Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()

Rotavirus (RV) cores were released from double-layered particles (DLPs) by high concentrations of CaCl(2), purified and ‘opened’ by treatment with EDTA or EGTA. Under appropriate in vitro conditions DLPs have been shown to have transcriptase and ‘open cores’ replicase activity. Furthermore, it has b...

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Autores principales: Desselberger, Ulrich, Richards, James, Tchertanov, Luba, Lepault, Jean, Lever, Andrew, Burrone, Oscar, Cohen, Jean
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier Science 2013
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Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3854842/
https://www.ncbi.nlm.nih.gov/pubmed/24091366
http://dx.doi.org/10.1016/j.virusres.2013.09.034
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author Desselberger, Ulrich
Richards, James
Tchertanov, Luba
Lepault, Jean
Lever, Andrew
Burrone, Oscar
Cohen, Jean
author_facet Desselberger, Ulrich
Richards, James
Tchertanov, Luba
Lepault, Jean
Lever, Andrew
Burrone, Oscar
Cohen, Jean
author_sort Desselberger, Ulrich
collection PubMed
description Rotavirus (RV) cores were released from double-layered particles (DLPs) by high concentrations of CaCl(2), purified and ‘opened’ by treatment with EDTA or EGTA. Under appropriate in vitro conditions DLPs have been shown to have transcriptase and ‘open cores’ replicase activity. Furthermore, it has been demonstrated that transcriptase activity and infectivity of native cores can be restored by transcapsidation with VP6, VP7 and VP4. The missing link for particle reconstitution in vitro has been the manipulation of ‘open cores’ to become functionally active cores again. The experiments described here were undertaken with the aim of exploring packaging of RV RNAs into opened cores in vitro. Rotavirus cores were opened by approximately 200 μM EGTA, leading to the release of genomic dsRNA. Conversely, RV cores were found to be stable in the presence of minimum concentrations of Ca(2+), Mg(2+), spermidine(3+) and cobalthexamine(3+) of between 40 and 300 μM. Aggregates of purified cores were resolved in the presence of 0.3 mM deoxycholate (minimum concentration). Core shells opened with EGTA were reconstituted by the addition of di- or trivalent cations within 2 min of the opening procedure. Addition of purified, baculovirus recombinant-expressed VP6 to native and reconstituted cores led to the formation of DLPs or DLP-like particles, which upon transfection into MA104 cells were infectious. The rescued infectivity likely originated in part from unopened and in part from reconstituted cores. Radiolabelled RV (+) ssRNAs could be packaged into reconstituted cores and DLPs, as indicated by resistance to RNase I digestion. The packaging reaction was, however, not RV RNA sequence-specific, since unrelated ssRNAs, such as those transcribed from HIV-2 cDNAs, were also packaged. The kinetics of packaging of homologous and heterologous RNAs were similar, as evidenced by competitive packaging assays. None of the packaged in vitro engineered RNA segments has so far been rescued into infectious virus.
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spelling pubmed-38548422013-12-26 Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity() Desselberger, Ulrich Richards, James Tchertanov, Luba Lepault, Jean Lever, Andrew Burrone, Oscar Cohen, Jean Virus Res Article Rotavirus (RV) cores were released from double-layered particles (DLPs) by high concentrations of CaCl(2), purified and ‘opened’ by treatment with EDTA or EGTA. Under appropriate in vitro conditions DLPs have been shown to have transcriptase and ‘open cores’ replicase activity. Furthermore, it has been demonstrated that transcriptase activity and infectivity of native cores can be restored by transcapsidation with VP6, VP7 and VP4. The missing link for particle reconstitution in vitro has been the manipulation of ‘open cores’ to become functionally active cores again. The experiments described here were undertaken with the aim of exploring packaging of RV RNAs into opened cores in vitro. Rotavirus cores were opened by approximately 200 μM EGTA, leading to the release of genomic dsRNA. Conversely, RV cores were found to be stable in the presence of minimum concentrations of Ca(2+), Mg(2+), spermidine(3+) and cobalthexamine(3+) of between 40 and 300 μM. Aggregates of purified cores were resolved in the presence of 0.3 mM deoxycholate (minimum concentration). Core shells opened with EGTA were reconstituted by the addition of di- or trivalent cations within 2 min of the opening procedure. Addition of purified, baculovirus recombinant-expressed VP6 to native and reconstituted cores led to the formation of DLPs or DLP-like particles, which upon transfection into MA104 cells were infectious. The rescued infectivity likely originated in part from unopened and in part from reconstituted cores. Radiolabelled RV (+) ssRNAs could be packaged into reconstituted cores and DLPs, as indicated by resistance to RNase I digestion. The packaging reaction was, however, not RV RNA sequence-specific, since unrelated ssRNAs, such as those transcribed from HIV-2 cDNAs, were also packaged. The kinetics of packaging of homologous and heterologous RNAs were similar, as evidenced by competitive packaging assays. None of the packaged in vitro engineered RNA segments has so far been rescued into infectious virus. Elsevier Science 2013-12-26 /pmc/articles/PMC3854842/ /pubmed/24091366 http://dx.doi.org/10.1016/j.virusres.2013.09.034 Text en © 2013 The Authors https://creativecommons.org/licenses/by-nc-sa/3.0/ Open Access under CC BY-NC-SA 3.0 (https://creativecommons.org/licenses/by-nc-sa/3.0/) license
spellingShingle Article
Desselberger, Ulrich
Richards, James
Tchertanov, Luba
Lepault, Jean
Lever, Andrew
Burrone, Oscar
Cohen, Jean
Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title_full Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title_fullStr Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title_full_unstemmed Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title_short Further characterisation of rotavirus cores: Ss(+)RNAs can be packaged in vitro but packaging lacks sequence specificity()
title_sort further characterisation of rotavirus cores: ss(+)rnas can be packaged in vitro but packaging lacks sequence specificity()
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3854842/
https://www.ncbi.nlm.nih.gov/pubmed/24091366
http://dx.doi.org/10.1016/j.virusres.2013.09.034
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