Comparison of human hepatoma HepaRG cells with human and rat hepatocytes in uptake transport assays in order to predict drug induced hepatotoxicity

Human hepatocytes are the gold standard for toxicological studies but they have several drawbacks, like scarce availability, high inter-individual variability, a short lifetime, which limits their applicability. The aim of our investigations was to determine, whether HepaRG cells could replace human hepatocytes in uptake experiments for toxicity studies. HepaRG is a hepatoma cell line with most hepatic functions, including a considerable expression of uptake transporters in contrast to other hepatic immortalized cell lines. We compared the effect of cholestatic drugs (bosentan, cyclosporinA, troglitazone,) and bromosulfophthalein on the uptake of taurocholate and estrone-3-sulfate in human and rat hepatocytes and HepaRG cells. The substrate uptake was significantly slower in HepaRG cells than in human hepatocytes, still, in the presence of drugs we observed a concentration dependent decrease in uptake. In all cell types, the culture time had a significant impact not only on the uptake process but on the inhibitory effect of drugs too. The most significant drug effect was measured at 4 h after seeding. Our report is among the first concerning interactions of the uptake transporters in the HepaRG, at the functional level. Results of the present study clearly show that concerning the inhibition of taurocholate uptake by cholestatic drugs, HepaRG cells are closer to human hepatocytes than rat hepatocytes. In conclusion, we demonstrated that HepaRG cells provide a suitable tool for hepatic uptake studies

Comparative analysis of new peptide conjugates of antitubercular drug candidates – model membrane and in vitro studies

Novel peptide conjugates of two antitubercular drug candidates were synthesised and characterised using new tuftsin peptide derivatives (OT14) as carrier moiety. As antitubercular drug candidates two pyridopyrimidine derivatives, TB803 (2-allylamino-4-oxopyrido[1,2-a]pyrimidine-3-carbaldehyde) and TB820 (4-oxo-2-(pyrrolidin-1-yl)-pyrido[1,2-a]pyrimidin-3-carbaldehyde) inhibiting vital enzyme of Mycobacterium tuberculosis were applied. Membrane affinity of the compounds TB803 and TB820 and their peptide conjugates was evaluated using experimental lipid mono- and bilayer models. Penetration ability was assessed tensiometrically from Langmuir monolayer study and applying quartz crystal microbalance for the supported lipid bilayer (SLB) system. Minimal inhibitory concentration (MIC) values remained in a similar micromolar range for both of the conjugates while their cellular uptake rate was improved significantly compared to the drug candidates. A correlation was found between membrane affinity properties and results of in vitro biological investigations. Analysis of physical/structural properties of SLB in contact with bioactive components and visualization of the structural change by atomic-force microscopy (AFM) provided information on the type and route of molecular interaction of drug construction with lipid layers. The possible role of electrostatic interactions between lipid layer and drug candidates was tested in Langmuir-balance experiments using negatively charged lipid mixture (DPPC+DPPG). Especially the peptide conjugates presented increased membrane affinity due to cationic character of the peptide sequence selected for the conjugate formation. That is supposed to be one reason for the enhanced cellular uptake observed in vitro for MonoMac6 cell line. The conjugation of antitubercular agents to a peptidic carrier is a promising approach to enhance membrane affinity, cellular uptake rate and in vitro selectivity

Identification of a claudin-4 and E-cadherin score to predict prognosis in breast cancer

The elevated expression of claudins (CLDN) and E-cadherin (CDH-1) was found to correlate with poor prognostic features. Our aim was to perform a comprehensive analysis to assess their potential to predict prognosis in breast cancer. The expression of CLDN-1, -3-5, -7, -8, -10, -15, -18, and E-cadherin at the mRNA level was evaluated in correlation with survival in datasets containing expression measurements of 1809 breast cancer patients. The breast cancer tissues of 197 patients were evaluated with tissue microarray technique and immunohistochemical method for CLDN-1-5, -7, and E-cadherin protein expression. An additional validation set of 387 patients was used to test the accuracy of the resulting prognostic score. Based on the bioinformatic screening of publicly-available datasets, the metagene of CLDN-3, -4, -7, and E-cadherin was shown to have the most powerful predictive power in the survival analyses. An immunohistochemical protein profile consisting of CLDN-2, -4, and E-cadherin was able to predict outcome in the most effective manner in the training set. Combining the overlapping members of the above two methods resulted in the claudin-4 and E-cadherin score (CURIO), which was able to accurately predict relapse-free survival in the validation cohort (P=0.029). The multivariate analysis, including clinicopathological variables and the CURIO, showed that the latter kept its predictive power (P=0.040). Furthermore, the CURIO was able to further refine prognosis, separating good versus poor prognosis subgroups in luminal A, luminal B, and triple-negative breast cancer intrinsic subtypes. In breast cancer, the CURIO provides additional prognostic information besides the routinely utilized diagnostic approaches and factors. © 2011 Japanese Cancer Association

In vitro biological evaluation of new antimycobacterial salicylanilide-tuftsin conjugates

Tuberculosis is caused by Mycobacterium tuberculosis, an intracellular pathogen that can survive in host cells, mainly in macrophages. An increase of multidrug-resistant tuberculosis qualifies this infectious disease as a major public health problem worldwide. The cellular uptake of the antimycobacterial agents by infected host cells is limited. Our approach is to enhance the cellular uptake of the antituberculars by target cell-directed delivery using drug-peptide conjugates to achieve an increased intracellular efficacy. In this study, salicylanilide derivatives (2-hydroxy-N-phenylbenzamides) with remarkable antimycobacterial activity were conjugated to macrophage receptor specific tuftsin based peptide carriers through oxime bond directly or by insertion of a GFLG tetrapeptide spacer. We have found that the in vitro antimycobacterial activity of the salicylanilides against M. tuberculosis H37Rv is preserved in the conjugates. While the free drug was ineffective on infected macrophage model, the conjugates were active against the intracellular bacteria. The fluorescently labelled peptide carriers that were modified with different fatty acid side chains showed outstanding cellular uptake rate to the macrophage model cells. The conjugation of the salicylanilides to tuftsin based carriers reduced or abolished the in vitro cytostatic activity of the free drugs with the exception of the palmitoylated conjugates. The conjugates degraded in the presence of rat liver lysosomal homogenate leading to the formation of an oxime bondlinked salicylanilide-amino acid fragment as the smallest active metabolite

A personal experience with the Marie Skłodowska Curie Actions Individual Fellowship

Trabajo presentado al MSCA Individual Fellowships Webinar, celebrado en Zaragoza (España) el 15 de mayo de 2020.TBNANO (Grant agreement ID: 842652.Peer reviewe

Fighting against intracellular pathogens: host cell-targeted drug delivery

Nanomedicine with active targeting strategies is one of the most promising approaches toensure that drug molecules reach their target sites and it brings us closer to eradicating harmful intracellular pathogens.This work has been supported by the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No 842652, by the Spanish MICINN project BIO2017-84246-C2-1-R and by Gobierno de Aragon (Diputacion General de Aragon-Fondo Social Europeo).Peer reviewe