Quantitative confocal spectral imaging analysis of mitoxantrone within living K562 cells: intracellular accumulation and distribution of monomers, aggregates, naphtoquinoxaline metabolite, and drug-target complexes

Confocal spectral imaging (CSI) technique was used for quantitative analysis of the uptake, subcellular localization, and characteristics of localized binding and retention of anticancer agent mitoxantrone (MITOX) within human K562 erythroleukemia cells. The CSI technique enables identification of the state and interactions of the drug within the living cells. Utilizing this unique property of the method, intracellular distributions were examined for monomeric MITOX in polar environment, MITOX bound with hydrophobic cellular structures, naphthoquinoxaline metabolite, and nucleic acid-related complexes of MITOX. The features revealed were compared for the cells treated with 2 microM or 10 microM of MITOX for 1 h and correlated to the known data on antitumor action of the drug. MITOX was found to exhibit high tendency to self-aggregation within intracellular media. The aggregates are concluded to be a determinant of long-term intracellular retention of the drug and a source of persistent intracellular binding of MITOX. Considerable penetration of MITOX in the hydrophobic cytoskeleton structures as well as growing accumulation of MITOX bound to nucleic acids within the nucleus were found to occur in the cells treated with a high concentration of the drug. These effects may be among the factors stimulating and/or accompanying high-dose mitoxantrone-induced programmed cell death or apoptosis.     

Synergistic effect of the combination of nanoparticulate Fe3O4 and Au with daunomycin on K562/A02 cells

In this study, we have explored the possibility of the combination of the high reactivity of nano Fe3O4 or Au nanoparticles and daunomycin, one of the most important antitumor drugs in the treatment of acute leukemia clinically, to inhibit MDR of K562/A02 cells. Initially, to determine whether the magnetic nanoparticle Fe3O4 and Au can facilitate the anticancer drug to reverse the resistance of cancer cells, we have explored the cytotoxic effect of daunomycin (DNR) with and without the magnetic nano-Fe3O4 or nano-Au on K562 and K562/A02 cells by MTT assay. Besides, the intracellular DNR concentration and apoptosis of the K562/A02 cells was further investigated by flow cytometry and confocal fluorescence microscopic studies. The MDR1 gene expression of the K562/A02 cells was also studied by RT-PCR method. Our results indicate that 5.0 x 10(-7) M nano-Fe3O4 or 2.0 x 10(-8) M nano-Au is biocompatible and can apparently raise the intracellular DNR accumulation of the K562/A02 cells and increase the apoptosis of tumor cells. Moreover, our observations illustrate that although these two kinds of nanoparticles themselves could not lower the MDRI gene expression of the K562/A02 cells, yet they could degrade the MDR1 gene level when combining with anticancer drug DNR. This raises the possibility to combine the nano-Fe3O4 or nano-Au with DNR to reverse the drug resistance of K562/A02 cells, which could offer a new strategy for the promising efficient chemotherapy of the leukemia patients.     

New insights in the cellular processing of platinum antitumor compounds, using fluorophore-labeled platinum complexes and digital fluorescence microscopy

The cellular distribution and processing pathways of two platinum compounds, modeling the antitumor drug cisplatin (cDDP) in human osteosarcoma (U2-OS) cells is reported. A [Pt(en)Cl] entity has been covalently linked to a carboxyfluorescein diacetate (CFDA) moiety and to a dinitrophenyl (DNP) moiety. The two different constructs were administered to living cell cultures that were analyzed using digital fluorescence microscopy. The non-fluorescent CFDA construct becomes fluorescent after cellular uptake and subsequent acetate hydrolysis by esterases, and is therefore suitable to monitor platinum in living cells; the DNP construct can be visualized by immunocytochemistry and consequently serves as a control. Both complexes were readily internalized by the cells, and localized throughout the whole cell. After 2-3 h the complex accumulated in the nucleus, but 6-8 h after incubation a punctuate staining of a cytoplasmic region was observed, that persisted and became more pronounced after 24 h. The overall fluorescence in the cell decreased over time, implying a secretion of the platinum complex. Surprisingly, the accumulation remained visible after 72 h. Co-localization experiments with a Golgi apparatus-selective stain indicate the involvement of Golgi vesicles in intracellular processing of cisplatin-derived complexes. Immunocytochemical studies, using the DNP derivative, resulted in very similar images as obtained with the CFDA construct. CFDA-boc (a non-platinum-containing fluorescein derivative) was used as control: a faint staining throughout the whole cell was observed. Cisplatin-resistant U2-OS/Pt cells showed staining patterns very similar to the U2-OS cells using both platinum constructs. This study illustrates that only a very small portion of the platinum complex eventually remains bound to DNA, as after 24 h no significant fluorescence could be observed in the nucleus. Cisplatin-derived complexes with fluorescent tags afford a new insight into the cellular processing of these complexes and therefore may contribute to further unraveling of the mechanism of platinum antitumor complexes.     

