Drug nanocarriers that have long been expected to revolutionize cancer therapy have yet to achieve the significant clinical success. Therefore, it remains controversial to pursue a complex drug nanocarrier that lacks clinical relevance. Herein, we developed an easily-synthesized anti-tumor drug that actively seeks the acidic tumor microenvironment while ignoring the normal tissue without the aid of additional carriers. This called “carrier-free” drug (CFD) is capable of switching its morphology from the unstructured solution to the spherical structure in response to tumor acidity. CFDs were the water-soluble zwitterionic unimers to prevent the non-specific distribution in the circulation, whereas they spontaneously formed into the particles tending to accumulation in tumor. CFD overloading in tumor cells caused the lysosomal dysfunction and autophagy blockage, thereby triggered the cell death. All the in vitro and in vivo data demonstrated the tumor-acidity-selective cytotoxicity of CFD. This facile strategy to create a self-delivering anticancer drug may cast a new light on the development of cancer therapy.Download high-res image (355KB)Download full-size image

Numerous preclinical studies have demonstrated that polycation mediated gene delivery systems successfully achieved efficient gene transfer into cells and animal models. However, results of their clinical trials to date have been disappointing. That self-assembled gene and polycation systems should be stable undergoing dilution in the body is one of the prerequisites to ensuring efficiency of gene transfer in clinical trials, but it was neglected in most preclinical studies. In this account, we developed the dilution-stable PAMAM G1-grafted polyrotaxane (PPG1) supermolecules in which PAMAM G1-grafted α-cyclodextrins are threaded onto a PEG chain capped with hydrophobic adamantanamine. The PPG1/pDNA polyplex (approximate 100 nm in diameter) was very stable and kept its initial particle size and a uniform size distribution at ultrahigh dilution, whereas DNA/PEI 25K polyplex was above three times bigger at a 16-fold dilution than the initial size and their particle size distribution indicated multiple peaks mainly due to forming loose and noncompacted aggregates. PPG1 supermolecules showed significantly superior transfection efficiencies compared to either PEI 25K or Lipofectamine 2000 in most cell lines tested including normal cells (HEK293A) and cancer cells (Bel7402, HepG2, and HeLa). Furthermore, we found that the PPG1 supermolecules delivered DNA into HEK293A through a caveolae-dependent pathway but not a clathrin-dependent pathway as PEI 25K did. These findings raised the intriguing possibility that the caveolae-dependent pathway of PPG1 supermolecule/pDNA polyplex avoiding lysosomal degradation was attributed to their high transfection efficiency. The dilution-stable PPG1 supermolecule polyplex facilitating caveolae-dependent internalization has potential applications to surmount the challenges of high dilutions in the body and lysosomal degradation faced by most gene therapy clinical trials.Keywords: caveolae-dependent pathway; dilution-stable; PAMAM dendrimer derivatives; polyrotaxane; supramolecular structures;

Poly(ethylene glycol)-poly(L-glutamine) (PEG-PLGA) copolymer EA-G2 (or EA-G1) was prepared by aminolysis of poly(ethylene glycol)-poly(L-benzyl glutamate) (PEG-PBLG) using PAMAM G2 (or G1). The chemical structure of PEG-PLGA was confirmed by FT-IR, 1H-NMR, DSC and GPC. The performances of the EA-G2 (or EA-G1) were assayed by enzyme degradation, MTT method and agarose gel electrophoresis. The particle size, zeta potential and morphology of EA-G2 (or EA-G1)/pDNA complexes were inspected by DLS and AFM. The cellular uptake mechanism was evaluated by endocytic inhibiting test, cell uptake test and observation of CLSM. The transfection activity was measured by flow cytometry. The EA-G2 (or EA-G1) exhibited good biodegradability, low cytotoxicity and great ability to combine with pDNA. The EA-G2 (or EA-G1) complexes exhibited particle sizes in the range 120–180 nm and zeta potentials in the range 20–40 mV, which were suitable for cell uptake. The cellular uptake of the EA-G2 complexes occurred mainly through clathrin-dependent and caveolin-mediated endocytosis, and at 6 h in 10% FBS and in serum-free media, the percentages of complex uptake reached 89.0% or 72.7%, respectively. EA-G2 complexes could efficiently mediate pEGFP-Cl into the cell nuclei. EA-G2 complexes displayed enhancing transfection efficiency and better serum tolerance. The results suggest that the EA-G2 has potential to be used as a biodegradable, efficient and serum-resistant gene vector.

