Decreased uptake and retention of rhodamine 123 by mitochondria in feline sarcoma virus-transformed mink cells

Targeting Multiple Homeostasis-Maintaining Systems by Ionophore Nigericin Is a Novel Approach for Senolysis

Within the present study we proposed a novel approach for senolysis based on the simultaneous disturbance of the several homeostasis-maintaining systems in senescent cells including intracellular ionic balance, energy production and intracellular utilization of damaged products. Of note, we could not induce senolysis by applying ouabain, amiloride, valinomycin or NH₄Cl-compounds that modify each of these systems solely. However, we found that ionophore nigericin can disturb plasma membrane potential, intracellular pH, mitochondrial membrane potential and autophagy at once. By affecting all of the tested homeostasis-maintaining systems, nigericin induced senolytic action towards stromal and epithelial senescent cells of different origins. Moreover, the senolytic effect of nigericin was independent of the senescence-inducing stimuli. We uncovered that K⁺ efflux caused by nigericin initiated pyroptosis in senescent cells. According to our data, the higher sensitivity of senescent cells compared to the control ones towards nigericin-induced death was partially mediated by the lower intracellular K⁺ content in senescent cells and by their predisposition towards pyroptosis. Finally, we proposed an interval dosing strategy to minimize the negative effects of nigericin on the control cells and to achieve maximal senolytic effect. Hence, our data suggest ionophore nigericin as a new senotherapeutic compound for testing against age-related diseases.

Methods for mitochondrial health assessment by High Content Imaging System

Mitochondria are important organelles responsible for energy production. Mitochondrial dysfunction relates to various pathological diseases. The investigation of mitochondrial heath is critical to evaluate the cellular status. Herein, we demonstrated an approach for determining the status of mitochondrial health by observing mitochondrial H₂O₂ (one type of ROS), membrane potential, and morphology (fragmentation and length) in live primary fibroblast cells. The cells were co-stained with fluorescent dyes (Hoechst 33342 and MITO-ID® Red/MitoPY1/JC-10) and continuously processed by the High Content Imaging System. We employed the Operetta CLS^TM to take fluorescent images with its given quickness and high resolution. The CellProfiler image analysis software was further used to identify cell and mitochondrial phenotypes in the thousand fluorescent images.•

We could quantitatively analyze fluorescent images with high-throughput and high-speed detection to track the alteration of mitochondrial status.

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The MMP assay is sensitive to FCCP even at the concentration of 0.01 µM.

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The fibroblast cells treated with stress inducers (H₂O₂, FCCP, and phenanthroline) revealed a significant change in mitochondrial health parameters, with more ROS accumulation, depolarized MMP, increased fragmentation, and reduced length of mitochondria.

Evidence of nigericin as a potential therapeutic candidate for cancers: A review

Emerging studies have shown that nigericin, an H⁺, K⁺ and Pb²⁺ ionophore, has exhibited a promising anti-cancer activity in various cancers. However, its anti-cancer mechanisms have not been fully elucidated. In this review, the recent progresses on the use of nigericin in human cancers have been summarized. By exchanging H⁺ and K⁺ across cell membranes, nigericin shows promising anti-cancer activities in in vitro and in vivo as a single agent or in combination with other anti-cancer drugs through decreasing intracellular pH (pHi). The underlying mechanisms of nigericin also include the inactivation of Wnt/β-catenin signals, blockade of Androgen Receptor (AR) signaling, and activation of Stress-Activated Protein Kinase/c-Jun N-terminal Kinase (SAPK/JNK) signaling pathways. In many cancers, nigericin is proved to specifically target putative Cancer Stem Cells (CSCs), and its synergistic effects on photodynamic therapy are also reported. Other mechanisms of nigericin including influencing the mitochondrial membrane potentials, inducing an increase in drug accumulation and autophagy, controlling insulin accumulation in nuclei, and increasing the cytotoxic activity of liposome-entrapped drugs, are also discussed. Notably, the potential adverse effects such as teratogenic effects, insulin resistance and eryptosis shall not be ignored. Taken together, these reports suggest that treatment of cancer cells with nigericin may offer a novel therapeutic strategy and future potential of translation to clinics.

Warburg effect-damping of electromagnetic oscillations

Mitochondrial dysfunction is a central defect in cells creating the Warburg and reverse Warburg effect cancers. However, the link between mitochondrial dysfunction and cancer has not yet been clearly explained. Decrease of mitochondrial oxidative energy production to about 50 % in comparison with healthy cells may be caused by inhibition of pyruvate transfer into mitochondrial matrix and/or disturbed H⁺ ion transfer across inner mitochondrial membrane into cytosol. Lowering of the inner membrane potential and shifting of the working point of mitochondria to high values of pH above an intermediate point causes reorganization of the ordered water layer at the mitochondrial membrane. The reorganized ordered water layers at high pH values release electrons which are transferred to the cytosol rim of the layer. The electrons damp electromagnetic activity of Warburg effect cancer cells or fibroblasts associated with reverse Warburg effect cancer cells leading to lowered electromagnetic activity, disturbed coherence, increased frequency of oscillations and decreased level of biological functions. In reverse Warburg effect cancers, associated fibroblasts supply energy-rich metabolites to the cancer cell resulting in increased power of electromagnetic field, fluctuations due to shift of oscillations to an unstable nonlinear region, decreased frequency and loss of coherence.

Targeting mitochondria for cancer treatment - two types of mitochondrial dysfunction

Two basic types of cancers were identified – those with the mitochondrial dysfunction in cancer cells (the Warburg effect) or in fibroblasts supplying energy rich metabolites to a cancer cell with functional mitochondria (the reverse Warburg effect). Inner membrane potential of the functional and dysfunctional mitochondria measured by fluorescent dyes (e.g. by Rhodamine 123) displays low and high values (apparent potential), respectively, which is in contrast to the level of oxidative metabolism. Mitochondrial dysfunction (full function) results in reduced (high) oxidative metabolism, low (high) real membrane potential, a simple layer (two layers) of transported protons around mitochondria, and high (low) damping of microtubule electric polar vibrations. Crucial modifications are caused by ordered water layer (exclusion zone). For the high oxidative metabolism one proton layer is at the mitochondrial membrane and the other at the outer rim of the ordered water layer. High and low damping of electric polar vibrations results in decreased and increased electromagnetic activity in cancer cells with the normal and the reverse Warburg effect, respectively. Due to nonlinear properties the electromagnetic frequency spectra of cancer cells and transformed fibroblasts are shifted in directions corresponding to their power deviations resulting in disturbances of interactions and escape from tissue control. The cancer cells and fibroblasts of the reverse Warburg effect tumors display frequency shifts in mutually opposite directions resulting in early generalization. High oxidative metabolism conditions high aggressiveness. Mitochondrial dysfunction, a gate to malignancy along the cancer transformation pathway, forms a narrow neck which could be convenient for cancer treatment.

