Pavel Barta

Gefitinib Induces Epidermal Growth Factor Receptor Dimers Which Alters the Interaction Characteristics with 125I-EGF

The tyrosine kinase inhibitor gefitinib inhibits growth in some tumor types by targeting the epidermal growth factor receptor (EGFR). Previous studies show that the affinity of the EGF-EGFR interaction varies between hosting cell line, and that gefitinib increases the affinity for some cell lines. In this paper, we investigate possible mechanisms behind these observations. Real-time interaction analysis in LigandTracer® Grey revealed that the HER2 dimerization preventing antibody pertuzumab clearly modified the binding of 125I-EGF to EGFR on HER2 overexpressing SKOV3 cells in the presence of gefitinib. Pertuzumab did not affect the binding on A431 cells, which express low levels of HER2. Cross-linking measurements showed that gefitinib increased the amount of EGFR dimers 3.0–3.8 times in A431 cells in the absence of EGF. In EGF stimulated SKOV3 cells the amount of EGFR dimers increased 1.8–2.2 times by gefitinib, but this effect was cancelled by pertuzumab. Gefitinib treatment did not alter the number of EGFR or HER2 expressed in tumor cell lines A431, U343, SKOV3 and SKBR3. Real-time binding traces were further analyzed in a novel tool, Interaction Map, which deciphered the different components of the measured interaction and supports EGF binding to multiple binding sites. EGFR and HER2 expression affect the levels of EGFR monomers, homodimers and heterodimers and EGF binds to the various monomeric/dimeric forms of EGFR with unique binding properties. Taken together, we conclude that dimerization explains the varying affinity of EGF – EGFR in different cells, and we propose that gefitinib induces EGFR dimmers, which alters the interaction characteristics with 125I-EGF.

Protein interactions with HER-family receptors can have different characteristics depending on the hosting cell line

Cell lines are common model systems in the development of therapeutic proteins and in the research on cellular functions and dysfunctions. In this field, the protein interaction assay is a frequently used tool for assessing the adequacy of a protein for diagnostic and therapeutic purposes. In this study, we investigated the extent to which the interaction characteristics depend on the choice of cell line for HER-family receptors. The interaction characteristics of two therapeutic antibodies (trastuzumab and cetuximab) and one Affibody molecule (ZHER2:342), interacting with the intended receptor were characterized with high precision using an automated real-time interaction method, in different cell lines (HaCaT, A431, HEP-G2, SKOV3, PC3, DU-145). Clear differences in binding affinity and kinetics, up to one order of magnitude, were found for the interaction of the same protein binding to the same receptor on different cells for all three proteins. For HER-family receptors, it is therefore important to refer to the measured affinity for a protein-receptor interaction together with the hosting cell line. The ability to accurately measure affinity and kinetics of a protein-receptor interaction on cell lines of different origins may increase the understanding of underlying receptor biology, and impact the selection of candidates in the development of therapeutic or diagnostic agents.

Circumventing the requirement of binding saturation for receptor quantification using interaction kinetic extrapolation

Quantification of the number of receptors per cell (NRPC) is important when assessing whether a tumor surface biomarker is suitable for medical imaging. One common method for NPRC quantification is to use a binding saturation assay, which is time consuming and requires large amounts of reagents. The aim of this study was to evaluate an alternative method based on kinetic extrapolation (KEX) and compare it with the classical manual saturation technique with regard to accuracy as well as time and reagent consumption. Epidermal growth factor receptor (EGFR) and HER2 receptor surface expression were quantified on five tumor cell lines using three 125I-labeled and 131I-labeled ligands (cetuximab and EGF for EGFR, trastuzumab for HER2 receptor) for both techniques. The KEX method involved interaction measurements in the LigandTracer, followed by KEX through computerized real-time interaction analysis to correct for nonsaturation on cells. Variability and NRPC estimates of the EGFR and HER2 receptor levels using the KEX method were comparable with the results from the classical saturation technique. However, the ligand consumption for the KEX method was 26–46% of the classical saturation technique. Furthermore, the KEX method reduced the workload radically. From the observations described in this study, we believe that the KEX method enables fast, credible, and easy NRPC quantification with a reduction in reagent consumption.

A comparison of in vitro methods for determining the membrane receptor expression in cell lines.

INTRODUCTION Determining the number of expressed receptors per cell (NRPC) in cell lines is an important prerequisite for many experimental procedures in biomedical research. This paper focuses on the comparison of a newly developed method of determining NRPC - the Kinetic extrapolation method (KEX) - with the standard saturation method. These two methods, both based on radiolabeled ligand-receptor binding, were compared with the data on receptor expression found using quantified western blotting. METHODS Four cell lines with different expressions of epidermal growth factor receptor (EGFR) were chosen for the experiment: A431, HaCaT, HCT116 and HepG2. Two radiolabeled monoclonal antibodies specific for EGFR were used as ligands: [(131)I]-cetuximab and [(131)I]-panitumumab. The classic manual technique based on the saturation of cell receptors was performed on cells seeded in 24-well plates. The KEX method uses the LigandTracer, a special instrument which detects ligand retention in real time from seeded cells onto a rotating Petri dish. The western blot analysis was performed according to the routinely used procedure. RESULTS A very close accordance between the manual saturation technique and the KEX method was found in all four cell lines used. The NRPC in the cell lines follows the same order using both ligands: A431>HaCaT>HCT116≈HepG2. Similarly, consistent data on EGFR expression in the studied cell lines were obtained using western blot analysis and the radiolabeled ligand binding assays. CONCLUSIONS The KEX method could be as similarly useful for determining receptor expression as is the classic saturation method and western blotting.

