Site-specific glycosylation of recombinant viral glycoproteins produced in nicotiana benthamiana
Site-specific glycosylation of recombinant viral glycoproteins produced in nicotiana benthamiana
There is an urgent need to establish large scale biopharmaceutical manufacturing capacity in Africa where the infrastructure for biologics production is severely limited. Molecular farming, whereby pharmaceuticals are produced in plants, offers a cheaper alternative to mainstream expression platforms, and is amenable to rapid large-scale production. However, there are several differences along the plant protein secretory pathway compared to mammalian systems, which constrain the production of complex pharmaceuticals. Viral envelope glycoproteins are important targets for immunization, yet in some cases they accumulate poorly in plants and may not be properly processed. Whilst the co-expression of human chaperones and furin proteases has shown promise, it is presently unclear how plant-specific differences in glycosylation impact the production of these proteins. In many cases it may be necessary to reproduce features of their native glycosylation to produce immunologically relevant vaccines, given that glycosylation is central to the folding and immunogenicity of these antigens. Building on previous work, we transiently expressed model glycoproteins from HIV and Marburg virus in Nicotiana benthamiana and mammalian cells. The proteins were purified and their site-specific glycosylation was determined by mass-spectrometry. Both glycoproteins yielded increased amounts of protein aggregates when produced in plants compared to the equivalent mammalian cell-derived proteins. The glycosylation profiles of the plant-produced glycoproteins were distinct from the mammalian cell produced proteins: they displayed lower levels of glycan occupancy, reduced complex glycans and large amounts of paucimannosidic structures. The elucidation of the site-specific glycosylation of viral glycoproteins produced in N. benthamiana is an important step toward producing heterologous viral glycoproteins in plants with authentic human-like glycosylation.
folding, glycoprotein, glycosylation, molecular pharming, occupancy, processing
Margolin, Emmanuel
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Allen, Joel D.
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Verbeek, Matthew
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van Diepen, Michiel
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Ximba, Phindile
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Chapman, Rosamund
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Meyers, Ann
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Williamson, Anna-Lise
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Crispin, Max
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Rybicki, Edward
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22 July 2021
Margolin, Emmanuel
11115ec2-7378-434a-8523-a031f397fed7
Allen, Joel D.
c89d5569-7659-4835-b535-c9586e956b3a
Verbeek, Matthew
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van Diepen, Michiel
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Ximba, Phindile
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Chapman, Rosamund
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Meyers, Ann
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Williamson, Anna-Lise
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Crispin, Max
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Rybicki, Edward
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Margolin, Emmanuel, Allen, Joel D., Verbeek, Matthew, van Diepen, Michiel, Ximba, Phindile, Chapman, Rosamund, Meyers, Ann, Williamson, Anna-Lise, Crispin, Max and Rybicki, Edward
(2021)
Site-specific glycosylation of recombinant viral glycoproteins produced in nicotiana benthamiana.
Frontiers in Plant Science, 12, [709344].
(doi:10.3389/fpls.2021.709344).
Abstract
There is an urgent need to establish large scale biopharmaceutical manufacturing capacity in Africa where the infrastructure for biologics production is severely limited. Molecular farming, whereby pharmaceuticals are produced in plants, offers a cheaper alternative to mainstream expression platforms, and is amenable to rapid large-scale production. However, there are several differences along the plant protein secretory pathway compared to mammalian systems, which constrain the production of complex pharmaceuticals. Viral envelope glycoproteins are important targets for immunization, yet in some cases they accumulate poorly in plants and may not be properly processed. Whilst the co-expression of human chaperones and furin proteases has shown promise, it is presently unclear how plant-specific differences in glycosylation impact the production of these proteins. In many cases it may be necessary to reproduce features of their native glycosylation to produce immunologically relevant vaccines, given that glycosylation is central to the folding and immunogenicity of these antigens. Building on previous work, we transiently expressed model glycoproteins from HIV and Marburg virus in Nicotiana benthamiana and mammalian cells. The proteins were purified and their site-specific glycosylation was determined by mass-spectrometry. Both glycoproteins yielded increased amounts of protein aggregates when produced in plants compared to the equivalent mammalian cell-derived proteins. The glycosylation profiles of the plant-produced glycoproteins were distinct from the mammalian cell produced proteins: they displayed lower levels of glycan occupancy, reduced complex glycans and large amounts of paucimannosidic structures. The elucidation of the site-specific glycosylation of viral glycoproteins produced in N. benthamiana is an important step toward producing heterologous viral glycoproteins in plants with authentic human-like glycosylation.
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Margolin_FrontPlantScie_2021
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Published date: 22 July 2021
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Funding Information:
This work is based upon research supported by the South African Medical Research Council with funds received from the South African Department of Science and Technology, the South African Research Chairs Initiative of the Department of Science and Technology, and the National Research Foundation (Grant number: 64819). Further funding support was provided by core funding from the Wellcome Trust (203135/Z/16/Z). The work in the laboratory of MC was supported by the International AIDS Vaccine Initiative (IAVI) through grant OPP1153692/INV-008352 funded by the Bill & Melinda Gates Foundation.
Publisher Copyright:
© Copyright © 2021 Margolin, Allen, Verbeek, van Diepen, Ximba, Chapman, Meyers, Williamson, Crispin and Rybicki.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
folding, glycoprotein, glycosylation, molecular pharming, occupancy, processing
Identifiers
Local EPrints ID: 450918
URI: http://eprints.soton.ac.uk/id/eprint/450918
ISSN: 1664-462X
PURE UUID: b8adecc0-7761-4a3d-9646-5bb44d29663f
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Date deposited: 20 Aug 2021 16:37
Last modified: 17 Mar 2024 04:09
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Author:
Emmanuel Margolin
Author:
Matthew Verbeek
Author:
Michiel van Diepen
Author:
Phindile Ximba
Author:
Rosamund Chapman
Author:
Ann Meyers
Author:
Anna-Lise Williamson
Author:
Edward Rybicki
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