The transient, heterogeneous nano-bio interface defined by the protein corona in biological environments dictates the biodistribution, immune recognition, metabolism, and clearance of nanomaterials. F Show more
The transient, heterogeneous nano-bio interface defined by the protein corona in biological environments dictates the biodistribution, immune recognition, metabolism, and clearance of nanomaterials. Far from being a drawback, this corona can be harnessed for targeted nanodrug delivery when its composition is predictably tuned or deliberately modulated. We hypothesized that preloading apolipoprotein E (ApoE), previously identified as a constituent of the corona of β-sheet-breaker peptide-functionalized gold nanoparticles (AuNPs), would enhance transport across the blood-brain barrier (BBB) and increase brain uptake. To test this, we synthesized AuNPs (approximately 12 nm) functionalized (AuNP-f) with CLPFFD or THRPPMWSPVWPCLPFFD peptides, both containing the β-sheet-breaker motif LPFFD, which recognizes β-amyloid aggregates implicated in Alzheimer's disease. After incubation with human plasma, hard-corona proteins were profiled by 2D IEF/SDS-PAGE and LC-MS/MS. Proteins were ranked based on their roles in nanoparticle trafficking and BBB transcytosis, and ApoE was selected for deliberate enrichment due to its recurrent presence. ApoE-decorated AuNP-f were evaluated in an in vitro BBB model and in vivo biodistribution assays using Sprague-Dawley rats. Brain accumulation was assessed ex vivo. Preloading ApoE onto AuNP-f significantly enhanced nanoparticle transport across the BBB in vitro and increased brain accumulation in rats. These results demonstrate that rational corona enrichment with ApoE improves BBB transit and brain accumulation without altering nanoparticle surface chemistry. Corona engineering thus offers a pragmatic route to brain-targeted nanodrug delivery and may be extended to other protein-receptor axes for organ-specific targeting. Show less
Low-density lipoprotein (LDL) aggregation is nowadays considered a therapeutic target in atherosclerosis. DP3, the retro-enantio version of the sequence Gly Tg mice were fed an HFD for 21 days to indu Show more
Low-density lipoprotein (LDL) aggregation is nowadays considered a therapeutic target in atherosclerosis. DP3, the retro-enantio version of the sequence Gly Tg mice were fed an HFD for 21 days to induce atherosclerosis and then randomized into three groups that received a daily subcutaneous administration (10 mg/kg) of i) vehicle, ii) DP3 peptide, or iii) a non-active peptide (IP321). The in vivo biodistribution of a fluorescent-labeled peptide version (TAMRA-DP3), and its colocalization with ApoB100 in the arterial intima, was analyzed by imaging system (IVIS) and confocal microscopy. Heart aortic roots were used for atherosclerosis detection and quantification. LDL functionality was analyzed by biochemical, biophysical, molecular, and cellular studies. Intimal neutral lipid accumulation in the aortic root was reduced in the DP3-treated group as compared to control groups. ApoB100 in LDLs from the DP3 group exhibited an increased percentage of α-helix secondary structures and decreased immunoreactivity to anti-ApoB100 antibodies. LDL from DP3-treated mice were protected against passive and sphingomyelinase (SMase)-induced aggregation, although they still experienced SMase-induced sphingomyelin phospholysis. In patients with familial hypercholesterolemia (FH), DP3 efficiently inhibited both SMase-induced phospholysis and aggregation. DP3 peptide administration inhibits atherosclerosis by preserving the α-helix secondary structures of ApoB100 in a humanized ApoB100 murine model that mimicks the hallmark of human hypercholesterolemia. Show less