Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation

Jana Ramon; Cláudio Pinheiro; Charysse Vandendriessche; Estefanía Lozano-Andrés; Herlinde De Keersmaecker; Deep Punj; Juan C Fraire; Edward Geeurickx; Marca H M Wauben; Pieter Vader; Roosmarijn E Vandenbroucke; An Hendrix; Stephan Stremersch; Stefaan C De Smedt; Koen Raemdonck; Kevin Braeckmans

doi:10.1186/s12951-025-03640-3

Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation

Jana Ramon, Cláudio Pinheiro, Charysse Vandendriessche, Estefanía Lozano-Andrés, Herlinde De Keersmaecker, Deep Punj, Juan C Fraire, Edward Geeurickx, Marca H M Wauben, Pieter Vader, Roosmarijn E Vandenbroucke, An Hendrix, Stephan Stremersch, Stefaan C De Smedt, Koen Raemdonck, Kevin Braeckmans^*

^*Corresponding author for this work

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

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Abstract

Despite the natural capacity of extracellular vesicles (EVs) to encapsulate intracellular compounds and transfer these to nearby or distant recipient cells, the intentional loading of EVs with cargo molecules remains a challenging endeavor. Pre-formation EV loading (i.e., during EV biogenesis), offers advantages compared to post-formation loading (i.e., after EV isolation), as EV integrity and composition are minimally perturbed. Pre-formation EV loading is primarily achieved through the genetic engineering of the producer cell, which is time consuming and not very flexible regarding the types of molecules that can be incorporated into EVs. In this work, we investigated the possibility of loading cargo molecules into EVs by delivering the cargo directly into the cytosol of the producer cells, which can subsequently be encapsulated into EVs as they are formed. For the cytosolic delivery of cargo molecules, we evaluated the use of photoporation. This membrane disruption technology has been demonstrated to successfully deliver a broad range of cargo molecules into virtually any cell type, while minimally impacting the cell's normal functioning and homeostasis. As a proof-of-concept, we delivered fluorescently labeled dextran macromolecules and anti-EGFP nanobodies into HEK293T cells genetically engineered with gag-EGFP fusion proteins, which are shuttled into EVs. Colocalization of cargo and EGFP fluorescence in secreted EVs can then serve as a convenient readout for successful EV loading. We established that photoporation had minimal impact on EV characteristics such as concentration, size, zeta potential and the enrichment of EV tetraspanin membrane surface molecules. We found that using EGFP-targeted nanobodies resulted in up to 53% loaded EVs (relative to the amount of EGFP EVs), while non-targeted dextran molecules produced on average 12% loaded EVs (relative to the amount of EGFP EVs). These results highlight the promise of photoporation for pre-formation loading of EVs.

Original language	English
Article number	556
Journal	Journal of Nanobiotechnology
Volume	23
Issue number	1
DOIs	https://doi.org/10.1186/s12951-025-03640-3
Publication status	Published - 8 Aug 2025

Keywords

Cytosol/metabolism
Dextrans/chemistry
Extracellular Vesicles/metabolism
Green Fluorescent Proteins/metabolism
HEK293 Cells
Humans

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Ramon, J., Pinheiro, C., Vandendriessche, C., Lozano-Andrés, E., De Keersmaecker, H., Punj, D., Fraire, J. C., Geeurickx, E., Wauben, M. H. M., Vader, P., Vandenbroucke, R. E., Hendrix, A., Stremersch, S., De Smedt, S. C., Raemdonck, K., & Braeckmans, K. (2025). Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation. Journal of Nanobiotechnology, 23(1), Article 556. https://doi.org/10.1186/s12951-025-03640-3

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title = "Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation",

abstract = "Despite the natural capacity of extracellular vesicles (EVs) to encapsulate intracellular compounds and transfer these to nearby or distant recipient cells, the intentional loading of EVs with cargo molecules remains a challenging endeavor. Pre-formation EV loading (i.e., during EV biogenesis), offers advantages compared to post-formation loading (i.e., after EV isolation), as EV integrity and composition are minimally perturbed. Pre-formation EV loading is primarily achieved through the genetic engineering of the producer cell, which is time consuming and not very flexible regarding the types of molecules that can be incorporated into EVs. In this work, we investigated the possibility of loading cargo molecules into EVs by delivering the cargo directly into the cytosol of the producer cells, which can subsequently be encapsulated into EVs as they are formed. For the cytosolic delivery of cargo molecules, we evaluated the use of photoporation. This membrane disruption technology has been demonstrated to successfully deliver a broad range of cargo molecules into virtually any cell type, while minimally impacting the cell's normal functioning and homeostasis. As a proof-of-concept, we delivered fluorescently labeled dextran macromolecules and anti-EGFP nanobodies into HEK293T cells genetically engineered with gag-EGFP fusion proteins, which are shuttled into EVs. Colocalization of cargo and EGFP fluorescence in secreted EVs can then serve as a convenient readout for successful EV loading. We established that photoporation had minimal impact on EV characteristics such as concentration, size, zeta potential and the enrichment of EV tetraspanin membrane surface molecules. We found that using EGFP-targeted nanobodies resulted in up to 53\% loaded EVs (relative to the amount of EGFP EVs), while non-targeted dextran molecules produced on average 12\% loaded EVs (relative to the amount of EGFP EVs). These results highlight the promise of photoporation for pre-formation loading of EVs.",

keywords = "Cytosol/metabolism, Dextrans/chemistry, Extracellular Vesicles/metabolism, Green Fluorescent Proteins/metabolism, HEK293 Cells, Humans",

author = "Jana Ramon and Cl{\'a}udio Pinheiro and Charysse Vandendriessche and Estefan{\'i}a Lozano-Andr{\'e}s and \{De Keersmaecker\}, Herlinde and Deep Punj and Fraire, \{Juan C\} and Edward Geeurickx and Wauben, \{Marca H M\} and Pieter Vader and Vandenbroucke, \{Roosmarijn E\} and An Hendrix and Stephan Stremersch and \{De Smedt\}, \{Stefaan C\} and Koen Raemdonck and Kevin Braeckmans",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = aug,

