33 research outputs found
Comparison of the kinetics of active efflux of Tc-99m-MIBI in cells with P-glycoprotein-mediated and multidrug-resistance protein-associated multidrug-resistance phenotypes
The overexpression of two membrane glycoproteins, P-glycoprotein and multidrug-resistance protein (MRP1) is a major cause of resistance to chemotherapeutic agents in the treatment of human cancers. Both proteins confer a similar multidrug-resistant (MDR) phenotype. Tc-99m-MIBI, a myocardial imaging agent, which is also useful for the detection of a variety of tumours, has been shown to be a substrate for P-glycoprotein and MRP1. It thus may provide additional information about the P-glycoprotein and MRP1 status of tumour cells. In order to obtain information on the substrate specificity of these proteins, we have studied the transport kinetics of Tc-MIBI in two cell lines, K562/ADR and GLC(4)/ADR, which overexpress P-glycoprotein and MRP1, respectively. The mean active efflux coefficient k(a), which is proportional to the ratio of maximal efflux rate V-M to the apparent Michaelis-Menten constant K-m, used to characterise the efficiency of the active efflux, was very similar being 1.9+/-0.6X10(-11) s(-1).cells.ml and 1.3+/-0.5X10(-11) s(-1).cells.ml for drug-resistant K562 and GLC4, respectively. These values are 50-100-times lower than for daunorubicin and other anthracycline derivatives, strongly suggesting that the efficiency of both transporters to pump Tc-MIBI is by far less than that to efflux anthracyclines. Our data show that (a) P-glycoprotein and MRP transporter efficiencies to wash out Tc-MIBI are similar, in spite of a different suspected mechanism of its transport and (b) that both transporters are less efficient to pump Tc-MIBI than to pump anthracyclines (the k(a) parameter is about 100-times lower for TC-MIBI than for anthracycline)
Low-temperature resonance-Raman spectra of Japanese-lacquer-tree (Rhus vernicifera) laccase, type-2-copper-depleted laccase and H2O2-treated type-2-copper-depleted laccase.
Resonance-Raman spectra of Japanese-lacquer-tree (Rhus vernicifera) laccase, type-2-copper-depleted laccase and the latter form treated with H2O2 were measured in liquid and frozen solution, on excitation into the 600 nm absorption band. Significant changes in intensity and/or frequency of the bands lying in the 370-430 cm-1 region were observed on freezing, indicating local structural rearrangements taking place at the blue copper site. These findings corroborate previous suggestions based on e.p.r. measurements and redox data [Morpurgo, Calabrese, Desideri & Rotilio (1981) Biochem. J. 193, 639-642]. They show the strong dependence of the physical properties of blue copper centres on local symmetry. Some conclusions on the origin of the Raman bands are also drawn
Accumulation of Eu3+ chelates in cells expressing or not P-glycoprotein: Implications for blood-brain barrier crossing
1 - ArticleAlzheimer's disease (AD) is the most commonly form of dementia in the elderly. The development of molecules able to detect biomarkers characteristic of AD is critical to its understanding and treatment. However, such molecules must be able to pass blood-brain barrier (BBB) which is a major impediment to the entry of many therapeutic drugs into the brain. Such a limitation applies to the development of magnetic resonance imaging molecular neuroimaging agents using biomarkers of AD-like P-amyloid deposits, as the common extracellular contrast agents (CAs) are not able to cross an intact BBB. In this work, we have studied the ability of a series of simple Eu3+ Complexes to enter cells overexpressing or not the ABCB1 (P-gp or P-glycoprotein) protein, which is expressed at the BBB and in human embryonic astrocytes. The intracellular uptake of the Eu3+ complexes of linear and macrocyclic polyaminocarboxylate ligands with different charges and lipophilicities was followed by atomic absorption spectrometry. Based on biochemical argument, we propose that lipophilic contrast agents can be efficiently taken up by cells and accumulate inside mitochondria when they are positively charged. The important point is that they are not P-gp substrates. which is one of the major obstacles for them to cross the BBB