Verena E. Plattner

Targeted drug delivery : Binding and uptake of plant lectins using human 5637 bladder cancer cells

In an effort to detect novel strategies in bladder cancer therapy, the potential and the applicability of different plant lectins was investigated using 5637 cells as a model for human urinary carcinoma. The cell-lectin interaction studies were performed with single cells as well as monolayers using flow cytometry and fluorimetry. As a result, wheat germ agglutinin (WGA) and Ulex europaeus agglutinin (UEA) revealed strongest interaction with single cells demonstrating a high presence of N-acetyl-d-glucosamine, sialic acid and alpha-l-fucose residues on the membrane surface. Considering monolayers, binding of most lectins depended on the culturing period pointing to a change in the glycocalyx composition during cultivation. However, constant binding capacities combined with a high specificity were detected for WGA. Cytoinvasion studies were performed with WGA and revealed a decreased fluorescence intensity at 37 degrees C as compared to 4 degrees C, which points to internalisation of the lectin and accumulation in acidic compartments. Intracellular localization was confirmed by addition of monensin that compensates the pH-gradient between acidic compartments and cytoplasm leading to a full reversal of the decline in fluorescence. According to these findings, some lectins, especially WGA, offer promising features for targeting drugs to bladder cancer cells. This might be interesting for the development of functionalized drug delivery systems for site specific antitumor therapy leading to reduced toxicity, prolonged exposition, and improved efficacy.

Validation of in vitro cell culture models of the blood–brain barrier: Tightness characterization of two promising cell lines

In the course of the validation of blood-brain barrier in vitro models the aim of this work was to characterize two promising continuous cell lines with regard to their tightness properties. PBMEC/C1-2 and ECV304 cells were cultured in several media with different compositions on Transwell inserts. Inducibility and functionality of tightness were investigated by transendothelial electrical resistance (TEER) and by transport studies with transcellular marker diazepam, glycine antagonist Bu101 and paracellular marker APTS-dextran. Inducibility, expression and localization of tight junctional proteins were assessed by western blotting and immunofluorescence microscopy. Presence of factors derived from glioma cell line C6 resulted in increased TEER in both cell lines. Comparison to APTS-dextran data across Caco-2 layers emphasized that correlations between permeability of the paracellular marker and TEER are dependent on each investigated cell line and the corresponding growth medium. Presence and inducibility of tight junctional proteins ZO-1 and Occludin were proven for ECV304 layers. Cell line ECV304 seemed to be suitable for TEER dependent transport studies, whereas PBMEC/C1-2 showed higher potential for P-gP studies.

Lectin Mediated Biorecognition as a Novel Strategy for Targeted Delivery to Bladder Cancer

PURPOSE Inadequate urothelial delivery of drugs is considered a primary cause of current shortcomings in adjuvant intravesical chemotherapy for bladder cancer. We report what is to our knowledge a novel biorecognitive approach to achieve more regionally selective targeting of malignant tissue and improve urothelial uptake based on specific interaction between lectins and bladder cell glycocalyces. MATERIALS AND METHODS We assessed the cytoadhesive and cytoinvasive potential of selected plant lectins in 3 human urothelial cell lines, corresponding to healthy tissue, and low and high grade carcinoma, respectively. Flow cytometry and fluorimetry were used to determine binding capacity and specificity in single cells and confluent monolayers. Monensin quenching experiments, microscopic analysis and enzyme treatment allowed further characterization of internalization, the uptake pathway and the potential cause of tumor selectivity. RESULTS Wheat germ agglutinin had the highest bioadhesive potential while peanut agglutinin was the most potent discriminator between healthy and cancerous tissue (p <0.01). In each case cell interaction was highly specific (greater than 80%) and proved decisive for efficient uptake. Within 60 minutes after exposure greater than 50% of membrane bound lectins were internalized in acidic compartments. Cancer associated aberrant glycosylation likely represents the determining cause of peanut agglutinin selectivity. CONCLUSIONS Given careful choice of the targeting ligand, the development of carbohydrate based delivery strategies for bladder cancer therapy seems feasible. Lectin bioadhesion may not only mediate preferential accumulation in malignant tissue but also promote cellular internalization via increased recruitment of membrane bound material to physiological uptake routes.

Expression of Claudin-1, Claudin-3 and Claudin-5 in human blood–brain barrier mimicking cell line ECV304 is inducible by glioma-conditioned media

Up to now no standard cell culture model of the blood-brain barrier is available. However, several models based on primary cells or continuous cell lines have been characterized and described in respect of different applications. One of the most important characteristics of the blood-brain barrier is the restriction of paracellular transport, respectively its tightness. Human cell line ECV304 is one of the promising continuous cell lines for blood-brain barrier modelling due to two reasons: on the one hand the cells are able to form significant tighter layers than most of the other cell lines used and on the other hand several properties of the blood-brain barrier are inducible by using glioma-conditioned medium. Claudins are transmembranal proteins which form the backbone of the tight junctions at the blood-brain barrier. We have investigated the presence and inducibility of the expression of Claudin-1, Claudin-3 and Claudin-5 using immunofluorescence microscopy. For the first time this study proves the presence of Claudin-1, Claudin-3 and Claudin-5 in ECV304 (obtained from ECACC) cell layers and the inducibility of their expression by glioma-conditioned media.