Circular dichroism study of the interaction of mitoxantrone, ametantrone and their Pd(II) complexes with deoxyribonucleic acid

The interaction of mitoxantrone, ametantrone and their Pd(II) complexes with DNA have been studied using absorption and circular dichroism spectroscopy. We have shown that mitoxantrone forms with Pd(II) a complex in which two Pd(II) ions are bound to two molecules of drug (D1 and D2). One Pd(II) ion is bound to the two nitrogens of the side chain on C-5 of molecule D1 and to the two nitrogens of the side chain on C-5 of molecule D2, whereas the second Pd(II) ion is bound to the nitrogens of the side chain on C-8 of molecule D1 and of molecule D2. The same complex is formed between Pd(II) and ametantrone. The stability constants for these complexes are, respectively, beta M = (1.4 +/- 0.5).10(19) and beta A = (2.5 +/- 0.5).10(18). They display antitumor activity against P 388 leukemia which compares with that of the free drugs. Interactions of the free drugs with DNA have been studied. Mitoxantrone and ametantrone are not optically active by themselves. However, through interaction with DNA, there is an induction of optical activity within the electronic transitions of both drugs. At a nucleotide/drug molar ratio lower than about 5 a CD signal of the couplet type is observed, suggesting that there is a coupling between the pi----pi transitions of the molecules of drugs intercalated between the base pairs. This coupling disappears when the molar ratio is increased. The interactions of the Pd(II) complexes with DNA do not give rise to induction of optical activity within the electronic transition of the drugs, indicating that the presence of the metal ion prevents the intercalation of the drugs between the base pairs.     

ATP/Mg2+-dependent binding of vincristine to the plasma membrane of multidrug-resistant K562 cells

To study the mechanism of active drug efflux in multidrug-resistant cells, the interaction between [3H] vincristine (VCR) and plasma membrane prepared from an adriamycin (ADM)-resistant variant (K562/ADM) of human myelogenous leukemia K562 cells was examined by filtration method. [3H]VCR bound to the plasma membrane prepared from K562/ADM cells, but not from parental K562 cells, depending on the concentrations of ATP and Mg2+. Adenosine 5'-O-(3-thio)triphosphate was not effective in the binding of [3H]VCR, indicating that ATP hydrolysis is required for this binding. Dissociation constant (Kd) of VCR binding was 0.24 +/- 0.04 microM in the presence of 3 mM ATP. In the absence of ATP, specific binding of VCR to K562/ADM membrane was also observed; however, the affinity (Kd = 9.7 +/- 3.1 microM) was 40 times lower than that observed in the presence of ATP. The high affinity VCR binding to K562/ADM membrane was dependent on temperature. The bound [3H]VCR molecules were rapidly released by unlabeled VCR added to the reaction mixture at 25 degrees C. The high affinity binding of [3H]VCR to K562/ADM membrane was inhibited by VCR, vinblastine, actinomycin D, and ADM, to which K562/ADM cells exhibit cross-resistance, whereas 5-fluorouracil and camptothecin, to which K562/ADM cells are equally sensitive as K562 cells, did not inhibit the [3H]VCR binding. Furthermore, verapamil and other agents, which are known to circumvent drug resistance by inhibiting the active efflux of antitumor agents from resistant cells, could also inhibit the high affinity [3H]VCR binding. These results indicate that ATP/Mg2+-dependent high affinity VCR binding to the membrane of resistant cells closely correlates with the active drug efflux of this resistant cell line.     

Drug sequestration in cytoplasmic organelles does not contribute to the diminished sensitivity of anthracyclines in multidrug resistant K562 cells.

