Association of host protein VARICOSE with HCPro within a multiprotein complex is crucial for RNA silencing suppression, translation, encapsidation and systemic spread of potato virus A infection.
Journal
PLoS pathogens
ISSN: 1553-7374
Titre abrégé: PLoS Pathog
Pays: United States
ID NLM: 101238921
Informations de publication
Date de publication:
10 2020
10 2020
Historique:
received:
02
05
2020
accepted:
02
09
2020
revised:
22
10
2020
pubmed:
13
10
2020
medline:
5
1
2021
entrez:
12
10
2020
Statut:
epublish
Résumé
In this study, we investigated the significance of a conserved five-amino acid motif 'AELPR' in the C-terminal region of helper component-proteinase (HCPro) for potato virus A (PVA; genus Potyvirus) infection. This motif is a putative interaction site for WD40 domain-containing proteins, including VARICOSE (VCS). We abolished the interaction site in HCPro by replacing glutamic acid (E) and arginine (R) with alanines (A) to generate HCProWD. These mutations partially eliminated HCPro-VCS co-localization in cells. We have earlier described potyvirus-induced RNA granules (PGs) in which HCPro and VCS co-localize and proposed that they have a role in RNA silencing suppression. We now demonstrate that the ability of HCProWD to induce PGs, introduce VCS into PGs, and suppress RNA silencing was impaired. Accordingly, PVA carrying HCProWD (PVAWD) infected Nicotiana benthamiana less efficiently than wild-type PVA (PVAWT) and HCProWD complemented the lack of HCPro in PVA gene expression only partially. HCPro was purified from PVA-infected leaves as part of high molecular weight (HMW) ribonucleoprotein (RNP) complexes. These complexes were more stable when associated with wild-type HCPro than with HCProWD. Moreover, VCS and two viral components of the HMW-complexes, viral protein genome-linked and cylindrical inclusion protein were specifically decreased in HCProWD-containing HMW-complexes. A VPg-mediated boost in translation of replication-deficient PVA (PVAΔGDD) was observed only if viral RNA expressed wild-type HCPro. The role of VCS-VPg-HCPro coordination in PVA translation was further supported by results from VCS silencing and overexpression experiments and by significantly elevated PVA-derived Renilla luciferase vs PVA RNA ratio upon VPg-VCS co-expression. Finally, we found that PVAWD was unable to form virus particles or to spread systemically in the infected plant. We highlight the role of HCPro-VCS containing multiprotein assemblies associated with PVA RNA in protecting it from degradation, ensuring efficient translation, formation of stable virions and establishment of systemic infection.
Identifiants
pubmed: 33045020
doi: 10.1371/journal.ppat.1008956
pii: PPATHOGENS-D-20-00899
pmc: PMC7581364
doi:
Substances chimiques
Multiprotein Complexes
0
Plant Proteins
0
Viral Proteins
0
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
e1008956Déclaration de conflit d'intérêts
The authors have declared that no competing interests exist.
Références
Mol Plant Pathol. 2016 Aug;17(6):943-58
pubmed: 26574906
PLoS One. 2013 Jun 11;8(6):e65705
pubmed: 23776530
Plant Cell. 2006 Dec;18(12):3386-98
pubmed: 17158604
Subcell Biochem. 2008;48:20-30
pubmed: 18925368
J Virol Methods. 2010 Mar;164(1-2):101-10
pubmed: 20026122
Mol Plant Microbe Interact. 2003 May;16(5):405-10
pubmed: 12744511
Autophagy. 2017;13(11):2000-2001
pubmed: 28960115
Mol Cell. 2013 Nov 21;52(4):591-601
pubmed: 24267452
Science. 2000 Oct 6;290(5489):142-4
pubmed: 11021800
Mol Plant Microbe Interact. 2013 Sep;26(9):1004-15
pubmed: 23697374
BMC Biotechnol. 2009 Jun 30;9:61
pubmed: 19566935
J Virol. 2015 Apr;89(8):4237-48
pubmed: 25631087
Virology. 2001 Jun 20;285(1):71-81
pubmed: 11414807
J Gen Virol. 2014 Feb;95(Pt 2):496-505
pubmed: 24214396
BMC Genomics. 2003 Dec 12;4(1):50
pubmed: 14672542
Virology. 1995 Oct 1;212(2):607-13
pubmed: 7571430
Mol Plant Pathol. 2018 Jan 24;:
pubmed: 29363853
Plant Cell. 2010 Feb;22(2):481-96
pubmed: 20190077
J Vis Exp. 2014 Apr 20;(86):
pubmed: 24796313
J Virol. 2015 Dec;89(24):12441-56
pubmed: 26423955
Plant Cell. 2007 May;19(5):1549-64
pubmed: 17513503
J Virol. 2019 Sep 12;93(19):
pubmed: 31341041
EMBO J. 1989 Feb;8(2):365-70
pubmed: 2656254
Mol Plant Microbe Interact. 2014 Mar;27(3):215-26
pubmed: 24405034
Nat Rev Drug Discov. 2017 Nov;16(11):773-786
pubmed: 29026209
Virology. 2013 Jan 20;435(2):472-84
pubmed: 23141719
Plant Cell. 2009 Oct;21(10):3270-9
pubmed: 19855049
Mol Plant Microbe Interact. 2013 Jul;26(7):734-44
pubmed: 23489059
J Virol. 2013 Apr;87(8):4302-12
pubmed: 23365448
Mol Plant Pathol. 2019 Mar;20(3):392-409
pubmed: 30375150
Plant Cell. 1995 May;7(5):549-59
pubmed: 7780307
Protein J. 2018 Oct;37(5):391-406
pubmed: 30069656
J Virol. 1989 Oct;63(10):4459-63
pubmed: 2674480
Virology. 2000 Mar 1;268(1):29-40
pubmed: 10683324
Virology. 2017 Oct;510:147-155
pubmed: 28735115
Sci Rep. 2015 Jun 25;5:11585
pubmed: 26108567
Trends Biochem Sci. 2010 Oct;35(10):565-74
pubmed: 20451393
Nature. 1994 Sep 22;371(6495):297-300
pubmed: 8090199
Virology. 1997 Oct 27;237(2):283-95
pubmed: 9356340
J Virol. 2017 Jan 18;91(3):
pubmed: 27852853
J Exp Bot. 2014 Apr;65(7):1689-97
pubmed: 24420565
Mol Plant Pathol. 2018 Mar;19(3):744-763
pubmed: 28371183
J Biol Chem. 2011 Jun 17;286(24):21937-43
pubmed: 21543324
Mol Plant Pathol. 2011 Feb;12(2):137-50
pubmed: 21199564
PLoS Pathog. 2010 Jan 15;6(1):e1000729
pubmed: 20084269
J Virol. 2011 Sep;85(17):9210-21
pubmed: 21697470
Virology. 1997 Feb 17;228(2):251-62
pubmed: 9123832
Science. 2008 May 30;320(5880):1185-90
pubmed: 18483398
J Virol. 2011 Jul;85(13):6784-94
pubmed: 21525344
J Biosci Bioeng. 2007 Jul;104(1):34-41
pubmed: 17697981
J Virol. 2014 Sep 1;88(17):9808-18
pubmed: 24942578
Plant J. 2016 Jan;85(1):30-45
pubmed: 26611351
Protein Cell. 2011 Mar;2(3):202-14
pubmed: 21468892
Viruses. 2020 Feb 11;12(2):
pubmed: 32053987
PLoS Pathog. 2015 Dec 07;11(12):e1005314
pubmed: 26641460