Entecavir Interacts with Influx Transporters hOAT1, hCNT2, hCNT3, but Not with hOCT2: The Potential for Renal Transporter-Mediated Cytotoxicity and Drug–Drug Interactions

Entecavir (ETV) is one of the most potent agents for the treatment of the hepatitis B viral infection. The drug is principally eliminated by the kidney. The goal of this study was to investigate the potential of ETV to interact in vitro with the renal SLC transporters hOAT1, hOCT2, hCNT2 and hCNT3. Potential drug–drug interactions of ETV at the renal transporters with antiviral drugs known to be excreted by the kidney (adefovir, tenofovir, cidofovir) as well as transporter-dependent cytotoxicity were also examined. Interactions with the selected transporters along with cytotoxicity were studied in several transiently transfected cellular models using specific substrates and inhibitors. ETV was found to be both a substrate and inhibitor of hOAT1 (IC50 = 175.3 μM), hCNT2 (IC50 = 241.9 μM) and hCNT3 (IC50 = 278.4 μM) transporters, although it interacted with the transporters with relatively low affinities. ETV inhibited the cellular uptake of adefovir, tenofovir, and cidofovir by hOAT1; however, effective inhibition was shown at ETV concentrations exceeding therapeutic levels. In comparison with adefovir, tenofovir, and cidofovir, ETV displayed no transporter-mediated cytotoxicity in cells transfected with hOAT1, hCNT2, and hCNT3. No significant interaction of ETV with hOCT2 was detected. The study demonstrates interactions of ETV with several human renal transporters. For the first time, an interaction of ETV with the hCNTs was proved. We show that the potency of ETV to cause nephrotoxicity and/or clinically significant drug-drug interactions related to the tested transporters is considerably lower than that of adefovir, tenofovir, and cidofovir.

Exploring Time-Resolved Characterization of the Heterogeneity and Dynamics of Ligand-Receptor Interactions on Living Cells

Patients affected by malignant brain tumor present an extremely poor prognosis, notwithstanding improvements in surgery techniques and therapeutic protocols. Late diagnosis and the limitation of conventional therapies are major reasons for this unsolved clinical problem. The blood-brain barrier formed by a complex of endothelial cells, astrocyte and pericytes reduces notably the diffusion of a large number of therapeutic agents. Nanotechnology involves the design, synthesis, and characterization of materials and devices that have a functional organization in at least one dimension on the nanometer scale. The nanoparticles have emerged as potential vectors for brain delivery able to overcome the difficulties of modern strategies. Nanoparticles drug delivery systems can be, also, used to provide targeted delivery of drugs, improve bioavailability, sustains release of drugs for systemic delivery. Moreover, multi-functionality can be engineered into a single nanoplatform so that it can provide tumor-specific detection, treatment, and follow-up monitoring. In this study we will focus on the blood-brain barrier role and possibilities of its therapeutic overcoming. Recent studies of some kinds of nanoparticles systems in brain tumors treatment are summarized.

The involvement of selected membrane transport mechanisms in the cellular uptake of 177Lu-labeled bombesin, somatostatin and gastrin analogues

INTRODUCTION Radiolabeled receptor-targeting peptides are a useful tool for the diagnostic imaging and radiotherapy of some malignancies. However, the retention of radioactivity in the kidney may result in renal radiotoxic injury. This study seeks to evaluate the role of endocytic receptor megalin, renal SLC influx transporters and fluid phase endocytosis (FPE) in the cellular accumulation of radiolabeled peptides. METHODS In vitro transport cellular studies using megalin ligands (RAP, albumin), fluid phase endocytosis (FPE) inhibitor rottlerin and low temperature were employed to evaluate the transport mechanisms of the peptides. Cells transfected with hOAT1 or hOCT2 were used to analyze the role of these SLC transporters. Somatostatin ((177)Lu-DOTA-[Tyr(3)]octreotate, (177)Lu-DOTA-[1-Nal(3)]octreotide), gastrin ((177)Lu-DOTA-sargastrin) and bombesin ((177)Lu-DOTA-[Pro(1),Tyr(4)]bombesin, (177)Lu-DOTA-[Lys(3)]bombesin, (177)Lu-PCTA-[Lys(3)]bombesin) analogues were involved in the study. RESULTS RAP, albumin and low temperature decreased the accumulation of all the studied peptides significantly. With one exception, rottlerin caused the concentration dependent inhibition of the cellular accumulation of the radiopeptides. No significant differences in the uptake of the peptides between the control cells and those transfected with hOAT1 or hOCT2 were observed. CONCLUSION The study showed that active transport mechanisms are decisive for the cellular accumulation in all tested (177)Lu-labeled somatostatin, gastrin and bombesin analogues. Besides receptor-mediated endocytosis by megalin, FPE participates significantly in the uptake. The tested types of renal SLC transporters are not involved in this process.

