Xianghui Xu

Cooperative Hierarchical Self-Assembly of Peptide Dendrimers and Linear Polypeptides into Nanoarchitectures Mimicking Viral Capsids †

Supramolecular self-assembly is regarded as ubiquitous and essential phenomenon during the early stages of life. In the past decade, self-assembly inspired from nature has been evolved as an effective and practical strategy for nanoarchitecture fabrication. With respect to the formation of soft matter, advances were achieved in the selfassembly of linear polymers, but the selfassembly of spherical macromolecules such as dendrimers is still at an early stage. The regulation of dispersive dendrimers into ordered nanoarchitectures as potential biomacromolecules remains challenging research work. Peptide dendrimers possess not only the general characteristics of typical dendrimers, but also certain unique properties of globular proteins. Initiating hierarchical self-assembly of globular or linear polypeptides may provide a powerful approach to fabricate supramolecular structures with transfer or delivery functions in medical applications as virosomes in cellular environment. Most dendrimers lack the driving forces for self-assembly; therefore, chemical or physical interactions were explored as driving forces. Herein, we report a novel approach to regulate the cooperative selfassembly of peptide dendrimers and linear polypeptides into capsid-like nanostruc-

Capsid-like supramolecular dendritic systems as pH-responsive nanocarriers for drug penetration and site-specific delivery

UNLABELLED Supramolecular dendritic systems emerge as a promising new-generation bioinspired nanoplatform for nanomedicine. Herein, we report capsid-like mimics self-assembled from peptide dendrimers and functionalized peptides to enhance drug penetration and site-specific delivery for tumor therapy. These drug-loaded supramolecular dendritic systems are endowed with capsid-like component and nanostructure by a facile supramolecular approach. As expected, the drug-loaded capsid-like nanocarriers show some desirable advantages for antitumor drug delivery: a) well-defined nanostructure to improve drug location at tumor site, b) capsid-like architecture to enhance drug penetration, c) high internalization, pH-controlled release and nuclear delivery to jointly achieve site-specific delivery. Based on these merits, the drug-loaded capsid nanocarriers provide efficient tumor suppression to 4T1 tumor bearing BALB/c mice and decrease the DOX-induced toxicity during treatment course. FROM THE CLINICAL EDITOR Dendrimers have been tested in many clinical trials as nanocarriers, without great success due to many limitations. Here, the authors attempted to address these issues by developing supramolecular dendritic systems, which mimic capsids in viruses. Both in-vitro and in-vivo studies showed promising results. This work should provide a platform for further development of dendrimer-based nanocarriers for drug delivery.

Anti-tumor drug delivery of pH-sensitive poly(ethylene glycol)-poly(L-histidine-)-poly(L-lactide) nanoparticles.

pH-sensitive poly(ethylene glycol)-poly(L-histidine)-poly(L-lactide) (PEG-PH-PLLA) nanoparticles were prepared and used as carriers for anti-tumor drug delivery. The morphology and properties of the nanoparticles such as pH sensitivity, zeta potential and mean diameters were investigated. The cytotoxicity of PEG-PH-PLLA nanoparticles was evaluated. Doxorubicin (DOX) was encapsulated in the nanoparticles to explore the release profile. The drug-loaded nanoparticles were incubated with HepG2 cells to study the in vitro anti-tumor effect. The results showed the sizes of both blank nanoparticles and drug-loaded nanoparticles in pH 7.4 were smaller than those of nanoparticles in pH 5.0, and the mean diameter of drug-loaded nanoparticles was much bigger than that of blank nanoparticles. The PEG-PH-PLLA nanoparticles were nontoxic to both NIH 3T3 fibroblasts and HepG2 cells. The release profile showed that the release of DOX in pH 5.0 was much faster than that in pH 7.4. The in vitro experiments demonstrated that the anti-tumor effect of drug-loaded nanoparticles was preferable to free doxorubicin. The pH-sensitive PEG-PH-PLLA nanoparticles are promising carriers for anti-tumor drug delivery.

