Role of Protein Charge Density on Hepatitis B Virus Capsid Formation

Xinyu Sun; Dong Li; Zhaoshuai Wang; Panchao Yin; Rundong Hu; Hui Li; Qiao Liu; Yunyi Gao; Baiping Ren; Jie Zheng; Yinan Wei; Tianbo Liu

doi:10.1021/acsomega.8b00021

Role of Protein Charge Density on Hepatitis B Virus Capsid Formation

Xinyu Sun, Dong Li, Zhaoshuai Wang, Panchao Yin, Rundong Hu, Hui Li, Qiao Liu, Yunyi Gao, Baiping Ren, Jie Zheng, Yinan Wei, Tianbo Liu

Chemistry

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

The role of electrostatic interactions in the viral capsid assembly process was studied by comparing the assembly process of a truncated hepatitis B virus capsid protein Cp149 with its mutant protein D2N/D4N, which has the same conformational structure but four fewer charges per dimer. The capsid protein self-assembly was investigated under a wide range of protein surface charge densities by changing the protein concentration, buffer pH, and solution ionic strength. Lowering the protein charge density favored the capsid formation. However, lowering charge beyond a certain point resulted in capsid aggregation and precipitation. Interestingly, both the wild-type and D2N/D4N mutant displayed identical assembly profiles when their charge densities matched each other. These results indicated that the charge density was optimized by nature to ensure an efficient and effective capsid proliferation under the physiological pH and ionic strength.

Original language	English
Pages (from-to)	4384-4391
Number of pages	8
Journal	ACS Omega
Volume	3
Issue number	4
DOIs	https://doi.org/10.1021/acsomega.8b00021
State	Published - Apr 30 2018

Bibliographical note

Publisher Copyright:
© 2018 American Chemical Society.

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1021/acsomega.8b00021

Cite this

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title = "Role of Protein Charge Density on Hepatitis B Virus Capsid Formation",

abstract = "The role of electrostatic interactions in the viral capsid assembly process was studied by comparing the assembly process of a truncated hepatitis B virus capsid protein Cp149 with its mutant protein D2N/D4N, which has the same conformational structure but four fewer charges per dimer. The capsid protein self-assembly was investigated under a wide range of protein surface charge densities by changing the protein concentration, buffer pH, and solution ionic strength. Lowering the protein charge density favored the capsid formation. However, lowering charge beyond a certain point resulted in capsid aggregation and precipitation. Interestingly, both the wild-type and D2N/D4N mutant displayed identical assembly profiles when their charge densities matched each other. These results indicated that the charge density was optimized by nature to ensure an efficient and effective capsid proliferation under the physiological pH and ionic strength.",

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T1 - Role of Protein Charge Density on Hepatitis B Virus Capsid Formation

AU - Sun, Xinyu

AU - Li, Dong

AU - Wang, Zhaoshuai

AU - Yin, Panchao

AU - Hu, Rundong

AU - Li, Hui

AU - Liu, Qiao

AU - Gao, Yunyi

AU - Ren, Baiping

AU - Zheng, Jie

AU - Wei, Yinan

AU - Liu, Tianbo

PY - 2018/4/30

Y1 - 2018/4/30

N2 - The role of electrostatic interactions in the viral capsid assembly process was studied by comparing the assembly process of a truncated hepatitis B virus capsid protein Cp149 with its mutant protein D2N/D4N, which has the same conformational structure but four fewer charges per dimer. The capsid protein self-assembly was investigated under a wide range of protein surface charge densities by changing the protein concentration, buffer pH, and solution ionic strength. Lowering the protein charge density favored the capsid formation. However, lowering charge beyond a certain point resulted in capsid aggregation and precipitation. Interestingly, both the wild-type and D2N/D4N mutant displayed identical assembly profiles when their charge densities matched each other. These results indicated that the charge density was optimized by nature to ensure an efficient and effective capsid proliferation under the physiological pH and ionic strength.

AB - The role of electrostatic interactions in the viral capsid assembly process was studied by comparing the assembly process of a truncated hepatitis B virus capsid protein Cp149 with its mutant protein D2N/D4N, which has the same conformational structure but four fewer charges per dimer. The capsid protein self-assembly was investigated under a wide range of protein surface charge densities by changing the protein concentration, buffer pH, and solution ionic strength. Lowering the protein charge density favored the capsid formation. However, lowering charge beyond a certain point resulted in capsid aggregation and precipitation. Interestingly, both the wild-type and D2N/D4N mutant displayed identical assembly profiles when their charge densities matched each other. These results indicated that the charge density was optimized by nature to ensure an efficient and effective capsid proliferation under the physiological pH and ionic strength.

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Role of Protein Charge Density on Hepatitis B Virus Capsid Formation

Abstract

Bibliographical note

ASJC Scopus subject areas

UN SDGs

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