Thermodynamic Stability and Kinetic Control of Capsid Morphologies in Hepatitis B Virus

Kevin Yang; Juana  Martin Gonzalez; Alireza Ramezani; Paul P.A.M. van der Schoot; Roya Zandi

doi:10.1063/5.0306971

Thermodynamic Stability and Kinetic Control of Capsid Morphologies in Hepatitis B Virus

Kevin Yang
, Juana Martin Gonzalez
, Alireza Ramezani
, Paul P.A.M. van der Schoot
, Roya Zandi (Corresponding author)

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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Polymorphism has been observed in viral capsid assembly, demonstrating the ability of identical protein dimers to adopt multiple geometries under the same solution conditions. A well-studied example is the hepatitis B virus (HBV), which forms two stable capsid morphologies both in vivo and in vitro. These capsids differ in diameter, containing either 90 or 120 protein dimers. Experiments have shown that their relative prevalence depends on the ionic conditions of the solution during assembly. We developed a model that incorporates salt effects by altering the intermolecular binding free energy between capsid proteins, thereby shifting the relative thermodynamic stability of the two morphologies. This model reproduces experimental results on the prevalence ratios of the large and small HBV capsids. We also constructed a kinetic model that captures the time-dependent ratio of the two morphologies under subcritical capsid concentrations, consistent with experimental data.

Originele taal-2	Engels
Artikelnummer	014112
Aantal pagina's	11
Tijdschrift	Journal of Chemical Physics
Volume	164
Nummer van het tijdschrift	1
DOI's	https://doi.org/10.1063/5.0306971
Status	Gepubliceerd - 7 jan. 2026

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This material was based upon work supported by the National Science Foundation under Grant Nos. NSF DMR-2131963 and MCB/PHY-2413062. P.v.d.S. received support from the Institute of Complex Molecular Systems of Eindhoven University of Technology during the period that this work was done.

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title = "Thermodynamic Stability and Kinetic Control of Capsid Morphologies in Hepatitis B Virus",

abstract = "Polymorphism has been observed in viral capsid assembly, demonstrating the ability of identical protein dimers to adopt multiple geometries under the same solution conditions. A well-studied example is the hepatitis B virus (HBV), which forms two stable capsid morphologies both in vivo and in vitro. These capsids differ in diameter, containing either 90 or 120 protein dimers. Experiments have shown that their relative prevalence depends on the ionic conditions of the solution during assembly. We developed a model that incorporates salt effects by altering the intermolecular binding free energy between capsid proteins, thereby shifting the relative thermodynamic stability of the two morphologies. This model reproduces experimental results on the prevalence ratios of the large and small HBV capsids. We also constructed a kinetic model that captures the time-dependent ratio of the two morphologies under subcritical capsid concentrations, consistent with experimental data.",

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AB - Polymorphism has been observed in viral capsid assembly, demonstrating the ability of identical protein dimers to adopt multiple geometries under the same solution conditions. A well-studied example is the hepatitis B virus (HBV), which forms two stable capsid morphologies both in vivo and in vitro. These capsids differ in diameter, containing either 90 or 120 protein dimers. Experiments have shown that their relative prevalence depends on the ionic conditions of the solution during assembly. We developed a model that incorporates salt effects by altering the intermolecular binding free energy between capsid proteins, thereby shifting the relative thermodynamic stability of the two morphologies. This model reproduces experimental results on the prevalence ratios of the large and small HBV capsids. We also constructed a kinetic model that captures the time-dependent ratio of the two morphologies under subcritical capsid concentrations, consistent with experimental data.

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Thermodynamic Stability and Kinetic Control of Capsid Morphologies in Hepatitis B Virus

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