Alternative splicing of coq-2 controls the levels of rhodoquinone in animals

Tan, June H. - Lautens, Margot - Romanelli-Cedrez, Laura - Wang, Jianbin - Schertzberg, Michael R. - Reinl, Samantha R. - Davis, Richard E. - Shepherd, Jennifer N. - Fraser, Andrew G. - Salinas, Gustavo

Resumen:

Parasitic helminths use two benzoquinones as electron carriers in the electron transport chain. In normoxia, they use ubiquinone (UQ), but in anaerobic conditions inside the host, they require rhodoquinone (RQ) and greatly increase RQ levels. We previously showed the switch from UQ to RQ synthesis is driven by a change of substrates by the polyprenyltransferase COQ-2 (Del Borrello et al., 2019; Roberts Buceta et al., 2019); however, the mechanism of substrate selection is not known. Here, we show helminths synthesize two coq-2 splice forms, coq-2a and coq-2e, and the coq-2e-specific exon is only found in species that synthesize RQ. We show that in Caenorhabditis elegans COQ-2e is required for efficient RQ synthesis and survival in cyanide. Importantly, parasites switch from COQ-2a to COQ-2e as they transit into anaerobic environments. We conclude helminths switch from UQ to RQ synthesis principally via changes in the alternative splicing of coq-2.