Strategies to improve drug delivery in bladder cancer therapy

Bladder cancer is the ninth most common malignancy in the world featuring very high gender variability in occurrence. Current options for bladder cancer therapy include surgery, immunotherapy, chemotherapy and radiotherapy with a trend towards multimodal treatments. However, successful management remains a challenge for urologists and oncologists because of the high risk for recurrence and progression. Particularly in the field of bladder cancer chemotherapy, efficacy of treatment might be improved by advanced drug delivery strategies aimed at prolonged residence time within the bladder cavity and increased permeability of the bladder wall during intravesical instillation. Moreover, a deeper understanding of the biology of bladder carcinogenesis and malignant progression stimulated the development of a new generation of anticancer drugs for targeted therapies that might result in increased treatment specificity together with lower toxic potential and higher therapeutic indices. This review discusses the available strategies for ‘targeted therapy’, focusing on molecular targets, and for ‘controlled delivery’, comprising all other approaches towards improved drug delivery.

Lectin binding patterns reflect the phenotypic status of in vitro chondrocyte models

In vitro studies using chondrocyte cell cultures have increased our understanding of cartilage physiology and the altered chondrocytic cell phenotype in joint diseases. Beside the use of primary cells isolated from cartilage specimens of donors, immortalized chondrocyte cell lines such as C-28/I2 and T/C-28a2 have facilitated reproducible and standardized experiments. Although carbohydrate structures appear of significance for cartilage function, the contribution of the chondrocyte glycocalyx to matrix assembly and alterations of the chondrocyte phenotype is poorly understood. Therefore, the present study aimed to evaluate the glycoprofile of primary human chondrocytes as well as of C-28/I2 and T/C-28a2 cells in culture. First, the chondrocytic phenotype of primary and immortalized cells was assessed using real-time reverse transcriptase polymerase chain reaction, immunofluorescence, and glycosaminoglycans staining. Then, a panel of lectins was selected to probe for a range of oligosaccharide sequences determining specific products of the O-glycosylation and N-glycosylation pathways. We found that differences in the molecular phenotype between primary chondrocytes and the immortalized chondrocyte cell models C-28/I2 and T/C-28a2 are reflected in the glycoprofile of the cells. In this regard, the glycocalyx of immortalized chondrocytes was characterized by reduced levels of high-mannose type and sialic acid-capped N-glycans as well as increased fucosylated O-glycosylation products. In summary, the present report emphasizes the glycophenotype as an integral part of the chondrocyte phenotype and points at a significant role of the glycophenotype in chondrocyte differentiation.

Characterization of two blood-brain barrier mimicking cell lines: distribution of lectin-binding sites and perspectives for drug delivery.

In the present study plant lectins with distinct sugar specificities were applied to two blood-brain barrier (BBB) mimicking cell lines, namely human ECV304 and porcine brain microvascular endothelial cells PBMEC/C1-2 in order to elucidate their glycosylation pattern and to evaluate the lectin-cell interaction for lectin-mediated targeting. The bioadhesive properties of fluorescein-labeled lectins were investigated with monolayers as well as single cells using fluorimetry and flow cytometry, followed by confirmation of the specificity of binding. For PBMEC/C1-2 layers highest binding capacity was found for wheat germ agglutinin (WGA), followed by Dolichus biflorus agglutinin (DBA) whereas single cell experiments revealed a predominance of DBA only. Analyzing ECV304 monolayers and single cells, WGA yielded the strongest interaction without any changes during cultivation. The binding capacities of the other lectins increased significantly during differentiation. As similar results to primary cells and brain sections were observed, both cell lines seem to be suitable as models for lectin-interaction studies. Thus, an additional focus was set on the mechanisms involved in uptake and intracellular fate of selected lectins. Cytoinvasion studies were performed with WGA for human ECV304 cells and WGA as well as DBA for PBMEC/C1-2 cells. For both lectins, the association rate to the cells was dependent on temperature which indicated cellular uptake.

Alteration of the glycosylation pattern of monocytic THP-1 cells upon differentiation and its impact on lectin-mediated drug delivery

In the present study, human monocytic THP-1 cells were treated with phorbol-12-myristate-13-acetate (PMA) in order to obtain macrophage-like cells. Before and after treatment, plant lectins with distinct sugar specificities were applied in order to elucidate the glycosylation patterns of both monocytic and macrophage-like cell types and to follow changes during differentiation. As a result of flow-cytometric analyses, for untreated as well as for PMA-differentiated cells WGA yielded the highest binding rate without significant changes in the binding capacity. For the other lectins, divergent results were obtained which point to reorganization of sugar residues on the cell surface during differentiation. Additionally, cytoinvasion being beneficial for enhanced drug absorption was studied with WGA which had displayed a high binding capacity together with a high specificity. For both untreated and PMA-differentiated cells decreased fluorescence intensity at 37 degrees C as compared to 4 degrees C was observable pointing to internalization and accumulation within acidic compartments. Moreover, WGA-functionalized PLGA nanoparticles were prepared, and their uptake evaluated. Uptake rates of 55% in case of PMA-differentiated cells suggested that WGA-grafted drug delivery systems might be an interesting approach for treatment of infectious diseases provoked by parasites, facultative intracellular bacteria, or viruses such as HIV.