From delocalized lipophilic cations to hypoxia: blocking tumor cell mitochondrial function leads to therapeutic gain with glycolytic inhibitors

An unexpected similarity between cancer and cardiac muscle cells in their sensitivity to anthracyclines and delocalized lipophilic cations (DLC) prompted a series of studies in which it was shown that the positive charge of these compounds is central to their selective accumulation and toxicity in these two distinct cell types. An initial finding to explain this phenomenon was that cancer and cardiac muscle cells exhibit high negative plasma membrane potentials resulting in increased uptake of these agents. However, the p-glycoprotein efflux pump was shown to be another factor underlying differential accumulation of these compounds, since it recognizes positively charged drugs and thereby actively reduces their intracellular concentrations. The delocalized positive charge and lipophilicity of DLCs leads to their retention and inhibition of ATP synthesis in mitochondria. Years later it was realized that cancer cells in the hypoxic portions of solid tumors were similar to those treated with DLCs in relying mainly on anaerobic metabolism for survival and could thus be targeted with a glycolytic inhibitor, 2-deoxy-D-glucose (2-DG). This hypothesis has lead to a Phase I clinical trial in which 2-DG is used to selectively kill the hypoxic tumor cell population which are resistant to standard chemotherapy or radiation.

Bioenergetic differences selectively sensitize tumorigenic liver progenitor cells to a new gold(I) compound

A hallmark of cancer cells is their ability to evade apoptosis and mitochondria play a critical role in this process. Delineating mitochondrial differences between normal and cancer cells has proven challenging due to the lack of matched cell lines. Here, we compare two matched liver progenitor cell (LPC) lines, one non-tumorigenic [p53-immortalized liver (PIL) 4] and the other tumorigenic (PIL2). Analysis of these cell lines and a p53 wild-type non-tumorigenic cell line [bipotential murine oval liver (BMOL)] revealed an increase in expression of genes encoding the antiapoptotic proteins cellular inhibitor of apoptosis protein (cIAP) 1 and yes associate protein in the PIL2 cells, which resulted in an increase in the protein encoded by these genes. PIL2 cells have higher mitochondrial membrane potential (Deltapsi(m)) compared with PIL4 and BMOL and had greater levels of reactive oxygen species, despite the fact that the mitochondrial antioxidant enzyme, manganese superoxide disumutase, was elevated at transcript and protein levels. Taken together, these results may account for the observed resistance of PIL2 cells to apoptotic stimuli compared with PIL4. We tested a new gold compound to show that hyperpolarized Deltapsi(m) led to its increased accumulation in mitochondria of PIL2 cells. This compound selectively induces apoptosis in PIL2 cells but not in PIL4 or BMOL. The gold compound depolarized the Deltapsi(m), depleted the adenosine triphosphate pool and activated caspase-3 and caspase-9, suggesting that apoptosis was mediated via mitochondria. This investigation shows that the non-tumorigenic and tumorigenic LPCs are useful models to delineate the role of mitochondrial dysfunction in tumorigenesis and for the future development of mitochondria-targeted chemotherapeutics that selectively target tumor cells.

The Design of Gold-Based, Mitochondria-Targeted Chemotherapeutics

Recent developments in understanding the central place of mitochondria as regulators of programmed cell death have stimulated enormous interest in using them as targets for cancer chemotherapy. To overcome drug resistance and the lack of selectivity of cancer drugs in differentiating between normal and tumour cells, many strategies have been described in recent literature, including the use of delocalized lipophilic cations that selectively accumulate in tumour-cell mitochondria. Thioredoxin reductase, an enzyme involved in redox regulation and cell growth, has also emerged recently as an attractive drug target. Here we discuss the rationale for the design of lipophilic, cationic Au(i) phosphine complexes that are targeted to mitochondria of tumour cells and have potent and selective anticancer activity for cancer cells but not for normal cells. Our discovery that the thioredoxin system may be a critical target responsible for the selective toxicity provides a new strategy in the development of mitochondria-targeted chemotherapeutics.

Enhancement of sensitivity to cisplatin by orobol is associated with increased mitochondrial cytochrome c release in human ovarian carcinoma cells

OBJECTIVES

Based on our previous report showing that orobol, a potent phosphatidylinositol 4-kinase (PI4K) inhibitor, produced cisplatin (DDP) sensitivity, we have determined the mechanism of orobol-sensitization effect.

METHODS AND RESULTS

Orobol produced >2-fold DDP sensitivity in human ovarian carcinoma 2008 cells and its DDP-resistant variant 2008/C13*5.25 cells (C13). Because orobol had no effect on conventional mechanisms such as DDP accumulation or cellular metallothionein and glutathione content, we have focused on the apoptotic signaling pathway. Orobol induced a significant increase in apoptosis in DDP-treated cells, as estimated by frequency of condensed nuclear chromatin with Hoechst 33342 stain, although orobol alone did not have any effect on apoptotic potential. The caspase-3-inhibiting peptide Ac-DEVD-CHO completely inhibited the orobol sensitization effect but did not block DDP cell cytotoxicity per se. Orobol rendered both of these cells resistant to rhodamine 123 (Rh) by more than 2.5-fold, indicating significant decrease of mitochondrial membrane potential (DeltaPsim). Confocal laser microscopy of cells stained with the mitochondria (MT)-specific dye Rh revealed that orobol decreased Rh-fluorescent intensity. Electron microscopy of these cells showed that orobol induced swelling and condensation of MT. Orobol suppressed both naturally expressed and the DDP-induced Bcl-2 expression significantly. Orobol and DDP treatment reduced cytochrome c level in MT determined by Western blot analysis, indicating increased amount of cytochrome c release from MT, whereas orobol alone did not alter the amount of cytochrome c in MT.

CONCLUSIONS

These results indicate that orobol produced DDP sensitivity in human ovarian carcinoma cells by inducing apoptosis through the MT-dependent signaling pathway.

