Apolipoprotein E peptide-modified colloidal carriers: the design determines the mechanism of uptake in vascular endothelial cells.

Supramolecular structures, particularly micelles and liposomes equipped with uptake-mediating address compounds, have attracted much attention as pharmaceutical formulations. Their development requires an understanding of the mechanism by which the carrier systems interact with and translocate into the target cells. We developed an apolipoprotein E-derived peptide, called A2, that efficiently translocates across cell membranes. Upon coupling of two palmitoyl chains (P2), the highly cationic sequence acquires detergent-like properties such as a strong tendency to self-associate and the ability to integrate into lipid bilayers. Confocal laser scanning microscopy and fluorescence activated cell sorting were used to compare the internalization of the fluorescence-labeled monomeric A2 with the uptake of the colloidal P2A2 micelles and P2A2-tagged liposomes into endothelial cells of blood vessels. Specific inhibitors of endocytosis were used to identify the underlying mechanisms. b.End3 and BAEC cells as example of endothelial cells of small capillaries and large vascular vessels, respectively, were examined. The uptake of monomeric A2 was characterized by poor cellular selectivity. A2 was efficiently internalized into both cell lines via at least two different mechanisms. Besides an endocytotic uptake route, a second passive pathway exists, that leads to a rapid distribution of A2 within the cytoplasm. Also liposomes tagged with P2A2 were non-selectively internalized into both b.End3 and BAEC cells. Their nonselective uptake was mediated by clathrin- and caveolin-independent endocytosis. In contrast, micellar P2A2 entered b.End3 cells via clathrin-mediated endocytosis, while no uptake of P2A2 into BAEC cells was observed. In conclusion, the specific clathrin-mediated uptake mode of P2A2 micelles might provide the basis for a blood brain barrier-specific targeting.

Insight into the role of HSPG in the cellular uptake of apolipoprotein E-derived peptide micelles and liposomes.

Liposomes and micellar carriers equipped with targeting and cellular uptake mediating peptides have attracted attention for numerous applications. The optimization of the carrier requires an understanding of how their properties influence target cell recognition and uptake. We developed a dipalmitoylated apolipoprotein E-derived peptide, named P2A2 as promising vector to mediate cellular uptake of potential micellar and liposomal carriers. Confocal laser scanning microscopy (CLSM) and fluorescence-activated cell sorting (FACS) were used to get insight into the internalization mediated by carboxyfluoresceine-labeled P2fA2 and the all-D amino acid analogue P2fa2 into brain capillary endothelial cells. Both peptide micelles and liposomes entered cells via endocytosis. Cell surface heparan sulfate proteoglycans (HSPGs) were involved in the internalization process of peptide-bearing liposomes characterized by a diameter of 100 nm, a low surface density of 100 peptide molecules per vesicle and a helical conformation of the vector. In contrast, peptide micelles characterized by a diameter of about 10 nm, a high peptide density caused by 19 associated molecules and a high conformational flexibility of the vector sequence did not address HSPG. Unspecific interactions between the carriers and membrane constituents predominate the two uptake processes but stereospecific components seem to be involved. Both routes differ with respect to transport efficiency. The results provide a prospective basis to optimize liposomes and micelles as drug delivery systems.

Well-defined, multifunctional nanostructures of a paramagnetic lipid and a lipopeptide for macrophage imaging.

In the field of nanomedicine there is a great demand for technologies that allow the creation of self-assembled structures of which the size and morphology can be accurately controlled. In the current study, we report a nanoparticle platform that is composed of a paramagnetic lipid and a fluorescently labeled lipopeptide. By judiciously controlling the ratio of the aforementioned amphiphilic molecules, a variety of well-defined nanosized supramolecular structures with different sizes and morphologies could be created. The hydrodynamic radii of the different structures were determined by dynamic light scattering. Cryo-TEM revealed the aggregate morphology to vary from small micellar structures to plate-like and even full grown ribbons of which the aspect ratios varied from a diameter of 5-8 nm to structures with a width of up to 25 nm and infinite length. Interestingly, nuclear magnetic resonance dispersion profiling revealed excellent properties for MRI and also showed that the relaxivity of the structures was tunable and morphology dependent. Finally, macrophage cells were treated with two selected nanoparticles and were shown to be avidly taken up. In conclusion we demonstrate a methodology to create structures that (1) are paramagnetic to enable their detection with MRI, (2) exhibit fluorescent properties, (3) can be tuned to defined sizes and shapes, and (4) are efficiently taken up by macrophage cells in vitro.

