The cellular machinery involved in the internalization of nonviral gene carriers and their subsequent trafficking to the nucleus directly impacts their therapeutic efficiency. Hence, identifying key endocytic pathways and organelles that contribute to the successful transfer of polyplexes to the nucleus generates new opportunities for improving carrier design. Previously, we showed that histone H3 tail peptides encoding a sequence known to participate in chromatin activation exhibit synergistic gene delivery activity with poly(ethylenimine) (PEI). Polyplexes containing H3 and PEI exhibited a reduced dependence on endocytic pathways that trafficked to lysosomes, and had enhanced sensitivity to an inhibitor associated with retrograde trafficking through the Golgi apparatus. Thus, we sought to determine whether caveolar uptake and transport through the Golgi and/or endoplasmic reticulum (ER) preceded nuclear delivery. By the use of a panel of chemical endocytic inhibitors, we determined that H3 polyplexes utilized caveolar pathways to a greater degree than PEI polyplexes. Caveolae-mediated endocytosis was found to be a productive route for gene expression by the H3/PEI-pDNA polyplexes, consistent with previous studies of polymer-mediated gene delivery. Additionally, the polyplexes substantially colocalized within the ER after only 5 min of incubation, and utilized retrograde Golgi-to-ER pathways at levels similar to pathogens known to traffic by these routes during infection. The results of this study have expanded our understanding of how caveolar polyplexes are trafficked to cell nuclei, and provide new evidence for the role of Golgi-ER pathways in transfection. These findings suggest new design criteria and opportunities to stragetically target nonviral gene delivery vehicles.
This goal of this work was to explore histone H3 tail peptides containing transcriptionally activating modifications for their potential as gene delivery materials. We have found that these H3 tail peptides, in combination with the cationic polymer poly(ethylenimine) (PEI), can effectively bind and protect plasmid DNA. The H3/PEI hybrid polyplexes were found to transfect a substantially larger number of CHO-K1 cells in vitro compared to both polyplexes that were formed with only the H3 peptides and those that were formed with only PEI at the same total charge ratio; however, transfection was similarly high for polyplexes both with and without transcriptionally activating modifications. Transfections with the endolysosomal inhibitors chloroquine and bafilomycin A1 indicated that the H3/PEI hybrid polyplexes exhibited slower uptake and a reduced dependence on endocytic pathways that trafficked to the lysosome, indicating a potentially enhanced reliance on caveolar uptake for efficient gene transfer. In addition, whereas PEI polyplexes typically exhibit a cytotoxic effect, the H3/PEI hybrid polyplexes did not compromise cell viability. In total, the current studies provide new evidence for the potential role for histone-based materials as effective gene transfer agents, and support for the importance of subcellular trafficking for nonviral gene delivery.
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