A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b

Takashi Imada; Koji Moriya; Masahiko Uchiyama; Naoto Inukai; Mitsuhiro Hitotsuyanagi; Akiko Masuda; Takehiro Suzuki; Shotaro Ayukawa; Yo Ichi Tagawa; Naoshi Dohmae; Michinori Kohara; Masayuki Yamamura; Daisuke Kiga

doi:10.1021/acssynbio.8b00188

A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b

Takashi Imada, Koji Moriya, Masahiko Uchiyama, Naoto Inukai, Mitsuhiro Hitotsuyanagi, Akiko Masuda, Takehiro Suzuki, Shotaro Ayukawa, Yo Ichi Tagawa, Naoshi Dohmae, Michinori Kohara, Masayuki Yamamura, Daisuke Kiga^*

^*Corresponding author for this work

School of Advanced Science and Engineering

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

1 Citation (Scopus)

Abstract

Although conjugation with polyethylene glycol (PEGylation) improves the pharmacokinetics of therapeutic proteins, it drastically decreases their bioactivity. Site-specific PEGylation counters the reduction in bioactivity, but developing PEGylated proteins with equivalent bioactivity to that of their unmodified counterparts remains challenging. This study aimed to generate PEGylated proteins with equivalent bioactivity to that of unmodified counterparts. Using interferon (IFN) as a model protein, a highly bioactive Lys-deficient protein variant generated using our unique directed evolution methods enables the design of a site-specific di-PEGylated protein. Antiviral activity of our di-PEGylated IFN was similar to that of unmodified IFN-α2b. The di-PEGylated IFN exhibited 3.0-fold greater antiviral activity than that of a commercial PEGylated IFN. Moreover, our di-PEGylated IFN showed higher in vitro and in vivo stability than those of unmodified IFN-α2b. Hence, we propose that highly bioactive Lys-deficient proteins solve the limitation of conventional PEGylation with respect to the reduction in bioactivity of PEGylated proteins.

Original language	English
Pages (from-to)	2537-2546
Number of pages	10
Journal	ACS Synthetic Biology
Volume	7
Issue number	11
DOIs	https://doi.org/10.1021/acssynbio.8b00188
Publication status	Published - 2018 Nov 16

Keywords

Lys-deficient proteins
directed evolution
genetic code engineering
interferon
site-specific di-PEGylation

ASJC Scopus subject areas

Biomedical Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)

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10.1021/acssynbio.8b00188

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Imada, T., Moriya, K., Uchiyama, M., Inukai, N., Hitotsuyanagi, M., Masuda, A., Suzuki, T., Ayukawa, S., Tagawa, Y. I., Dohmae, N., Kohara, M., Yamamura, M., & Kiga, D. (2018). A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b. ACS Synthetic Biology, 7(11), 2537-2546. https://doi.org/10.1021/acssynbio.8b00188

Imada, T, Moriya, K, Uchiyama, M, Inukai, N, Hitotsuyanagi, M, Masuda, A, Suzuki, T, Ayukawa, S, Tagawa, YI, Dohmae, N, Kohara, M, Yamamura, M & Kiga, D 2018, 'A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b', ACS Synthetic Biology, vol. 7, no. 11, pp. 2537-2546. https://doi.org/10.1021/acssynbio.8b00188

@article{73d914e56a8c4fcba979ed4427d6f261,

title = "A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b",

abstract = "Although conjugation with polyethylene glycol (PEGylation) improves the pharmacokinetics of therapeutic proteins, it drastically decreases their bioactivity. Site-specific PEGylation counters the reduction in bioactivity, but developing PEGylated proteins with equivalent bioactivity to that of their unmodified counterparts remains challenging. This study aimed to generate PEGylated proteins with equivalent bioactivity to that of unmodified counterparts. Using interferon (IFN) as a model protein, a highly bioactive Lys-deficient protein variant generated using our unique directed evolution methods enables the design of a site-specific di-PEGylated protein. Antiviral activity of our di-PEGylated IFN was similar to that of unmodified IFN-α2b. The di-PEGylated IFN exhibited 3.0-fold greater antiviral activity than that of a commercial PEGylated IFN. Moreover, our di-PEGylated IFN showed higher in vitro and in vivo stability than those of unmodified IFN-α2b. Hence, we propose that highly bioactive Lys-deficient proteins solve the limitation of conventional PEGylation with respect to the reduction in bioactivity of PEGylated proteins.",

keywords = "Lys-deficient proteins, directed evolution, genetic code engineering, interferon, site-specific di-PEGylation",

author = "Takashi Imada and Koji Moriya and Masahiko Uchiyama and Naoto Inukai and Mitsuhiro Hitotsuyanagi and Akiko Masuda and Takehiro Suzuki and Shotaro Ayukawa and Tagawa, {Yo Ichi} and Naoshi Dohmae and Michinori Kohara and Masayuki Yamamura and Daisuke Kiga",

