Protein polymer nanoparticles engineered as chaperones protect against apoptosis in human retinal pigment epithelial cells.

αB-Crystallin is a protein chaperone with anti-apoptotic and anti-inflammatory activity that is apically secreted in exosomes by polarized human retinal pigment epithelium. A 20 amino acid mini-peptide derived from residues 73-92 of αB-crystallin protects human retinal pigment epithelial (RPE) cells from oxidative stress, a process involved in the progression of age-related macular degeneration (AMD). Unfortunately, due to its small size, its development as a therapeutic requires a robust controlled release system. To achieve this goal, the αB-crystallin peptide was re-engineered into a protein polymer nanoparticle/macromolecule with the purpose of increasing the hydrodynamic radius/molecular weight and enhancing potency via multivalency or an extended retention time. The peptide was recombinantly fused with two high molecular weight (~40kDa) protein polymers inspired by human tropoelastin. These elastin-like polypeptides (ELPs) include the following: (i) a soluble peptide called S96 and (ii) a diblock copolymer called SI that assembles multivalent nanoparticles at physiological temperature. Fusion proteins, cryS96 and crySI, were found to reduce aggregation of alcohol dehydrogenase and insulin, which demonstrates that ELP fusion did not diminish chaperone activity. Next their interaction with RPE cells was evaluated under oxidative stress. Unexpectedly, H2O2-induced stress dramatically enhanced cellular uptake and nuclear localization of both cryS96 and crySI ELPs. Accompanying uptake, both fusion proteins protected RPE cells from apoptosis, as indicated by reduced caspase 3 activation and TUNEL staining. This study demonstrates the in vitro feasibility of modulating the hydrodynamic radius for small peptide chaperones by seamless fusion with protein polymers; furthermore, they may have therapeutic applications in diseases associated with oxidative stress, such as AMD.

Chemotherapy targeting by DNA capture in viral protein particles.

AIM: This study tests the hypothesis that DNA intercalation and electrophilic interactions can be exploited to noncovalently assemble doxorubicin in a viral protein nanoparticle designed to target and penetrate tumor cells through ligand-directed delivery. We further test whether this new paradigm of doxorubicin targeting shows therapeutic efficacy and safety in vitro and in vivo. MATERIALS & METHODS: We tested serum stability, tumor targeting and therapeutic efficacy in vitro and in vivo using biochemical, microscopy and cytotoxicity assays. RESULTS: Self-assembly formed approximately 10-nm diameter serum-stable nanoparticles that can target and ablate HER2+ tumors at >10× lower dose compared with untargeted doxorubicin, while sparing the heart after intravenous delivery. The targeted nanoparticle tested here allows doxorubicin potency to remain unaltered during assembly, transport and release into target cells,while avoiding peripheral tissue damage and enabling lower, and thus safer, drug dose for tumor killing. CONCLUSION: This nanoparticle may be an improved alternative to chemical conjugates and signal-blocking antibodies for tumor-targeted treatment.

Tumor detection and elimination by a targeted gallium corrole.

Sulfonated gallium(III) corroles are intensely fluorescent macrocyclic compounds that spontaneously assemble with carrier proteins to undergo cell entry. We report in vivo imaging and therapeutic efficacy of a tumor-targeted corrole noncovalently assembled with a heregulin-modified protein directed at the human epidermal growth factor receptor (HER). Systemic delivery of this protein-corrole complex results in tumor accumulation, which can be visualized in vivo owing to intensely red corrole fluorescence. Targeted delivery in vivo leads to tumor cell death while normal tissue is spared. These findings contrast with the effects of doxorubicin, which can elicit cardiac damage during therapy and required direct intratumoral injection to yield similar levels of tumor shrinkage compared with the systemically delivered corrole. The targeted complex ablated tumors at >5 times a lower dose than untargeted systemic doxorubicin, and the corrole did not damage heart tissue. Complexes remained intact in serum and the carrier protein elicited no detectable immunogenicity. The sulfonated gallium(III) corrole functions both for tumor detection and intervention with safety and targeting advantages over standard chemotherapeutic agents.

Histidylated lipid-modified Sendai viral envelopes mediate enhanced membrane fusion and potentiate targeted gene delivery.

Recent studies have demonstrated that covalent grafting of a single histidine residue into a twin-chain aliphatic hydrocarbon compound enhances its endosome-disrupting properties and thereby generates an excellent DNA transfection system. Significant increase in gene delivery efficiencies has thus been obtained by using endosome-disrupting multiple histidine functionalities in the molecular architecture of various cationic polymers. To take advantage of this unique feature, we have incorporated L-histidine (N,N-di-n-hexadecylamine) ethylamide (L(H)) in the membrane of hepatocyte-specific Sendai virosomes containing only the fusion protein (F-virosomes (Process for Producing a Targeted Gene (Sarkar, D. P., Ramani, K., Bora, R. S., Kumar, M., and Tyagi, S. K. (November 4, 1997) U. S. Patent 5,683,866))). Such L(H)-modified virosomal envelopes were four times more (p < 0.001) active in terms of fusion with its target cell membrane. On the other hand, the presence of L(H) in reconstituted influenza and vesicular stomatitis virus envelopes failed to enhance spike glycoprotein-induced membrane fusion with host cell membrane. Circular dichroism and limited proteolysis experiments with F-virosomes indicated that the presence of L(H) leads to conformational changes in the F protein. The molecular mechanism associated with the increased membrane fusion induced by L(H) has been addressed in the light of fusion-competent conformational change in F protein. Such enhancement of fusion resulted in a highly efficient gene delivery system specific for liver cells in culture and in whole animals.

On the disulfide-linker strategy for designing efficacious cationic transfection lipids: an unexpected transfection profile.

Herein, employing a previously reported disulfide-linker strategy, we have designed and synthesized a novel cationic lipid 2 with a disulfide-linker and its non-disulfide control analog lipid 1. The relative efficacies of lipids 1 and 2 in transfecting CHO, COS-1 and MCF-7 cells were measured using both reporter gene and whole cell histochemical staining assays. In stark contrast to the expectation based on the disulfide-linker strategy, the control non-disulfide cationic lipid 1 showed phenomenally superior in vitro transfection efficacies to its essentially transfection incompetent disulfide counterpart lipid 2. Results in DNase I protection experiments and the electrophoretic gel patterns in the presence of glutathione, taken together, are consistent with the notion that the success of the disulfide-linker strategy may depend more critically on the DNase I sensitivity of the lipoplexes than on the efficient DNA release induced by intracellular glutathione pool.

Cationic transfection lipids in gene therapy: successes, set-backs, challenges and promises.

The clinical success of gene therapy is critically dependent on the development of efficient and safe gene delivery reagents, popularly known as "Transfection Vectors". The transfection vectors commonly used in gene therapy are mainly of two types: viral and non-viral. The efficiencies of viral transfection vectors are, in general, superior to their non-viral counterparts. However, the myriads of potentially adverse immunogenic aftermaths associated with the use of viral vectors are increasingly making the non-viral gene delivery reagents as the vectors of choice. Among the existing arsenal of non-viral gene delivery reagents, the distinct advantages associated with the use of cationic transfection lipids include their: (a) robust manufacture; (b) ease in handling & preparation techniques; (c) ability to inject large lipid:DNA complexes and (d) low immunogenic response. The present review will highlight the successes, set-backs, challenges and future promises of cationic transfection lipids in non-viral gene therapy.