Detalles Bibliográficos
2020
Agencia Nacional de Investigación e Innovación
Canadian Institutes of Health Research
Rhodoquinone
Rodoquinona
Ubiquinone
Ubiquinona
C. elegans
Electron transport chain
Cadena de transporte de electrones
Helminth
Helmintos
Ciencias Naturales y Exactas
Ciencias Biológicas
Bioquímica y Biología Molecular
Inglés
Institut Pasteur de Montevideo
IPMON en REDI
https://hdl.handle.net/20.500.12381/3125
Acceso abierto
Reconocimiento-CompartirIgual 4.0 Internacional. (CC BY-SA)
_version_ 1808165740364169216
author Tan, June H.
author2 Lautens, Margot
Romanelli-Cedrez, Laura
Wang, Jianbin
Schertzberg, Michael R.
Reinl, Samantha R.
Davis, Richard E.
Shepherd, Jennifer N.
Fraser, Andrew G.
Salinas, Gustavo
author2_role author
author
author
author
author
author
author
author
author
author_facet Tan, June H.
Lautens, Margot
Romanelli-Cedrez, Laura
Wang, Jianbin
Schertzberg, Michael R.
Reinl, Samantha R.
Davis, Richard E.
Shepherd, Jennifer N.
Fraser, Andrew G.
Salinas, Gustavo
author_role author
bitstream.checksum.fl_str_mv 2d6047b2c47a34748db9b1d0017b96da
e883ff7c4a8e5e5b4ef0830c8daf6c61
bitstream.checksumAlgorithm.fl_str_mv MD5
MD5
bitstream.url.fl_str_mv https://redi.anii.org.uy/jspui/bitstream/20.500.12381/3125/2/license.txt
https://redi.anii.org.uy/jspui/bitstream/20.500.12381/3125/1/elife-56376-v2%20%281%29.pdf
collection IPMON en REDI
dc.creator.none.fl_str_mv Tan, June H.
Lautens, Margot
Romanelli-Cedrez, Laura
Wang, Jianbin
Schertzberg, Michael R.
Reinl, Samantha R.
Davis, Richard E.
Shepherd, Jennifer N.
Fraser, Andrew G.
Salinas, Gustavo
dc.date.accessioned.none.fl_str_mv 2022-12-28T16:32:37Z
dc.date.available.none.fl_str_mv 2022-12-28T16:32:37Z
dc.date.issued.none.fl_str_mv 2020-08-03
dc.description.abstract.none.fl_txt_mv Parasitic helminths use two benzoquinones as electron carriers in the electron transport chain. In normoxia, they use ubiquinone (UQ), but in anaerobic conditions inside the host, they require rhodoquinone (RQ) and greatly increase RQ levels. We previously showed the switch from UQ to RQ synthesis is driven by a change of substrates by the polyprenyltransferase COQ-2 (Del Borrello et al., 2019; Roberts Buceta et al., 2019); however, the mechanism of substrate selection is not known. Here, we show helminths synthesize two coq-2 splice forms, coq-2a and coq-2e, and the coq-2e-specific exon is only found in species that synthesize RQ. We show that in Caenorhabditis elegans COQ-2e is required for efficient RQ synthesis and survival in cyanide. Importantly, parasites switch from COQ-2a to COQ-2e as they transit into anaerobic environments. We conclude helminths switch from UQ to RQ synthesis principally via changes in the alternative splicing of coq-2.
dc.description.sponsorship.none.fl_txt_mv Agencia Nacional de Investigación e Innovación
Canadian Institutes of Health Research
dc.identifier.anii.es.fl_str_mv FCE_1_2019_1_155779
dc.identifier.doi.none.fl_str_mv 10.7554/eLife.56376
dc.identifier.uri.none.fl_str_mv https://hdl.handle.net/20.500.12381/3125
dc.language.iso.none.fl_str_mv eng
dc.publisher.es.fl_str_mv eLife
dc.rights.es.fl_str_mv Acceso abierto
dc.rights.license.none.fl_str_mv Reconocimiento-CompartirIgual 4.0 Internacional. (CC BY-SA)
dc.rights.none.fl_str_mv info:eu-repo/semantics/openAccess
dc.source.es.fl_str_mv eLife
dc.source.none.fl_str_mv reponame:IPMON en REDI
instname:Institut Pasteur de Montevideo
instacron:Institut Pasteur de Montevideo
dc.subject.anii.none.fl_str_mv Ciencias Naturales y Exactas
Ciencias Biológicas
Bioquímica y Biología Molecular
dc.subject.es.fl_str_mv Rhodoquinone
Rodoquinona
Ubiquinone
Ubiquinona
C. elegans
Electron transport chain
Cadena de transporte de electrones
Helminth
Helmintos
dc.title.none.fl_str_mv Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
dc.type.es.fl_str_mv Artículo
dc.type.none.fl_str_mv info:eu-repo/semantics/article
dc.type.version.es.fl_str_mv Publicado
dc.type.version.none.fl_str_mv info:eu-repo/semantics/publishedVersion
description Parasitic helminths use two benzoquinones as electron carriers in the electron transport chain. In normoxia, they use ubiquinone (UQ), but in anaerobic conditions inside the host, they require rhodoquinone (RQ) and greatly increase RQ levels. We previously showed the switch from UQ to RQ synthesis is driven by a change of substrates by the polyprenyltransferase COQ-2 (Del Borrello et al., 2019; Roberts Buceta et al., 2019); however, the mechanism of substrate selection is not known. Here, we show helminths synthesize two coq-2 splice forms, coq-2a and coq-2e, and the coq-2e-specific exon is only found in species that synthesize RQ. We show that in Caenorhabditis elegans COQ-2e is required for efficient RQ synthesis and survival in cyanide. Importantly, parasites switch from COQ-2a to COQ-2e as they transit into anaerobic environments. We conclude helminths switch from UQ to RQ synthesis principally via changes in the alternative splicing of coq-2.