Effect of acute hypoxia on glomus cell Em and psi m as measured by fluorescence imaging

We have reinvestigated the hypothesis of the relative importance of glomus cell plasma and mitochondrial membrane potentials (E(m) and psi(m), respectively) in acute hypoxia by a noninvasive fluorescence microimaging technique using the voltage-sensitive dyes bis-oxonol and JC-1, respectively. Short-term (24 h)-cultured rat glomus cells and cultured PC-12 cells were used for the study. Glomus cell E(m) depolarization was indirectly confirmed by an increase in bis-oxonol (an anionic probe) fluorescence due to a graded increase in extracellular K(+). Fluorescence responses of glomus cell E(m) to acute hypoxia (approximately 10 Torr Po(2)) indicated depolarization in 20%, no response in 45%, and hyperpolarization in 35% of the cells tested, whereas all PC-12 cells consistently depolarized in response to hypoxia. Furthermore, glomus cell E(m) hyperpolarization was confirmed with high CO (approximately 500 Torr). Glomus cell psi(m) depolarization was indirectly assessed by a decrease in JC-1 (a cationic probe) fluorescence. Accordingly, 1 microM carbonyl cyanide p-trifluoromethoxyphenylhydrazone (an uncoupler of oxidative phosphorylation), high CO (a metabolic inhibitor), and acute hypoxia (approximately 10 Torr Po(2)) consistently depolarized the mitochondria in all glomus cells tested. Likewise, all PC-12 cell mitochondria depolarized in response to FCCP and hypoxia. Thus, although bis-oxonol could not show glomus cell depolarization consistently, JC-1 monitored glomus cell mitochondrial depolarization as an inevitable phenomenon in hypoxia. Overall, these responses supported our "metabomembrane hypothesis" of chemoreception.

Effects of irradiation on 99m Tc sestamibi and 201Tl uptake in a human papillary thyroid carcinoma cell line

Both 99mTc sestamibi and 201Tl have been used in conjunction with 131I scintigraphy for follow-up of patients with thyroid cancer. The aim of the study was to determine if irradiation affects tracer uptake in papillary thyroid cancer cells. The human papillary carcinoma cell line (PAP/ES-1) used in this study was generated from a papillary thyroid tumour obtained after surgery. For the in vitro uptake studies cells were seeded at 2 x 105 cells/well into 12-well microtitre plates. Irradiation was performed with a 60Co source (total dose, 2 Gy and 10 Gy). After incubation at 37 degrees C the supernatants were saved for determination of the unincorporated activity. The reaction was stopped by washing the cells four times in ice cold phosphate buffered saline. Total cellular uptake was determined by measuring cell lysate radioactivity in a Compugammasystem and was expressed as per cent uptake per mg of total cellular protein. At continuous incubation 201Tl uptake was significantly (P<0.01) higher after radiation whereas no effect of irradiation was found on 99mTc sestamibi uptake. Pulsed experiments revealed that irradiated cells displayed a faster 201Tl efflux. The net tracer retention at 90 min was similar to 201Tl to that of 99mTc sestamibi. We conclude that 99mTc sestamibi kinetics in thyroid cancer are not affected by irradiation and may therefore be superior to 201Tl in the follow-up of thyroid cancer shortly after radiotherapy.

Assessment of membrane potentials of mitochondrial populations in living cells

Mitochondrial membrane potentials (MMP) reflect the functional status of mitochondria within cells. Fluorescent probes to estimate these potentials within cells have been available for some time, but measurements of populations of mitochondria are not possible by existing methods. Therefore, comparisons between different cell types (e.g., fibroblasts and neuroblastoma), fibroblast cell lines from different patients, or even the same cell following various experimental paradigms are not feasible. The current approach estimates populations of MMP within living cells at 37 degrees C using the combination of conventional fluorescence microscopy and three-dimensional deconvolution by exhaustive photon reassignment. With this method, raw images are acquired rapidly with low-intensity (nonlaser) light with minimal concentrations of fluorescent dye. The method uses the fluorescent dye tetramethylrhodamine methyl ester, which equilibrates in cells according to the Nernst equation and provides a numerical, replicable estimate of MMP for populations of cellular mitochondria. This method can detect either increases or decreases in MMP as small as 5%. Furthermore, MMP in different cell types appear distinct. Values in fibroblasts (-105 +/- 0.9 mV) and N2a cells (-81 +/- 0.7 mV) were very different by this method. This approach bridges investigations of individual mitochondria to those that assess MMP by examining global fluorescence from cells.

Staining of cellular mitochondria with LDS-751

We have found the dye LDS-751 to bind almost exclusively to mitochondria when incubated with viable, nucleated cells. Treatment of cells with the nuclear stain acridine orange and LDS-751 revealed little colocalization when the cells were examined by confocal microscopy. Staining with the dye rhodamine 123, which is known to bind polarized mitochondria, was virtually identical to the pattern observed with LDS-751. This staining pattern was observed to be consistent over a range of 0.02-20 microg/ml LDS-751 and was consistent between both fibroblasts and monocytes. Depolarization of mitochondria with the mitochondrial depolarizing agents phenyl arsine oxide and carbonyl cyanide m-chlorophenylhydrazone (CCCP) dramatically reduced both LDS-751 staining, and rhodamine 123 fluorescence. Taken together, these results suggest that LDS-751 is excluded from the nucleus and binds the polarized membranes of mitochondria. Given this, interpretation of LDS-751 fluorescence as being indicative of nuclear status, as is commonly done to discriminate between leukocytes and erythrocytes, is unwarranted and may lead to erroneous conclusions if mitochondria become depolarized upon processing.

Extramitochondrial localization of mortalin/mthsp70/PBP74/GRP75

Subcellular fractionation and immunofluorescence microscopy were used to identify the specific sites of intracellular residence of mortalin, also called a mitochondrial homologue of the hsp70 family, in immortal human cell lines previously assigned to four distinct complementation groups (A-D) for indefinite cell division. In addition to the mitochondria it was seen in the endoplasmic reticulum (ER) fractions of all the cell lines analyzed. Interestingly, three of the group A cells lines (EJ, GM639, and HT1080), in addition to the mitochondria and ER, exhibited cytosolically (extra-organelle) localized pool of mortalin. These findings demonstrate that mortalin is not present exclusively in mitochondria. Its residence in different organelles may be the basis of differential distribution observed previously in different human cell lines.

p53-independent inhibition of proliferation and p21(WAF1/Cip1)-modulated induction of cell death by the antioxidants N-acetylcysteine and vitamin E

Epidemiological evidence has suggested an association between diets rich in antioxidants and diminished risks of various types of cancer. Proposed mechanisms for protective effects of antioxidants have involved inhibition of free radical-mediated DNA damage. Recent data suggest that antioxidants may prevent or eliminate cancerous cells through their ability to inhibit proliferation or to induce programmed cell death (PCD). To begin to identify cell cycle and cell death regulatory factors involved in antioxidant-induced growth arrest and PCD, we have studied colorectal carcinoma cells (CRCs) that differ in expression of the tumor suppressor protein p53, and of the cyclin-dependent kinase (CDK) inhibitor p21(Waf1/Cip1). The antioxidants, N-acetylcysteine (NAC) and vitamin E either inhibited proliferation in a p53-independent manner without affecting cell viability or induced cell death. Growth arrest was not associated with upregulation of the CDK inhibitors p21(Waf1/Cip1), p18(ink4c) or p16(ink4a), but was associated with a decrease in reactive oxygen species (ROS). In contrast to previous observations, the absence of p21(Waf1/Cip1) increased susceptibility of CRCs to antioxidant-induced PCD. NAC decreased levels of retinoblastoma protein (Rb) phosphorylation in all cells tested, but Rb was cleaved only in cells which underwent NAC-induced death. Although NAC decreased ROS in all cells studied, cell lines in which PCD occurred had higher baseline levels of ROS than cell lines in which proliferation was blocked. These observations suggest that expression of p21(Waf1/Cip1) and basal levels of ROS are important determinants of outcome after antioxidant treatment.

