Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction

Silvia Weiss; Simon Decker; Christoph Kugler; Laura Bocanegra Gómez; Helene Fasching; Denise Benisch; Fatih Alioglu; Levente Ferencz; Theresa Birkfeld; Filip Ilievski; Volker Baumann; Alina Duran; Enes Dusinovic; Nadine Follrich; Sandra Milenkovic; Dajana Mihalicokova; Daniel Paunov; Karla Singeorzan; Nikolaus Zehetmayer; Dejan Zivanonvic; Ulrich Lächelt; Auke Boersma; Thomas Rülicke; Haider Sami; Manfred Ogris

doi:10.1021/acsami.4c19340

Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction

Silvia Weiss, Simon Decker, Christoph Kugler, Laura Bocanegra Gómez, Helene Fasching, Denise Benisch, Fatih Alioglu, Levente Ferencz, Theresa Birkfeld, Filip Ilievski, Volker Baumann, Alina Duran, Enes Dusinovic, Nadine Follrich, Sandra Milenkovic, Dajana Mihalicokova, Daniel Paunov, Karla Singeorzan, Nikolaus Zehetmayer, Dejan ZivanonvicUlrich Lächelt, Auke Boersma, Thomas Rülicke, Haider Sami, Manfred Ogris

Department of Pharmaceutical Sciences

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Splice-switching oligonucleotides (SSOs) can restore protein functionality in pathologies and are promising tools for manipulating the RNA-splicing machinery. Delivery vectors can considerably improve SSO functionality in vivo and allow dose reduction, thereby addressing the challenges of RNA-targeted therapeutics. Here, we report a biocompatible SSO nanocarrier, based on redox-responsive disulfide cross-linked low-molecular-weight linear polyethylenimine (cLPEI), for overcoming multiple biological barriers from subcellular compartments to en-route serum stability and finally in vivo delivery challenges. Intracellularly responsive cross-links of cLPEI significantly accelerated the endosomal escape and offered efficient SSO release to the cell's nucleus, thereby leading to high splice correction in vitro. In vivo performance of cLPEI-SSOs was investigated in a novel transgenic mouse model for splice correction, spatiotemporal tracking of SSO delivery in wild-type mice, and biodistribution in a colorectal cancer peritoneal metastasis model. A single intravenous application of 5 mg kg-1 cLPEI-SSOs induced splice correction in liver, lung, kidney, and bladder, giving functional protein, which was validated by RT-PCR. Near-infrared (NIR) fluorescence imaging and X-ray computed tomography revealed improved organ retention and reduced renal excretion of SSOs. NIR microscopy demonstrated the accumulation of SSOs in angiogenic tumors within the pancreas. Successful nuclear delivery of SSOs was observed in the hepatocytes. Thus, cLPEI nanocarriers resulted in highly efficient splice correction in vivo, highlighting the critical role of the enhanced SSO bioavailability.

Original language	English
Pages (from-to)	9000-9018
Number of pages	19
Journal	ACS applied materials & interfaces
Volume	17
Issue number	6
Early online date	28 Jan 2025
DOIs	https://doi.org/10.1021/acsami.4c19340
Publication status	Published - 12 Feb 2025

Austrian Fields of Science 2012

210002 Nanobiotechnology
301208 Pharmaceutical technology
304004 Gene therapy

Keywords

splice correction
intravenous
phosphorothioate
crosslinked polyethylenimine
endosomal escape
optical tomography
biological barriers

UN SDGs

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

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10.1021/acsami.4c19340Licence: CC BY 4.0

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Weiss, S., Decker, S., Kugler, C., Gómez, L. B., Fasching, H., Benisch, D., Alioglu, F., Ferencz, L., Birkfeld, T., Ilievski, F., Baumann, V., Duran, A., Dusinovic, E., Follrich, N., Milenkovic, S., Mihalicokova, D., Paunov, D., Singeorzan, K., Zehetmayer, N., ... Ogris, M. (2025). Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction. ACS applied materials & interfaces, 17(6), 9000-9018. https://doi.org/10.1021/acsami.4c19340

