Functional analysis of the 5' genomic sequence of a bovine norovirus.
Functional analysis of the 5' genomic sequence of a bovine norovirus.
BACKGROUND: Jena Virus (JV), a bovine Norovirus, causes enteric disease in cattle and represents a potential model for the study of enteric norovirus infection and pathogenesis. The positive sense RNA genome of JV is organised into ORF1 (non-structural proteins), ORF2 (major capsid protein) and ORF3 (minor capsid protein). The lack of a cell culture system for studying JV replication has meant that work to date has relied upon in vitro systems to study non-structural protein synthesis and processing. PRINCIPAL FINDINGS: Only two of the three major ORF1 proteins were identified (p110 and 2C) following in vitro translation of JV RNA, the N-term protein was not detected. The N-term encoding genomic sequence (5'GS) was tested for IRES-like function in a bi-cistronic system and displayed no evidence of IRES-like activity. The site of translation initiation in JV was determined to be at the predicted nucleotide 22. Following the insertion of an epitope within the 5'GS the JV N-term protein was identified in vitro and within RNA transfected cells. CONCLUSIONS: The in vitro transcription/translation system is currently the best system for analysing protein synthesis and processing in JV. Unlike similarly studied human noroviruses JV initially did not appear to express the N-terminal protein, presenting the possibility that the encoding RNA sequence had a regulatory function, most likely involved in translation initiation in an IRES-like manner. This was not the case and, following determination of the site of translation initiation the N-term protein was detected using an epitope tag, both in vitro and in vivo. Although slightly larger than predicted the N-term protein was detected in a processed form in vivo, thus not only demonstrating initial translation of the ORF1 polyprotein but also activity of the viral protease. These findings indicate that the block to noroviral replication in cultured cells lies elsewhere.
e2169-[8pp]
Salim, Omar
a8a00604-9e57-4638-8c96-5b37e75fee90
Clarke, Ian N.
ff6c9324-3547-4039-bb2c-10c0b3327a8b
Lambden, Paul R.
4fcd536e-2d9a-4366-97c6-386e6b005698
14 May 2008
Salim, Omar
a8a00604-9e57-4638-8c96-5b37e75fee90
Clarke, Ian N.
ff6c9324-3547-4039-bb2c-10c0b3327a8b
Lambden, Paul R.
4fcd536e-2d9a-4366-97c6-386e6b005698
Salim, Omar, Clarke, Ian N. and Lambden, Paul R.
(2008)
Functional analysis of the 5' genomic sequence of a bovine norovirus.
PLoS ONE, 3 (5), .
(doi:10.1371/journal.pone.0002169).
Abstract
BACKGROUND: Jena Virus (JV), a bovine Norovirus, causes enteric disease in cattle and represents a potential model for the study of enteric norovirus infection and pathogenesis. The positive sense RNA genome of JV is organised into ORF1 (non-structural proteins), ORF2 (major capsid protein) and ORF3 (minor capsid protein). The lack of a cell culture system for studying JV replication has meant that work to date has relied upon in vitro systems to study non-structural protein synthesis and processing. PRINCIPAL FINDINGS: Only two of the three major ORF1 proteins were identified (p110 and 2C) following in vitro translation of JV RNA, the N-term protein was not detected. The N-term encoding genomic sequence (5'GS) was tested for IRES-like function in a bi-cistronic system and displayed no evidence of IRES-like activity. The site of translation initiation in JV was determined to be at the predicted nucleotide 22. Following the insertion of an epitope within the 5'GS the JV N-term protein was identified in vitro and within RNA transfected cells. CONCLUSIONS: The in vitro transcription/translation system is currently the best system for analysing protein synthesis and processing in JV. Unlike similarly studied human noroviruses JV initially did not appear to express the N-terminal protein, presenting the possibility that the encoding RNA sequence had a regulatory function, most likely involved in translation initiation in an IRES-like manner. This was not the case and, following determination of the site of translation initiation the N-term protein was detected using an epitope tag, both in vitro and in vivo. Although slightly larger than predicted the N-term protein was detected in a processed form in vivo, thus not only demonstrating initial translation of the ORF1 polyprotein but also activity of the viral protease. These findings indicate that the block to noroviral replication in cultured cells lies elsewhere.
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Published date: 14 May 2008
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Local EPrints ID: 59405
URI: http://eprints.soton.ac.uk/id/eprint/59405
ISSN: 1932-6203
PURE UUID: 0960745b-5df3-4e30-9e6b-01e2e9e94521
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Date deposited: 17 Sep 2008
Last modified: 16 Mar 2024 03:17
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Author:
Omar Salim
Author:
Paul R. Lambden
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