Time-resolved microfluorometric study of the binding sites of lipophilic cationic pyrene probes in mitochondria of living HeLa cells

Lipophilic dye cations specifically bind to the mitochondria of living cells. Using fluorescent dyes, the mitochondria can easily be observed with a fluorescence microscope. Electron microscopy has shown that the dyes are bound to the inner mitochondrial membranes and the cristae. Using time-resolved fluorescence microscopy we have investigated, whether the dye molecules are preferentially accumulated at the strongly hydrophobic protein complexes of energy metabolism or at the lipids of the inner membrane system. In order to use our nanosecond-pulsed laser fluorometer we synthesized specially designed lipophilic pyrene cations with S1 lifetimes in the nanosecond domain, which specifically stain mitochondria in living HeLa cells. Model experiments with artificial membranes such as liposomes, proteoliposomes and also protein complexes have shown that the fluorescence is strongly quenched by oxygen if the pyrene probes are bound to lipids. Binding to proteins causes a much smaller quenching effect. In artificial systems, all decays were single exponential. This is in contrast with incubated HeLa cells, which showed double-exponential fluorescence decays. Comparing these with the artificial systems we came to the conclusion that in HeLa cells the long-lived species 1 are pyrene probes preferentially bound to the proteins of the inner mitochondrial membranes. The short-lived species 2 is caused by fluorescence resonance energy transfer from the pyrene probes as donors to cytochromes of the inner membranes as acceptors. From our decay data we estimated a mean distance between donor and acceptor of about 40 A. This is the same order of magnitude as the mean diameters of several mitochondrial protein complexes. Therefore we assumed that species 2 are pyrene probes bound either to mitochondrial proteins with cytochromes as constituents or to the interface between these proteins and the phospholipids of the membranes. Thus both species 1 and species 2 are spatially related to mitochrondrial proteins. This agrees with the observation that respiration of HeLa cells as well as cytochrome c oxidase vesicles (COVs) are inhibited with increasing concentration of pyrene probes. Finally, we studied the photodynamic effect on irradiation of HeLa cells and of COVs after incubation with lipophilic pyrene and porphyrine cations.

Rhodamine 123: a useful probe for monitoring T cell activation

The T cell activation pathway involves an increase in mitochondrial activity. This can be evaluated in individual cells using the fluorescent probe rhodamine 123 (Rh123) and flow cytometry. Peripheral blood mononuclear cells (PBMC) were stimulated with optimal concentrations of phytohaemagglutinin (PHA), superantigens (Sag) SEA and SEC2, and allogeneic cells. Activation kinetics were followed at days 1, 2, 4 and 7. In all activation conditions, Rh123 uptake was augmented with the CD25 expression, cell size, and DNA synthesis. Rh123 uptake reflected an increase in mitochondrial activity and mass, as assessed by experiments in which Rh123 was substituted for by the 10-nonyl acridine orange, which stains mitochondria in an energy-independent manner. The spectral characteristics of Rh123 allowed us to double stain cells with Rh123 and phycoerythrin-conjugated monoclonal antibodies. In PHA-activated cultures, CD4+ and CD8+ cells incorporated essentially the same amount of Rh123 at all time points, suggesting that the two subsets did not differ in their activation kinetics. Accordingly, after 1 week of culture, no significant modification in the CD4/CD8 ratio was observed. Sag-activated CD4+ cells incorporated a higher amount of Rh123 than did CD8+ cells and preferentially expanded after 1 week of culture as indicated by the increase in the CD4/CD8 ratio. The different behavior of the CD4 and CD8 subsets observed by dual color flow cytometry in the PHA and Sag models was confirmed using purified CD4+ and CD8+ cell preparations obtained by immunomagnetic sorting. CD4+ cells were also the preferential target in the allogeneic model, although the magnitude of the phenomenon was lower than in the Sag model. Present data indicate that Rh123 is a reliable marker for monitoring the mitochondrial compartment during T cell activation. The possibility of phenotyping Rh123-stained cells adds to the applicability of the probe.

Modulation of rhodamine 123 uptake by nigericin in sensitive and multidrug resistant leukemic cells

We have investigated the effect of the ionophore nigericin (NIG) in multidrug resistant (MDR) cells, using intracellular accumulation of the fluorescent dye rhodamine 123 (R123). NIG increased the accumulation of R123 in half of the murine MDR RFLC3 population but not in the human MDR CEM/VLB 100 cells. Co-treatment of RFLC3 with NIG plus verapamil showed additive effect on the accumulation of R123. The increase in R123 accumulation observed in RFLC3 was not the consequence of a direct effect of NIG on P-glycoprotein and was accompanied by a redistribution of the dye throughout the cell and a high cytotoxicity, which prevents the use of NIG as a resistance modulating agent.

Influence of trans-membrane potential and of hydrophobic interactions on dye accumulation in mitochondria of living cells. Photoaffinity labelling of mitochondrial proteins, action of potential dissipating drugs, and competitive staining

The lipophilic cationic fluorescent dye azopentylmethylindocarbocyanine (APMC) specifically stains the mitochondria in living cells. The dye contains a photosensitive diazirine ring and is suitable for photoaffinity labelling of mitochondrial proteins. By a combination of photoaffinity labelling cell cultures of mouse fibroblasts (LM) with APMC, lysis of the labelled cells, subsequent micro-gel electrophoresis and detection of the fluorescence of the labelled proteins in the gel lanes with a sensitive microfluorimeter, we determined the number, apparent molecular masses, and relative intensity of the labelled proteins. In LM cells, three proteins with apparent molecular masses of 31, 40, and 74 kDa were labelled with high intensity, and proteins of 28, 29, 44, 48, 49, 66, and 105 kDa with low intensity. Two effects mainly determine the binding of lipophilic dye cations to mitochondrial proteins in living cells: (1) interaction of the trans-membrane potential of the inner mitochondrial membrane with the dye cations; and (2) hydrophobic interactions between the strongly lipophilic proteins of the inner membrane and the lipophilic dye molecules. Preincubation of the cell cultures with drugs that dissipate the trans-membrane potential, such as valinomycin, 2,4-dinitrophenol (DNP) and 3-chlorcarbonyl-cyanide-phenylhydrazone (CCCP), strongly reduces or even prevents APMC labelling of mitochondrial proteins. The influence of hydrophobic interactions was investigated by competitive staining experiments using dyes with very different lipophilic properties. The lipophilicity of the dyes was characterized by their Rm values in reversed phase thin-layer chromatography.(ABSTRACT TRUNCATED AT 250 WORDS)

