Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons

Shahar Bracha; Hannah J. Johnson; Nicole A. Pranckevicius; Francesca Catto; Athena E. Economides; Sergey Litvinov; Karoliina Hassi; Marco Tullio Rigoli; Cristina Cheroni; Matteo Bonfanti; Alessia Valenti; Sarah Stucchi; Shruti Attreya; Paul D. Ross; Daniel Walsh; Nati Malachi; Hagay Livne; Reut Eshel; Vladislav Krupalnik; Doron Levin; Stuart Cobb; Petros Koumoutsakos; Nicolò Caporale; Giuseppe Testa; Adriano Aguzzi; Anita A. Koshy; Lilach Sheiner; Oded Rechavi

doi:10.1038/s41564-024-01750-6

Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons

Shahar Bracha^*, Hannah J. Johnson, Nicole A. Pranckevicius, Francesca Catto, Athena E. Economides, Sergey Litvinov, Karoliina Hassi, Marco Tullio Rigoli, Cristina Cheroni, Matteo Bonfanti, Alessia Valenti, Sarah Stucchi, Shruti Attreya, Paul D. Ross, Daniel Walsh, Nati Malachi, Hagay Livne, Reut Eshel, Vladislav Krupalnik, Doron LevinStuart Cobb, Petros Koumoutsakos, Nicolò Caporale, Giuseppe Testa^*, Adriano Aguzzi^*, Anita A. Koshy^*, Lilach Sheiner^*, Oded Rechavi^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Delivering macromolecules across biological barriers such as the blood–brain barrier limits their application in vivo. Previous work has demonstrated that Toxoplasma gondii, a parasite that naturally travels from the human gut to the central nervous system (CNS), can deliver proteins to host cells. Here we engineered T. gondii’s endogenous secretion systems, the rhoptries and dense granules, to deliver multiple large (>100 kDa) therapeutic proteins into neurons via translational fusions to toxofilin and GRA16. We demonstrate delivery in cultured cells, brain organoids and in vivo, and probe protein activity using imaging, pull-down assays, scRNA-seq and fluorescent reporters. We demonstrate robust delivery after intraperitoneal administration in mice and characterize 3D distribution throughout the brain. As proof of concept, we demonstrate GRA16-mediated brain delivery of the MeCP2 protein, a putative therapeutic target for Rett syndrome. By characterizing the potential and current limitations of the system, we aim to guide future improvements that will be required for broader application.

Original language	English
Pages (from-to)	2051-2072
Number of pages	22
Journal	Nature Microbiology
Volume	9
Issue number	8
DOIs	https://doi.org/10.1038/s41564-024-01750-6
State	Published - Aug 2024

Funding

Funders	Funder number
Nadal Colton Applied Research Fund
Technology and Research Initiative Fund
Royal Society of Edinburgh
TRIF
European Commission
UA Tissue Acquisition
University of Arizona
University of Glasgow
Morris Kahn Foundation
International Rett Syndrome Foundation
National Institutes of Health	NS095994, T32AG061897
NIH	P30CA023074
European Research Council	341117
Wellcome Trust	104111
Aegis Foundation	0604916191, 0140001000

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Bracha, S., Johnson, H. J., Pranckevicius, N. A., Catto, F., Economides, A. E., Litvinov, S., Hassi, K., Rigoli, M. T., Cheroni, C., Bonfanti, M., Valenti, A., Stucchi, S., Attreya, S., Ross, P. D., Walsh, D., Malachi, N., Livne, H., Eshel, R., Krupalnik, V., ... Rechavi, O. (2024). Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons. Nature Microbiology, 9(8), 2051-2072. https://doi.org/10.1038/s41564-024-01750-6

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title = "Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons",

abstract = "Delivering macromolecules across biological barriers such as the blood–brain barrier limits their application in vivo. Previous work has demonstrated that Toxoplasma gondii, a parasite that naturally travels from the human gut to the central nervous system (CNS), can deliver proteins to host cells. Here we engineered T. gondii{\textquoteright}s endogenous secretion systems, the rhoptries and dense granules, to deliver multiple large (>100 kDa) therapeutic proteins into neurons via translational fusions to toxofilin and GRA16. We demonstrate delivery in cultured cells, brain organoids and in vivo, and probe protein activity using imaging, pull-down assays, scRNA-seq and fluorescent reporters. We demonstrate robust delivery after intraperitoneal administration in mice and characterize 3D distribution throughout the brain. As proof of concept, we demonstrate GRA16-mediated brain delivery of the MeCP2 protein, a putative therapeutic target for Rett syndrome. By characterizing the potential and current limitations of the system, we aim to guide future improvements that will be required for broader application.",