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title = "Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction",

abstract = "Splice-switching oligonucleotides (SSOs) can restore protein functionality in pathologies and are promising tools for manipulating the RNA-splicing machinery. Delivery vectors can considerably improve SSO functionality in vivo and allow dose reduction, thereby addressing the challenges of RNA-targeted therapeutics. Here, we report a biocompatible SSO nanocarrier, based on redox-responsive disulfide cross-linked low-molecular-weight linear polyethylenimine (cLPEI), for overcoming multiple biological barriers from subcellular compartments to en-route serum stability and finally in vivo delivery challenges. Intracellularly responsive cross-links of cLPEI significantly accelerated the endosomal escape and offered efficient SSO release to the cell's nucleus, thereby leading to high splice correction in vitro. In vivo performance of cLPEI-SSOs was investigated in a novel transgenic mouse model for splice correction, spatiotemporal tracking of SSO delivery in wild-type mice, and biodistribution in a colorectal cancer peritoneal metastasis model. A single intravenous application of 5 mg kg-1 cLPEI-SSOs induced splice correction in liver, lung, kidney, and bladder, giving functional protein, which was validated by RT-PCR. Near-infrared (NIR) fluorescence imaging and X-ray computed tomography revealed improved organ retention and reduced renal excretion of SSOs. NIR microscopy demonstrated the accumulation of SSOs in angiogenic tumors within the pancreas. Successful nuclear delivery of SSOs was observed in the hepatocytes. Thus, cLPEI nanocarriers resulted in highly efficient splice correction in vivo, highlighting the critical role of the enhanced SSO bioavailability.",

keywords = "splice correction, intravenous, phosphorothioate, crosslinked polyethylenimine, endosomal escape, optical tomography, biological barriers",

author = "Silvia Weiss and Simon Decker and Christoph Kugler and G{\'o}mez, {Laura Bocanegra} and Helene Fasching and Denise Benisch and Fatih Alioglu and Levente Ferencz and Theresa Birkfeld and Filip Ilievski and Volker Baumann and Alina Duran and Enes Dusinovic and Nadine Follrich and Sandra Milenkovic and Dajana Mihalicokova and Daniel Paunov and Karla Singeorzan and Nikolaus Zehetmayer and Dejan Zivanonvic and Ulrich L{\"a}chelt and Auke Boersma and Thomas R{\"u}licke and Haider Sami and Manfred Ogris",

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doi = "10.1021/acsami.4c19340",

language = "English",

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Weiss, S , Decker, S , Kugler, C , Gómez, LB, Fasching, H, Benisch, D, Alioglu, F, Ferencz, L, Birkfeld, T, Ilievski, F, Baumann, V, Duran, A, Dusinovic, E, Follrich, N, Milenkovic, S, Mihalicokova, D, Paunov, D, Singeorzan, K, Zehetmayer, N, Zivanonvic, D, Lächelt, U, Boersma, A, Rülicke, T, Sami, H & Ogris, M 2025, 'Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction', ACS applied materials & interfaces, vol. 17, no. 6, pp. 9000-9018. https://doi.org/10.1021/acsami.4c19340