Photoaffinity labelling with fluorescence detection. Dye accumulation at four mitochondrial proteins in HeLa and LM cells

A micromethod was developed for investigating the interactions between fluorescent dyes and cellular proteins. The lipophilic cationic dye APMC (azopentylmethylcarbocyanine) contains a photosensitive diazirine ring and is suitable for photoaffinity labelling. By combining photoaffinity labelling of cultured cells, micro-gel electrophoresis and detection of the fluorescence with a microfluorimeter, we established a highly sensitive and rapid procedure to identify APMC labelled proteins. Cells which had been incubated for 10 min with 10(-8) M APMC could be analysed for APMC binding without difficulty. Under our experimental conditions this corresponds to about 0.2 nmol APMC per mg protein. The lipophilic APMC specifically stains the mitochondria in living HeLa and LM cells. The fluorescing mitochondria can be easily detected under a fluorescence microscope. By photoaffinity labelling we were able to show that at low dye concentrations APMC preferentially marks four proteins with apparent molecular masses of 31, 40, 66, and 74 kDa. In order to establish that these are mitochondrial proteins, we isolated and analysed the mitochondria from incubated HeLa and LM cells; again, the same four proteins were detected. They are most probably proteins of the inner mitochondrial membranes, which accumulate the lipophilic APMC cations.

Assessment of ram sperm mitochondrial function by quantitative determination of sperm rhodamine 123 accumulation

A simple procedure is described for determining the functional state of ram sperm mitochondria by quantitative measurement of sperm rhodamine 123 (R 123) accumulation. Sperm were incubated with 1 microgram/ml R 123, and the accumulated R 123 was measured fluorimetrically after release from washed sperm by detergent lysis. Ram sperm R 123 uptake was maximal after 30 min of incubation and responded to changes in both sperm (P < 0.01) and R 123 (P < 0.01) concentration. There was a linear relationship (r = 0.98) between R 123 uptake and the proportion of cold-shocked sperm present in a sperm sample. R 123 uptake was unaffected by 20 mM 2-deoxyglucose or by 10 mM malonate (the latter being sufficient to reduce O2 uptake; P < 0.01). R 123 accumulation in ram sperm was reduced by 6 mg/ml sodium pentobarbitone (P < 0.05), by 1 microM 2,4-dinitrophenol (P < 0.01), and by 0.05% Triton X-100 (P < 0.01). It is concluded that quantitative estimation of R 123 uptake complements oxygen uptake in detecting mitochondrial dysfunction in ram sperm. While it is largely unaffected by inhibition of glycolysis, and is less sensitive than oxygen uptake to trichloroacetic acid cycle inhibition, R 123 uptake is sensitive to factors directly reducing the mitochondrial membrane potential of ram sperm. It may therefore by useful in the evaluation of the effects of such membrane-mediated injuries as cold shock and freezing damage on ram sperm mitochondria.

The concentration jump method. Kinetics of vital staining of mitochondria in HeLa cells with lipophilic cationic fluorescent dyes

Lipophilic cationic fluorescent dyes (D) specifically stain the mitochondria of living cells. A perfusion chamber for cell cultures is described, which can be used to determine the kinetics of vital staining of the mitochondria of single selected cells in situ. In these experiments styrylpyridinium dyes and cultures of HeLa cells were used. The dyes differ strongly in their lipophilic properties; Rm values and the partition coefficients Po/w between n-octanol (o) and water (w) were determined in order to characterize their lipophilicity. In the thermostat-regulated chamber the concentration of the dye CD can be increased from CD = 0 to CD > 0 within a few seconds (concentration jump). Thus, the time t = 0 for the beginning of the vital staining and the dye concentration in the cell medium during the staining experiment, CD = const., are unambiguously defined. The concentration of the dye, Cb, which is bound to the mitochondria (b), is proportional to the intensity of the fluorescence Ib. On the other hand, the free dye molecules (f) in the aqueous medium exhibit practically no fluorescence, I(f) << Ib. The intensity of the fluorescence I = Ib was measured as a function of time t; the measured values were corrected for photobleaching. The fluorescence intensity I(t) at first increases linearly with t and reaches a saturation value for t-->infinity. In the linear range of I(t) the flow J(o) = (dI/dt)o of the dye into the cell depends strongly on the dye concentration and increases linearly with CD. The concentration range CD = 10(-9)-10(-5) M at 37 degrees C was investigated. From the linear correlation between J(o) and CD it follows that the kinetics of the vital staining of mitochondria is controlled by diffusion. At t = 0 the flow of the xenobiotic agent through the cell membrane determines the rate of staining. The slope dJ(o)/dCD of the plot J(o) vs CD describes the efficiency of dye accumulation at the mitochondria and strongly increases with increasing lipophilicity of the dye molecules. Thus lipophilic dyes pass through the cell membrane more easily than less lipophilic molecules.

Identification of genes that exhibit increased expression after flat reversion of NIH/3T3 cells transformed by human activated Ha-ras oncogene

By differential hybridization, we have isolated 14 cDNA clones corresponding to genes that are more highly expressed in the flat revertant cell line R1 than in the parental human Ha-ras oncogene-transformed NIH/3T3 cell line (EJ-NIH/3T3). From cross-hybridization experiments, we determined that 5 sequence families accounted for the 14 clones. DNA sequencing revealed that four out of five selected cDNA clones represented mitochondrial genes (cytochrome b, cytochrome c oxidase subunit II, NADH dehydrogenase subunits 1 and 4, respectively), whereas one cDNA clone was homologous to the alpha 2 (type I collagen gene. Although a Southern blot analysis of the studied cell lines showed similar copy numbers of mitochondrial genomes, the transcript levels of the mitochondrial genes were high in R1, intermediate in NIH/3T3 and low in EJ-NIH/3T3 and partially revertant R2 cell lines. alpha 2 (type I) collagen mRNA levels were high in R1 and NIH/3T3, intermediate in R2 and low in EJ-NIH/3T3 cells. These results suggest that a complex alteration of the expression of mitochondrial and extracellular matrix components may be closely associated with the flat reversion of the transformed cells.

Time-resolved polarization measurements of porphyrin fluorescence in solution and in single cells

Porphyrin monomers, dimers and aggregates, which can be differentiated on the basis of their fluorescence lifetimes, are shown to possess different degrees of fluorescence polarization. This opens up new possibilities for microscopic imaging of these individual components in photosensitization and tumour detection. A rough estimate of the size of the porphyrin aggregates is obtained from the data of time-resolved fluorescence anisotropy.