Bio-Inspired Supramolecular Hybrid Dendrimers Self-Assembled from Low-Generation Peptide Dendrons for Highly Efficient Gene Delivery and Biological Tracking

Currently, supramolecular self-assembly of dendrons and dendrimers emerges as a powerful and challenging strategy for developing sophisticated nanostructures with excellent performances. Here we report a supramolecular hybrid strategy to fabricate a bio-inspired dendritic system as a versatile delivery nanoplatform. With a rational design, dual-functionalized low-generation peptide dendrons (PDs) self-assemble onto inorganic nanoparticles via coordination interactions to generate multifunctional supramolecular hybrid dendrimers (SHDs). These SHDs exhibit well-defined nanostructure, arginine-rich peptide corona, and fluorescent signaling properties. As expected, our bio-inspired supramolecular hybrid strategy largely enhances the gene transfection efficiency of SHDs approximately 50 000-fold as compared to single PDs at the same R/P ratio. Meanwhile the bio-inspired SHDs also (i) provide low cytotoxicity and serum resistance in gene delivery; (ii) provide inherent fluorescence for tracking intracellular pathways including cellular uptake, endosomal escape, and gene release; and (iii) work as an alternative reference for monitoring desired protein expression. More importantly, in vivo animal experiments demonstrate that SHDs offer considerable gene transfection efficiency (in muscular tissue and in HepG2 tumor xenografts) and real-time bioimaging capabilities. These SHDs will likely stimulate studies on bio-inspired supramolecular hybrid dendritic systems for biomedical applications both in vitro and in vivo.

Bioinspired Therapeutic Dendrimers as Efficient Peptide Drugs Based on Supramolecular Interactions for Tumor Inhibition

Bioinspired tryptophan-rich peptide dendrimers (TRPDs) are designed as a new type of dendritic peptide drugs for efficient tumor therapy. The TRPDs feature a precise molecular structure and excellent water solubility and are obtained in a facile process. Based on the unique features of peptide dendrimers, including highly branched structures, abundant terminal groups, and globular-protein-like architectures, the therapeutic dendrimers show significant supramolecular interactions with DNA through the tryptophan residues (indole rings and amino groups). Further experimental results indicate that TRPDs are efficient antitumor agents both in vitro and in vivo.

Cationic lipid-coated PEI/DNA polyplexes with improved efficiency and reduced cytotoxicity for gene delivery into mesenchymal stem cells

Background Effective gene transfection without serum deprivation is a prerequisite for successful stem cell-based gene therapy. Polyethylenimine (PEI) is an efficient nonviral gene vector, but its application has been hindered by serum sensitivity and severe cytotoxicity. Methods To solve this problem, a new family of lipopolyplexes was developed by coating PEI/DNA polyplexes with three serum-resistant cationic lipids, namely, lysinylated, histidylated, and arginylated cholesterol. The physical properties, transfection efficiency, cellular uptake, subcellular distribution, and cytotoxicity of the lipopolyplexes was investigated. Results The outer coat composed of lysinylated or histidylated cholesterol remarkably improved the transfection efficiency of the polyplex with a low PEI/DNA ratio of 2 in the presence of serum. The resulting lysinylated and histidylated cholesterol lipopolyplexes were even more efficient than the best performing polyplex with a high PEI/DNA ratio of 10. Results from cellular uptake and subcellular distribution studies suggest that their higher transfection efficiency may result from accelerated DNA nuclear localization. The superiority of the lipopolyplexes over the best performing polyplex was also confirmed by delivering the therapeutic gene, hVEGF165. Equally importantly, the lipid coating removed the necessity of introducing excess free PEI chains into the transfection solution for higher efficiency, generating lipopolyplexes with no signs of cytotoxicity. Conclusion Noncovalent modification of polyplexes with lysinylated and histidylated cholesterol lipids can simultaneously improve efficiency and reduce the toxicity of gene delivery under serum conditions, showing great promise for genetic modification of bone marrow stem cells.