Incorporation of an apoE-derived lipopeptide in high-density lipoprotein MRI contrast agents for enhanced imaging of macrophages in atherosclerosis.

Magnetic resonance (MR) imaging is becoming a pivotal diagnostic method to identify and characterize vulnerable atherosclerotic plaques. We previously reported a reconstituted high-density lipoprotein (rHDL) nanoparticle platform enriched with Gd-based amphiphiles as a plaque-specific MR imaging contrast agent. Further modification can be accomplished by inserting targeting moieties into this platform to potentially allow for improved intraplaque macrophage uptake. Since studies have indicated that intraplaque macrophage density is directly correlated to plaque vulnerability, modification of the rHDL platform may allow for better detection of vulnerable plaques. In the current study we incorporated a carboxyfluoresceine-labeled apolipoprotein E-derived lipopeptide, P2fA2, into rHDL. The in vitro macrophage uptake and in vivo MR efficacy were demonstrated using murine J774A.1 macrophages and the apolipoprotein E knock-out (apoE(-/-)) mouse model of atherosclerosis. The in vitro studies indicated enhanced association of murine macrophages to P2fA2 enriched rHDL (rHDL-P2A2) nanoparticles, relative to rHDL, using optical techniques and MR imaging. The in vivo studies showed a more pronounced and significantly higher signal enhancement of the atherosclerotic wall 24 h after the 50 micromol Gd/kg injection of rHDL-P2A2 relative to administration of rHDL. The normalized enhancement ratio for atherosclerotic wall of rHDL-P2A2 contrast agent injection was 90%, while that of rHDL was 53% 24 h post-injection. Confocal laser scanning microscopy revealed that rHDL-P2A2 nanoparticles co-localized primarily with intraplaque macrophages. The results of the current study confirm the hypothesis that intraplaque macrophage uptake of rHDL may be enhanced by the incorporation of the P2fA2 peptide into the modified HDL particle.

Affinity interactions between phenylboronic acid-carrying self-assembled monolayers and flavin adenine dinucleotide or horseradish peroxidase.

A method is provided for the recognition of glycated molecules based on their binding affinities to boronate-carrying monolayers. The affinity interaction of flavin adenine dinucleotide (FAD) and horseradish peroxidase (HRP) with phenylboronic acid monolayers on gold was investigated by using voltammetric and microgravimetric methods. Conjugates of 3-aminophenylboronic acid and 3,3'-dithiodipropionic acid di(N-hydroxysuccinimide ester) or 11-mercaptoundecanoic acid were prepared and self-assembled on gold surfaces to generate monolayers. FAD is bound to this modified surface and recognized by a pair of redox peaks with a formal potential of -0.433 V in a 0.1 M phosphate buffer solution, pH 6.5. Upon addition of a sugar to the buffer, the bound FAD could be replaced, indicating that the binding is reversible. Voltammetric, mass measurements, and photometric activity assays show that the HRP can also be bound to the interface. This binding is reversible, and HRP can be replaced by sorbitol or removed in acidic solution. The effects of pH, incubation time, and concentration of H(2)O(2) were studied by comparing the catalytic reduction of H(2)O(2) in the presence of the electron-donor thionine. The catalytic current of the HRP-loaded electrode was proportional to HRP concentrations in the incubation solution in the range between 5 microg mL(-1) and 0.1 mg mL(-1) with a linear slope of 3.34 microA mL mg(-1) and a correlation coefficient of 0.9945.