Targeted axonal import (TAxI) peptide delivers functional proteins into spinal cord motor neurons after peripheral administration.

A significant unmet need in treating neurodegenerative disease is effective methods for delivery of biologic drugs, such as peptides, proteins, or nucleic acids into the central nervous system (CNS). To date, there are no operative technologies for the delivery of macromolecular drugs to the CNS via peripheral administration routes. Using an in vivo phage-display screen, we identify a peptide, targeted axonal import (TAxI), that enriched recombinant bacteriophage accumulation and delivered protein cargo into spinal cord motor neurons after intramuscular injection. In animals with transected peripheral nerve roots, TAxI delivery into motor neurons after peripheral administration was inhibited, suggesting a retrograde axonal transport mechanism for delivery into the CNS. Notably, TAxI-Cre recombinase fusion proteins induced selective recombination and tdTomato-reporter expression in motor neurons after intramuscular injections. Furthermore, TAxI peptide was shown to label motor neurons in the human tissue. The demonstration of a nonviral-mediated delivery of functional proteins into the spinal cord establishes the clinical potential of this technology for minimally invasive administration of CNS-targeted therapeutics.

Cystine-knot peptides: emerging tools for cancer imaging and therapy.

Cystine-knot miniproteins, also known as knottins, constitute a large family of structurally related peptides with diverse amino acid sequences and biological functions. Knottins have emerged as attractive candidates for drug development as they potentially fill a niche between small molecules and protein biologics, offering drug-like properties and the ability to bind to clinical targets with high affinity and selectivity. Due to their extremely high stability and unique structural features, knottins also demonstrate promise in addressing challenging drug development goals, including the potential for oral delivery and the ability to access intracellular drug targets. Several naturally-occurring knottins have recently received approval for treating chronic pain and irritable bowel syndrome, while others are under development for tumor imaging applications. To expand beyond nature's repertoire, rational and combinatorial protein engineering methods are generating tumor-targeting knottins for use as cancer diagnostics and therapeutics.

Engineered knottin peptide enables noninvasive optical imaging of intracranial medulloblastoma.

Central nervous system tumors carry grave clinical prognoses due to limited effectiveness of surgical resection, radiation, and chemotherapy. Thus, improved strategies for brain tumor visualization and targeted treatment are critically needed. We demonstrate that mouse cerebellar medulloblastoma (MB) can be targeted and illuminated with a fluorescent, engineered cystine knot (knottin) peptide that binds with high affinity to αvß3, αvß5, and α5ß1 integrin receptors. This integrin-binding knottin peptide, denoted EETI 2.5F, was evaluated as a molecular imaging probe in both orthotopic and genetic models of MB. Following tail vein injection, fluorescence arising from dye-conjugated EETI 2.5F was localized to the tumor compared with the normal surrounding brain tissue, as measured by optical imaging. The imaging signal intensity correlated with tumor volume. Due to its unique ability to bind to α5ß1 integrin, EETI 2.5F showed superior in vivo and ex vivo brain tumor imaging contrast compared with other engineered integrin-binding knottin peptides and with c(RGDfK), a well-studied integrin-binding peptidomimetic. Next, EETI 2.5F was fused to an antibody fragment crystallizable (Fc) domain (EETI 2.5F-Fc) to determine if a larger integrin-binding protein could also target intracranial brain tumors. EETI 2.5F-Fc, conjugated to a fluorescent dye, illuminated MB following i.v. injection and was able to distribute throughout the tumor parenchyma. In contrast, brain tumor imaging signals were not detected in mice injected with EETI 2.5F proteins containing a scrambled integrin-binding sequence, demonstrating the importance of target specificity. These results highlight the potential of using EETI 2.5F and EETI 2.5-Fc as targeted molecular probes for brain tumor imaging.

Application of an HIV gp41-derived peptide for enhanced intracellular trafficking of synthetic gene and siRNA delivery vehicles.

Endosomal release is an efficiency-limiting step for many nonviral gene delivery vehicles. In this work, nonviral gene delivery vehicles were modified with a membrane-lytic peptide taken from the endodomain of HIV gp41. Peptide was covalently linked to polyethylenimine (PEI) and the peptide-modified polymer was complexed with DNA. The resulting nanoparticles were shown to have similar physicochemical properties as complexes formed with unmodified PEI. The gp41-derived peptide demonstrated significant lytic activity both as free peptide and when conjugated to PEI. Significant increases in transgene expression were achieved in HeLa cells when compared to unmodified polyplexes at low polymer to DNA ratios. Additionally, peptide-modified polyplexes mediated significantly enhanced siRNA delivery compared to unmodified polyplexes. Despite increases in transgene expression and siRNA knockdown, there was no increase in internalization or binding of modified carriers as determined by flow cytometry. The hypothesis that the gp41-derived peptide increases the endosomal escape of vehicles is supported by confocal microscopy imaging of DNA distributions in transfected cells. This work demonstrates the use of a lytic peptide for improved trafficking of nonviral gene delivery vehicles.

Nonviral approaches for neuronal delivery of nucleic acids.

The delivery of therapeutic nucleic acids to neurons has the potential to treat neurological disease and spinal cord injury. While select viral vectors have shown promise as gene carriers to neurons, their potential as therapeutic agents is limited by their toxicity and immunogenicity, their broad tropism, and the cost of large-scale formulation. Nonviral vectors are an attractive alternative in that they offer improved safety profiles compared to viruses, are less expensive to produce, and can be targeted to specific neuronal subpopulations. However, most nonviral vectors suffer from significantly lower transfection efficiencies than neurotropic viruses, severely limiting their utility in neuron-targeted delivery applications. To realize the potential of nonviral delivery technology in neurons, vectors must be designed to overcome a series of extra- and intracellular barriers. In this article, we describe the challenges preventing successful nonviral delivery of nucleic acids to neurons and review strategies aimed at overcoming these challenges.

