Magdalena Cañete

The influence of surface functionalization on the enhanced internalization of magnetic nanoparticles in cancer cells

The internalization and biocompatibility of iron oxide nanoparticles surface functionalized with four differently charged carbohydrates have been tested in the human cervical carcinoma cell line (HeLa). Neutral, positive, and negative iron oxide nanoparticles were obtained by coating with dextran, aminodextran, heparin, and dimercaptosuccinic acid, resulting in colloidal suspensions stable at pH 7 with similar aggregate size. No intracellular uptake was detected in cells incubated with neutral charged nanoparticles, while negative particles showed different behaviour depending on the nature of the coating. Thus, dimercaptosuccinic-coated nanoparticles showed low cellular uptake with non-toxic effects, while heparin-coated particles showed cellular uptake only at high nanoparticle concentrations and induced abnormal mitotic spindle configurations. Finally, cationic magnetic nanoparticles show excellent properties for possible in vivo biomedical applications such as cell tracking by magnetic resonance imaging (MRI) and cancer treatment by hyperthermia: (i) they enter into cells with high effectiveness, and are localized in endosomes; (ii) they can be easily detected inside cells by optical microscopy, (iii) they are retained for relatively long periods of time, and (iv) they do not induce any cytotoxicity.

MTT assay for cell viability: Intracellular localization of the formazan product is in lipid droplets

Although MTT is widely used to assess cytotoxicity and cell viability, the precise localization of its reduced formazan product is still unclear. In the present study the localization of MTT formazan was studied by direct microscopic observation of living HeLa cells and by colocalization analysis with organelle-selective fluorescent probes. MTT formazan granules did not colocalize with mitochondria as revealed by rhodamine 123 labeling or autofluorescence. Likewise, no colocalization was observed between MTT formazan granules and lysosomes labeled by neutral red. Taking into account the lipophilic character and lipid solubility of MTT formazan, an evaluation of the MTT reaction was performed after treatment of cells with sunflower oil emulsions to induce a massive occurrence of lipid droplets. Under this condition, lipid droplets revealed a large amount of MTT formazan deposits. Kinetic studies on the viability of MTT-treated cells showed no harmful effects at short times. Quantitative structure-activity relations (QSAR) models were used to predict and explain the localization of both the MTT tetrazolium salt and its formazan product. These predictions were in agreement with experimental observations on the accumulation of MTT formazan product in lipid droplets.

Morphological criteria to distinguish cell death induced by apoptotic and necrotic treatments.

We present a comparative study of apoptotic and necrotic morphology (light and scanning electron microscopy), induced by well known experimental conditions (photodynamic treatments, etoposide, hydrogen peroxide, freezing-thawing and serum deprivation) on cell cultures. Our results indicate that morphological criteria (apoptotic cell rounding and shrinkage, and appearance of membrane bubbles in early necrosis) allow to distinguish these cell death mechanisms, and also show that, independently of the damaging agents, the necrotic process occurs in a characteristic sequence (coalescence of membrane bubbles in a single big one that detaches from cells remaining on the substrate).

Porphycenes: Facts and Prospects in Photodynamic Therapy of Cancer

The photodynamic process induces cell damage and death by the combined effect of a photosensitizer (PS), visible light, and molecular oxygen, which generate singlet oxygen ((1)O(2)) and other reactive oxygen species that are responsible for cytotoxicity. The most important application of this process with increasing biomedical interest is the photodynamic therapy (PDT) of cancer. In addition to hematoporphyrin-based drugs, 2nd generation PSs with better photochemical properties are now studied using cell cultures, experimental tumors and clinical trials. Porphycene is a structural isomer of porphyrin and constitutes an interesting new class of PS. Porphycene derivatives show higher absorption than porphyrins in the red spectral region (lambda > 600 nm, epsilon > 50000 M-(1)cm(-1)) owing to the lower molecular symmetry. Photophysical and photobiological properties of porphycenes make them excellent candidates as PSs, showing fast uptake and diverse subcellular localizations (mainly membranous organelles). Several tetraalkylporphycenes and the tetraphenyl derivative (TPPo) induce photodamage and cell death in vitro. Photodynamic treatments of cultured tumor cells with TPPo and its palladium(II) complex induce cytoskeletal changes, mitotic blockage, and dose-dependent apoptotic or necrotic cell death. Some pharmacokinetic and phototherapeutic studies on experimental tumors after intravenous or topical application of lipophilic alkyl-substituted porphycene derivatives are known. Taking into account all these features, porphycene PSs should be very useful for PDT of cancer and other biomedical applications.

Synthesis of 2,7,12,17-tetraphenylporphycene (TPPo). First aryl-substituted porphycene for the photodynamic therapy of tumors

Abstract We report on the synthesis of 2,7,12,17-tetraphenylporphycene (TPPo), the first example of an aryl-substituted porphycene macrocycle. A modification of the general porphycene synthetic method has been used, thus avoiding an intermediate sublimation. TPPo has an absorption maximum at 659 nm ( e = 50.000 M −1 cm −1 ), and shows good sensitizing properties: it photoproduces singlet oxygen with a quantum yield of ca. 0.25, is phototoxic to cells, and has low dark toxicity. These properties make TPPo a suitable candidate for the photodynamic therapy of tumors.