The effect of chelator type on in vitro receptor binding and stability in 177Lu-labeled cetuximab and panitumumab

Monoclonal antibodies are used in the therapy of various diseases. Thanks to their high specific uptake in target tissues, these antibodies can be utilized in targeted radioimmunotherapy as carriers of radioisotopes to tumors. However, important characteristics of antibodies such as target binding and stability in the organism may be affected by various structural parameters. This study has focused on the potential influence of selected chelators on radiochemical quality and in vitro receptor binding capacity in two modified monoclonal antibodies-cetuximab and panitumumab, both ligands of the epidermal growth factor receptor (EGFR). These two antibodies were each coupled with three macrocyclic chelators (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid, 1,4,7-triazacyclononane-1,4,7-triacetic acid, and 3,6,9,15-tetraazabicyclo[9.3.1]-pentadeca-1(15),11,13-triene-4-(S)-(4-isothiocyanatobenzyl)-3,6,9-triacetic acid) and labeled with lutetium-177. The stability of the preparations was checked, and the cell binding to EGFR-expressing cell lines was examined. The used method led to very stable radiolabeled preparations. The results showed that binding to the target cells was not affected by the type of chelator. All three chelators may be useful for the labeling of cetuximab and panitumumab with lutetium-177 in future preclinical or clinical studies. Our study revealed previously unpublished fact that the type of chelator selected does not affect binding of EGFR-targeted antibodies labeled with lutetium-177.

Preclinical evaluation of radiolabelled nimotuzumab, a promising monoclonal antibody targeting the epidermal growth factor receptor

BACKGROUND Radiolabelled monoclonal antibodies with affinity towards tumour-associated antigens may enhance the efficacy of cancer treatment with targeted radiotherapy. The humanized antibody nimotuzumab represents a promising vector to deliver radioactivity to tumours overexpressing epidermal growth factor receptor type 1 (ErbB1). We analysed the effect of radiolabelling nimotuzumab on its uptake in cancer cells and its biodistribution profile in preclinical experiments. METHODS Nimotuzumab was labelled with (131) I by oxidative iodination and with (177) Lu using nimotuzumab conjugates with two different chelators (DTPA and DOTA) and two different spacers (p-SCN-Bn and NHS). For the receptor studies, two cell lines (HaCaT and A431) were used. Biodistribution studies were performed in male Wistar rats. RESULTS The choice of radiolabel and the manner of its attachment to nimotuzumab had little effect on the internalization of the antibody into ErbB1-expressing cell lines. However, the type of radiolabel, the way in which it was attached to nimotuzumab and the radiolabelling procedure, significantly affected the blood clearance, liver uptake and liver persistence of radiolabelled nimotuzumab. (131) I-nimotuzumab had the longest elimination half-life and the lowest radioactivity uptake in the liver. (177) Lu-labelled nimotuzumab exhibited a shorter elimination half-life, high radioactivity and long-term retention in the liver.

The in vivo disposition and in vitro transmembrane transport of two model radiometabolites of DOTA-conjugated receptor-specific peptides labelled with (177) Lu.

In vivo metabolism of the radiolabelled receptor-specific peptides has been described; however, information regarding the pharmacokinetic behaviour of the degradation products within the body is very scarce. The present study was designed to obtain new knowledge on the disposition and elimination of low-molecular radiometabolites of receptor-specific peptides in the organism and to reveal the potential involvement of selected membrane transport mechanisms in the cellular uptake of radiometabolites, especially in the kidney. The study compared pharmacokinetics of two radiometabolites: a final metabolite of somatostatin analogues, (177)Lu-DOTA-DPhe, and a tripeptide metabolite of (177)Lu-DOTA-minigastrin 11, (177)Lu-DOTA-DGlu-Ala-Tyr. Their pharmacokinetics was compared with that of respective parent (177)Lu-radiopeptide. Both radiometabolites exhibited relative rapid clearing from most body tissues in rats in vivo along with predominant renal excretion. The long-term renal retention of the smaller radiometabolite (177)Lu-DOTA-DPhe was lower than that of (177)Lu-DOTA-DGlu-Ala-Tyr. An uptake of (177)Lu-DOTA-DPhe by human renal influx transporter organic cation transporter 2 was found in vitro in a cellular model. The study brings the first experimental data on the in vivo pharmacokinetics of radiometabolites of receptor-specific somatostatin and gastrin analogues. The found results may indicate a negative correlation between the degree of decomposition of the parent peptide chain and the renal retention of the metabolite.