Cells that acquire multidrug resistance (MDR) are characterized by a decreased accumulation of a variety of drugs. In addition, sequestration of drugs in intracellular vesicles has often been associated with MDR. However, the nature and role of intracellular vesicles in MDR are unclear. We addressed the relationship between MDR and vesicular anthracycline accumulation in the erythroleukemia cell line K562 and a drug-resistant counterpart K562/ADR that overexpresses P-glycoprotein. We used four anthracyclines (all of which are P-glycoprotein substrates): daunorubicin and idarubicin, which have good affinity for DNA and as weak bases can accumulate inside acidic compartments; hydroxyrubicin, which binds to DNA but is uncharged at physiological or acidic pH and thus cannot accumulate in acidic compartments; and WP900, an enantiomer of daunorubicin, which is a weak DNA binder but has the same pKa and lipophilicity as daunorubicin. The intrinsic fluorescence of anthracyclines allowed us to use macro- and micro-spectrofluorescence, flow cytometry, and confocal microscopy to characterize their nuclear or intravesicular accumulation in living cells. We found that vesicular accumulation of daunorubicin, WP900 and idarubicin, containing a basic 3'-amine was predominantly restricted to lysosomes in both cell lines, that pH regulation of acidic compartments was not defective in human K562 cells, and that vesicular drug accumulation was much more pronounced in the parental tumor cell line than in the multidrug-resistant cells. These results indicate that vesicular anthracycline sequestration does not contribute to the diminished sensitivity to anthracyclines in multidrug-resistant K562 cells.     

Mitoxantrone changes spectrin-aminophospholipid interactions

Understanding drug-membrane and drug-membrane protein interactions would be a crucial step towards understanding the action and biological properties of anthracyclines, as the cell membrane with its integral and peripheral proteins is the first barrier encountered by these drugs. In this paper, we briefly describe mitoxantrone-monolayer and mitoxantrone-bilayer interactions, focusing on the effect of mitoxantrone on the interactions between erythroid or nonerythroid spectrin with phosphatidylethanolamine-enriched mono- and bilayers. We found that mitoxantrone markedly modifies the interaction of erythroid and nonerythroid spectrins with phosphatidylethanolamine/phosphatidylcholine (PE/PC) monolayers. The change in delta pi induced by spectrins is several-fold larger in the presence of 72 nM mitoxantrone than in its absence: spectrin/mitoxantrone complexes induced a strong compression of the monolayer. Spin-labelling experiments showed that spectrin/mitoxantrone complexes caused significant changes in the order parameter measured using a 5'-doxyl stearate probe in the bilayer, but they practically did not affect the mobility of 16'-doxyl stearate. These results indicate close-to-surface interactions/penetrations without significant effect on the mid-region of the hydrophobic core of the bilayer. The obtained apparent equilibrium dissociation constants indicated relatively similar mitoxantrone-phospholipid and mitoxantrone-spectrin (erythroid and nonerythroid) binding affinities. These results might in part, explain the effect of mitoxantrone on spectrin distribution in the living cells.     

Mitoxantrone changes spectrin-aminophospholipid interactions

Understanding drug-membrane and drug-membrane protein interactions would be a crucial step towards understanding the action and biological properties of anthracyclines, as the cell membrane with its integral and peripheral proteins is the first barrier encountered by these drugs. In this paper, we briefly describe mitoxantrone-monolayer and mitoxantrone-bilayer interactions, focusing on the effect of mitoxantrone on the interactions between erythroid or nonerythroid spectrin with phosphatidylethanolamine-enriched mono- and bilayers. We found that mitoxantrone markedly modifies the interaction of erythroid and nonerythroid spectrins with phosphatidylethanolamine/phosphatitydcholine (PE/PC) monolayers. The change in Δπ induced by spectrins is several-fold larger in the presence of 72?nM mitoxantrone than in its absence: spectrin/mitoxantrone complexes induced a strong compression of the monolayer. Spin-labelling experiments showed that spectrin/mitoxantrone complexes caused significant changes in the order parameter measured using a 5′-doxyl stearate probe in the bilayer, but they practically did not affect the mobility of 16′-doxyl stearate. These results indicate close-to-surface interactions/penetrations without significant effect on the mid-region of the hydrophobic core of the bilayer. The obtained apparent equilibrium dissociation constants indicated relatively similar mitoxantrone-phospholipid and mitoxantrone-spectrin (erythroid and nonerythroid) binding affinities. These results might in part, explain the effect of mitoxantrone on spectrin distribution in the living cells.     