Liver and brain imaging through dimercaptosuccinic acid-coated iron oxide nanoparticles

BACKGROUND & AIM Uptake, cytotoxicity and interaction of improved superparamagnetic iron oxide nanoparticles were studied in cells, tissues and organs after single and multiple exposures. MATERIAL & METHOD We prepared dimercaptosuccinic acid-coated iron oxide nanoparticles by thermal decomposition in organic medium, resulting in aqueous suspensions with a small hydrodynamic size (< 100 nm), high saturation magnetization and susceptibility, high nuclear magnetic resonance contrast and low cytotoxicity. RESULTS In vitro and in vivo behavior showed that these nanoparticles are efficient carriers for drug delivery to the liver and brain that can be combined with MRI detection.

Do folate-receptor targeted liposomal photosensitizers enhance photodynamic therapy selectivity?

One of the current goals in photodynamic therapy research is to enhance the selective targeting of tumor cells in order to minimize the risk and the extension of unwanted side-effects caused by normal cell damage. Special attention is given to receptor mediated delivery systems, in particular, to those targeted to folate receptor. Incorporation of a model photosensitizer (ZnTPP) into a folate-targeted liposomal formulation has been shown to lead an uptake by HeLa cells (folate receptor positive cells) 2-fold higher than the non-targeted formulation. As a result, the photocytotoxicity induced by folate-targeted liposomes was improved. This selectivity was completely inhibited with an excess of folic acid present in the cell culture media. Moreover, A549 cells (folate receptor deficient cells) have not shown variations in the liposomal incorporation. Nevertheless, the differences observed were slighter than expected. Both folate-targeted and non-targeted liposomes localize in acidic lysosomes, which confirms that the non-specific adsorptive pathway is also involved. These results are consistent with the singlet oxygen kinetics measured in living cells treated with both liposomal formulations.

Loss of e-cadherin mediated cell-cell adhesion as an early trigger of apoptosis induced by photodynamic treatment

Photodynamic treatment with different photosensitizers (PSs) can result in the specific induction of apoptosis in many cell types. It is commonly accepted that this apoptotic response depends on the mitochondrial accumulation of the PS. Accumulation in other cellular organelles, such as lysosomes or the Golgi complex, and subsequent photodamage resulting in an apoptotic process has been also described. However, the role played by cell adhesion in apoptosis induced in epithelial cells after photodynamic treatment is not well characterized. Here, we have used a murine keratinocyte line, showing a strong dependence on E‐cadherin for cell–cell adhesion and survival, to analyze the relevance of this adhesion complex in the context of zinc(II)‐phthalocyanine (ZnPc) photodynamic treatment. We report that under apoptotic conditions, ZnPc phototreatment induces a rapid disorganization of the E‐cadherin mediated cell–cell adhesion, which largely preceded both the detachment of cells from the substrate, via β‐1 integrins and the induction of apoptotic mitochondrial markers. Therefore, the alteration in E‐cadherin, α‐ and β‐catenins adhesion proteins preceded the release of cytochrome c (cyt c) from mitochondria to the cytosol and the activation of caspase 3. In addition, blocking E‐cadherin function with a specific antibody (Decma‐1) induced apoptosis in this cell system. These results strongly suggest that the E‐cadherin adhesion complex could be the primary target of ZnPc phototreatment, and that loss of E‐cadherin mediated cell adhesion after early photodamage triggers an apoptotic response.

Photodynamic damage to HeLa cell microtubules induced by thiazine dyes

Abstract The aim of this study was to analyze possible alterations of the microtubule cytoskeleton of cultured cells subjected to photodynamic treatments with the thiazine dyes methylene blue or toluidine blue. Indirect immunofluorescence labeling of α-tubulin was performed in HeLa cells after 1 or 18 h of incubation with thiazines followed by red-light irradiation for 15 min [leading to surviving fractions (SF) of about 65% (SF65) or 1% (SF1), respectively]. Untreated control cells showed the normal distribution of interphase microtubules, whereas considerable or severe disorganization of the microtubule network was observed after SF65 or SF1 photodynamic treatments, respectively. A great amount of blebs showing homogeneous fluorescence was also found on the cell surface after SF1 treatments. Possible mechanisms responsible for the photodamage to microtubules induced by thiazine dyes are briefly discussed.

Photodamage Induced by Zinc(II)-phthalocyanine to Microtubules, Actin, α-Actinin and Keratin of HeLa Cells¶

We have studied the photosensitizing effects of zinc(II)‐phthalocyanine (ZnPc) on the cytoskeleton of HeLa cells using sublethal (10−7M, followed by 1 or 3 min of red light to induce 20%, LD20, or 60%, LD60, cell death, respectively) or lethal (5 × 10−6M and 15 min of irradiation, LD100) experimental conditions. The immunofluorescent analysis of the cytoskeleton showed a variable photodamage to microtubules (MT), actin microfilaments (AF) and intermediate filaments of keratin (KF), as well as on α‐actinin, which was dependent on treatment conditions. Both sublethal treatments induced deep alterations on interphase and mitotic MT. The mitotic index increased with time with the maximum at 18 h (12%) or 24 h (14%) after LD20 or LD60, respectively. The alterations on AF and α‐actinin were much more severe than those observed on KF at any evaluated time. With the exception of the KF, which remained partially organized, the MT and AF network was severely damaged by the lethal treatment. Western blot analysis for α‐tubulin, G‐actin and α‐actinin from soluble and insoluble fractions confirmed the results observed by immunofluorescence, thus indicating that these cytoskeletal components are involved in cell damage and death by ZnPc photosensitization.