Packaging of DNA origami in viral capsids: towards synthetic viruses.

We report a new type of nanoparticle, consisting of a nucleic acid core (>7500 nt) folded into a 35 nm DNA origami sphere, encapsulated by a capsid composed of all three SV40 virus capsid proteins. Compared to the prototype reported previously, whose capsid consists of VP1 only, the new nanoparticle closely adopts the unique intracellular pathway of the native SV40, suggesting that the proteins of the synthetic capsid retain their native viral functionality. Some of the challenges in the design of such near-future composite drugs destined for gene delivery are discussed.

Packaging of DNA origami in viral capsids.

Here we show the encapsulation of 35 nm diameter, nearly-spherical, DNA origami by self-assembly of SV40-like (simian virus 40) particles. The self-assembly of this new type of nanoparticles is highly reproducible and efficient. The structure of these particles was determined by cryo-EM. The capsid forms a regular SV40 lattice of T = 7d icosahedral symmetry and the structural features of encapsulated DNA origami are fully visible. These particles are a promising biomaterial for use in various medical applications.

Simian virus 40 induces lamin A/C fluctuations and nuclear envelope deformation during cell entry.

The canonical gate of viruses and viral genomes into the nucleus in non-dividing cells is the nuclear pore, embedded within the nuclear envelope. However, we found that for SV40, the nuclear envelope poses a major hurdle to infection: FISH analysis revealed that the majority of viral DNA remains trapped in the ER; silencing of Lamin A/C rendered the cells more susceptible to infection; and proliferating cells are more susceptible to infection than quiescent cells. Surprisingly, we observed that following SV40 infection the nuclear envelope, including lamins A/C, B1, B2 and the nuclear pore complex, was dramatically deformed, as seen by immunohistochemistry. The infection induced fluctuations in the level of lamin A/C, dephosphorylation of an unknown epitope and leakage to the cytoplasm just prior to and during nuclear entry. Deformations were transient, and the spherical structure of the nuclear envelope was restored subsequent to nuclear entry. Nuclear envelope deformations and lamin A/C dephosphorylation depended on caspase-6 cleavage of lamin A/C. Notably, we have previously reported that inhibition of caspase-6 abolishes SV40 infection. Taken together the results suggest that alterations of the nuclear lamina, induced by the infecting virus, are involved in the nuclear entry of the SV40 genome. We propose that SV40 utilize this unique, previously unknown mechanism for direct trafficking of its genome from the ER to the nucleus. As SV40 serves as a paradigm for the pathogenic human BK, JC and Merkel cell polyomavirus, this study suggests nuclear entry as a novel drug target for these infections.

A model for non-viral gene delivery: through syndecan adhesion molecules and powered by actin.

BACKGROUND: Cell transfection requires cationic DNA complexes and heparan sulfate proteoglycans (HSPGs) at the cell surface. Syndecans are transmembrane HSPGs that are ubiquitously expressed on adherent cells. Their polyanionic heparan sulfate moieties are bound at the distal end of their ectodomain, thus facilitating interaction with large cationic particles. METHODS: We propose a model for cell entry involving syndecans as receptors for the DNA complexes by comparing transfection with bacteria uptake and using drug inhibition experiments along with confocal microscopy. RESULTS: When combined with results from the literature, our data suggest the following sequence of events: after initial particle binding, gradual electrostatic zippering of the plasma membrane onto the particle is sustained by lateral diffusion of syndecan molecules that cluster into cholesterol-rich rafts. Clustering in turn triggers PKC activity and linker protein-mediated actin binding to the cytoplasmic tail of the syndecans. Resulting tension fibers and a growing network of cortical actin may then pull the particle into the cell. CONCLUSIONS: Diversion of integrin- and syndecan-mediated cell adhesion processes for particle engulfment appears to be widely exploited by animals (chylomicrons), by pathogens (bacteria, viruses) and, as suggested here, by non-viral vectors.