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Dimeric cationic amphiphilic polyproline helices for mitochondrial targeting.
Pharm Res. 2011 Nov;28(11):2797-807. doi: 10.1007/s11095-011-0493-7
Geisler IM, Chmielewski J
Abstract:
PURPOSE:
Efficient delivery of therapeutic biopolymers across cell membranes remains a daunting challenge. The development of cell-penetrating peptides (CPPs) has been useful; however, many CPPs are found trapped within endosomes, limiting their use as delivery agents. We optimize a class of CPPs, cationic amphiphilic polyproline helices (CAPHs), for direct transport into cells with mitochondrial localization through dimerization.
METHODS:
The CAPH P11LRR used for this study has been found to enter cells by two distinct pathways: an endocytotic pathway was favored at low concentrations; internalization by direct transport was observed at higher concentrations. CAPH was dimerized to probe if direct transport within cells may be enhanced through increased association of CAPH with the membrane and through the association of individual peptides within the membrane.
RESULTS:
The dimerization of the CAPH was found to significantly increase cellular uptake over its monomeric counterpart, with a concomitant lowering of the concentration threshold favoring direct transport. Evidence for direct transport within cells and mitochondrial localization was observed.
CONCLUSIONS:
CAPH cellular uptake efficiency can be significantly enhanced through peptide dimerization while favoring cell entry via direct transport at low concentration with low cell toxicity.
Efficient delivery of therapeutic biopolymers across cell membranes remains a daunting challenge. The development of cell-penetrating peptides (CPPs) has been useful; however, many CPPs are found trapped within endosomes, limiting their use as delivery agents. We optimize a class of CPPs, cationic amphiphilic polyproline helices (CAPHs), for direct transport into cells with mitochondrial localization through dimerization.
METHODS:
The CAPH P11LRR used for this study has been found to enter cells by two distinct pathways: an endocytotic pathway was favored at low concentrations; internalization by direct transport was observed at higher concentrations. CAPH was dimerized to probe if direct transport within cells may be enhanced through increased association of CAPH with the membrane and through the association of individual peptides within the membrane.
RESULTS:
The dimerization of the CAPH was found to significantly increase cellular uptake over its monomeric counterpart, with a concomitant lowering of the concentration threshold favoring direct transport. Evidence for direct transport within cells and mitochondrial localization was observed.
CONCLUSIONS:
CAPH cellular uptake efficiency can be significantly enhanced through peptide dimerization while favoring cell entry via direct transport at low concentration with low cell toxicity.