author = "Shahar Bracha and Johnson, {Hannah J.} and Pranckevicius, {Nicole A.} and Francesca Catto and Economides, {Athena E.} and Sergey Litvinov and Karoliina Hassi and Rigoli, {Marco Tullio} and Cristina Cheroni and Matteo Bonfanti and Alessia Valenti and Sarah Stucchi and Shruti Attreya and Ross, {Paul D.} and Daniel Walsh and Nati Malachi and Hagay Livne and Reut Eshel and Vladislav Krupalnik and Doron Levin and Stuart Cobb and Petros Koumoutsakos and Nicol{\`o} Caporale and Giuseppe Testa and Adriano Aguzzi and Koshy, {Anita A.} and Lilach Sheiner and Oded Rechavi",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = aug,

doi = "10.1038/s41564-024-01750-6",

language = "אנגלית",

volume = "9",

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Bracha, S, Johnson, HJ, Pranckevicius, NA, Catto, F, Economides, AE, Litvinov, S, Hassi, K, Rigoli, MT, Cheroni, C, Bonfanti, M, Valenti, A, Stucchi, S, Attreya, S, Ross, PD, Walsh, D, Malachi, N, Livne, H, Eshel, R, Krupalnik, V, Levin, D, Cobb, S, Koumoutsakos, P, Caporale, N, Testa, G, Aguzzi, A, Koshy, AA, Sheiner, L & Rechavi, O 2024, 'Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons', Nature Microbiology, vol. 9, no. 8, pp. 2051-2072. https://doi.org/10.1038/s41564-024-01750-6

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T1 - Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons

AU - Bracha, Shahar

AU - Johnson, Hannah J.

AU - Pranckevicius, Nicole A.

AU - Catto, Francesca

AU - Economides, Athena E.

AU - Litvinov, Sergey

AU - Hassi, Karoliina

AU - Rigoli, Marco Tullio

AU - Cheroni, Cristina

AU - Bonfanti, Matteo

AU - Valenti, Alessia

AU - Stucchi, Sarah

AU - Attreya, Shruti

AU - Ross, Paul D.

AU - Walsh, Daniel

AU - Malachi, Nati

AU - Livne, Hagay

AU - Eshel, Reut

AU - Krupalnik, Vladislav

AU - Levin, Doron

AU - Cobb, Stuart

AU - Koumoutsakos, Petros

AU - Caporale, Nicolò

AU - Testa, Giuseppe

AU - Aguzzi, Adriano

AU - Koshy, Anita A.

AU - Sheiner, Lilach

AU - Rechavi, Oded

PY - 2024/8

Y1 - 2024/8

N2 - Delivering macromolecules across biological barriers such as the blood–brain barrier limits their application in vivo. Previous work has demonstrated that Toxoplasma gondii, a parasite that naturally travels from the human gut to the central nervous system (CNS), can deliver proteins to host cells. Here we engineered T. gondii’s endogenous secretion systems, the rhoptries and dense granules, to deliver multiple large (>100 kDa) therapeutic proteins into neurons via translational fusions to toxofilin and GRA16. We demonstrate delivery in cultured cells, brain organoids and in vivo, and probe protein activity using imaging, pull-down assays, scRNA-seq and fluorescent reporters. We demonstrate robust delivery after intraperitoneal administration in mice and characterize 3D distribution throughout the brain. As proof of concept, we demonstrate GRA16-mediated brain delivery of the MeCP2 protein, a putative therapeutic target for Rett syndrome. By characterizing the potential and current limitations of the system, we aim to guide future improvements that will be required for broader application.

AB - Delivering macromolecules across biological barriers such as the blood–brain barrier limits their application in vivo. Previous work has demonstrated that Toxoplasma gondii, a parasite that naturally travels from the human gut to the central nervous system (CNS), can deliver proteins to host cells. Here we engineered T. gondii’s endogenous secretion systems, the rhoptries and dense granules, to deliver multiple large (>100 kDa) therapeutic proteins into neurons via translational fusions to toxofilin and GRA16. We demonstrate delivery in cultured cells, brain organoids and in vivo, and probe protein activity using imaging, pull-down assays, scRNA-seq and fluorescent reporters. We demonstrate robust delivery after intraperitoneal administration in mice and characterize 3D distribution throughout the brain. As proof of concept, we demonstrate GRA16-mediated brain delivery of the MeCP2 protein, a putative therapeutic target for Rett syndrome. By characterizing the potential and current limitations of the system, we aim to guide future improvements that will be required for broader application.

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Engineering Toxoplasma gondii secretion systems for intracellular delivery of multiple large therapeutic proteins to neurons

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