Tumor-Specific Multiple Stimuli-Activated Dendrimeric Nanoassemblies with Metabolic Blockade Surmount Chemotherapy Resistance

Chemotherapy resistance remains a serious impediment to successful antitumor therapy around the world. However, existing chemotherapeutic approaches are difficult to cope with the notorious multidrug resistance in clinical treatment. Herein, we developed tumor-specific multiple stimuli-activated dendrimeric nanoassemblies with a metabolic blockade to completely combat both physiological barriers and cellular factors of multidrug resistance. With a sophisticated molecular and supramolecular engineering, this type of tumor-specific multiple stimuli-activated nanoassembly based on dendrimeric prodrugs can hierarchically break through the sequential physiological barriers of drug resistance, including stealthy dendritic PEGylated corona to optimize blood transportation, robust nanostructures for efficient tumor passive targeting and accumulation, enzyme-activated tumor microenvironment targeted to deepen tumor penetration and facilitate cellular uptake, cytoplasmic redox-sensitive disintegration for sufficient release of encapsulated agents, and lysosome acid-triggered nucleus delivery of antitumor drugs. In the meantime, we proposed a versatile tactic of a tumor-specific metabolism blockade for provoking several pathways (ATP restriction, apoptotic activation, and anti-apoptotic inhibition) to restrain multiple cellular factors of drug resistance. The highly efficient antitumor activity to drug-resistant MCF-7R tumor in vitro and in vivo supports this design and strongly defeats both physiological barriers and cellular factors of chemotherapy resistance. This work sets up an innovative dendrimeric nanosystem to surmount multidrug resistance, contributing to the development of a comprehensive nanoparticulate strategy for future clinical applications.

Supramolecular PEGylated Dendritic Systems as pH/Redox Dual-Responsive Theranostic Nanoplatforms for Platinum Drug Delivery and NIR Imaging

Recently, self-assembling small dendrimers into supramolecular dendritic systems offers an alternative strategy to develop multifunctional nanoplatforms for biomedical applications. We herein report a dual-responsive supramolecular PEGylated dendritic system for efficient platinum-based drug delivery and near-infrared (NIR) tracking. With a refined molecular/supramolecular engineering, supramolecular dendritic systems were stabilized by bioreducible disulfide bonds and endowed with NIR fluorescence probes, and PEGylated platinum derivatives coordinated onto the abundant peripheral groups of supramolecular dendritic templates to generate pH/redox dual-responsive theranostic supramolecular PEGylated dendritic systems (TSPDSs). TSPDSs markedly improved the pharmacokinetics and biodistribution of platinum-based drugs, owing to their stable nanostructures and PEGylated shells during the blood circulation. Tumor intracellular environment (low pH value and high glutathione concentration) could trigger the rapid disintegration of TSPDSs due to acid-labile coordination bonds and redox-cleavable disulfide linkages, and then platinum-based drugs were delivered into the nuclei to exert antitumor activity. In vivo antitumor treatments indicated TSPDSs not only provided high antitumor efficiency which was comparable to clinical cisplatin, but also reduced renal toxicity of platinum-based drugs. Moreover, NIR fluorescence of TSPDSs successfully visualized in vitro and in vivo fate of nanoplatforms and disclosed the intracellular platinum delivery and pharmacokinetics. These results confirm tailor-made supramolecular dendritic system with sophisticated nanostructure and excellent performance is a promising candidate as smart theranostic nanoplatforms.

Virus-inspired mimics: self-assembly of dendritic lipopeptides into arginine-rich nanovectors for improving gene delivery

With inspirations from natural viruses, arginine-containing dendritic lipopeptides were designed for bioinspired fabrication. Self-assembling the defined amphiphilic lipopeptides generated virus-inspired nanovectors with an arginine-rich corona. These nanovectors provided some remarkable benefits for gene delivery, including well-defined nanostructure, high transfection efficiency, serum resistance and low cytotoxicity.

Design and self-assembly of amphiphilic peptide dendron-jacketed polysaccharide polymers into available nanomaterials

An amphiphilic peptide dendron-jacketed dextran polymer was designed and synthesized via click chemistry. The biocompatible peptide dendron-jacketed dextran could self-assemble into nanoparticles and serve as drug carriers in aqueous media.