescence appearance. 57% total cardiolipin was present in the outer leaflets of inner membranes of isolated organelles, a distribution confirmed by saturation measurements for mitoplasts and inside-out submitochondrial particles. The same asymmetry was directly observed in situ with mitochondrial membranes of quiescent L1210 cells, and with mitochondrial membranes of respiring yeasts. Nevertheless, alterations in ATP synthesis and inhibition of mitochondrial protein synthesis revealed that cardiolipin distribution was apparently tightly correlated with mitochondrial membrane assembly and activity.