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Augmenting glycosylation-directed folding pathways enhances the fidelity of HIV Env immunogen production in plants

Augmenting glycosylation-directed folding pathways enhances the fidelity of HIV Env immunogen production in plants
Augmenting glycosylation-directed folding pathways enhances the fidelity of HIV Env immunogen production in plants

Heterologous glycoprotein production relies on host glycosylation-dependent folding. When the biosynthetic machinery differs from the usual expression host, there is scope to remodel the assembly pathway to enhance glycoprotein production. Here we explore the integration of chaperone coexpression with glyco-engineering to improve the production of a model HIV-1 envelope antigen. Calreticulin was coexpressed to support protein folding together with Leishmania major STT3D oligosaccharyltransferase, to improve glycan occupancy, RNA interference to suppress the formation of truncated glycans, and Nicotiana benthamiana plants lacking α1,3-fucosyltransferase and β1,2-xylosyltransferase was used as an expression host to prevent plant-specific complex N-glycans forming. This approach reduced the formation of undesired aggregates, which predominated in the absence of glyco-engineering. The resulting antigen also exhibited increased glycan occupancy, albeit to a slightly lower level than the equivalent mammalian cell-produced protein. The antigen was decorated almost exclusively with oligomannose glycans, which were less processed compared with the mammalian protein. Immunized rabbits developed comparable immune responses to the plant-produced and mammalian cell-derived antigens, including the induction of autologous neutralizing antibodies when the proteins were used to boost DNA and modified vaccinia Ankara virus-vectored vaccines. This study demonstrates that engineering glycosylation-directed folding offers a promising route to enhance the production of complex viral glycoproteins in plants.

Animals, Antibodies, Neutralizing, Antigens, Viral/metabolism, Glycoproteins/genetics, Glycosylation, HIV Antibodies, HIV Infections, Mammals/metabolism, Polysaccharides/metabolism, Rabbits
0006-3592
2919-2937
Margolin, Emmanuel
11115ec2-7378-434a-8523-a031f397fed7
Allen, Joel D
c873d886-2a66-475b-ae04-57a10b37e716
Verbeek, Matthew
11b94818-ee37-4403-9e27-f45cc30a55e9
Chapman, Ros
c65d24d4-aa1d-42f3-b295-9efcce55e3ac
Meyers, Ann
d592add7-f7fc-43ef-9b87-81a148365b8b
van Diepen, Michiel
7f5a26a9-c6f6-4925-9975-a43abb087754
Ximba, Phindile
640ee0ae-f5c9-46c1-99d5-0391cb1e9c73
Motlou, Thopisang
7f28c0ab-3b0b-42d8-9594-1f6dad332c80
Moore, Penny L
9999f702-7de5-40af-b3f2-57a9d57f1abd
Woodward, Jeremy
86aac548-ed3e-4253-a175-c7d1c052b283
Strasser, Richard
173f6f6a-e86c-4d8e-8665-84c6c7920f2b
Crispin, Max
cd980957-0943-4b89-b2b2-710f01f33bc9
Williamson, Anna-Lise
ebcc479d-ce96-4d3e-a8bd-8aaa19db9065
Rybicki, Edward P
607e427a-c417-4753-bd45-449fb519378f
Margolin, Emmanuel
11115ec2-7378-434a-8523-a031f397fed7
Allen, Joel D
c873d886-2a66-475b-ae04-57a10b37e716
Verbeek, Matthew
11b94818-ee37-4403-9e27-f45cc30a55e9
Chapman, Ros
c65d24d4-aa1d-42f3-b295-9efcce55e3ac
Meyers, Ann
d592add7-f7fc-43ef-9b87-81a148365b8b
van Diepen, Michiel
7f5a26a9-c6f6-4925-9975-a43abb087754
Ximba, Phindile
640ee0ae-f5c9-46c1-99d5-0391cb1e9c73
Motlou, Thopisang
7f28c0ab-3b0b-42d8-9594-1f6dad332c80
Moore, Penny L
9999f702-7de5-40af-b3f2-57a9d57f1abd
Woodward, Jeremy
86aac548-ed3e-4253-a175-c7d1c052b283
Strasser, Richard
173f6f6a-e86c-4d8e-8665-84c6c7920f2b
Crispin, Max
cd980957-0943-4b89-b2b2-710f01f33bc9
Williamson, Anna-Lise
ebcc479d-ce96-4d3e-a8bd-8aaa19db9065
Rybicki, Edward P
607e427a-c417-4753-bd45-449fb519378f