A new method for testing cell ageing using two mitochondria specific fluorescent probes

Cell culture techniques have considerably improved our understanding of the numerous changes related to aging. For instance, murine lymphocytes obtained from animals older than 6 months progressively lose their, in vitro, proliferative capacity. Numerous studies have shown that this loss is due to changes in the mitochondrial compartment such as reduction in the transmembrane potential and/or membrane mass. Using two mitochondria specific probes with a potential-dependent (Rhodamine 123) or independent (Nonyl Acridine Orange) uptake, we found that the decline in the respiratory activity in the mouse occurred approximately 6 months prior to the decrease in mitochondrial membrane mass. The analysis of the Rh 123/NAO fluorescence ratio measured in splenocytes obtained from mice aged more than 6 months, showed that there was a linear loss of respiratory efficiency per unit of mitochondrial membrane mass. Moreover, cells with a ratio of less than 0.85 were incapable of proliferating and remained quiescent. The time separating the infection points of the two dye uptake curves might provide informations about the regulation and coordination of nuclear and/or mitochondrial genomes. Moreover, the ratio between the two fluorescent probes, in particular during the linear phase, may also have a predictive value.

Power transmission along biological membranes

Hypothesis on long-distance power transmission along extended energy-transducing membranes (Skulachev, 1969, 1971, 1980), has been experimentally proven in four different systems, namely, (i) trichomes of filamentous cyanobacterium Phormidium uncinatum; (ii) filamentous mitochondria and mitochondrial network in fibroblasts; (iii) clusters of roundish heart muscle mitochondria interconnected with mitochondrial junctions; (iv) mixed animal cell cultures interconnected with gap junctions. In all cases, energy was shown to be transmitted in the form of a transmembrane electric potential difference. The transmission occurred for distances as long as several tens of micrometers. Since the (a) delta-muH-bearing cytoplasmic membrane of cyanobacteria and the inner mitochondrial membrane and (b) delta-muNa-bearing outer animal cell membrane were found to be competent in such an effect, one may assume that the power transmission is a fundamental function of extended membrane systems. This mechanism can be used at the intracellular level (mitochondrial) as well as at the supracellular level (cytoplasmic and outer cell membranes). Studies on the possible involvement of membranes in lateral transport of oxygen, ions, fatty acids and membrane proteins seem to hold good promise.

Intravital fluorescence microscopy of endothelial cells on vascular grafts

The ability to evaluate the extent of initial endothelial cell coverage on a vascular graft subsequent to an endothelial cell seeding technique would be desirable to substantiate the durability of the endothelial cell lining. To this end, we have evaluated the use of intravital fluorescence microscopy to assess human endothelial cell interaction with vascular grafts. Five fluorescent stains, mithramycin, Hoechst 33342, sulfofluorescein diacetate, Nile red, and rhodamine 123 were evaluated for their ability to fluorescently label human endothelial cells. The staining capability of each dye was also evaluated with respect to accuracy in determining seeded cell number and cell spreading. Of the stains evaluated, rhodamine 123 produced the most desirable characteristics. We observed excellent cell visualization after a 30-min incubation. Unlike the other four stains, rhodamine 123 exhibited a bright orange fluorescence emission at a 510-nm excitation wavelength while the underlying dacron or expanded polytetrafluoroethylene demonstrated minimal autofluorescence. Rhodamine 123 also exhibited no inhibitory effect on cell attachment to plastic or subsequent cell growth in culture. Intravital fluorescence microscopy could be easily utilized in the operating room to visualize part or all of an endothelial cell-seeded graft prior to implantation and would permit a quantitative as well as qualitative evaluation of the seeding process. Since intravital fluorescence imaging does not require tissue fixation, the same surface as that evaluated for seeding efficiency can be directly implanted.

Relationship between cellular accumulation of rhodamine 123 (R123) and cytotoxicity in B16 melanoma cells

Rhodamine 123 (R123) is a mitochondria-specific prototype anticancer agent because its target is the energy-producing mechanism of the cell. The goal of this study was to investigate the relationship between intracellular R123 accumulation and cytotoxicity in a R123-sensitive cell line (RS) and a R123-resistant subline (RR) that we developed. Cytotoxicity after exposure to R123 (0-60 micrograms/ml) was assessed using the clonogenic assay. Intracellular R123 was extracted with acid-alcohol and measured by fluorimetry. The rate of R123 accumulation over 1 hr was significantly higher (P less than 0.0001) for RS cells (4.65 +/- 0.39 micrograms/min/10(6) cells) than for RR cells (1.29 +/- 0.24 micrograms/min/10(6) cells). R123 accumulation in RS cells was strongly correlated (r = 0.80; P less than 0.0001) with cytotoxicity. Treatment of RR cells with verapamil (100 microM) reversed R123 resistance. The resulting dose-survival curve was identical to the dose-response curve of RS cells treated with R123 alone. Cellular content of R123 in RR cells treated with verapamil increased to a level similar to that of RS cells and correlated with cytotoxicity. These data suggest that cytotoxicity of R123 in B16 cells results from increased cellular accumulation of R123.

Nutritional pharmacology in the treatment of neoplastic disease

The altered energy metabolism and substrate requirements of tumour cells can provide a target for selective antineoplastic therapy. The supply of substrates for tumour energy metabolism can be reduced by dietary manipulation (e.g. ketogenic diet) or by pharmacological means at the cellular level (e.g. inhibitors of glycolysis or oxidative phosphorylation). Both these approaches are examined with a view to the development of selective and therefore non-toxic methods of controlling tumour growth in vivo.

A recessive cellular mutation in v-fes-transformed mink cells restores contact inhibition and anchorage-dependent growth

A contact-inhibited revertant of mink cells transformed by the Gardner-Arnstein strain of feline sarcoma virus was isolated by fluorescence-activated sorting of cells stained with the mitochondria-specific dye rhodamine 123. The revertant cell line exhibited a decrease in its proliferative rate and saturation density and a complete loss of its capacity for anchorage-independent growth, but it remained tumorigenic when inoculated into nude mice. The revertant cells retained a rescuable Gardner-Arnstein feline sarcoma provirus, expressed high levels of the v-fes oncogene product and its associated tyrosine kinase activity, manifested elevated levels of phosphotyrosine-containing cellular proteins similar to those observed in v-fes-transformed cells, and were refractory to retransformation by retroviruses containing the v-fes, v-fms, and v-ras oncogenes. Fusion of the revertant and parental cells generated somatic cell hybrids which formed colonies in semisolid medium, indicating that the block in transformation was recessive. These data together with the observation that the revertant phenotype is unstable in continuous culture suggest that the loss of transformation is due to the presence of limiting quantities of a gene product which functions downstream of the v-fes-coded kinase in the mitogenic pathway.

