Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles

Daniel Alfandari; Irit Rosenhek-Goldian; Ewa Kozela; Reinat Nevo; Marcela Bahlsen Senprún; Anton Moisieiev; Noam Sogauker; Ido Azuri; Samuel Gelman; Edo Kiper; Daniel Ben Hur; Raviv Dharan; Raya Sorkin; Ziv Porat; Mattia I. Morandi; Neta Regev-Rudzki

doi:10.1021/acsnano.4c07503

Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles

Daniel Alfandari, Irit Rosenhek-Goldian, Ewa Kozela, Reinat Nevo, Marcela Bahlsen Senprún, Anton Moisieiev, Noam Sogauker, Ido Azuri, Samuel Gelman, Edo Kiper, Daniel Ben Hur, Raviv Dharan, Raya Sorkin, Ziv Porat, Mattia I. Morandi^*, Neta Regev-Rudzki^*

^*Corresponding author for this work

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

Abstract

The malaria parasite, Plasmodium falciparum, secretes extracellular vesicles (EVs) to facilitate its growth and to communicate with the external microenvironment, primarily targeting the host’s immune cells. How parasitic EVs enter specific immune cell types within the highly heterogeneous pool of immune cells remains largely unknown. Using a combination of imaging flow cytometry and advanced fluorescence analysis, we demonstrated that the route of uptake of parasite-derived EVs differs markedly between host T cells and monocytes. T cells, which are components of the adaptive immune system, internalize parasite-derived EVs mainly through an interaction with the plasma membrane, whereas monocytes, which function in the innate immune system, take up these EVs via endocytosis. The membranal/endocytic balance of EV internalization is driven mostly by the amount of endocytic incorporation. Integrating atomic force microscopy with fluorescence data analysis revealed that internalization depends on the biophysical properties of the cell membrane rather than solely on molecular interactions. In support of this, altering the cholesterol content in the cell membrane tilted the balance in favor of one uptake route over another. Our results provide mechanistic insights into how P. falciparum-derived EVs enter into diverse host cells. This study highlights the sophisticated cell-communication tactics used by the malaria parasite.

Original language	English
Pages (from-to)	9760-9778
Number of pages	19
Journal	ACS Nano
Volume	19
Issue number	10
DOIs	https://doi.org/10.1021/acsnano.4c07503
State	Published - 18 Mar 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.

Keywords

cellular uptake
EVs
extracellular vesicles
imaging flow cytometry
malaria
membrane deformability

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Alfandari, D., Rosenhek-Goldian, I., Kozela, E., Nevo, R., Senprún, M. B., Moisieiev, A., Sogauker, N., Azuri, I., Gelman, S., Kiper, E., Ben Hur, D., Dharan, R., Sorkin, R., Porat, Z., Morandi, M. I., & Regev-Rudzki, N. (2025). Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles. ACS Nano, 19(10), 9760-9778. https://doi.org/10.1021/acsnano.4c07503

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title = "Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles",

abstract = "The malaria parasite, Plasmodium falciparum, secretes extracellular vesicles (EVs) to facilitate its growth and to communicate with the external microenvironment, primarily targeting the host{\textquoteright}s immune cells. How parasitic EVs enter specific immune cell types within the highly heterogeneous pool of immune cells remains largely unknown. Using a combination of imaging flow cytometry and advanced fluorescence analysis, we demonstrated that the route of uptake of parasite-derived EVs differs markedly between host T cells and monocytes. T cells, which are components of the adaptive immune system, internalize parasite-derived EVs mainly through an interaction with the plasma membrane, whereas monocytes, which function in the innate immune system, take up these EVs via endocytosis. The membranal/endocytic balance of EV internalization is driven mostly by the amount of endocytic incorporation. Integrating atomic force microscopy with fluorescence data analysis revealed that internalization depends on the biophysical properties of the cell membrane rather than solely on molecular interactions. In support of this, altering the cholesterol content in the cell membrane tilted the balance in favor of one uptake route over another. Our results provide mechanistic insights into how P. falciparum-derived EVs enter into diverse host cells. This study highlights the sophisticated cell-communication tactics used by the malaria parasite.",

