Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control

Markus Schmid; Patrick Ernst; Annemarie Honegger; Maarit Suomalainen; Martina Zimmermann; Lukas Braun; Sarah Stauffer; Cristian Thom; Birgit Dreier; Matthias Eibauer; Anja Kipar; Viola Vogel; Urs F. Greber; Ohad Medalia; Andreas Plückthun

doi:10.1038/s41467-017-02707-6

Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control

Markus Schmid
, Patrick Ernst
, Annemarie Honegger
, Maarit Suomalainen
, Martina Zimmermann
, Lukas Braun
, Sarah Stauffer
, Cristian Thom
, Birgit Dreier
, Matthias Eibauer
, Anja Kipar
, Viola Vogel
, Urs F. Greber
, Ohad Medalia
, Andreas Plückthun

Department of Life Sciences

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

77 Scopus citations

Abstract

Most systemic viral gene therapies have been limited by sequestration and degradation of virions, innate and adaptive immunity, and silencing of therapeutic genes within the target cells. Here we engineer a high-affinity protein coat, shielding the most commonly used vector in clinical gene therapy, human adenovirus type 5. Using electron microscopy and crystallography we demonstrate a massive coverage of the virion surface through the hexon-shielding scFv fragment, trimerized to exploit the hexon symmetry and gain avidity. The shield reduces virion clearance in the liver. When the shielded particles are equipped with adaptor proteins, the virions deliver their payload genes into human cancer cells expressing HER2 or EGFR. The combination of shield and adapter also increases viral gene delivery to xenografted tumors in vivo, reduces liver off-targeting and immune neutralization. Our study highlights the power of protein engineering for viral vectors overcoming the challenges of local and systemic viral gene therapies.

Original language	English
Article number	450
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-02707-6
State	Published - 1 Dec 2018

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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Cite this

Schmid, M., Ernst, P., Honegger, A., Suomalainen, M., Zimmermann, M., Braun, L., Stauffer, S., Thom, C., Dreier, B., Eibauer, M., Kipar, A., Vogel, V., Greber, U. F., Medalia, O., & Plückthun, A. (2018). Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control. Nature Communications, 9(1), Article 450. https://doi.org/10.1038/s41467-017-02707-6

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title = "Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control",

abstract = "Most systemic viral gene therapies have been limited by sequestration and degradation of virions, innate and adaptive immunity, and silencing of therapeutic genes within the target cells. Here we engineer a high-affinity protein coat, shielding the most commonly used vector in clinical gene therapy, human adenovirus type 5. Using electron microscopy and crystallography we demonstrate a massive coverage of the virion surface through the hexon-shielding scFv fragment, trimerized to exploit the hexon symmetry and gain avidity. The shield reduces virion clearance in the liver. When the shielded particles are equipped with adaptor proteins, the virions deliver their payload genes into human cancer cells expressing HER2 or EGFR. The combination of shield and adapter also increases viral gene delivery to xenografted tumors in vivo, reduces liver off-targeting and immune neutralization. Our study highlights the power of protein engineering for viral vectors overcoming the challenges of local and systemic viral gene therapies.",

author = "Markus Schmid and Patrick Ernst and Annemarie Honegger and Maarit Suomalainen and Martina Zimmermann and Lukas Braun and Sarah Stauffer and Cristian Thom and Birgit Dreier and Matthias Eibauer and Anja Kipar and Viola Vogel and Greber, \{Urs F.\} and Ohad Medalia and Andreas Pl{\"u}ckthun",

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Schmid, M, Ernst, P, Honegger, A, Suomalainen, M, Zimmermann, M, Braun, L, Stauffer, S, Thom, C, Dreier, B, Eibauer, M, Kipar, A, Vogel, V, Greber, UF, Medalia, O & Plückthun, A 2018, 'Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control', Nature Communications, vol. 9, no. 1, 450. https://doi.org/10.1038/s41467-017-02707-6

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T1 - Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control

AU - Schmid, Markus

AU - Ernst, Patrick

AU - Honegger, Annemarie

AU - Suomalainen, Maarit

AU - Zimmermann, Martina

AU - Braun, Lukas

AU - Stauffer, Sarah

AU - Thom, Cristian

AU - Dreier, Birgit

AU - Eibauer, Matthias

AU - Kipar, Anja

AU - Vogel, Viola

AU - Greber, Urs F.

AU - Medalia, Ohad

AU - Plückthun, Andreas

PY - 2018/12/1

Y1 - 2018/12/1

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AB - Most systemic viral gene therapies have been limited by sequestration and degradation of virions, innate and adaptive immunity, and silencing of therapeutic genes within the target cells. Here we engineer a high-affinity protein coat, shielding the most commonly used vector in clinical gene therapy, human adenovirus type 5. Using electron microscopy and crystallography we demonstrate a massive coverage of the virion surface through the hexon-shielding scFv fragment, trimerized to exploit the hexon symmetry and gain avidity. The shield reduces virion clearance in the liver. When the shielded particles are equipped with adaptor proteins, the virions deliver their payload genes into human cancer cells expressing HER2 or EGFR. The combination of shield and adapter also increases viral gene delivery to xenografted tumors in vivo, reduces liver off-targeting and immune neutralization. Our study highlights the power of protein engineering for viral vectors overcoming the challenges of local and systemic viral gene therapies.

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Adenoviral vector with shield and adapter increases tumor specificity and escapes liver and immune control

Abstract

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