Mitochondrial biogenesis and mitochondrial activity during the progression of the cell cycle of human leukemic cells

Mitochondrial (mt) biogenesis and mt function were investigated during the cell cycle of leukemic cells. The study shows that the activity of enzymes involved in oxidative phosphorylation increases in the early G1 phase. This increase in activity precedes that of other mt enzymes such as citrate synthase and adenylate kinase. Therefore, the synthesis of mt enzymes, needed for the reduplication of the mt mass in the course of the cell cycle, occurs in a sequential order. The enzymes of the system for oxidative phosphorylation are composed of several subunits. Some of these subunits are encoded on mtDNA and synthesized by mt-specific RNA and protein synthesis. This explains why inhibition of mt protein synthesis during the progression of the cell cycle of G1-enriched cells results in an increasing shortage of ATP. This lack of ATP results first in progression delay and, subsequently, in a cell cycle block in early G1. Furthermore, shortage of ATP impairs the increase in activity of at least one mt matrix enzyme. This study offers new information about a number of aspects of mt biogenesis and mt function during cell cycle progression and elucidates the cytostatic mechanism resulting from prolonged inhibition of mt protein synthesis.

Effect of antibiotics on the binding of pargyline to monoamine oxidase in cultured hepatocytes

The laser dye rhodamine 123 has been used to establish that the binding of [3H]pargyline to monoamine oxidase is a more sensitive indicator of mitochondrial perturbation than measurements of protein synthesis, secretion, or degradation. The amount of monoamine oxidase labelled depends on the antibiotic used. The labelling was considerably lower in the presence of gentamycin than in the presence of either chloramphenicol or of penicillin and streptomycin. The accumulation of gentamycin within the cells was the cause of the reduced labelling of monoamine oxidase which was not accompanied by an alteration in the metabolism of pargyline. The gentamycin effect can be prevented by incubating the cells in medium supplemented with methylamine prior to adding the monoamine oxidase inhibitor. Long term culture of cells with gentamycin can result in the cell culture medium becoming dark brown. Under these conditions the monoamine oxidase labelling is increased due to an inhibition of pargyline metabolism. The results indicate that the choice of antibiotic is important in patients being treated with both antibiotics and monoamine oxidase inhibitors.

A recessive cellular mutation in v-fes-transformed mink cells restores contact inhibition and anchorage-dependent growth

A contact-inhibited revertant of mink cells transformed by the Gardner-Arnstein strain of feline sarcoma virus was isolated by fluorescence-activated sorting of cells stained with the mitochondria-specific dye rhodamine 123. The revertant cell line exhibited a decrease in its proliferative rate and saturation density and a complete loss of its capacity for anchorage-independent growth, but it remained tumorigenic when inoculated into nude mice. The revertant cells retained a rescuable Gardner-Arnstein feline sarcoma provirus, expressed high levels of the v-fes oncogene product and its associated tyrosine kinase activity, manifested elevated levels of phosphotyrosine-containing cellular proteins similar to those observed in v-fes-transformed cells, and were refractory to retransformation by retroviruses containing the v-fes, v-fms, and v-ras oncogenes. Fusion of the revertant and parental cells generated somatic cell hybrids which formed colonies in semisolid medium, indicating that the block in transformation was recessive. These data together with the observation that the revertant phenotype is unstable in continuous culture suggest that the loss of transformation is due to the presence of limiting quantities of a gene product which functions downstream of the v-fes-coded kinase in the mitogenic pathway.

In situ flow cytometric analysis of nonyl acridine orange-stained mitochondria from splenocytes

Due to its spectral characteristics, the fluorochrome nonyl acridine orange (NAO) (lambda abs:489 nm, lambda em:525 nm), which is spontaneously incorporated by mitochondria with a high relative specificity, provides a new probe for the in situ study of these organelles by flow cytometry. In 15 min at 20 degrees C, the dye at 4.75 X 10(-6) M saturates the mitochondrial binding sites present in 1.5 X 10(6) cells. Unlike Rh 123, the fixation of the probe is not affected by the action of uncouplers and ionophores. Unlike acridine orange, its binding is not sensitive to nucleases. By studying the mitochondrial incorporation of the fluorochrome during the cell cycle of murine splenocytes, it was possible to show that the biogenesis of NAO-stained mitochondrial constituents mainly occurs during the G1 phase.

Activated monocytes induce arthritis-associated changes in mitochondria of cultured synovial fibroblasts

We have recently shown that synovial fibroblasts cultured from patients with reactive or rheumatoid arthritis exhibit increased autofluorescence when compared with controls. Morphological studies suggested that this increase was related to the anomalous structure of mitochondria in cells cultured from rheumatoid or non-rheumatoid inflammatory synovial tissue. The present study describes attempts to find an explanation for these observations. The effects of conditioned media of cultured mononuclear cells were tested on normal synovial fibroblasts. Conditioned media of monocytes stimulated with lipopolysaccharide or poly-IC induced an increase in the cellular autofluorescence and changes in the morphology of mitochondria in normal fibroblasts. These changes were indistinguishable from those seen in synovial fibroblasts cultured from various arthritides. Indomethacin or gold salts did not abolish the effects of monocyte-conditioned media. Abnormal mitochondria could not be induced in the presence of cycloheximide. This study describes a new aspect of monocyte-fibroblast interactions during rheumatoid and non-rheumatoid inflammation of synovial tissue.

Efficacy of Pt(Rh-123)2 as a radiosensitizer with fractionated X rays

The complex of tetrachloroplatinate and rhodamine-123, Pt(Rh-123)2 has demonstrated cytotoxic and antitumor effects and radiosensitizing potential in vitro and in vivo. Using the FSaIIC in vivo-in vitro tumor system, tumor cell survival indicated a dose modifying factor (DMF) of 1.51 due to the addition of Pt(Rh-123)2. Pt(Rh-123)2 was added to two fractionated radiation protocols. The drug was administered by i.p. injection on three different multiple injection schedules, each reaching a cumulative dose of 75 mg/kg in those groups receiving the maximum treatment. Radiation was delivered in 3 Gy fractions in the morning and afternoon or daily for five days. Pt(Rh-123)2 was administered daily at 25 or 15 mg/kg or on alternate days at 25 mg/kg. The DMFs obtained ranged from 1.8 +/- 0.2 to 1.25 +/- 0.1. The pharmacokinetics of [195mPt]-Pt(Rh-123)2 after i.p. injection of 100 mg/kg of the drug were characterized in mice bearing the Lewis lung carcinoma using a two compartment model. The total exposure of the lung carcinoma to the drug as reflected by the area under the concentration vs. time curve was 1.5 times greater than that of the normal lung tissue. The formation of DNA cross-links and single strand breaks in SCC-25 cells exposed to Pt(Rh-123)2 (100 microM) and 6 Gy under normally oxygenated and hypoxic conditions immediately following treatment or 6 hours later were measured by DNA alkaline elution. Over the time course, the level of DNA cross-linking increased in the normally oxygenated cells by 1.5-fold and the hypoxic cells by 4-fold. The overall effects of Pt(Rh-123)2 in the presence of radiation results from both DNA cross-linking and single strand breaks.

