Enhanced Cellular Uptake of Peptide-Targeted Nanoparticles through Increased Peptide Hydrophilicity and Optimized Ethylene Glycol Peptide-Linker Length

Ligand-targeted nanoparticles are emerging drug delivery vehicles for cancer therapy. Here, we demonstrate that the cellular uptake of peptide-targeted liposomes and micelles can be significantly enhanced by increasing the hydrophilicity of the targeting peptide sequence while simultaneously optimizing the EG peptide-linker length. Two distinct disease models were analyzed, as the nanoparticles were functionalized with either VLA-4 or HER2 antagonistic peptides to target multiple myeloma or breast cancer cells, respectively. Our results demonstrated that including a short oligolysine chain adjacent to the targeting peptide sequence effectively increased cellular uptake of targeted nanoparticles up to ∼80-fold using an EG6 peptide-linker in liposomes and ∼27-fold using an EG18 peptide-linker in micelles for the VLA-4/multiple myeloma system. Similar trends were also observed in the HER2/breast cancer system with the EG18 peptide-linker resulting in optimal uptake for both types of nanoparticles. Cellular uptake efficiency of these formulations was also confirmed under fluidic conditions mimicking physiological systems. Taken together, these results demonstrated the significance of using the right design elements to improve the cellular uptake of nanoparticles

A Systematic Analysis of Peptide Linker Length and Liposomal Polyethylene Glycol Coating on Cellular Uptake of Peptide-Targeted Liposomes

PEGylated liposomes are attractive pharmaceutical nanocarriers; however, literature reports of ligand-targeted nanoparticles have not consistently shown successful results. Here, we employed a multifaceted synthetic strategy to prepare peptide-targeted liposomal nanoparticles with high purity, reproducibility, and precisely controlled stoichiometry of functionalities to evaluate the role of liposomal PEG coating, peptide EG-linker length, and peptide valency on cellular uptake in a systematic manner. We analyzed these parameters in two distinct disease models where the liposomes were functionalized with either HER2- or VLA-4-antagonistic peptides to target HER2-overexpressing breast cancer cells or VLA-4-overexpressing myeloma cells, respectively. When targeting peptides were tethered to nanoparticles with an EG45 (∼PEG2000) linker in a manner similar to a more traditional formulation, their cellular uptake was not enhanced compared to non-targeted versions regardless of the liposomal PEG coating used. Conversely, reduction of the liposomal PEG to PEG350 and the peptide linker to EG12 dramatically enhanced cellular uptake by ∼9 fold and ∼100 fold in the breast cancer and multiple myeloma cells, respectively. Uptake efficiency reached a maximum and a plateau with ∼2% peptide density in both disease models. Taken together, these results demonstrate the significance of using the right design elements such as the appropriate peptide EG-linker length in coordination with the appropriate liposomal PEG coating and optimal ligand density in efficient cellular uptake of liposomal nanoparticles

Nonchromatographic Affinity Precipitation Method for the Purification of Bivalently Active Pharmaceutical Antibodies from Biological Fluids

This Article describes an affinity-based precipitation method for the rapid and nonchromatographic purification of bivalently active monoclonal antibodies by combining the selectivity of affinity chromatography with the simplicity of salt-induced precipitation. This procedure involves (i) precipitation of proteins heavier than immunoglobulins with ammonium sulfate; (ii) formation and selective precipitation of cyclic antibody complexes created by binding to trivalent haptens specific for the antibody; and (iii) membrane filtration of the solubilized antibody pellet to remove the trivalent hapten from the purified antibody. We applied this technique to the purification of two pharmaceutical antibodies, trastuzumab and rituximab, by synthesizing trivalent haptens specific for each antibody. Using this method, we were able to purify both antibodies from typical contaminants including CHO cell conditioned media, ascites fluid, DNA, and other antibodies with yields >85% and with >95% purity. The purified antibodies displayed native binding levels to cell lines expressing the target proteins demonstrating that the affinity-based precipitation method did not adversely affect the antibodies. The selectivity of the affinity-based precipitation method for bivalently active antibodies was established by purifying trastuzumab from a solution containing both active and chemically denatured trastuzumab. Prior to purification, the solutions displayed 20–76% reduction in binding activity, and after purification, native binding activity was restored, indicating that the purified product contained only bivalently active antibody. Taken together, the affinity-based precipitation method provides a rapid and straightforward process for the purification of antibodies with the potential to improve product quality while decreasing the purification costs at both the lab and the industrial scale