Efficient
protein delivery into the target cell is highly desirable
for protein therapeutics. Current approaches for protein delivery
commonly suffer from low-loading protein capacity, poor specificity
for target cells, and invisible protein release. Herein, we report
a protein@inorganic nanodumpling (ND) system as an intracellular protein
delivery platform. Similar to a traditional Chinese food, the dumpling,
ND consists of a protein complex “filling” formed by
metal-ion-directed self-assembly of protein cargos fused to histidine-rich
green fluorescent proteins (H39GFPs), which are further
encapsulated by an external surface “wrapper” of manganese
dioxide (MnO2) via in situ biomineralization.
This ND structure allows for a high loading capacity (>63 wt %)
for
protein cargos with enhanced stability. NDs can be targeted and internalized
into cancer cells specifically through folic acid receptors by surface-tailored
folic acid. The protein cargo release is in a bistimuli-responsive
manner, triggered by an either reductive or acidic intracellular microenvironment.
Moreover, the MnO2 nanowrapper is an efficient fluorescence
quencher for inner fused GFPs and also a “switch-on”
magnetic resonance imaging (MRI) agent via triggered
release of Mn2+ ions, which enables activatable fluorescence/MRI
bimodal imaging of protein release. Finally, the ND is highly potent
and specific to deliver functional protein ribonuclease A (RNase A)
into cultured target cells and the tumor site in a xenografted mouse
model, eliminating the tumor cells with high therapeutic efficacy.
Our approach provides a promising alternative to advance protein-based
cancer therapeutics.
A charge designable and tunable green fluorescent protein (GFP)-based protein delivery strategy was proposed. The acquired His29GFP selectively permeates the cell membrane at a target pH of 6.5 and escapes from the endosome efficiently. The delivered RNase A caused substantial mRNA degradation in HeLa cells, and proliferation inhibition in different cell lines and a 3D tumor model at pH 6.5.
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