Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles

Federica Sebastiani; Marianna Yanez Arteta; Michael Lerche; Lionel Porcar; Christian Lang; Ryan A. Bragg; Charles S. Elmore; Venkata R. Krishnamurthy; Robert A. Russell; Tamim Darwish; Harald Pichler; Sarah Waldie; Martine Moulin; Michael Haertlein; V. Trevor Forsyth; Lennart Lindfors; Marité Cárdenas

doi:10.1021/acsnano.0c10064

Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles

Federica Sebastiani^*, Marianna Yanez Arteta, Michael Lerche, Lionel Porcar, Christian Lang, Ryan A. Bragg, Charles S. Elmore, Venkata R. Krishnamurthy, Robert A. Russell, Tamim Darwish, Harald Pichler, Sarah Waldie, Martine Moulin, Michael Haertlein, V. Trevor Forsyth, Lennart Lindfors, Marité Cárdenas

^*Corresponding author for this work

Institute of Molecular Biotechnology (6550)

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

Abstract

Emerging therapeutic treatments based on the production of proteins by delivering mRNA have become increasingly important in recent times. While lipid nanoparticles (LNPs) are approved vehicles for small interfering RNA delivery, there are still challenges to use this formulation for mRNA delivery. LNPs are typically a mixture of a cationic lipid, distearoylphosphatidylcholine (DSPC), cholesterol, and a PEG-lipid. The structural characterization of mRNA-containing LNPs (mRNA-LNPs) is crucial for a full understanding of the way in which they function, but this information alone is not enough to predict their fate upon entering the bloodstream. The biodistribution and cellular uptake of LNPs are affected by their surface composition as well as by the extracellular proteins present at the site of LNP administration, e.g., apolipoproteinE (ApoE). ApoE, being responsible for fat transport in the body, plays a key role in the LNP's plasma circulation time. In this work, we use small-angle neutron scattering, together with selective lipid, cholesterol, and solvent deuteration, to elucidate the structure of the LNP and the distribution of the lipid components in the absence and the presence of ApoE. While DSPC and cholesterol are found to be enriched at the surface of the LNPs in buffer, binding of ApoE induces a redistribution of the lipids at the shell and the core, which also impacts the LNP internal structure, causing release of mRNA. The rearrangement of LNP components upon ApoE incubation is discussed in terms of potential relevance to LNP endosomal escape.

Original language	English
Pages (from-to)	6709-6722
Number of pages	14
Journal	ACS Nano
Volume	15
Issue number	4
DOIs	https://doi.org/10.1021/acsnano.0c10064
Publication status	Published - 27 Apr 2021

Keywords

ApoE
lipid nanoparticles
mRNA delivery
protein corona
small-angle scattering

ASJC Scopus subject areas

General Materials Science
General Engineering
General Physics and Astronomy

UN SDGs

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

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10.1021/acsnano.0c10064

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Sebastiani, F., Yanez Arteta, M., Lerche, M., Porcar, L., Lang, C., Bragg, R. A., Elmore, C. S., Krishnamurthy, V. R., Russell, R. A., Darwish, T., Pichler, H., Waldie, S., Moulin, M., Haertlein, M., Forsyth, V. T., Lindfors, L., & Cárdenas, M. (2021). Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles. ACS Nano, 15(4), 6709-6722. https://doi.org/10.1021/acsnano.0c10064

Sebastiani, F, Yanez Arteta, M, Lerche, M, Porcar, L, Lang, C, Bragg, RA, Elmore, CS, Krishnamurthy, VR, Russell, RA, Darwish, T, Pichler, H, Waldie, S, Moulin, M, Haertlein, M, Forsyth, VT, Lindfors, L & Cárdenas, M 2021, 'Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles', ACS Nano, vol. 15, no. 4, pp. 6709-6722. https://doi.org/10.1021/acsnano.0c10064

