An optimized reverse genetics system suitable for efficient recovery of simian, human, and murine-like rotaviruses

Liliana Sánchez-Tacuba; Ningguo Feng; Nathan J. Meade; Kenneth H. Mellits; Philippe H. Jaïs; Linda L. Yasukawa; Theresa K. Resch; Baoming Jiang; Susana López; Siyuan Ding; Harry B. Greenberg

doi:10.1128/JVI.01294-20

An optimized reverse genetics system suitable for efficient recovery of simian, human, and murine-like rotaviruses

Liliana Sánchez-Tacuba, Ningguo Feng, Nathan J. Meade, Kenneth H. Mellits, Philippe H. Jaïs, Linda L. Yasukawa, Theresa K. Resch, Baoming Jiang, Susana López, Siyuan Ding^*, Harry B. Greenberg^*

^*Corresponding author for this work

Microbiology-Immunology

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

53 Scopus citations

Abstract

An entirely plasmid-based reverse genetics (RG) system was recently developed for rotavirus (RV), opening new avenues for in-depth molecular dissection of RV biology, immunology, and pathogenesis. Several improvements to further optimize the RG efficiency have now been described. However, only a small number of individual RV strains have been recovered to date. None of the current methods have supported the recovery of murine RV, impeding the study of RV replication and pathogenesis in an in vivo suckling mouse model. Here, we describe useful modifications to the RG system that significantly improve rescue efficiency of multiple RV strains. In addition to the 11 group A RV segment-specific (+)RNAs [(+)ssRNAs], a chimeric plasmid was transfected, from which the capping enzyme NP868R of African swine fever virus (ASFV) and the T7 RNA polymerase were expressed. Second, a genetically modified MA104 cell line was used in which several components of the innate immunity were degraded. Using this RG system, we successfully recovered the simian RV RRV strain, the human RV CDC-9 strain, a reassortant between murine RV D6/2 and simian RV SA11 strains, and several reassortants and reporter RVs. All these recombinant RVs were rescued at a high efficiency (≥80% success rate) and could not be reliably rescued using several recently published RG strategies (<20%). This improved system represents an important tool and great potential for the rescue of other hard-to-recover RV strains such as low-replicating attenuated vaccine candidates or low-cell culture passage clinical isolates from humans or animals.

Original language	English (US)
Article number	e01294-20
Journal	Journal of virology
Volume	94
Issue number	18
DOIs	https://doi.org/10.1128/JVI.01294-20
State	Published - Sep 2020

Funding

This work is supported by a postdoctoral scholarship from CONACyT to L.S.-T., National Institutes of Health (NIH) grants R01 AI125249 and U19 AI116484 and a VA Merit Grant (GRH0022) awarded to H.B.G., and NIH grants K99/R00 AI135031 and R01 AI150796 and an Early Career Award from the Thrasher Research Fund to S.D.

Keywords

Interferons
Reverse genetics
Rotavirus

ASJC Scopus subject areas

Microbiology
Immunology
Insect Science
Virology

UN SDGs

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

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10.1128/JVI.01294-20

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title = "An optimized reverse genetics system suitable for efficient recovery of simian, human, and murine-like rotaviruses",

abstract = "An entirely plasmid-based reverse genetics (RG) system was recently developed for rotavirus (RV), opening new avenues for in-depth molecular dissection of RV biology, immunology, and pathogenesis. Several improvements to further optimize the RG efficiency have now been described. However, only a small number of individual RV strains have been recovered to date. None of the current methods have supported the recovery of murine RV, impeding the study of RV replication and pathogenesis in an in vivo suckling mouse model. Here, we describe useful modifications to the RG system that significantly improve rescue efficiency of multiple RV strains. In addition to the 11 group A RV segment-specific (+)RNAs [(+)ssRNAs], a chimeric plasmid was transfected, from which the capping enzyme NP868R of African swine fever virus (ASFV) and the T7 RNA polymerase were expressed. Second, a genetically modified MA104 cell line was used in which several components of the innate immunity were degraded. Using this RG system, we successfully recovered the simian RV RRV strain, the human RV CDC-9 strain, a reassortant between murine RV D6/2 and simian RV SA11 strains, and several reassortants and reporter RVs. All these recombinant RVs were rescued at a high efficiency (≥80% success rate) and could not be reliably rescued using several recently published RG strategies (<20%). This improved system represents an important tool and great potential for the rescue of other hard-to-recover RV strains such as low-replicating attenuated vaccine candidates or low-cell culture passage clinical isolates from humans or animals.",

keywords = "Interferons, Reverse genetics, Rotavirus",

author = "Liliana S{\'a}nchez-Tacuba and Ningguo Feng and Meade, {Nathan J.} and Mellits, {Kenneth H.} and Ja{\"i}s, {Philippe H.} and Yasukawa, {Linda L.} and Resch, {Theresa K.} and Baoming Jiang and Susana L{\'o}pez and Siyuan Ding and Greenberg, {Harry B.}",

year = "2020",

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doi = "10.1128/JVI.01294-20",

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AU - Sánchez-Tacuba, Liliana

AU - Feng, Ningguo

AU - Meade, Nathan J.

AU - Mellits, Kenneth H.

AU - Jaïs, Philippe H.

AU - Yasukawa, Linda L.

AU - Resch, Theresa K.

AU - Jiang, Baoming

AU - López, Susana

AU - Ding, Siyuan

AU - Greenberg, Harry B.

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An optimized reverse genetics system suitable for efficient recovery of simian, human, and murine-like rotaviruses

Abstract

Funding

Keywords

ASJC Scopus subject areas

UN SDGs

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