Margolin, Emmanuel, Allen, Joel D, Verbeek, Matthew, Chapman, Ros, Meyers, Ann, van Diepen, Michiel, Ximba, Phindile, Motlou, Thopisang, Moore, Penny L, Woodward, Jeremy, Strasser, Richard, Crispin, Max, Williamson, Anna-Lise and Rybicki, Edward P (2022) Augmenting glycosylation-directed folding pathways enhances the fidelity of HIV Env immunogen production in plants. Biotechnology and Bioengineering, 119 (10), 2919-2937. (doi:10.1002/bit.28169).

Record type: Article

Abstract

Heterologous glycoprotein production relies on host glycosylation-dependent folding. When the biosynthetic machinery differs from the usual expression host, there is scope to remodel the assembly pathway to enhance glycoprotein production. Here we explore the integration of chaperone coexpression with glyco-engineering to improve the production of a model HIV-1 envelope antigen. Calreticulin was coexpressed to support protein folding together with Leishmania major STT3D oligosaccharyltransferase, to improve glycan occupancy, RNA interference to suppress the formation of truncated glycans, and Nicotiana benthamiana plants lacking α1,3-fucosyltransferase and β1,2-xylosyltransferase was used as an expression host to prevent plant-specific complex N-glycans forming. This approach reduced the formation of undesired aggregates, which predominated in the absence of glyco-engineering. The resulting antigen also exhibited increased glycan occupancy, albeit to a slightly lower level than the equivalent mammalian cell-produced protein. The antigen was decorated almost exclusively with oligomannose glycans, which were less processed compared with the mammalian protein. Immunized rabbits developed comparable immune responses to the plant-produced and mammalian cell-derived antigens, including the induction of autologous neutralizing antibodies when the proteins were used to boost DNA and modified vaccinia Ankara virus-vectored vaccines. This study demonstrates that engineering glycosylation-directed folding offers a promising route to enhance the production of complex viral glycoproteins in plants.

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Accepted/In Press date: 27 June 2022
e-pub ahead of print date: 4 July 2022
Published date: October 2022
Additional Information: © 2022 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals LLC.
Keywords: Animals, Antibodies, Neutralizing, Antigens, Viral/metabolism, Glycoproteins/genetics, Glycosylation, HIV Antibodies, HIV Infections, Mammals/metabolism, Polysaccharides/metabolism, Rabbits
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Identifiers

Local EPrints ID: 470352
URI: http://eprints.soton.ac.uk/id/eprint/470352
DOI: doi:10.1002/bit.28169
ISSN: 0006-3592
PURE UUID: 1370d4d3-c554-4013-bf70-9675bf64430e
ORCID for Max Crispin: ORCID iD orcid.org/0000-0002-1072-2694

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Date deposited: 06 Oct 2022 17:11
Last modified: 17 Mar 2024 03:47

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Contributors

Author: Emmanuel Margolin
Author: Joel D Allen
Author: Matthew Verbeek
Author: Ros Chapman
Author: Ann Meyers
Author: Michiel van Diepen
Author: Phindile Ximba
Author: Thopisang Motlou
Author: Penny L Moore
Author: Jeremy Woodward
Author: Richard Strasser
Author: Max Crispin ORCID iD
Author: Anna-Lise Williamson
Author: Edward P Rybicki

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