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title = "Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles",

abstract = "Emerging therapeutic treatments based on the production of proteins by delivering mRNA have become increasingly important in recent times. While lipid nanoparticles (LNPs) are approved vehicles for small interfering RNA delivery, there are still challenges to use this formulation for mRNA delivery. LNPs are typically a mixture of a cationic lipid, distearoylphosphatidylcholine (DSPC), cholesterol, and a PEG-lipid. The structural characterization of mRNA-containing LNPs (mRNA-LNPs) is crucial for a full understanding of the way in which they function, but this information alone is not enough to predict their fate upon entering the bloodstream. The biodistribution and cellular uptake of LNPs are affected by their surface composition as well as by the extracellular proteins present at the site of LNP administration, e.g., apolipoproteinE (ApoE). ApoE, being responsible for fat transport in the body, plays a key role in the LNP's plasma circulation time. In this work, we use small-angle neutron scattering, together with selective lipid, cholesterol, and solvent deuteration, to elucidate the structure of the LNP and the distribution of the lipid components in the absence and the presence of ApoE. While DSPC and cholesterol are found to be enriched at the surface of the LNPs in buffer, binding of ApoE induces a redistribution of the lipids at the shell and the core, which also impacts the LNP internal structure, causing release of mRNA. The rearrangement of LNP components upon ApoE incubation is discussed in terms of potential relevance to LNP endosomal escape. ",

keywords = "ApoE, lipid nanoparticles, mRNA delivery, protein corona, small-angle scattering",

author = "Federica Sebastiani and {Yanez Arteta}, Marianna and Michael Lerche and Lionel Porcar and Christian Lang and Bragg, {Ryan A.} and Elmore, {Charles S.} and Krishnamurthy, {Venkata R.} and Russell, {Robert A.} and Tamim Darwish and Harald Pichler and Sarah Waldie and Martine Moulin and Michael Haertlein and Forsyth, {V. Trevor} and Lennart Lindfors and Marit{\'e} C{\'a}rdenas",

note = "Funding Information: F.S. acknowledges support from the Knowledge Foundation (Sweden) with a ProSpekt grant (20180101). M.C. thanks the Swedish Research Council for financial support (2014-3981, 2018-03990, and 2018-0483). The authors thank the ILL (Grenoble, France) for allocations of beam time on D22 with a corresponding DOI number: 10.5291/ILL-DATA.9-13-866. This project has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under grant agreement no. 731019 (EUSMI) to access beamtime at the KWS-2 instrument operated by JCNS at Heinz Maier-Leibnitz Zentrum, Garching, Germany. We thank Aurel Radulescu for help with data reduction and instrument configuration at KWS-2 and Christopher Garvey for discussions during the beamtime. V.T.F. acknowledges the UK Engineering and Physical Sciences Research Council (EPSRC) for grants EP/C015452/1 and GR/R99393/01 under which the Deuteration Laboratory within ILL{\textquoteright}s Life Sciences Group was created. We thank Gernot A. Strohmeier for purifying the deuterated cholesterol (average 89% D). We also thank Linda Thunberg for purifying the deuterated MC3. Yeast strain RH6829 for deuterated cholesterol was kindly provided by Howard Riezman (University of Geneva, Switzerland). The National Deuteration Facility in Australia is partly funded by The National Collaborative Research Infrastructure Strategy (NCRIS), an Australian Government initiative. This work benefited from the use of the SasView application, originally developed under NSF award DMR-0520547. SasView contains code developed with funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under the SINE2020 project, grant agreement no. 654000. Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

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doi = "10.1021/acsnano.0c10064",

language = "English",

volume = "15",

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T1 - Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles

AU - Sebastiani, Federica

AU - Yanez Arteta, Marianna

AU - Lerche, Michael

AU - Porcar, Lionel

AU - Lang, Christian

AU - Bragg, Ryan A.

AU - Elmore, Charles S.

AU - Krishnamurthy, Venkata R.

AU - Russell, Robert A.