Mass spectrometry approaches to monitor protein-drug interactions

Recent advances in mass spectrometry-based approaches have enabled the investigation of drug-protein interactions in various ways including the direct detection of drug-target complexes, the examination of drug-induced changes in the target protein structure, and the monitoring of enzymatic target activity. Mass spectrometry-based proteomics methods also permit the unbiased analysis of changes in protein abundance and post-translational modifications induced by drug action. Finally, chemoproteomic affinity enrichment studies enable the deconvolution of drug targets under close to physiological conditions. This review provides an overview of current methods for the characterization of drug-target interactions by mass spectrometry and describes a protocol for chemoproteomic target binding studies using immobilized bioactive molecules.     

Immunogold labelling of tumour cells during NK/target cell interactions

Using a system of immunocolloidal gold labelling, we have monitored the expression and distribution of transferrin receptors (TfRs) within the K562 cell line, during NK/target cell interactions. An indirect method of immunolabelling was used to effectively immunolabel tumour cells without disrupting the natural effector:target interactions. Successful localization of TfRs demonstrates the potential of the described technique for discerning antigenic distribution of other cell:cell interactions. Immunolabelling has also provided a useful method for demonstrating receptor down-regulation within NK target cells, as a proposed cause of reduced receptor expression by TPA-treated cells. Following 30 and 60 min incubation periods with TPA, approximately 15 and 30%, respectively, of the gold/antibody complexes were relocated from the surface membrane to an intracellular location within endocytotic vesicles. The demonstration of receptor down-regulation is important as a proposed cause of TPA-induced tumour cell resistance to NK-mediated cytolysis.     

Changes in the Expression of miR-381 and miR-495 Are Inversely Associated with the Expression of the MDR1 Gene and Development of Multi-Drug Resistance

Multidrug resistance (MDR) frequently develops in cancer patients exposed to chemotherapeutic agents and is usually brought about by over-expression of P-glycoprotein (P-gp) which acts as a drug efflux pump to reduce the intracellular concentration of the drug(s). Thus, inhibiting P-gp expression might assist in overcoming MDR in cancer chemotherapy. MiRNAome profiling using next-generation sequencing identified differentially expressed microRNAs (miRs) between parental K562 cells and MDR K562 cells (K562/ADM) induced by adriamycin treatment. Two miRs, miR-381 and miR-495, that were strongly down-regulated in K562/ADM cells, are validated to target the 3’-UTR of the MDR1 gene. These miRs are located within a miR cluster located at chromosome region 14q32.31, and all miRs in this cluster appear to be down-regulated in K562/ADM cells. Functional analysis indicated that restoring expression of miR-381 or miR-495 in K562/ADM cells was correlated with reduced expression of the MDR1 gene and its protein product, P-gp, and increased drug uptake by the cells. Thus, we have demonstrated that changing the levels of certain miR species modulates the MDR phenotype in leukemia cells, and propose further exploration of the use of miR-based therapies to overcome MDR.     

Bioregulatory mechanisms at the level of cell organelle interactions: microspectrofluorometric in situ studies.

The spatiotemporal analysis of bioregulatory mechanisms at the level of intracellular multienzyme complexes and organelle interactions is made possible by the availability of endogenous and exogenous fluorescence probes, the development of microspectrofluorometers allowing one- and two-dimensional scans of intracellular fluorescence reactions, and the use of micromanipulatory techniques enabling the rapid alteration of metabolic states. Absorbed photons are not only a tool for quantitative evaluation of metabolic processes, they can also trigger alterations of cell membranes and functions as mediated by photosensitizer drugs. In the hierarchy of intracellular organization different levels of complexity are accessible to study, such as the regulation of multienzyme complexes and the interaction of organelle complexes. Typical applications of these methods are the investigation of drug effects (e.g., on melanoma cells), metabolic and structural alterations (e.g., in cystic fibrosis and Gaucher fibroblasts), organelle interactions in cells treated with toxic agents. The implications are relevant to biotechnology for better control of metabolite production and processing, design and testing of new drugs, understanding of drug resistance and better targeting of drugs or probes to selected intracellular sites. In addition, such in vitro methods can contribute to the provision of an alternative to "whole animal experiments" as already achieved in human and mouse fibroblasts, hepatocytes, hepatoma, Swiss 3T3 cells and other cells in culture, especially with regards to an analysis of the action of xenobiotics and drugs in cell physiology and pathology, fluorescence recovery after photobleaching, study of cytoskeleton dynamics and multiparameter probing of organelle activity during in vitro wound repair.     

