Abstract
Targeting neuropeptide systems is important for future advancements in treatment of neurological and psychiatric illnesses. However, many of the peptides and their analogs do not cross the blood-brain barrier (BBB) efficiently. Nanoparticles such as iron oxide can cross the BBB, and here we describe a novel method for the conjugation of a peptide antisauvagine-30 (ASV-30) to iron oxide nanoparticles. Previous research has shown that direct infusion of ASV-30 into the brain reduces anxiety-like behavior in animal models via actions on corticotropin releasing factor type 2 (CRF2) receptors. Therefore, we tested whether iron oxide+ASV-30 complexes cross the BBB of rats and then determined whether iron oxide+ASV-30 nanoparticles are localized with CRF2-expressing neurons. Finally we tested the hypothesis that systemic infusion of iron oxide+ASV-30 can reduce anxiety-like behavior. First we describe the synthesis and demonstrate the stability of iron oxide-peptide nanoparticle complexes. Next, nanoparticles (87.7 μg/kg Fe2O3) with or without ASV-30 (200 μg/kg, ip) were injected into male rats 30 min prior to transcardial perfusion and brain fixation for immunohistochemical analysis, or before testing on the elevated plus maze (EPM) in an amphetamine withdrawal model of anxiety. Systemically administered iron oxide+ASV-30 particles were present in the brain and associated with neurons, including those that express CRF2 receptors, but did not localize with the iron storage protein ferritin. Furthermore, systemic administration of ironoxide+ASV-30 reduced amphetamine withdrawal-induced anxiety without affecting locomotion, suggesting that the anxiolytic effects of ASV-30 were preserved and the bioavailability of ASV-30 was sufficient. The findings demonstrate a novel approach to peptide delivery across the BBB and provide insight as to the neural distribution and efficacy of this nanotechnology.
Highlights
As our understanding of neuropeptide regulation of neuronal function increases, the need to effectively manipulate neuropeptide levels or receptor activity in the brain is becoming more necessary
APTES-coated Fe2O3 nanoparticles conjugated to ASV-30 were stable for at least 3 h in physiological conditions in vitro, and were observed throughout the brain 30 min following systemic administration in vivo
Iron oxide nanoparticles were able to effectively cross the blood-brain barrier (BBB) without interference from conjugated ASV-30 in a time course where the peptide was still attached to the nanoparticle
Summary
As our understanding of neuropeptide regulation of neuronal function increases, the need to effectively manipulate neuropeptide levels or receptor activity in the brain is becoming more necessary. Functionalized polyethylene glycol (PEG) and PEGylated dendrigraft polyL-lysines (DGL) nanomaterials have been utilized to deliver therapeutically-relevant peptides to the brain (e.g., Karatas et al, 2009; Lui et al, 2016) These require the nanomaterial to be conjugated to receptors or molecules to take advantage of receptor-mediated transport across the BBB but have the potential to significantly alter transport of endogenous ligands reliant on receptor-mediated transport (e.g., transferrin/iron, leptin, insulin) when nanomaterials are administered in chronic, therapeutic settings (Karatas et al, 2009; Lalatsa et al, 2014; Lui et al, 2016). Aminosilane functionalization prevents aggregation, allows for amino acid attachment and is not cytotoxic (Natarajan et al, 2008; Rivet et al, 2012)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