Localization of mitochondria in plant cells by vital staining with rhodamine 123

The positively-charged fluorescent dye rhodamine 123 (r-123) specifically stains mitochondria in living plant protoplasts, suspensionculture cells, and root hairs. This dye functions as a vital stain and permits visualization of the localization, distribution and movement of the mitochondria. Dehydration of root hairs caused mitochondria to aggregate into clumps. Mitochondria were either homogenous or heterogeneous and were frequently seen to accumulate in the perinuclear regions of suspension-culture cells but not in those of protoplasts or root-hair cells. Dinitrophenol and high concentrations of ethyleneglycol-bis(β-aminoethyl ether)-N,N,N',N'-tetraacetic acid and KCl immediately eliminated fluorescence in r-123-stained mitochondria whereas ionomycin enhanced it. Treatment of seedlings with r-123 resulted in differential brightness of fluorescence in different tissues. Meristematic tissues, such as root and shoot tips, exhibited the brightest fluorescence. The cytotoxicity of r-123 in both germinating seedlings and suspension-culture cells was low. The specificity, sensitivity and low toxicity of r-123 should make it a useful tool in experiments designed to examine agents and conditions which affect the location, the physiological status or the viability of mitochondria.

Increased uptake and retention of rhodamine 123 by mitochondria of old human fibroblasts

Binding of the fluorescent dye R123 by a variety of mammalian cells has been shown to be dependent on the high transmembrane potential maintained in functional mitochondria. Recent studies in our laboratory have shown that old human fibroblasts (HF) bind and retain more R123 than young HF. In an effort to determine whether this difference in R123 uptake indeed reflected a difference in mitochondrial transmembrane potential, drugs known to disrupt the transmembrane potential of mitochondria were used to monitor the R123-mitochondria interaction of young and old HF. Distinct differences indicating that old HF maintain a higher mitochondrial transmembrane potential were observed. More significantly, perhaps this difference reflects an age-related change(s) in the structure and/or function of mitochondria.

Species-specific differences in the toxicity of rhodamine 123 towards cultured mammalian cells

The toxicity of cationic fluorescent dye, rhodamine 123, towards a number of independently established cell lines from three different species, namely human, mouse, and Chinese hamster, has been examined. All of the cell lines from any one species that were examined were found to exhibit similar sensitivities towards rhodamine 123 and no appreciable differences were observed between the normal and transformed cell types. However, in comparison to the cells of human origin, mouse and Chinese hamster cell lines exhibited about 10-fold and 70-fold higher resistance, respectively, and these differences appeared to be species related. In contrast to rhodamine 123, no differences in relative toxicities for these cell lines were observed for the structurally related neutral dye, rhodamine B. Fluorescence studies with rhodamine 123 show that in comparison to mouse and Chinese hamster cells, the more sensitive human cells show much higher uptake/binding of the drug, and a good correlation was seen in these studies between the extent of dye uptake/binding and the relative sensitivities of cell lines to rhodamine 123. These results provide evidence that the observed species-related differences in cellular toxicities are due to differences in the cellular uptake/binding of the dye.

Intramitochondrial dyes allow selective in vitro photolysis of carcinoma cells

Carcinoma cell mitochondria preferentially accumulate and retain certain cationic dyes to a much greater extent than most normal cells. Thus, they can potentially serve as targets for highly selective photochemotherapy. We evaluated 10 rhodamine and cyanine dyes as carcinoma-specific mitochondrial photosensitizers in vitro. The most effective, N,N'-bis(2-ethyl-1,3-dioxolane)kryptocyanine (EDKC), caused marked, light-dependent killing of human bladder, squamous, and colon carcinoma cell lines after 30-min incubations at 1-0.01 microM but was minimally toxic to human keratinocytes and to normal monkey kidney epithelial cells (CV-1). Carcinoma cell phototoxicity was proportional to the amount of dye incorporated by the different cell lines. Selective killing ratios were 70-1000 for 0.1 microM dye and light doses of 100-175 J/cm2 between 680 and 720 nm.

Intracellular distribution of a platinum-rhodamine 123 complex in cis-platinum sensitive and resistant human squamous carcinoma cell lines

The platinum(II) tetrachlorodianion and two molecules of rhodamine-123 associate to form a neutral tight ion pair. To examine the intracellular fate of this ionic complex, the levels of uptake after a 1-hr exposure to a 100 microM concentration of each component of the complex, the complex itself and cis-diamminedichloroplatinum(II) (CDDP) were measured in SCC-25 cells. The uptake of Pt(Rh-123)2 was measured by two independent methods: fluorescence and 195mPt gamma-counting. There was excellent agreement between these two methods as to the amount of Pt(Rh-123)2 which was taken up by the cells, indicating that the Pt(Rh-123)2 is probably entering cell intact. Association with Rh-123 increased the amount of platinum which entered the cells by about 70-fold compared to CDDP and increased by about 700-fold the amount of platinum which entered the cells compared to K2PtCl4. The subcellular distributions of Pt(Rh-123)2, Rh-123, CDDP and K2PtCl4 were also examined. When measured by fluorescence or 195mPt gamma-counting, 40-54% of the Pt(Rh-123)2 was in the nuclei of the SCC-25 or SCC-25/CP cells and 27-35% was in the cytosol of the cells. There was excellent agreement between the findings of fluorescence and 195mPt gamma-counting regarding the amount of Pt(Rh-123)2 in each of the subcellular fractions immediately after incubation with the drug and over the time course of observation after drug removal, indicating that the Pt(Rh-123)2 is probably remaining largely intact intracellularly. On a per mg protein basis, there was about a 55-fold greater amount of platinum in the nuclei of the SCC-25 cells exposed to Pt(Rh-123)2 compared to cells exposed to CDDP. In the SCC-25/CP cells, there was about 258-fold greater platinum in the nuclei of cells exposed to Pt(Rh-123)2 than those exposed to CDDP because CDDP was taken up to a much lesser extent by the SCC-25/CP cells. Association of Rh-123 with potassium tetrachlorodianion forms a tight ion pair, which enters cells in relatively high amounts and is selectively concentrated in the nuclei of the cells.