Short interfering RNAs (siRNAs) as chemotherapeutic RNAi agents hold great promise for a significant improvement in cancer therapy. Despite the promise, effective transport of siRNA with minimal side effects remains a challenge. The common problem associated with the low delivery efficiencies of current polycation-based gene delivery systems is their low stability in the presence of salt and serum. In the present study we developed the polyglutamate derivatives (PGS) polyelectrolyte brushes for NF-κB p65 siRNA delivery. The PGS polyelectrolyte brushes/siRNA polyplex was colloidally stable (150 nm diameter) in physiological saline (150 mM NaCl), likely due to the osmotic brushes of PGS. The size-controlled siRNA/PGS polyplex also showed the serum resistance resulting in their efficient cellular uptake was not negatively influenced by the presence of serum. The endothermic profile of ITC, their low values of Gibbs free energy and binding constants Kb under salt conditions provided the direct evidence that PGS polyelectrolyte brushes had a much lower binding affinity for serum proteins, compared with PEI 25KDa. PGS polyelectrolyte brushes delivering NF-κB p65 siRNA achieved efficient down-regulation of NF-κB p65 protein in HeLa cells. The NF-κB p65 down-regulation mediated by PGS polyelectrolyte brushes was more significant than PEI 25KDa and comparable to Lipofectamine 2000. Furthermore, the combination treatment with PGS polyelectrolyte brushes/NF-κB p65 siRNA polyplex and doxorubicin demonstrated synergistic apoptotic and cytotoxic effects on HeLa cancer cells. The high stability in physiological saline and salt-induced serum resistance of PGS polyelectrolyte brushes/siRNA polyplex has potential applications together with standard chemotherapies such as doxorubicin to be a viable method to improve the clinical outcomes in cancer therapies.

It was recently reported that polyanion/DNA/polycation ternary polyplexes markedly improve gene transfection activity in comparison with the original DNA/polycation binary polyplexes. In this study to explore the influence of the polyanion on the physico-chemical properties and biological activity of polyanion/pDNA/polycation ternary polyplexes four types of biocompatible polyanions were selected, mainly based on the acid strength of the anionic functional groups and the molecular rigidity on forming ternary polyplexes with 25 kDa polyethyleneimine and DNA. Polyanion loosening of the DNA polyplex, weakening of the adsorption of serum proteins and improving of cellular uptake, which are thought to be important factors leading to a high transfection efficiency of DNA ternary polyplexes, were specifically investigated. Electrophoresis retardation analysis indicated that the loosening capacity of polyanions depended on the pKa value of the functional anion groups as well as the flexibility of the polyanion. The low pKa and flexible structure of the polyanions tended to loosen the compact DNA polyplexes. Thermodynamic analysis by isothermal titration calorimetry provided direct evidence about the serum protein–DNA ternary polyplex interactions. The polyanion/pDNA/polycation ternary polyplexes exhibited obviously lower binding affinities and less adsorption to serum proteins compared with the original DNA/polycation binary polyplexes. These relatively stable DNA ternary polyplexes maintained high levels of cellular uptake and intracellular accumulation in serum-containing medium that correlated with their high transfection efficiency. In contrast, the original pDNA/polycation binary polyplexes became clustered by strong adsorption of large amounts of serum proteins, leading to a sharp reduction in cellular uptake and intracellular accumulation, and thus low gene transfer efficiency. These results provide a basis for the development of polyanion/DNA/polycation ternary polyplexes for polyfection.

