Simple Autofluorescence-Restrictive Sorting of eGFP+ RPE Cells Allows Reliable Assessment of Targeted Retinal Gene Therapy

Sidsel Alsing Kalaee; Anna Bøgh Lindholm; Jakob Haldrup; Emilie Grarup Jensen; Jacob Giehm Mikkelsen; Lars Aagaard; Anne Louise Askou; Thomas Juhl Corydon

doi:10.3389/fddev.2022.898568

Simple Autofluorescence-Restrictive Sorting of eGFP⁺ RPE Cells Allows Reliable Assessment of Targeted Retinal Gene Therapy

Sidsel Alsing Kalaee, Anna Bøgh Lindholm, Jakob Haldrup, Emilie Grarup Jensen, Jacob Giehm Mikkelsen, Lars Aagaard, Anne Louise Askou^*, Thomas Juhl Corydon

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Abstract

Gene therapy is a promising therapeutic modality for ocular diseases arising in and affecting the retina and choroid. In this context, delivering gene therapy to the multifunctional retinal pigment epithelium (RPE) cells situated between the retina and choroid is desired. Efficacy assessment of any gene therapy strategy, whether it is gene augmentation, inhibition, or editing is initially tested in vitro in cell models, where delivery is simple and efficient. However, efficacy assessment in vivo in animal models is far more complex and several factors can influence the result significantly. Here we report a simple fluorescence activated cell sorting (FACS)-based enrichment method for direct assessment of efficacy and potential off-target effects of gene therapy co-delivered with an eGFP reporter to murine RPE cells using subretinal administration. Isolation of true eGFP+ RPE cells by FACS is notoriously difficult due to their intrinsic autofluorescence resulting in decreased sensitivity and false positives. Combining retinal dissection and harvest of RPE cells with a FACS-gating strategy utilizing the GFP filter and a neighboring filter, to separate the eGFP signal from autofluorescence, allows a significant enrichment of gene therapy-targeted eGFP+ RPE cells. In our hands the method may provide quantitative and qualitative advances in terms of up to 7-fold enrichment of true eGFP+ RPE cells compared to a standard protocol. The isolated cells can subsequently be utilized for reliable assessment of changes in DNA, RNA, or protein. This method allows proof-of-principle analysis of early gene therapy development and investigation of new delivery strategies or therapeutic approaches targeting RPE cells in vivo.

Original language	English
Article number	898568
Journal	Frontiers in Drug Delivery
Volume	2
Number of pages	16
DOIs	https://doi.org/10.3389/fddev.2022.898568
Publication status	Published - May 2022

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10.3389/fddev.2022.898568Licence: CC BY

Cite this

@article{6be1a5ae30ac423a826d957c9a902501,

title = "Simple Autofluorescence-Restrictive Sorting of eGFP+ RPE Cells Allows Reliable Assessment of Targeted Retinal Gene Therapy",

abstract = "Gene therapy is a promising therapeutic modality for ocular diseases arising in and affecting the retina and choroid. In this context, delivering gene therapy to the multifunctional retinal pigment epithelium (RPE) cells situated between the retina and choroid is desired. Efficacy assessment of any gene therapy strategy, whether it is gene augmentation, inhibition, or editing is initially tested in vitro in cell models, where delivery is simple and efficient. However, efficacy assessment in vivo in animal models is far more complex and several factors can influence the result significantly. Here we report a simple fluorescence activated cell sorting (FACS)-based enrichment method for direct assessment of efficacy and potential off-target effects of gene therapy co-delivered with an eGFP reporter to murine RPE cells using subretinal administration. Isolation of true eGFP+ RPE cells by FACS is notoriously difficult due to their intrinsic autofluorescence resulting in decreased sensitivity and false positives. Combining retinal dissection and harvest of RPE cells with a FACS-gating strategy utilizing the GFP filter and a neighboring filter, to separate the eGFP signal from autofluorescence, allows a significant enrichment of gene therapy-targeted eGFP+ RPE cells. In our hands the method may provide quantitative and qualitative advances in terms of up to 7-fold enrichment of true eGFP+ RPE cells compared to a standard protocol. The isolated cells can subsequently be utilized for reliable assessment of changes in DNA, RNA, or protein. This method allows proof-of-principle analysis of early gene therapy development and investigation of new delivery strategies or therapeutic approaches targeting RPE cells in vivo.",