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doi = "10.1186/s12951-025-03640-3",

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Ramon, J, Pinheiro, C, Vandendriessche, C, Lozano-Andrés, E, De Keersmaecker, H, Punj, D, Fraire, JC, Geeurickx, E, Wauben, MHM, Vader, P, Vandenbroucke, RE, Hendrix, A, Stremersch, S, De Smedt, SC, Raemdonck, K & Braeckmans, K 2025, 'Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation', Journal of Nanobiotechnology, vol. 23, no. 1, 556. https://doi.org/10.1186/s12951-025-03640-3

TY - JOUR

T1 - Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation

AU - Ramon, Jana

AU - Pinheiro, Cláudio

AU - Vandendriessche, Charysse

AU - Lozano-Andrés, Estefanía

AU - De Keersmaecker, Herlinde

AU - Punj, Deep

AU - Fraire, Juan C

AU - Geeurickx, Edward

AU - Wauben, Marca H M

AU - Vader, Pieter

AU - Vandenbroucke, Roosmarijn E

AU - Hendrix, An

AU - Stremersch, Stephan

AU - De Smedt, Stefaan C

AU - Raemdonck, Koen

AU - Braeckmans, Kevin

PY - 2025/8/8

Y1 - 2025/8/8

N2 - Despite the natural capacity of extracellular vesicles (EVs) to encapsulate intracellular compounds and transfer these to nearby or distant recipient cells, the intentional loading of EVs with cargo molecules remains a challenging endeavor. Pre-formation EV loading (i.e., during EV biogenesis), offers advantages compared to post-formation loading (i.e., after EV isolation), as EV integrity and composition are minimally perturbed. Pre-formation EV loading is primarily achieved through the genetic engineering of the producer cell, which is time consuming and not very flexible regarding the types of molecules that can be incorporated into EVs. In this work, we investigated the possibility of loading cargo molecules into EVs by delivering the cargo directly into the cytosol of the producer cells, which can subsequently be encapsulated into EVs as they are formed. For the cytosolic delivery of cargo molecules, we evaluated the use of photoporation. This membrane disruption technology has been demonstrated to successfully deliver a broad range of cargo molecules into virtually any cell type, while minimally impacting the cell's normal functioning and homeostasis. As a proof-of-concept, we delivered fluorescently labeled dextran macromolecules and anti-EGFP nanobodies into HEK293T cells genetically engineered with gag-EGFP fusion proteins, which are shuttled into EVs. Colocalization of cargo and EGFP fluorescence in secreted EVs can then serve as a convenient readout for successful EV loading. We established that photoporation had minimal impact on EV characteristics such as concentration, size, zeta potential and the enrichment of EV tetraspanin membrane surface molecules. We found that using EGFP-targeted nanobodies resulted in up to 53% loaded EVs (relative to the amount of EGFP EVs), while non-targeted dextran molecules produced on average 12% loaded EVs (relative to the amount of EGFP EVs). These results highlight the promise of photoporation for pre-formation loading of EVs.

AB - Despite the natural capacity of extracellular vesicles (EVs) to encapsulate intracellular compounds and transfer these to nearby or distant recipient cells, the intentional loading of EVs with cargo molecules remains a challenging endeavor. Pre-formation EV loading (i.e., during EV biogenesis), offers advantages compared to post-formation loading (i.e., after EV isolation), as EV integrity and composition are minimally perturbed. Pre-formation EV loading is primarily achieved through the genetic engineering of the producer cell, which is time consuming and not very flexible regarding the types of molecules that can be incorporated into EVs. In this work, we investigated the possibility of loading cargo molecules into EVs by delivering the cargo directly into the cytosol of the producer cells, which can subsequently be encapsulated into EVs as they are formed. For the cytosolic delivery of cargo molecules, we evaluated the use of photoporation. This membrane disruption technology has been demonstrated to successfully deliver a broad range of cargo molecules into virtually any cell type, while minimally impacting the cell's normal functioning and homeostasis. As a proof-of-concept, we delivered fluorescently labeled dextran macromolecules and anti-EGFP nanobodies into HEK293T cells genetically engineered with gag-EGFP fusion proteins, which are shuttled into EVs. Colocalization of cargo and EGFP fluorescence in secreted EVs can then serve as a convenient readout for successful EV loading. We established that photoporation had minimal impact on EV characteristics such as concentration, size, zeta potential and the enrichment of EV tetraspanin membrane surface molecules. We found that using EGFP-targeted nanobodies resulted in up to 53% loaded EVs (relative to the amount of EGFP EVs), while non-targeted dextran molecules produced on average 12% loaded EVs (relative to the amount of EGFP EVs). These results highlight the promise of photoporation for pre-formation loading of EVs.

KW - Cytosol/metabolism

KW - Dextrans/chemistry

KW - Extracellular Vesicles/metabolism

KW - Green Fluorescent Proteins/metabolism

KW - HEK293 Cells

KW - Humans

U2 - 10.1186/s12951-025-03640-3

DO - 10.1186/s12951-025-03640-3

M3 - Article

C2 - 40775713

VL - 23

JO - Journal of Nanobiotechnology

JF - Journal of Nanobiotechnology

IS - 1

M1 - 556

ER -

Pre-formation loading of extracellular vesicles with exogenous molecules using photoporation

Abstract

Keywords

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