Cationic nanocarrier mediated intracellular therapeutic agent delivery acts as a double-edged sword: the carriers promote cellular uptake, but interact nonspecifically and strongly with negatively charged endogenic proteins and cell membranes, which results in aggregates and high cytotoxicity. The present study was aimed at exploring zwitterionic polyaspartamide derivative nanoparticles for efficient intracellular delivery with low cytotoxicity. Poly(aspartic acid) partially grafted tetraethylenepentamine (PASP-pg-TEPA) with different isoelectric points (IEPs) was synthesized. The PASP-pg-TEPA formed zwitterionic nanoparticles with an irregular core and a well-defined shell structure in aqueous medium. Their particle size decreased from about 300 to 80 nm with an increase of the IEP from 7.5 to 9.1. The surface charge of the PASP-pg-TEPA nanoparticles could be tuned from positive to negative with a change of the pH of the medium. The nanoparticles with an IEP above 8.5 exhibited good stability under simulated physiological conditions. It was noted that the zwitterionic PASP-pg-TEPA nanoparticles displayed highly efficient cellular uptake in HeLa cells (approximately 99%) in serum-containing medium and did not adversely affect the cell viability at concentrations up to 1 mg/mL. Furthermore, thermodynamic analysis using isothermal titration calorimetry provided direct evidence that these zwitterionic nanoparticles had low binding affinities for serum protein. Therefore, the zwitterionic PASP-pg-TEPA nanoparticles could overcome limitations of cationic nanocarriers and achieve efficient intracellular delivery with low cytotoxicity.

In the present study, we developed novel insulin-loaded hyaluronic acid (HA) nanoparticles for insulin delivery. The insulin-loaded HA nanoparticles were prepared by reverse-emulsion-freeze-drying method. This method led to a homogenous population of small HA nanoparticles with average size of 182.2 nm and achieved high insulin entrapment efficiencies (approximately 95%). The pH-sensitive HA nanoparticles as an oral delivery carrier showed advantages in protecting insulin against the strongly acidic environment of the stomach, and not destroying the junction integrity of epithelial cells which promise long-term safety for chronic insulin treatment. The results of transport experiments suggested that insulin-loaded HA nanoparticles were transported across Caco-2 cell monolayers mainly via transcellular pathway and their apparent permeability coefficient from apical to basolateral had more than twofold increase compared with insulin solution. The efflux ratio of Papp (B to A) to Papp (A to B) less than 1 demonstrated that HA nanoparticle-mediated transport of insulin across Caco-2 cell monolayers underwent active transport. The results of permeability through the rat small intestine confirmed that HA nanoparticles significantly enhanced insulin transport through the duodenum and ileum. Diabetic rats treated with oral insulin-loaded HA nanoparticles also showed stronger hypoglycemic effects than insulin solution. Therefore, these HA nanoparticles could be a promising candidate for oral insulin delivery.

Inefficient endosomal escape and poor nuclear import are thought to contribute to low gene transfer efficiency of polycations. To overcome these drawbacks, we prepared multiple gene delivery formulations including low cytotoxic polycation, histone containing NLSs and chloroquine as the endosomolytic agent.Comb-shaped poly (L-glutamic acid) grafted low-molecular-weight polyethylenimine (PLGE) copolymer was synthesized by aminolysis of poly-γ-benzyl-L-glutamate using low-molecular-weight polyethylenimine (800 Da). The formation of DNA/histone/PLGE terplex was observed by atomic force microscope and gel retardation assay. The particle size and zeta potential of DNA complexes with varying content of histone were also measured to confirm the terplex formation. Cytotoxicity of vectors was assayed by MTT. Multiple gene delivery formulations were optimized to their best transfection efficiency that was monitored by fluorescence microscope and flow cytometry. In vivo gene delivery of the optimal formulation was evaluated by the GFP-expression levels in drosophila melanogaster.The DNA/histone/PLGE terplex was successfully formed. The PLGE and histone together condensed DNA into small, discrete particles (less than 200 nm in diameter) in isotonic solution. Cytotoxicity of PLGE and histone were much lower than that of PEI 25 K. Either histone or chloroquine contributed to enhancing the levels of transfection activity of PLGE polymer. However, chloroquine and histone did not show a synergistic effect on the improvement of transfection efficiency. The optimal formulation was the DNA/histone/PLGE terplex at the N/P ratio of 15 and histone/ DNA weight ratio of 0.8. Compared with Lipofectamine 2000 and PEI 25 K, the optimal formulation showed significantly increased levels of GFP-expression both in vitro and in vivo.This formulation provided a versatile approach for preparing high efficiency of the polycation-based gene vectors. It also reinforced the finding of earlier studies that nuclear import and endosomal escape were rate-limiting steps for nonviral gene delivery.