eu_rights_str_mv openAccess
format article
id IPMON_585202a81e78cb33e93bb22c3a664f0f
identifier_str_mv FCE_1_2019_1_155779
10.7554/eLife.56376
instacron_str Institut Pasteur de Montevideo
institution Institut Pasteur de Montevideo
instname_str Institut Pasteur de Montevideo
language eng
network_acronym_str IPMON
network_name_str IPMON en REDI
oai_identifier_str oai:redi.anii.org.uy:20.500.12381/3125
publishDate 2020
reponame_str IPMON en REDI
repository.mail.fl_str_mv msarroca@pasteur.edu.uy
repository.name.fl_str_mv IPMON en REDI - Institut Pasteur de Montevideo
repository_id_str 9421_2
rights_invalid_str_mv Reconocimiento-CompartirIgual 4.0 Internacional. (CC BY-SA)
Acceso abierto
spelling Reconocimiento-CompartirIgual 4.0 Internacional. (CC BY-SA)Acceso abiertoinfo:eu-repo/semantics/openAccess2022-12-28T16:32:37Z2022-12-28T16:32:37Z2020-08-03https://hdl.handle.net/20.500.12381/3125FCE_1_2019_1_15577910.7554/eLife.56376Parasitic helminths use two benzoquinones as electron carriers in the electron transport chain. In normoxia, they use ubiquinone (UQ), but in anaerobic conditions inside the host, they require rhodoquinone (RQ) and greatly increase RQ levels. We previously showed the switch from UQ to RQ synthesis is driven by a change of substrates by the polyprenyltransferase COQ-2 (Del Borrello et al., 2019; Roberts Buceta et al., 2019); however, the mechanism of substrate selection is not known. Here, we show helminths synthesize two coq-2 splice forms, coq-2a and coq-2e, and the coq-2e-specific exon is only found in species that synthesize RQ. We show that in Caenorhabditis elegans COQ-2e is required for efficient RQ synthesis and survival in cyanide. Importantly, parasites switch from COQ-2a to COQ-2e as they transit into anaerobic environments. We conclude helminths switch from UQ to RQ synthesis principally via changes in the alternative splicing of coq-2.Agencia Nacional de Investigación e InnovaciónCanadian Institutes of Health ResearchengeLifeeLifereponame:IPMON en REDIinstname:Institut Pasteur de Montevideoinstacron:Institut Pasteur de MontevideoRhodoquinoneRodoquinonaUbiquinoneUbiquinonaC. elegansElectron transport chainCadena de transporte de electronesHelminthHelmintosCiencias Naturales y ExactasCiencias BiológicasBioquímica y Biología MolecularAlternative splicing of coq-2 controls the levels of rhodoquinone in animalsArtículoPublicadoinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/articleInstitut Pasteur de MontevideoUniversidad de la República. Facultad de QuímicaUniversity of Toronto. The Donnelly CentreUniversity of Colorado. School of MedicineUniversity of TennesseeGonzaga University//Ciencias Naturales y Exactas/Ciencias Biológicas/Bioquímica y Biología MolecularTan, June H.Lautens, MargotRomanelli-Cedrez, LauraWang, JianbinSchertzberg, Michael R.Reinl, Samantha R.Davis, Richard E.Shepherd, Jennifer N.Fraser, Andrew G.Salinas, GustavoLICENSElicense.txtlicense.txttext/plain; charset=utf-85334https://redi.anii.org.uy/jspui/bitstream/20.500.12381/3125/2/license.txt2d6047b2c47a34748db9b1d0017b96daMD52ORIGINALelife-56376-v2 (1).pdfelife-56376-v2 (1).pdfapplication/pdf3463624https://redi.anii.org.uy/jspui/bitstream/20.500.12381/3125/1/elife-56376-v2%20%281%29.pdfe883ff7c4a8e5e5b4ef0830c8daf6c61MD5120.500.12381/31252022-12-28 13:32:39.012oai:redi.anii.org.uy:20.500.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en REDI - Institut Pasteur de Montevideofalse
spellingShingle Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
Tan, June H.
Rhodoquinone
Rodoquinona
Ubiquinone
Ubiquinona
C. elegans
Electron transport chain
Cadena de transporte de electrones
Helminth
Helmintos
Ciencias Naturales y Exactas
Ciencias Biológicas
Bioquímica y Biología Molecular
status_str publishedVersion
title Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
title_full Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
title_fullStr Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
title_full_unstemmed Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
title_short Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
title_sort Alternative splicing of coq-2 controls the levels of rhodoquinone in animals
topic Rhodoquinone
Rodoquinona
Ubiquinone
Ubiquinona
C. elegans
Electron transport chain
Cadena de transporte de electrones
Helminth
Helmintos
Ciencias Naturales y Exactas
Ciencias Biológicas
Bioquímica y Biología Molecular
url https://hdl.handle.net/20.500.12381/3125

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