The Packaging of Different Cargo into Enveloped Viral Nanoparticles

Fan, Cuiying; Tsvetkova, Irina B.; Khuong, Y-Lan; Moore, Alan W.; Arnold, Randy J.; Goicochea, Nancy L.; Dragnea, Bogdan; Mukhopadhyay, Suchetana

doi:10.1021/mp3002667

Cited by 37 publications

(42 citation statements)

References 58 publications

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“…Specific RNA sequences or chemistry are not essential for assembly, as demonstrated by early in vitro experiments in which ssRNA capsid proteins assembled around heterologous nucleic acids and even polyvinylsulfate (72, 73), and more recent experiments in which capsid proteins assembled around various negatively charged substrates (e.g. (72–85)). We begin this section by describing what these experiments and theoretical models have revealed about how assembly depends on the physical characteristics of RNA or other polyelectrolytes, such as charge, size, and structure.…”

Section: Capsid Assembly Around Nucleic Acids and Other Polyelectromentioning

confidence: 99%

Mechanisms of Virus Assembly

Perlmutter

Hagan

2015

Annu. Rev. Phys. Chem.

293

279

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Viruses are nanoscale entities containing a nucleic acid genome encased in a protein shell called a capsid, and in some cases surrounded by a lipid bilayer membrane. This review summarizes the physics that govern the processes by which capsids assembles within their host cells and in vitro. We describe the thermodynamics and kinetics for assembly of protein subunits into icosahedral capsid shells, and how these are modified in cases where the capsid assembles around a nucleic acid or on a lipid bilayer. We present experimental and theoretical techniques that have been used to characterize capsid assembly, and we highlight aspects of virus assembly which are likely to receive significant attention in the near future.

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Section: Capsid Assembly Around Nucleic Acids and Other Polyelectromentioning

confidence: 99%

Mechanisms of Virus Assembly

Perlmutter

Hagan

2015

Annu. Rev. Phys. Chem.

293

279

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“…19–21, 23, 34 In vitro , alphavirus CP requires polyanionic cargo to form core-like particles (CLPs); the protein alone will not self-assemble in response to ionic strength or pH at any concentration yet tested. 16, 35–39 In vitro -assembled CLPs are structurally and functionally similar to cores of mature virions 14, 16 as they appear to have T=4 symmetry and are able to interact with viral glycoproteins 26, 40–42 to form functional virus-like particles. 41, 42 …”

mentioning

confidence: 99%

Self-Assembly of an Alphavirus Core-like Particle Is Distinguished by Strong Intersubunit Association Energy and Structural Defects

et al. 2015

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Weak association energy can lead to uniform nanostructures: defects can anneal due to subunit lability. What happens when strong association energy leads to particles where defects are trapped? Alphaviruses are enveloped viruses whose icosahedral nucleocapsid core can assemble independently. We used a simplest case system to study Ross River virus (RRV) core-like particle (CLP) self-assembly using purified capsid protein and a short DNA oligomer. We find that capsid protein binds the oligomer with high affinity to form an assembly-competent unit (U). Subsequently, U assembles with concentration dependence into CLPs. We determined that U-U pairwise interactions are very strong (ca. −6 kcal/mol) compared to other virus assembly systems. Nonetheless, assembled RRV CLPs appeared morphologically uniform and cryo-EM image reconstruction with imposed icosahedral symmetry yielded a T=4 structure. However, 2D class averages of the CLPs show that virtually every class had disordered regions. These results suggested that irregular cores may be present in RRV virions. To test this hypothesis, we determined 2D class averages of RRV virions using authentic virions or only the core from intact virions isolated by computational masking. Virion-based class averages were symmetrical, geometric, and corresponded well to projections of image reconstructions. In core-based class averages, cores and envelope proteins in many classes were disordered. These results suggest that partly-disordered components are common even in ostensibly well-ordered viruses, a biological realization of a patchy particle. Biological advantages of partly-disordered complexes may arise from their ease of dissociation and asymmetry.

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“…Viral containers have been successfully employed for the encapsulation of non-native cargo such as nanoparticles. [13] As discussed above, they were evolved to carry their construction plan encapsulated into the protein capsid. Therefore, the inner surface of these containers is mostly positively charged to facilitate RNA encapsulation.…”

Section: Figurementioning

confidence: 99%

Multi‐Component Self‐Assembly of Proteins and Inorganic Particles: From Discrete Structures to Biomimetic Materials

Künzle

Lach

Beck

2019

Israel Journal of Chemistry

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Due to their defined structure, proteins are suitable building blocks for the bottom‐up construction of multi‐component materials. Especially protein containers, with their inherent cavity, can be used to encapsulate synthetic components such as inorganic nanoparticles. This way, multi‐component discrete structures can be assembled. With recent advances in computational protein design, novel protein containers were successfully created, with a high potential for application in biomedicine and materials research. Moreover, engineered protein containers offer a unique building block for the self‐assembly of three‐dimensional materials. They combine the molecular precision of proteins with nanoscale dimensions. Designed interactions lead to novel protein scaffolds. In addition, nanoparticles encapsulated inside the container cavity introduce orthogonal functionality, important for the realization of nanostructured biomimetic materials with emergent properties.

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The Packaging of Different Cargo into Enveloped Viral Nanoparticles

Cited by 37 publications

References 58 publications

Mechanisms of Virus Assembly

Mechanisms of Virus Assembly

Self-Assembly of an Alphavirus Core-like Particle Is Distinguished by Strong Intersubunit Association Energy and Structural Defects

Multi‐Component Self‐Assembly of Proteins and Inorganic Particles: From Discrete Structures to Biomimetic Materials

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