Magnétoliposomes furtifs pour l'imagerie par résonance magnétique et le traitement des cancers (étude pharmacocinétique et biodistribution )

CHATENAY M.-PARIS 11-BU Pharma. (920192101) / SudocSudocFranceF

Sterically stabilized superparamagnetic liposomes for MR imaging and cancer therapy : pharmacokinetics and biodistribution

International audienc

Liposomes loaded with histone deacetylase inhibitors for breast cancer therapy

International audienceHistone deacetylase (HDAC) inhibitors (HDACi) of the class I trichostatin A (TSA), CG1521 (CG), and PXD101 (PXD) were incorporated at a high rate (approximately 1mM) in liposomes made of egg phosphatidylcholine/cholesterol/distearoylphosphoethanolamine-polyethylenglycol(2000) (64:30:6). Physicochemical parameters (size, zeta potential, loading, stability, release kinetics) of these HDACi-loaded pegylated liposomes were optimized and their cytotoxicity (MTT test) was measured in MCF-7, T47-D, MDA-MB-231 and SkBr3 breast cancer cell lines. In MCF-7 cells, TSA and PXD were efficient inducers of proteasome-mediated estradiol receptor alpha degradation and they both affected estradiol-induced transcription (TSA>PXD) contrary to CG. Moreover, TSA most efficiently altered breast cancer cell viability as compared to the free drug, CG-liposomes being the weakest, while unloaded liposomes had nearly no cytotoxicity. Pegylated liposomes loaded with TSA or PXD remained stable in size, charge and biological activity for one month when stored at 4 degrees C. All HDACi-loaded liposomes released slowly the encapsulated drug in vitro, CG-loaded liposomes showed the slowest release kinetic. These formulations could improve the efficacy of HDACi not only in breast cancers but also in other solid tumors because most of these drugs are poor water soluble and unstable in vivo, and their administration remains a challenge

Rere-dependent Retinoic Acid signaling controls brain asymmetry and handedness

While the vertebrate brain appears largely bilaterally symmetrical in humans, it presents local morphological Left-Right (LR) asymmetries as, for instance, in the petalia. Moreover, higher functions such as speech or handedness are asymmetrically localized in the cortex. How these brain asymmetries are generated remains unknown. Here, we reveal a striking parallel between the control of bilateral symmetry in the brain and in the precursors of vertebrae called somites, where a “default” asymmetry is buffered by Retinoic Acid (RA) signaling. This mechanism is evident in zebrafish and mouse and, when perturbed in both species, it translates in the brain into lateralized alterations of patterning, neuronal differentiation and behavior. We demonstrate that altering levels of the mouse RA coactivator Rere results in subtle cortex asymmetry and profoundly altered handedness, linking patterning and function in the motor cortex. Together our data uncover a novel mechanism that could underlie the establishment of brain asymmetries and handedness in vertebrates