Fluorescent verapamil analogue for monitoring acidic intracellular organelles in multidrug resistant and sensitive cells

Resistance to chemotherapeutic agent is a major cause of treatment failure in patients with cancer. In many cases, the primaly mechanism leading to a multidrug-resistant phenotype is the plasma-membrane localized overexpression of drug efflux transporters, such as P-glycoprotein. However, acidic intracellular organelles seem also to participate in resistance to chemotherapeutic drugs and the determination of the pH of these organelles is of importance. In the present study we have used a new fluorescent derivative of verapamil, 2-2-diphenyl-5-[(methylaminomethyl)anthracene] pentanenitrile (EDP 96), and show that it is an efficient inhibitor of the P-gp-mediated efflux of anthracycline in K562 resistant cells. The fluorescence of EDP 96 is environmental and pH sensitive. EDP 96 is a weak base (pKa=6.0) and its accumulation into K562 cells is accompanied by a significant fluorescence increase due to its entry of the drug into acidic regions in the cells. We have used this properties to develop a new method to accurately determine the pH of acidic organelle.     

Changes in the free-radical state and level of free iron during the formation of drug resistance in tumor cells

The development of resistance of K562 human erythroleukemia cells to doxorubicin, a widely used antitumor antibiotic with the prooxidant action, leads to changes in the free-radical state of cells. It has been found that the formation of superoxide anion in resistant cells decreases. The introduction of doxorubicin to the culture medium induced a considerably lesser increase in the formation of O2*- in resistant cells compared to sensitive cells. At the same time, a strong decrease in the ESR signal of semiquinone type with a g-factor of 2.006 was observed in a culture of resistant cells grown in the absence of doxorubicin as compared with sensitive cells grown under similar conditions. At the same time, a decrease in the level of paramagnetic nitrosyl complexes of nonheme iron in resistant cells was recorded, indicating a decrease in the content of free nonheme iron as a result of the formation of drug resistance. In addition, a decrease in the level of mRNA of the transferrin receptor in resistant cells was found by the RT-PCR. These data indicate the development of a coodinated redox-dependent adaptive response, which makes itself evident as a suppression of free radical processes during the formation of resistance of K562 cells to doxorubicin.     

Topoisomerase II-mediated alterations of K562 drug resistant sublines

In order to further elucidate the, roles of DNA topoisomerase II (topo II) subtypes, α and β, as drug targets in chemotherapy, we have determined the enzyme levels in K562 cells selected for resistance to mitoxantrone (K562/Mxn), daunorubicin (K562/Dnr) and idarubicin (K562/Ida 20 and K562/Ida 60), as well as topo II-DNA complex formation, DNA damage and cytotoxicity, induced by topo II interactive agents, for example etoposide, teniposide, mitoxantrone and amsacrine. As compared to the parental cells, topo IIα/β protein levels in K562/Mxn, K562/Dnr, K562/Ida 20 and 60 lines, measured with Western blot, were 17/67%, 85/88, 24/31% and 10/7% respectively. DNA damage, determined by DNA unwinding technique, induced by teniposide and amsacrine correlated with both topo IIα/β protein levels (r ²=0.8/0.9,P=0.03/0.01 andr ²=0.8/0.9,P=0.04/0.01, respectively). Topo II-DNA complex formation induced by all studied drugs correlated with topo IIβ protein levels (r ²-range 0.8–0.9,P-range 0.01–0.04), while the correlation with topo IIα was weaker. Topo IIα/β protein levels tended to show an inverse correlation with the cytotoxicity of etoposide (r ²=−0.9/−0.7,P=0.01/0.06). The overall topo II-DNA complex formation correlated with drug-induced DNA damage (r ²=0.9,P=0.0001), whilst not with the cytotoxicity. Our findings indicate that both topo II isozymes are the targets of the antitumor agents studied, and of potential clinical relevance for prediction of treatment efficacy. They could play a role in tailored chemotherapy.     