Application of an environmentally sensitive fluorophore for rapid analysis of the binding and internalization efficiency of gene carriers.

Nonviral gene carriers must associate with and become internalized by cells in order to mediate efficient transfection. Methods to quantitatively measure and distinguish between cell association and internalization of delivery vectors are necessary to characterize the trafficking of vector formulations. Here, we demonstrate the utility of nitro-2,1,3-benzoxadiazol-4-yl (NBD)-labeled oligonucleotides for discrimination between bound and internalized gene carriers associated with cells. Dithionite quenches the fluorescence of extracellular NBD-labeled material, but is unable to penetrate the cell membrane and quench internalized material. We have verified that dithionite-mediated quenching of extracellular materials occurs in both polymer- and lipid-based gene delivery systems incorporating NBD-labeled oligonucleotides. By exploiting this property, the efficiencies of cellular binding and internalization of lipid- and polymer-based vectors were studied and correlated to their transfection efficiencies. Additionally, spatiotemporal information regarding binding and internalization of NBD-labeled gene carriers can be obtained using conventional wide-field fluorescence microscopy, since dithionite-mediated quenching of extracellular materials reveals the intracellular distribution of gene carriers without the need for optical sectioning. Hence, incorporation of environmentally sensitive NBD-oligos into gene carriers allows for facile assessment of binding and internalization efficiencies of vectors in live cells.

Analysis of the intracellular barriers encountered by nonviral gene carriers in a model of spatially controlled delivery to neurons.

BACKGROUND: Neuron-specific, nonviral gene delivery vehicles are useful tools for the potential treatment of neurological disease and spinal cord injury. For minimally invasive, peripheral administration, gene carriers must efficiently mediate uptake at axon terminals, retrograde axonal transport, vesicular escape, and nuclear entry. The design of improved vehicles will benefit from an understanding of the barriers that limit nonviral delivery to neurons. Here, we demonstrate a detailed analysis of intracellular trafficking of both a lipid-based and a polymer-based delivery vehicle following site-specific exposure to neuron-like cells. METHODS: Site-specific exposure of gene carriers to soma or neurites of neuron-like PC-12 cells was accomplished using a microfluidic, compartmented culture chamber. Binding and internalization of vehicles at neurites and soma were quantified using an environmentally sensitive fluorescent marker. The intracellular transport of gene carriers was analyzed by time-lapse particle tracking in live cells, and transfection efficiencies were measured using green fluorescent protein (GFP) as a reporter gene. RESULTS: While the lipid-based carrier mediated measurable transfection when delivered to neuronal soma, neuritic delivery of this formulation failed to produce reporter gene expression due to limited internalization and transport. In contrast, the polymeric nanoparticles displayed active retrograde transport toward neuronal soma, but failed to produce measurable reporter gene expression. CONCLUSIONS: These results highlight distinct intracellular barriers preventing efficient neuronal transfection by the nonviral carriers examined, and provide a basis for the rational improvement of existing nonviral systems.

Evaluation of an LC8-binding peptide for the attachment of artificial cargo to dynein.

The limited cytoplasmic mobility of nonviral gene carriers is likely to contribute to their low transfection efficiency. This limitation could be overcome by mimicking the viral strategy of recruiting the dynein motor complex for efficient transport toward the host cell nucleus. A promising approach for attaching artificial cargo to dynein is through an adaptor peptide that binds the 8 kDa light chain (LC8) found in the cargo-binding region of the dynein complex. Several viral proteins that bind LC8 have in common an LC8-binding motif defined by (K/R)XTQT. Short peptides containing this motif have also been shown to bind recombinant LC8 in vitro. However, since the majority of intracellular LC8 exists outside of the dynein complex, it remains unclear whether peptides displaying this LC8-binding motif can access and bind to dynein-associated LC8. In this study, we employed biochemical analysis to investigate the feasibility of attaching artificial cargo to the dynein motor complex using a peptide displaying the well-characterized LC8-binding motif. We report that free intracellular LC8 bound specifically to an LC8-binding (TQT) peptide and not to a control peptide with a mutated LC8-binding motif. However, a similar binding interaction between the TQT peptide and intracellular dynein was not detected. To determine whether dynein binding of the TQT peptide was prevented by competition with free intracellular LC8 or due to the inability of the peptide to access its LC8 binding site in the dynein complex, the TQT peptide was evaluated for its ability to bind either purified LC8 or purified dynein. Our results demonstrate that, while the TQT peptide readily binds free LC8, it cannot bind to dynein-associated LC8. The results emphasize the need to identify functional dynein-binding peptides and highlight the importance of designing peptides that bind to the intact dynein motor complex.

Gold nanoparticles as a versatile platform for optimizing physicochemical parameters for targeted drug delivery.

The development of targeted vehicles for systemic drug delivery relies on optimizing both the cell-targeting ligand and the physicochemical characteristics of the nanoparticle carrier. A versatile platform based on modification of gold nanoparticles with thiolated polymers is presented in which design parameters can be varied independently and systematically. Nanoparticle formulations of varying particle size, surface charge, surface hydrophilicity, and galactose ligand density were prepared by conjugation of PEG-thiol and galactose-PEG-thiol to gold colloids. This platform was applied to screen for nanoparticle formulations that demonstrate hepatocyte-targeted delivery in vivo. Nanoparticle size and the presence of galactose ligands were found to significantly impact the targeting efficiency. Thus, this platform can be readily applied to determine design parameters for targeted drug delivery systems.Modified gold nanoparticles are a suitable model for nanoparticle-based gene carriers.