TY - JOUR

T1 - Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction

AU - Weiss, Silvia

AU - Decker, Simon

AU - Kugler, Christoph

AU - Gómez, Laura Bocanegra

AU - Fasching, Helene

AU - Benisch, Denise

AU - Alioglu, Fatih

AU - Ferencz, Levente

AU - Birkfeld, Theresa

AU - Ilievski, Filip

AU - Baumann, Volker

AU - Duran, Alina

AU - Dusinovic, Enes

AU - Follrich, Nadine

AU - Milenkovic, Sandra

AU - Mihalicokova, Dajana

AU - Paunov, Daniel

AU - Singeorzan, Karla

AU - Zehetmayer, Nikolaus

AU - Zivanonvic, Dejan

AU - Lächelt, Ulrich

AU - Boersma, Auke

AU - Rülicke, Thomas

AU - Sami, Haider

AU - Ogris, Manfred

PY - 2025/2/12

Y1 - 2025/2/12

N2 - Splice-switching oligonucleotides (SSOs) can restore protein functionality in pathologies and are promising tools for manipulating the RNA-splicing machinery. Delivery vectors can considerably improve SSO functionality in vivo and allow dose reduction, thereby addressing the challenges of RNA-targeted therapeutics. Here, we report a biocompatible SSO nanocarrier, based on redox-responsive disulfide cross-linked low-molecular-weight linear polyethylenimine (cLPEI), for overcoming multiple biological barriers from subcellular compartments to en-route serum stability and finally in vivo delivery challenges. Intracellularly responsive cross-links of cLPEI significantly accelerated the endosomal escape and offered efficient SSO release to the cell's nucleus, thereby leading to high splice correction in vitro. In vivo performance of cLPEI-SSOs was investigated in a novel transgenic mouse model for splice correction, spatiotemporal tracking of SSO delivery in wild-type mice, and biodistribution in a colorectal cancer peritoneal metastasis model. A single intravenous application of 5 mg kg-1 cLPEI-SSOs induced splice correction in liver, lung, kidney, and bladder, giving functional protein, which was validated by RT-PCR. Near-infrared (NIR) fluorescence imaging and X-ray computed tomography revealed improved organ retention and reduced renal excretion of SSOs. NIR microscopy demonstrated the accumulation of SSOs in angiogenic tumors within the pancreas. Successful nuclear delivery of SSOs was observed in the hepatocytes. Thus, cLPEI nanocarriers resulted in highly efficient splice correction in vivo, highlighting the critical role of the enhanced SSO bioavailability.

AB - Splice-switching oligonucleotides (SSOs) can restore protein functionality in pathologies and are promising tools for manipulating the RNA-splicing machinery. Delivery vectors can considerably improve SSO functionality in vivo and allow dose reduction, thereby addressing the challenges of RNA-targeted therapeutics. Here, we report a biocompatible SSO nanocarrier, based on redox-responsive disulfide cross-linked low-molecular-weight linear polyethylenimine (cLPEI), for overcoming multiple biological barriers from subcellular compartments to en-route serum stability and finally in vivo delivery challenges. Intracellularly responsive cross-links of cLPEI significantly accelerated the endosomal escape and offered efficient SSO release to the cell's nucleus, thereby leading to high splice correction in vitro. In vivo performance of cLPEI-SSOs was investigated in a novel transgenic mouse model for splice correction, spatiotemporal tracking of SSO delivery in wild-type mice, and biodistribution in a colorectal cancer peritoneal metastasis model. A single intravenous application of 5 mg kg-1 cLPEI-SSOs induced splice correction in liver, lung, kidney, and bladder, giving functional protein, which was validated by RT-PCR. Near-infrared (NIR) fluorescence imaging and X-ray computed tomography revealed improved organ retention and reduced renal excretion of SSOs. NIR microscopy demonstrated the accumulation of SSOs in angiogenic tumors within the pancreas. Successful nuclear delivery of SSOs was observed in the hepatocytes. Thus, cLPEI nanocarriers resulted in highly efficient splice correction in vivo, highlighting the critical role of the enhanced SSO bioavailability.

KW - splice correction

KW - intravenous

KW - phosphorothioate

KW - crosslinked polyethylenimine

KW - endosomal escape

KW - optical tomography

KW - biological barriers

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U2 - 10.1021/acsami.4c19340

DO - 10.1021/acsami.4c19340

M3 - Article

C2 - 39873730

SN - 1944-8244

VL - 17

SP - 9000

EP - 9018

JO - ACS applied materials & interfaces

JF - ACS applied materials & interfaces

IS - 6

ER -

Accelerated Endosomal Escape of Splice-Switching Oligonucleotides Enables Efficient Hepatic Splice Correction

Abstract

Austrian Fields of Science 2012

Keywords

UN SDGs

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