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Minimal impact of ZAP on lentiviral vector production and transduction efficiency
Author(s) -
Helin Sertkaya,
Laura Hidalgo,
Mattia Ficarelli,
Dorota Kmieć,
Adrian W. Signell,
Sadfer Ali,
Hannah Parker,
Harry Wilson,
Stuart J. D. Neil,
Michael H. Malim,
Conrad A. Vink,
Chad M. Swanson
Publication year - 2021
Publication title -
molecular therapy — methods and clinical development
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.285
H-Index - 32
ISSN - 2329-0501
DOI - 10.1016/j.omtm.2021.08.008
Subject(s) - cpg site , biology , transduction (biophysics) , viral vector , vector (molecular biology) , virology , rna , transgene , murine leukemia virus , viral replication , promoter , lentivirus , virus , genetics , gene , gene expression , dna methylation , recombinant dna , biochemistry , viral disease
The antiviral protein ZAP binds CpG dinucleotides in viral RNA to inhibit replication. This has likely led to the CpG suppression observed in many RNA viruses, including retroviruses. Sequences added to retroviral vector genomes, such as internal promoters, transgenes, or regulatory elements, substantially increase CpG abundance. Because these CpGs could allow retroviral vector RNA to be targeted by ZAP, we analyzed whether it restricts vector production, transduction efficiency, and transgene expression. Surprisingly, even though CpG-high HIV-1 was efficiently inhibited by ZAP in HEK293T cells, depleting ZAP did not substantially increase lentiviral vector titer using several packaging and genome plasmids. ZAP overexpression also did not inhibit lentiviral vector titer. In addition, decreasing CpG abundance in a lentiviral vector genome did not increase its titer, and a gammaretroviral vector derived from murine leukemia virus was not substantially restricted by ZAP. Overall, we show that the increased CpG abundance in retroviral vectors relative to the wild-type retroviruses they are derived from does not intrinsically sensitize them to ZAP. Further understanding of how ZAP specifically targets transcripts to inhibit their expression may allow the development of CpG sequence contexts that efficiently recruit or evade this antiviral system.

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