note = "Funding Information: This research was partially supported by a Gamma Project Grant for T.I. from the Education Academy of Computational Life Science of the Tokyo Institute of Technology a Waseda University Grant for Special Research Projects (Special Research 2017B-226) for D.K. from Waseda University, a Grant-in-Aid for Scientific Research (KAKENHI, 15KT0148) for S.A. from the Ministry of Education Science and Culture of Japan and a Grant for Industrial Technology Research for D.K from New Energy and Technology Developmental Organization (Industrial Technology Research Grant Program 05A02512d). Funding Information: We thank Kanako Azami for technical support, Hiroshi Nakayama, Seketsu Fukuzawa, and Koichiro Kodama for the analysis of the simplified genetic code, and Kazuyoshi Mihara, Hiroshi Tsutsumi, and Department of Technical Support and Promotion of Shared Research Apparatus for the analysis of CD in the study. This research was partially supported by a Gamma Project Grant for T.I. from the Education Academy of Computational Life Science of the Tokyo Institute of Technology, a Waseda University Grant for Special Research Projects (Special Research 2017B-226) for D.K. from Waseda University, a Grant-in-Aid for Scientific Research (KAKENHI, 15KT0148) for S.A. from the Ministry of Education, Science and Culture of Japan and a Grant for Industrial Technology Research for D.K from New Energy and Technology Developmental Organization (Industrial Technology Research Grant Program 05A02512d). Publisher Copyright: {\textcopyright} 2018 American Chemical Society.",

year = "2018",

month = nov,

day = "16",

doi = "10.1021/acssynbio.8b00188",

language = "English",

volume = "7",

pages = "2537--2546",

journal = "ACS Synthetic Biology",

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publisher = "American Chemical Society",

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T1 - A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b

AU - Imada, Takashi

AU - Moriya, Koji

AU - Uchiyama, Masahiko

AU - Inukai, Naoto

AU - Hitotsuyanagi, Mitsuhiro

AU - Masuda, Akiko

AU - Suzuki, Takehiro

AU - Ayukawa, Shotaro

AU - Tagawa, Yo Ichi

AU - Dohmae, Naoshi

AU - Kohara, Michinori

AU - Yamamura, Masayuki

AU - Kiga, Daisuke

N1 - Funding Information: This research was partially supported by a Gamma Project Grant for T.I. from the Education Academy of Computational Life Science of the Tokyo Institute of Technology a Waseda University Grant for Special Research Projects (Special Research 2017B-226) for D.K. from Waseda University, a Grant-in-Aid for Scientific Research (KAKENHI, 15KT0148) for S.A. from the Ministry of Education Science and Culture of Japan and a Grant for Industrial Technology Research for D.K from New Energy and Technology Developmental Organization (Industrial Technology Research Grant Program 05A02512d). Funding Information: We thank Kanako Azami for technical support, Hiroshi Nakayama, Seketsu Fukuzawa, and Koichiro Kodama for the analysis of the simplified genetic code, and Kazuyoshi Mihara, Hiroshi Tsutsumi, and Department of Technical Support and Promotion of Shared Research Apparatus for the analysis of CD in the study. This research was partially supported by a Gamma Project Grant for T.I. from the Education Academy of Computational Life Science of the Tokyo Institute of Technology, a Waseda University Grant for Special Research Projects (Special Research 2017B-226) for D.K. from Waseda University, a Grant-in-Aid for Scientific Research (KAKENHI, 15KT0148) for S.A. from the Ministry of Education, Science and Culture of Japan and a Grant for Industrial Technology Research for D.K from New Energy and Technology Developmental Organization (Industrial Technology Research Grant Program 05A02512d). Publisher Copyright: © 2018 American Chemical Society.

PY - 2018/11/16

Y1 - 2018/11/16

N2 - Although conjugation with polyethylene glycol (PEGylation) improves the pharmacokinetics of therapeutic proteins, it drastically decreases their bioactivity. Site-specific PEGylation counters the reduction in bioactivity, but developing PEGylated proteins with equivalent bioactivity to that of their unmodified counterparts remains challenging. This study aimed to generate PEGylated proteins with equivalent bioactivity to that of unmodified counterparts. Using interferon (IFN) as a model protein, a highly bioactive Lys-deficient protein variant generated using our unique directed evolution methods enables the design of a site-specific di-PEGylated protein. Antiviral activity of our di-PEGylated IFN was similar to that of unmodified IFN-α2b. The di-PEGylated IFN exhibited 3.0-fold greater antiviral activity than that of a commercial PEGylated IFN. Moreover, our di-PEGylated IFN showed higher in vitro and in vivo stability than those of unmodified IFN-α2b. Hence, we propose that highly bioactive Lys-deficient proteins solve the limitation of conventional PEGylation with respect to the reduction in bioactivity of PEGylated proteins.

AB - Although conjugation with polyethylene glycol (PEGylation) improves the pharmacokinetics of therapeutic proteins, it drastically decreases their bioactivity. Site-specific PEGylation counters the reduction in bioactivity, but developing PEGylated proteins with equivalent bioactivity to that of their unmodified counterparts remains challenging. This study aimed to generate PEGylated proteins with equivalent bioactivity to that of unmodified counterparts. Using interferon (IFN) as a model protein, a highly bioactive Lys-deficient protein variant generated using our unique directed evolution methods enables the design of a site-specific di-PEGylated protein. Antiviral activity of our di-PEGylated IFN was similar to that of unmodified IFN-α2b. The di-PEGylated IFN exhibited 3.0-fold greater antiviral activity than that of a commercial PEGylated IFN. Moreover, our di-PEGylated IFN showed higher in vitro and in vivo stability than those of unmodified IFN-α2b. Hence, we propose that highly bioactive Lys-deficient proteins solve the limitation of conventional PEGylation with respect to the reduction in bioactivity of PEGylated proteins.

KW - Lys-deficient proteins

KW - directed evolution

KW - genetic code engineering

KW - interferon

KW - site-specific di-PEGylation

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A Highly Bioactive Lys-Deficient IFN Leads to a Site-Specific Di-PEGylated IFN with Equivalent Bioactivity to That of Unmodified IFN-α2b

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