In Vitro Assembly of Virus-Derived Designer Shells Around Inorganic Nanoparticles.

Nanoparticle-templated assembly of virus shells provides a promising approach to the production of hybrid nanomaterials and a potential avenue toward new mechanistic insights in virus phenomena originating in many-body effects, which cannot be understood from examining the properties of molecular subunits alone. This approach complements the successful molecular biology perspective traditionally used in virology, and promises a deeper understanding of viruses and virus-like particles through an expanded methodological toolbox. Here we present protocols for forming a virus coat protein shell around functionalized inorganic nanoparticles.

Examining the Heterogeneous Genome Content of Multipartite Viruses BMV and CCMV by Native Mass Spectrometry.

Since the concept was first introduced by Brian Chait and co-workers in 1991, mass spectrometry of proteins and protein complexes under non-denaturing conditions (native MS) has strongly developed, through parallel advances in instrumentation, sample preparation, and data analysis tools. However, the success rate of native MS analysis, particularly in heterogeneous mega-Dalton (MDa) protein complexes, still strongly depends on careful instrument modification. Here, we further explore these boundaries in native mass spectrometry, analyzing two related endogenous multipartite viruses: the Brome Mosaic Virus (BMV) and the Cowpea Chlorotic Mottle Virus (CCMV). Both CCMV and BMV are approximately 4.6 megadalton (MDa) in mass, of which approximately 1 MDA originates from the genomic content of the virion. Both viruses are produced as mixtures of three particles carrying different segments of the genome, varying by approximately 0.1 MDA in mass (~2%). This mixture of particles poses a challenging analytical problem for high-resolution native MS analysis, given the large mass scales involved. We attempt to unravel the particle heterogeneity using both Q-TOF and Orbitrap mass spectrometers extensively modified for analysis of very large assemblies. We show that manipulation of the charging behavior can provide assistance in assigning the correct charge states. Despite their challenging size and heterogeneity, we obtained native mass spectra with resolved series of charge states for both BMV and CCMV, demonstrating that native MS of endogenous multipartite virions is feasible. Graphical Abstract ᅟ.

Segmented GFP-like aptamer probes for functional imaging of viral genome trafficking.

Recently developed GFP-like RNA aptamers harbor a few unique potential benefits for in vivo RNA imaging applications, including co-packaging of viral genomes. Here we examine them in the context of co-packaging of RNA strands during virion assembly and trafficking. The approach is applicable both in vitro and in vivo, thus bridging an existing methodological gap. We have found that splitting the aptamer sequence in the loop region into two separate parts allows for subsequent self-assembly into a functional unit, which preserves the dye-binding pocket. In presence of the dye, virus-like particles encapsulating segmented GFP-like aptamers provided bright fluorescence emission and showed negligible bleaching due to continuous chromophore exchange: two desirable characteristics for real-time in vivo single particle studies requiring a broader dynamic range than currently available. Proof-of-principle in vivo imaging experiments confirmed detectability of aptamer-loaded virus-like particles in barley root cells even in presence of significant autofluorescence background.

Encapsulation of nanoparticles in virus protein shells.

The self-assembly of virus-like particles may lead to materials which combine the unique characteristics of viruses, such as precise size control and responsivity to environmental cues, with the properties of abiotic cargo. For a few different viruses, shell proteins are amenable to the in vitro encapsulation of non-genomic cargo in a regular protein cage. In this chapter we describe protocols of high-efficiency in vitro self-assembly around functionalized gold nanoparticles for three examples of icosahedral and non-icosahedral viral protein cages derived from a plant virus, an animal virus, and a human retrovirus. These protocols can be readily adapted with small modifications to work for a broad variety of inorganic and organic nanoparticles.