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author = "Daniel Alfandari and Irit Rosenhek-Goldian and Ewa Kozela and Reinat Nevo and Senpr{\'u}n, {Marcela Bahlsen} and Anton Moisieiev and Noam Sogauker and Ido Azuri and Samuel Gelman and Edo Kiper and {Ben Hur}, Daniel and Raviv Dharan and Raya Sorkin and Ziv Porat and Morandi, {Mattia I.} and Neta Regev-Rudzki",

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year = "2025",

month = mar,

day = "18",

doi = "10.1021/acsnano.4c07503",

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Alfandari, D, Rosenhek-Goldian, I, Kozela, E, Nevo, R, Senprún, MB, Moisieiev, A, Sogauker, N, Azuri, I, Gelman, S, Kiper, E, Ben Hur, D, Dharan, R, Sorkin, R, Porat, Z, Morandi, MI & Regev-Rudzki, N 2025, 'Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles', ACS Nano, vol. 19, no. 10, pp. 9760-9778. https://doi.org/10.1021/acsnano.4c07503

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T1 - Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles

AU - Alfandari, Daniel

AU - Rosenhek-Goldian, Irit

AU - Kozela, Ewa

AU - Nevo, Reinat

AU - Senprún, Marcela Bahlsen

AU - Moisieiev, Anton

AU - Sogauker, Noam

AU - Azuri, Ido

AU - Gelman, Samuel

AU - Kiper, Edo

AU - Ben Hur, Daniel

AU - Dharan, Raviv

AU - Sorkin, Raya

AU - Porat, Ziv

AU - Morandi, Mattia I.

AU - Regev-Rudzki, Neta

PY - 2025/3/18

Y1 - 2025/3/18

N2 - The malaria parasite, Plasmodium falciparum, secretes extracellular vesicles (EVs) to facilitate its growth and to communicate with the external microenvironment, primarily targeting the host’s immune cells. How parasitic EVs enter specific immune cell types within the highly heterogeneous pool of immune cells remains largely unknown. Using a combination of imaging flow cytometry and advanced fluorescence analysis, we demonstrated that the route of uptake of parasite-derived EVs differs markedly between host T cells and monocytes. T cells, which are components of the adaptive immune system, internalize parasite-derived EVs mainly through an interaction with the plasma membrane, whereas monocytes, which function in the innate immune system, take up these EVs via endocytosis. The membranal/endocytic balance of EV internalization is driven mostly by the amount of endocytic incorporation. Integrating atomic force microscopy with fluorescence data analysis revealed that internalization depends on the biophysical properties of the cell membrane rather than solely on molecular interactions. In support of this, altering the cholesterol content in the cell membrane tilted the balance in favor of one uptake route over another. Our results provide mechanistic insights into how P. falciparum-derived EVs enter into diverse host cells. This study highlights the sophisticated cell-communication tactics used by the malaria parasite.

AB - The malaria parasite, Plasmodium falciparum, secretes extracellular vesicles (EVs) to facilitate its growth and to communicate with the external microenvironment, primarily targeting the host’s immune cells. How parasitic EVs enter specific immune cell types within the highly heterogeneous pool of immune cells remains largely unknown. Using a combination of imaging flow cytometry and advanced fluorescence analysis, we demonstrated that the route of uptake of parasite-derived EVs differs markedly between host T cells and monocytes. T cells, which are components of the adaptive immune system, internalize parasite-derived EVs mainly through an interaction with the plasma membrane, whereas monocytes, which function in the innate immune system, take up these EVs via endocytosis. The membranal/endocytic balance of EV internalization is driven mostly by the amount of endocytic incorporation. Integrating atomic force microscopy with fluorescence data analysis revealed that internalization depends on the biophysical properties of the cell membrane rather than solely on molecular interactions. In support of this, altering the cholesterol content in the cell membrane tilted the balance in favor of one uptake route over another. Our results provide mechanistic insights into how P. falciparum-derived EVs enter into diverse host cells. This study highlights the sophisticated cell-communication tactics used by the malaria parasite.

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KW - EVs

KW - extracellular vesicles

KW - imaging flow cytometry

KW - malaria

KW - membrane deformability

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Host Immune Cell Membrane Deformability Governs the Uptake Route of Malaria-Derived Extracellular Vesicles

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Keywords

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