Allosteric Control of Icosahedral Capsid Assembly

Lázaro, Guillermo R.; Hagan, Michael F.

doi:10.1021/acs.jpcb.6b02768

Cited by 30 publications

(39 citation statements)

References 89 publications

(269 reference statements)

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“…This behavior is indicative of kinetic trapping, known to occur in assembly reactions at high concentrations or binding affinities (73,74). The ability of an inactive conformation to avoid this trap is consistent with simulations of bulk assembly (59,60), and the ability of budding to proceed in the presence of high subunit concentrations (when conformational changes are accounted for), which is consistent with the observation of high densities of GPs in the membranes of cells infected with Sindbis virus (75).…”

Section: Gp Conformational Changes Avoid Kinetic Trapssupporting

confidence: 84%

“…Experiments on several viral families suggest that viral proteins interconvert between ''assembly active'' and ''assembly inactive'' conformations, which are respectively compatible or incompatible with assembly into the virion (56)(57)(58). Computational models suggest that such conformational dynamics can suppress kinetic traps (59,60). Conformational changes of the alphavirus GPs E1 and E2 are required for dimerization in the cytoplasm, and it has been proposed that the GPs interconvert between assembly inactive and assembly active conformations (58), possibly triggered by interaction with NC proteins (18).…”

Section: Subunit Conformational Changesmentioning

confidence: 99%

See 1 more Smart Citation

Why Enveloped Viruses Need Cores—The Contribution of a Nucleocapsid Core to Viral Budding

Lázaro

Mukhopadhyay

Hagan

2018

Biophysical Journal

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During the lifecycle of many enveloped viruses, a nucleocapsid core buds through the cell membrane to acquire an outer envelope of lipid membrane and viral glycoproteins. However, the presence of a nucleocapsid core is not required for assembly of infectious particles. To determine the role of the nucleocapsid core, we develop a coarse-grained computational model with which we investigate budding dynamics as a function of glycoprotein and nucleocapsid interactions, as well as budding in the absence of a nucleocapsid. We find that there is a transition between glycoprotein-directed budding and nucleocapsid-directed budding that occurs above a threshold strength of nucleocapsid interactions. The simulations predict that glycoprotein-directed budding leads to significantly increased size polydispersity and particle polymorphism. This polydispersity can be explained by a theoretical model accounting for the competition between bending energy of the membrane and the glycoprotein shell. The simulations also show that the geometry of a budding particle leads to a barrier to subunit diffusion, which can result in a stalled, partially budded state. We present a phase diagram for this and other morphologies of budded particles. Comparison of these structures against experiments could establish bounds on whether budding is directed by glycoprotein or nucleocapsid interactions. Although our model is motivated by alphaviruses, we discuss implications of our results for other enveloped viruses.

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Section: Gp Conformational Changes Avoid Kinetic Trapssupporting

confidence: 84%

Section: Subunit Conformational Changesmentioning

confidence: 99%

Why Enveloped Viruses Need Cores—The Contribution of a Nucleocapsid Core to Viral Budding

Lázaro

Mukhopadhyay

Hagan

2018

Biophysical Journal

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“…In contrast, the assembly-incompetent Y132A mutant tetramer 22 showed similar FOA with the hexamer state as the WT tetramer (21%), suggesting that the assembly inhibition is not caused by altered inter-dimer orientation. We hypothesize that the "assembly active" conformation is a tetramer that adopts a more "hexamer-like" conformation, in agreement with the theory of allosteric assembly 18,19,35 . The frequency of such conformations is increased for the V124W mutant, explaining its acceleration of the capsid assembly kinetics.…”

Section: Systemsupporting

confidence: 85%

“…Nucleocapsid assembly is an important event in the viral replication cycle 2, 12 . It is governed by weak association energies between core protein subunits and is highly sensitive to the assembly conditions 18,35,39 . It has been proposed that for HBV, the assembly is nucleated by an intermediate of three dimers, a triangular hexamer shown in Figure 1C, and that nucleus formation requires the adoption of a rare "assembly-active" conformation by a capsid protein dimer [17][18][19] .…”

Section: Discussionmentioning

confidence: 99%

Mechanism of action of HBV capsid assembly modulators predicted from binding to early assembly intermediates

Pavlova

Bassit

et al. 2020

Preprint

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Interfering with the self-assembly of virus nucleocapsids is a promising approach for the development of novel antiviral agents. Applied to hepatitis B virus (HBV), this approach has led to several classes of capsid assembly modulators (CAMs) that target the virus by either accelerating nucleocapsid assembly or misdirecting it into non-capsid-like particles. Here, we have assessed the structures of early nucleocapsid assembly intermediates, with and without bound CAMs, using molecular dynamics simulations. We find that distinct conformations of the intermediates are induced depending on whether the bound CAM accelerates or misdirects assembly; these structures are predictive of the final assembly. We also selected non-capsid-like structures from our simulations for virtual screening, resulting in the discovery of several compounds with moderate anti-viral activity and low toxicity. Cryo-electron microscopy and capsid melting experiments suggest that our compounds possess a novel mechanism for assembly modulation, potentially opening new avenues for HBV inhibition.

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“…Second, the formation of a structure must be initiated by a nucleation event ('nucleation'). Due to cooperative or allosteric effects in binding, there might be a significant nucleation barrier [15][16][17][18][19] . Third, following nucleation, structures grow via aggregation of substructures ('growth').…”

Section: Introductionmentioning

confidence: 99%

Stochastic Yield Catastrophes and Robustness in Self-Assembly

Gartner

Graf

Wilke

et al. 2019

Preprint

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A guiding principle in self-assembly is that, for high production yield, nucleation of structures must be significantly slower than their growth. However, details of the mechanism that impedes nucleation are broadly considered irrelevant. Here, we analyze self-assembly into finite-sized target structures employing mathematical modeling. We investigate two key scenarios to delay nucleation: (i) by introducing a slow activation step for the assembling constituents and, (ii) by decreasing the dimerization rate. These scenarios have widely different characteristics. While the dimerization scenario exhibits robust behavior, the activation scenario is highly sensitive to demographic fluctuations. These demographic fluctuations ultimately disfavor growth compared to nucleation and can suppress yield completely. The occurrence of this stochastic yield catastrophe does not depend on model details but is generic as soon as number fluctuations between constituents are taken into account. On a broader perspective, our results reveal that stochasticity is an important limiting factor for self-assembly and that the specific implementation of the nucleation process plays a significant role in determining the yield.

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Allosteric Control of Icosahedral Capsid Assembly

Cited by 30 publications

References 89 publications

Why Enveloped Viruses Need Cores—The Contribution of a Nucleocapsid Core to Viral Budding

Why Enveloped Viruses Need Cores—The Contribution of a Nucleocapsid Core to Viral Budding

Mechanism of action of HBV capsid assembly modulators predicted from binding to early assembly intermediates

Stochastic Yield Catastrophes and Robustness in Self-Assembly

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