author = "Kalaee, {Sidsel Alsing} and Lindholm, {Anna B{\o}gh} and Jakob Haldrup and Jensen, {Emilie Grarup} and Mikkelsen, {Jacob Giehm} and Lars Aagaard and Askou, {Anne Louise} and Corydon, {Thomas Juhl}",

year = "2022",

month = may,

doi = "10.3389/fddev.2022.898568",

language = "English",

volume = "2",

journal = "Frontiers in Drug Delivery",

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Simple Autofluorescence-Restrictive Sorting of eGFP⁺ RPE Cells Allows Reliable Assessment of Targeted Retinal Gene Therapy. / Kalaee, Sidsel Alsing; Lindholm, Anna Bøgh; Haldrup, Jakob et al.
In: Frontiers in Drug Delivery, Vol. 2, 898568, 05.2022.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

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T1 - Simple Autofluorescence-Restrictive Sorting of eGFP+ RPE Cells Allows Reliable Assessment of Targeted Retinal Gene Therapy

AU - Kalaee, Sidsel Alsing

AU - Lindholm, Anna Bøgh

AU - Haldrup, Jakob

AU - Jensen, Emilie Grarup

AU - Mikkelsen, Jacob Giehm

AU - Aagaard, Lars

AU - Askou, Anne Louise

AU - Corydon, Thomas Juhl

PY - 2022/5

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N2 - Gene therapy is a promising therapeutic modality for ocular diseases arising in and affecting the retina and choroid. In this context, delivering gene therapy to the multifunctional retinal pigment epithelium (RPE) cells situated between the retina and choroid is desired. Efficacy assessment of any gene therapy strategy, whether it is gene augmentation, inhibition, or editing is initially tested in vitro in cell models, where delivery is simple and efficient. However, efficacy assessment in vivo in animal models is far more complex and several factors can influence the result significantly. Here we report a simple fluorescence activated cell sorting (FACS)-based enrichment method for direct assessment of efficacy and potential off-target effects of gene therapy co-delivered with an eGFP reporter to murine RPE cells using subretinal administration. Isolation of true eGFP+ RPE cells by FACS is notoriously difficult due to their intrinsic autofluorescence resulting in decreased sensitivity and false positives. Combining retinal dissection and harvest of RPE cells with a FACS-gating strategy utilizing the GFP filter and a neighboring filter, to separate the eGFP signal from autofluorescence, allows a significant enrichment of gene therapy-targeted eGFP+ RPE cells. In our hands the method may provide quantitative and qualitative advances in terms of up to 7-fold enrichment of true eGFP+ RPE cells compared to a standard protocol. The isolated cells can subsequently be utilized for reliable assessment of changes in DNA, RNA, or protein. This method allows proof-of-principle analysis of early gene therapy development and investigation of new delivery strategies or therapeutic approaches targeting RPE cells in vivo.

AB - Gene therapy is a promising therapeutic modality for ocular diseases arising in and affecting the retina and choroid. In this context, delivering gene therapy to the multifunctional retinal pigment epithelium (RPE) cells situated between the retina and choroid is desired. Efficacy assessment of any gene therapy strategy, whether it is gene augmentation, inhibition, or editing is initially tested in vitro in cell models, where delivery is simple and efficient. However, efficacy assessment in vivo in animal models is far more complex and several factors can influence the result significantly. Here we report a simple fluorescence activated cell sorting (FACS)-based enrichment method for direct assessment of efficacy and potential off-target effects of gene therapy co-delivered with an eGFP reporter to murine RPE cells using subretinal administration. Isolation of true eGFP+ RPE cells by FACS is notoriously difficult due to their intrinsic autofluorescence resulting in decreased sensitivity and false positives. Combining retinal dissection and harvest of RPE cells with a FACS-gating strategy utilizing the GFP filter and a neighboring filter, to separate the eGFP signal from autofluorescence, allows a significant enrichment of gene therapy-targeted eGFP+ RPE cells. In our hands the method may provide quantitative and qualitative advances in terms of up to 7-fold enrichment of true eGFP+ RPE cells compared to a standard protocol. The isolated cells can subsequently be utilized for reliable assessment of changes in DNA, RNA, or protein. This method allows proof-of-principle analysis of early gene therapy development and investigation of new delivery strategies or therapeutic approaches targeting RPE cells in vivo.

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