RanBP2 regulates the anti-retroviral activity of TRIM5α by SUMOylation at a predicted phosphorylated SUMOylation motif

TRIM5α is a cytoplasmic restriction factor that blocks post-entry retroviral infection. Evidence suggests that its antiviral activity can be regulated by SUMO, but how this is achieved remains unknown. Here, we show that TRIM5α forms a complex with RanGAP1, Ubc9, and RanBP2 at the nuclear pore, and...

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Veröffentlicht in:	Communications biology 2018-01, Vol.1 (1), p.193-193, Article 193
Hauptverfasser:	Maarifi, Ghizlane, Fernandez, Juliette, Portilho, Débora M., Boulay, Aude, Dutrieux, Jacques, Oddos, Stéphane, Butler-Browne, Gillian, Nisole, Sébastien, Arhel, Nathalie J.
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Schlagworte:	13/106 13/109 13/89 14/19 14/63 631/326/596/1787 631/326/596/2556 631/80/458/538 82/83 Antiviral activity Antiviral agents Biology Biomedical and Life Sciences Cytoplasm Human health and pathology Infectious diseases Innate immunity Life Sciences Localization Microbiology and Parasitology Ran-binding protein SUMO protein Virology
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creator	Maarifi, Ghizlane Fernandez, Juliette Portilho, Débora M. Boulay, Aude Dutrieux, Jacques Oddos, Stéphane Butler-Browne, Gillian Nisole, Sébastien Arhel, Nathalie J.
description	TRIM5α is a cytoplasmic restriction factor that blocks post-entry retroviral infection. Evidence suggests that its antiviral activity can be regulated by SUMO, but how this is achieved remains unknown. Here, we show that TRIM5α forms a complex with RanGAP1, Ubc9, and RanBP2 at the nuclear pore, and that RanBP2 E3 SUMO ligase promotes the SUMOylation of endogenous TRIM5α in the cytoplasm. Loss of RanBP2 blocked SUMOylation of TRIM5α, altered its localization in primary cells, and suppressed the antiviral activity of both rhesus and human orthologs. In cells, human TRIM5α is modified on K84 within a predicted phosphorylated SUMOylation motif (pSUM) and not on K10 as found in vitro. Non-modified TRIM5α lacked antiviral activity, indicating that only SUMOylated TRIM5α acts as a restriction factor. This work illustrates the importance of the nuclear pore in intrinsic antiviral immunity, acting as a hub where virus, SUMO machinery, and restriction factors can meet. Ghizlane Maarifi et al. demonstrate that a nuclear pore component, RanBP2, SUMOylates the retroviral restriction factor TRIM5α to promote its antiviral activity. This study suggests an unexpected role of the nuclear pore for regulating anti-viral innate immunity.
doi_str_mv	10.1038/s42003-018-0198-0
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Evidence suggests that its antiviral activity can be regulated by SUMO, but how this is achieved remains unknown. Here, we show that TRIM5α forms a complex with RanGAP1, Ubc9, and RanBP2 at the nuclear pore, and that RanBP2 E3 SUMO ligase promotes the SUMOylation of endogenous TRIM5α in the cytoplasm. Loss of RanBP2 blocked SUMOylation of TRIM5α, altered its localization in primary cells, and suppressed the antiviral activity of both rhesus and human orthologs. In cells, human TRIM5α is modified on K84 within a predicted phosphorylated SUMOylation motif (pSUM) and not on K10 as found in vitro. Non-modified TRIM5α lacked antiviral activity, indicating that only SUMOylated TRIM5α acts as a restriction factor. This work illustrates the importance of the nuclear pore in intrinsic antiviral immunity, acting as a hub where virus, SUMO machinery, and restriction factors can meet. 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Evidence suggests that its antiviral activity can be regulated by SUMO, but how this is achieved remains unknown. Here, we show that TRIM5α forms a complex with RanGAP1, Ubc9, and RanBP2 at the nuclear pore, and that RanBP2 E3 SUMO ligase promotes the SUMOylation of endogenous TRIM5α in the cytoplasm. Loss of RanBP2 blocked SUMOylation of TRIM5α, altered its localization in primary cells, and suppressed the antiviral activity of both rhesus and human orthologs. In cells, human TRIM5α is modified on K84 within a predicted phosphorylated SUMOylation motif (pSUM) and not on K10 as found in vitro. Non-modified TRIM5α lacked antiviral activity, indicating that only SUMOylated TRIM5α acts as a restriction factor. This work illustrates the importance of the nuclear pore in intrinsic antiviral immunity, acting as a hub where virus, SUMO machinery, and restriction factors can meet. 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subjects	13/106 13/109 13/89 14/19 14/63 631/326/596/1787 631/326/596/2556 631/80/458/538 82/83 Antiviral activity Antiviral agents Biology Biomedical and Life Sciences Cytoplasm Human health and pathology Infectious diseases Innate immunity Life Sciences Localization Microbiology and Parasitology Ran-binding protein SUMO protein Virology
title	RanBP2 regulates the anti-retroviral activity of TRIM5α by SUMOylation at a predicted phosphorylated SUMOylation motif
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