Exosomes are a valuable biomaterial for the development of novel nanocarriers as functionally advanced drug delivery systems. To control and modify the performance of exosomal nanocarriers, we developed hybrid exosomes by fusing their membranes with liposomes using the freeze–thaw method. Exosomes embedded with a specific membrane protein isolated from genetically modified cells were fused with various liposomes, confirming that membrane engineering methods can be combined with genetic modification techniques. Cellular uptake studies performed using the hybrid exosomes revealed that the interactions between the developed exosomes and cells could be modified by changing the lipid composition or the properties of the exogenous lipids. These results suggest that the membrane-engineering approach reported here offers a new strategy for developing rationally designed exosomes as hybrid nanocarriers for use in advanced drug delivery systems.
PKH
dyes, which are currently the most widely used fluorescent
probes for extracellular vesicle (EV) labeling, have some limitations.
For example, these dyes tend to aggregate, leading to formation of
EV-like nanoparticles that can be taken up by cells. Moreover, it
has been suggested that PKH dyes trigger an enlargement of EVs because
of membrane fusion or intercalation. To overcome these limitations,
we developed three novel extracellular vesicular-membrane-binding
fluorescent probesMem dye-Green, Mem dye-Red, and Mem dye-Deep
Redfor monitoring EV uptake into cells. The dyes contain a
cyanine group as a fluorescent scaffold and amphiphilic moieties on
the cyanine. The three dyes have different photophysical characteristics.
To investigate the characteristics of the Mem dyes for EV labeling,
we performed nanoparticle tracking, zeta potential measurements, and
confocal microscopy. The dyes enable highly sensitive fluorescence
imaging of EVs. They can also be used to observe EV dynamics in live
cells. The Mem dyes show excellent EV labeling with no aggregation
and less particle enlargement.
Nanometer-size gel particles, or nanogels, have potential for delivering therapeutic macromolecules. A cationic surface promotes cellular internalization of nanogels, but undesired electrostatic interactions, such as with blood components, cause instability and toxicities. Poly(ethylene glycol) coating has been used to shield charges, but this decreases delivery efficiency. Technical difficulties in synthesis and controlling molecular weights make it unfeasible to, instead, coat with biodegradable polymers. Our proposed solution is cationized nanogels enzymatically functionalized with branched polysaccharide chains, forming a shell to shield charges and increase stability. Biodegradation of the polysaccharides by an endogenous enzyme would then expose the cationic charges, allowing cellular internalization and cargo delivery. We tested this concept, preparing maltopentaose functionalized cholesteryl poly(l-lysine) nanogel and using tandem enzymatic polymerization with glycogen phosphorylase and glycogen branching enzyme, to add branched amylose moieties, forming a CbAmyPL nanogel. We characterized CbAmyPL nanogels and investigated their suitability as small interfering RNA (siRNA) carriers in murine renal carcinoma (Renca) cells. The nanogels had neutral ζ potential values that became positive after degradation by α-amylase. Foster resonance energy transfer demonstrated that the nanogels formed stable complexes with siRNA, even in the presence of bovine serum albumin and after α-amylase exposure. The nanogels, with or without α-amylase, were not cytotoxic. Complexes of CbAmyPL with siRNA against vascular endothelial growth factor (VEGF), when incubated alone with Renca cells decreased VEGF mRNA levels by only 20%. With α-amylase added, however, VEGF mRNA knockdown by the siRNA/nanogels complexes was 50%. Our findings strongly supported the hypothesis that enzyme-responsive nanogels are promising as a therapeutic siRNA delivery platform.
Abstract:Protein nanocages are self-organized complexes of oligomers whose three-dimensional architecture can been determined in detail. These structures possess nanoscale inner cavities into which a variety of molecules, including therapeutic or diagnostic agents, can be encapsulated. These properties yield these particles suitable for a new class of drug delivery carrier, or as a bioimaging reagent that might respond to biochemical signals in many different cellular processes. We report here the design, synthesis, and biological characterization of a hepatocyte-specific nanocage carrying small heat-shock protein. These nanoscale protein cages, with a targeting peptide composed of a preS1 derivative from the hepatitis B virus on their surfaces, were prepared by genetic engineering techniques. PreS1-carrying nanocages showed lower cytotoxicity and significantly higher specificity for human hepatocyte cell lines than other cell lines in vitro. These results suggested that small heat-shock protein-based nanocages present great potential for the development of effective targeted delivery of various agents to specific cells.
A new siRNA delivery system using a cationic glyco-star polymer is described. Spermine-modified 8-arm amylose star polymer (with a degree of polymerization of approximately 60 per arm) was synthesized by chemoenzymatic methods. The cationic star polymer effectively bound to siRNA and formed spherical complexes with an average hydrodynamic diameter of 230 nm. The cationic 8-arm star polymer complexes showed superior cellular uptake characteristics and higher gene silencing effects than a cationic 1-arm polymer. These results suggest that amylose-based star polymers are a promising nanoplatform for glycobiomaterials.
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