In vitro vascular toxicity of tariquidar, a potential tool for in vivo PET studies.

The P-glicoprotein (P-gp) inhibitor tariquidar is used to detect functional alterations of blood brain barrier pumps in PET imaging. The doses required, however, up to 4-fold higher than those already used in clinical trials to reverse multidrug resistance, cause syncopal episode and hypotension. Therefore, the effects of these doses toward the vasculature were investigated and an in-depth analysis of tariquidar-mediated effects on A7r5 and EA.hy926 cells viability, on the mechanical activity of freshly and cultured rat aorta rings and on L-type Ca2+ current [ICa(L)] of A7r5 cells has been performed. In both A7r5 and EA.hy926 cells, tariquidar was not cytotoxic up to 1µM concentration. On the contrary, at 10µM, it caused apoptosis already after 24h treatment. In fresh aorta rings, 10µM tariquidar partially relaxed phenylephrine-, but not 60mM K+ (K60)-induced contraction. In rings treated with 10µM tariquidar for 7days, the contractile response to both phenylephrine and K60 remained unchanged. Finally, tariquidar did not modify ICa1.2 intensity and kinetics. In conclusion, Tariquidar might exert both cytotoxic and acute, weak vascular effects at concentrations comparable to those employed in PET imaging. This implies that caution should be exercised when using it as diagnostic tool.

Design of a Novel Composite H2 S-Releasing Hydrogel for Cardiac Tissue Repair.

The design of 3D scaffolds is a crucial step in the field of regenerative medicine. Scaffolds should be degradable and bioresorbable as well as display good porosity, interconnecting pores, and topographic features; these properties favour tissue integration and vascularization. These requirements could be fulfilled by hybrid hydrogels using a combination of natural and synthetic components. Here, the mechanical and biological properties of a polyethylene glycol-fibrinogen hydrogel (PFHy) are improved in order to favour the proliferation and differentiation of human Sca-1(pos) cardiac progenitor cells (hCPCs). PFHys are modified by embedding air- or perfluorohexane-filled bovine serum albumin microbubbles (MBs) and characterized. Changes in cell morphology are observed in MBs-PFHys, suggesting that MBs could enhance the formation of bundles of cells and influence the direction of the spindle growth. The properties of MBs as carriers of active macromolecules are also exploited. For the first time, enzyme-coated MBs have been used as systems for the production of hydrogen sulfide (H2 S)-releasing scaffolds. Novel H2 S-releasing PFHys are produced, which are able to improve the growth of hCPCs. This novel 3D cell-scaffold system will allow the assessment of the effects of H2 S on the cardiac muscle regeneration with its potential applications in tissue repair.

Ligand Promiscuity between the Efflux Pumps Human P-Glycoprotein and S. aureus NorA.

Thirty-two diverse compounds were evaluated for their ability to inhibit both Pgp-mediated efflux in mouse T-lymphoma L5178 MDR1 and NorA-mediated efflux in S. aureus SA-1199B. Only four compounds were strong inhibitors of both efflux pumps. Three compounds were found to inhibit Pgp exclusively and strongly, while seven compounds inhibited only NorA. These results demonstrate that Pgp and NorA inhibitors do not necessarily overlap, opening the way to safer therapeutic use of effective NorA inhibitors.

N,N-bis(cyclohexanol)amine aryl esters inhibit P-glycoprotein as transport substrates.

P-Glycoprotein (Pgp) inhibition by three sets of four isomers of N,N-bis(cyclohexanol)amine aryl esters was assessed on rhodamine 123 (R123) efflux in human MDR1-gene transfected mouse T-lymphoma L5178 cells and on Sf9 ATPase activity. The most active compounds inhibited Pgp with IC(50) values much lower than those of either cyclosporin A (CSA) or GF120918. As to R123 efflux inhibition, the role of the bond present in the second aryl moiety appeared important since the triple bond derivatives (3a-d) were the most powerful as compared to the double bond (2a-d) and the single bond (1a-d) counterparts. Concentration-inhibition curves of 2c and 3d exhibited a biphasic behaviour suggesting the existence of two binding sites in the recognition domain of Pgp. Persistence of inhibition by these compounds resulted to be intermediate between that caused by CSA and GF120918. R123 exhibited positive interaction with CSA, 1d, 1c, 2d, 2c and 3c, the concentration-inhibition curves being shifted leftward when R123 concentration was increased, while it exhibited negative interaction with 3d and no effect with GF120918. Sf9 ATPase activity was stimulated in an increasing order of potency by 2c, 3c, 2d, CSA, epirubicin and 3d. In a decreasing order of potency 3d, 2c, GF120918, CSA, 2d and 3c inhibited at sub-nanomolar concentrations epirubicin-stimulated ATPase activity. In conclusion, isomeric geometry and restriction of molecular flexibility of N,N-bis(cyclohexanol)amine aryl esters were crucial for their presentation to and inhibition of Pgp as transport substrates, R123 and epirubicin cooperating with them to this inhibition.

A novel approach for predicting P-glycoprotein (ABCB1) inhibition using molecular interaction fields.

P-glycoprotein (Pgp or ABCB1) is an ABC transporter protein involved in intestinal absorption, drug metabolism, and brain penetration, and its inhibition can seriously alter a drug's bioavailability and safety. In addition, inhibitors of Pgp can be used to overcome multidrug resistance. Given this dual purpose, reliable in silico procedures to predict Pgp inhibition are of great interest. A large and accurate literature collection yielded more than 1200 structures; a model was then constructed using various molecular interaction field-based technologies, considering pharmacophoric features and those physicochemical properties related to membrane partitioning. High accuracy was demonstrated internally with two different validation sets and, moreover, using a number of molecules, for which Pgp inhibition was not experimentally available but was evaluated in-house. All of the validations confirmed the robustness of the model and its suitability to help medicinal chemists in drug discovery. The information derived from the model was rationalized as a pharmacophore for competitive Pgp inhibition.

From taxuspine x to structurally simplified taxanes with remarkable p-glycoprotein inhibitory activity.

Three simplified "non-natural" natural taxanes, related to taxuspine X, were synthetized and assayed as P-glycoprotein (P-gp) inhibitors. One of them (6) proved to be a very efficient P-gp inhibitor with an IC50 = 7.2 × 10(-6) M. In addition, to rationalize biological data, a pharmacophoric model was built through a ligand-based approach. This model represents the first example of a pharmacophore, which describes interactions of taxanes with P-gp.

N,N-bis(cyclohexanol)amine aryl esters: a new class of highly potent transporter-dependent multidrug resistance inhibitors.

A new series of Pgp-dependent MDR inhibitors having a N,N-bis(cyclohexanol)amine scaffold was designed on the basis of the frozen analogue approach. The scaffold chosen gives origin to different geometrical isomers. The new compounds showed a wide range of potencies and efficacies on doxorubicin-resistant erythroleukemia K562 cells in the pirarubicin uptake assay. The most interesting compounds (isomers of 3) were studied further evaluating their action on the ATPase activity present in rat small intestine membrane vesicles and doxorubicin cytotoxicity potentiation on K562 cells. The latter assay was performed also on the isomers of 4. The four isomers of each set present different behavior in each of these tests. Compound 3d shows the most promising properties as it was able to completely reverse Pgp-dependent pirarubicin extrusion at low nanomolar concentration, inhibited ATPase activity at 5 x 10(-9) and increased the cytotoxicity of doxorubicin with a reversal fold (RF) of 36.4 at 3 microM concentration.