PIC-BE诱导K562/ADM细胞凋亡及逆转其MDR的研究

β榄香烯吗素（ＰＩＣ－ＢＥ）是抗癌新药β榄香烯的水溶性衍生物．采用人红白血病的多药耐药性（ＭＤＲ）细胞株Ｋ５６２／ＡＤＭ作为实验模型,观察ＰＩＣ－ＢＥ对Ｋ５６２／ＡＤＭ细胞的生长抑制和凋亡诱导作用,并进而研究其对该细胞ＭＤＲ的可能影响．结果显示：（１）Ｋ５６２／ＡＤＭ细胞对ＡＤＭ具有明显的抗性,与Ｋ５６２细胞相比,抗性倍数约为４０倍,而两者对ＰＩＣ－ＢＥ的ＩＣ５０接近,无显著差异;（２）ＰＩＣ－ＢＥ（１０．０～３０．０μｇ／ｍｌ）对Ｋ５６２／ＡＤＭ细胞具有明显的生长抑制和凋亡诱导作用,两种作用的强度在一定的范围内均具药物浓度和作用时间依赖性;（３）低毒剂量ＰＩＣ－ＢＥ（１０．０μｇ／ｍｌ）与ＡＤＭ（４．０μｇ／ｍｌ）联合应用,可显著增强ＡＤＭ对该细胞的生长抑制和凋亡诱导作用,升高细胞内ＡＤＭ的浓度,降低该细胞对ＡＤＭ的ＩＣ５０,使该细胞对ＡＤＭ的抗性有数倍逆转．上述结果提示,ＰＩＣ－ＢＥ不仅是一种有效的广谱抗肿瘤剂,而且也是一种有效的ＭＤＲ逆转剂     

Changes in the free-radical state and the level of free iron during the development of drug resistance in tumor cells

The free-radical state of K562 human erythroleukemia cells changes during the development of resistance to doxorubicin, an antitumor antibiotic with prooxidant action widely used in oncology. It was found that the level of superoxide anion in the resistant cells decreased. The addition of doxorubicin to the culture medium induced a much smaller increase in O ₂ ^? generation in the resistant cells than in the sensitive cells. Again, the semiquinone-type EPR signal with a g-factor of 2.006 considerably decreased in the resistant cells grown without doxorubicin as compared with the sensitive cells under the same conditions. The EPR study has shown that the level of paramagnetic nitrosyl complexes of nonheme iron in the resistant cells decreased, which indicates that the content of free nonheme iron declined in development of drug resistance. In addition, we have found with the use of RT-PCR that the level of mRNA of the transferrin receptor decreased in the resistant cells. The data suggest that the suppression of free-radical processes during the development of resistance of K562 cells to doxorubicin is a coordinated redox-dependent adaptive response.     

Impact of exogenous lysolipids on sensitive and multidrug resistant K562 cells: 1H NMR studies

The ability of lysolipids to enter into a membrane bi-layer and disturb the membrane structure was used to study the behavior of K562 erythroleukemic cells, K562 wild type (K562wt) as well as the multidrug resistant cells K562adr. Both types of cells, when analyzed by proton NMR spectroscopy exhibit the high resolution signals assigned to so-called "mobile lipid" signals, which, in most cases, are located outside the lipid bi-layer as lipid droplets. In order to perform these studies, the K562wt and K562adr cells were treated for 48h with lysophosphatidylcholine oleoyl (LPC18), lysophosphatidylcholine palmitoyl (LPC16) and L-alpha-lysophosphatidyslerine (LPS). After evaluating toxicity of lysolipids, proton NMR of whole treated cells was used to analyze the mobile lipid content. Nile red staining and fluorescence microscopy were used to detect the presence of intracellular lipid droplets. Membrane lipid asymmetry perturbation was estimated by annexin V staining with use of flow cytometry. Using fluorescence spectroscopy the functioning of P-glycoprotein (P-gp) responsible for multidrug resistance was also evaluated after the treatment with lysolipids. Lysolipids were found to be more toxic for K562wt than for K562adr cells. LPS and LPC16 produced an increased of a mobile lipid NMR signal and amount of lipid droplets in K562wt cells only. LPC18, with the lowest toxicity, has shown more intense effects on NMR spectra with a large increase of lipid NMR signal without changes in lipid droplet staining. The functioning of the P-gp pump and membrane asymmetry were not modified by any of the lysolipids used.