AU - Darwish, Tamim

AU - Pichler, Harald

AU - Waldie, Sarah

AU - Moulin, Martine

AU - Haertlein, Michael

AU - Forsyth, V. Trevor

AU - Lindfors, Lennart

AU - Cárdenas, Marité

N1 - Funding Information: F.S. acknowledges support from the Knowledge Foundation (Sweden) with a ProSpekt grant (20180101). M.C. thanks the Swedish Research Council for financial support (2014-3981, 2018-03990, and 2018-0483). The authors thank the ILL (Grenoble, France) for allocations of beam time on D22 with a corresponding DOI number: 10.5291/ILL-DATA.9-13-866. This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement no. 731019 (EUSMI) to access beamtime at the KWS-2 instrument operated by JCNS at Heinz Maier-Leibnitz Zentrum, Garching, Germany. We thank Aurel Radulescu for help with data reduction and instrument configuration at KWS-2 and Christopher Garvey for discussions during the beamtime. V.T.F. acknowledges the UK Engineering and Physical Sciences Research Council (EPSRC) for grants EP/C015452/1 and GR/R99393/01 under which the Deuteration Laboratory within ILL’s Life Sciences Group was created. We thank Gernot A. Strohmeier for purifying the deuterated cholesterol (average 89% D). We also thank Linda Thunberg for purifying the deuterated MC3. Yeast strain RH6829 for deuterated cholesterol was kindly provided by Howard Riezman (University of Geneva, Switzerland). The National Deuteration Facility in Australia is partly funded by The National Collaborative Research Infrastructure Strategy (NCRIS), an Australian Government initiative. This work benefited from the use of the SasView application, originally developed under NSF award DMR-0520547. SasView contains code developed with funding from the European Union’s Horizon 2020 research and innovation program under the SINE2020 project, grant agreement no. 654000. Publisher Copyright: © 2021 American Chemical Society.

PY - 2021/4/27

Y1 - 2021/4/27

N2 - Emerging therapeutic treatments based on the production of proteins by delivering mRNA have become increasingly important in recent times. While lipid nanoparticles (LNPs) are approved vehicles for small interfering RNA delivery, there are still challenges to use this formulation for mRNA delivery. LNPs are typically a mixture of a cationic lipid, distearoylphosphatidylcholine (DSPC), cholesterol, and a PEG-lipid. The structural characterization of mRNA-containing LNPs (mRNA-LNPs) is crucial for a full understanding of the way in which they function, but this information alone is not enough to predict their fate upon entering the bloodstream. The biodistribution and cellular uptake of LNPs are affected by their surface composition as well as by the extracellular proteins present at the site of LNP administration, e.g., apolipoproteinE (ApoE). ApoE, being responsible for fat transport in the body, plays a key role in the LNP's plasma circulation time. In this work, we use small-angle neutron scattering, together with selective lipid, cholesterol, and solvent deuteration, to elucidate the structure of the LNP and the distribution of the lipid components in the absence and the presence of ApoE. While DSPC and cholesterol are found to be enriched at the surface of the LNPs in buffer, binding of ApoE induces a redistribution of the lipids at the shell and the core, which also impacts the LNP internal structure, causing release of mRNA. The rearrangement of LNP components upon ApoE incubation is discussed in terms of potential relevance to LNP endosomal escape.

AB - Emerging therapeutic treatments based on the production of proteins by delivering mRNA have become increasingly important in recent times. While lipid nanoparticles (LNPs) are approved vehicles for small interfering RNA delivery, there are still challenges to use this formulation for mRNA delivery. LNPs are typically a mixture of a cationic lipid, distearoylphosphatidylcholine (DSPC), cholesterol, and a PEG-lipid. The structural characterization of mRNA-containing LNPs (mRNA-LNPs) is crucial for a full understanding of the way in which they function, but this information alone is not enough to predict their fate upon entering the bloodstream. The biodistribution and cellular uptake of LNPs are affected by their surface composition as well as by the extracellular proteins present at the site of LNP administration, e.g., apolipoproteinE (ApoE). ApoE, being responsible for fat transport in the body, plays a key role in the LNP's plasma circulation time. In this work, we use small-angle neutron scattering, together with selective lipid, cholesterol, and solvent deuteration, to elucidate the structure of the LNP and the distribution of the lipid components in the absence and the presence of ApoE. While DSPC and cholesterol are found to be enriched at the surface of the LNPs in buffer, binding of ApoE induces a redistribution of the lipids at the shell and the core, which also impacts the LNP internal structure, causing release of mRNA. The rearrangement of LNP components upon ApoE incubation is discussed in terms of potential relevance to LNP endosomal escape.

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Apolipoprotein E Binding Drives Structural and Compositional Rearrangement of mRNA-Containing Lipid Nanoparticles

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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