RNA interfere (RNAi)-based technology holds great promise in cancer treatment. The use of small interfering RNA (siRNA), however, is hampered by its low delivery efficiency in vivo when they are diluted in blood biofluids and in the presence of serum and salt. In this study, we developed the polyglutamate derivative polymer brush, poly(ethyleneglycol) monomethyl ether-b-polyglutamate-g-spermine (mPEG-b-PG-g-spermine, PPGS), which could efficiently deliver survivin-siRNA under ultra-high dilution and in the presence of salt (NaCl 150 mM) and serum (10% FBS), most likely due to its PEG-shelled polymer brush structure. On the contrary, aggregation occurred when PEI/siRNA polyplex dispersed in saline and serum-containing media and PEI polyplex dissociated after making a 256-fold dilution. PPGS/si-survivin polyplex exhibited high cellular uptake efficiency and efficiently down-regulated the expression of survivin mRNA in the cisplatin-resistance of non-small cell human lung adenocarcinoma (A549/DDP) cells in the presence of serum. However, either PEI polyplex or Lipofectmine 2000 complex was unstable in serum and salt-containing media and at high dilution rates, which resulted in their dramatical decrease of cellular uptake and gene-silencing efficiency in these conditions. The PPGS/si-survivin polyplex also exhibited synergistic effects of killing the cancer cells by combination treatment with cisplatin. Therefore, the PPGS gene carrier showed great potential in systemic siRNA delivery, and its combination with chemotherapeutic drug is promising in treating drug resistant cancers.Download high-res image (299KB)Download full-size image

Poly(ethylene glycol)-poly(L-glutamine) (PEG-PLGA) copolymer EA-G2 (or EA-G1) was prepared by aminolysis of poly(ethylene glycol)-poly(L-benzyl glutamate) (PEG-PBLG) using PAMAM G2 (or G1). The chemical structure of PEG-PLGA was confirmed by FT-IR, 1H-NMR, DSC and GPC. The performances of the EA-G2 (or EA-G1) were assayed by enzyme degradation, MTT method and agarose gel electrophoresis. The particle size, zeta potential and morphology of EA-G2 (or EA-G1)/pDNA complexes were inspected by DLS and AFM. The cellular uptake mechanism was evaluated by endocytic inhibiting test, cell uptake test and observation of CLSM. The transfection activity was measured by flow cytometry. The EA-G2 (or EA-G1) exhibited good biodegradability, low cytotoxicity and great ability to combine with pDNA. The EA-G2 (or EA-G1) complexes exhibited particle sizes in the range 120–180 nm and zeta potentials in the range 20–40 mV, which were suitable for cell uptake. The cellular uptake of the EA-G2 complexes occurred mainly through clathrin-dependent and caveolin-mediated endocytosis, and at 6 h in 10% FBS and in serum-free media, the percentages of complex uptake reached 89.0% or 72.7%, respectively. EA-G2 complexes could efficiently mediate pEGFP-Cl into the cell nuclei. EA-G2 complexes displayed enhancing transfection efficiency and better serum tolerance. The results suggest that the EA-G2 has potential to be used as a biodegradable, efficient and serum-resistant gene vector.