Formation of cellular close-ended tunneling nanotubes through mechanical deformation

Minhyeok Chang; O. Chul Lee; Gayun Bu; Jaeho Oh; Na Oh Yunn; Sung Ho Ryu; Hyung Bae Kwon; Anatoly B. Kolomeisky; Sang Hee Shim; Junsang Doh; Jae Hyung Jeon; Jong Bong Lee

doi:10.1126/sciadv.abj3995

Formation of cellular close-ended tunneling nanotubes through mechanical deformation

Minhyeok Chang, O. Chul Lee, Gayun Bu, Jaeho Oh, Na Oh Yunn, Sung Ho Ryu, Hyung Bae Kwon, Anatoly B. Kolomeisky, Sang Hee Shim, Junsang Doh, Jae Hyung Jeon, Jong Bong Lee

School of Medicine

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

Abstract

Membrane nanotubes or tunneling nanotubes (TNTs) that connect cells have been recognized as a previously unidentified pathway for intercellular transport between distant cells. However, it is unknown how this delicate structure, which extends over tens of micrometers and remains robust for hours, is formed. Here, we found that a TNT develops from a double filopodial bridge (DFB) created by the physical contact of two filopodia through helical deformation of the DFB. The transition of a DFB to a close-ended TNT is most likely triggered by disruption of the adhesion of two filopodia by mechanical energy accumulated in a twisted DFB when one of the DFB ends is firmly attached through intercellular cadherin-cadherin interactions. These studies pinpoint the mechanistic questions about TNTs and elucidate a formation mechanism.

Original language	English (US)
Article number	3995
Journal	Science Advances
Volume	8
Issue number	13
DOIs	https://doi.org/10.1126/sciadv.abj3995
State	Published - Apr 2022

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title = "Formation of cellular close-ended tunneling nanotubes through mechanical deformation",

abstract = "Membrane nanotubes or tunneling nanotubes (TNTs) that connect cells have been recognized as a previously unidentified pathway for intercellular transport between distant cells. However, it is unknown how this delicate structure, which extends over tens of micrometers and remains robust for hours, is formed. Here, we found that a TNT develops from a double filopodial bridge (DFB) created by the physical contact of two filopodia through helical deformation of the DFB. The transition of a DFB to a close-ended TNT is most likely triggered by disruption of the adhesion of two filopodia by mechanical energy accumulated in a twisted DFB when one of the DFB ends is firmly attached through intercellular cadherin-cadherin interactions. These studies pinpoint the mechanistic questions about TNTs and elucidate a formation mechanism.",

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AU - Chang, Minhyeok

AU - Lee, O. Chul

AU - Bu, Gayun

AU - Oh, Jaeho

AU - Yunn, Na Oh

AU - Ryu, Sung Ho

AU - Kwon, Hyung Bae

AU - Kolomeisky, Anatoly B.

AU - Shim, Sang Hee

AU - Doh, Junsang

AU - Jeon, Jae Hyung

AU - Lee, Jong Bong

PY - 2022/4

Y1 - 2022/4

N2 - Membrane nanotubes or tunneling nanotubes (TNTs) that connect cells have been recognized as a previously unidentified pathway for intercellular transport between distant cells. However, it is unknown how this delicate structure, which extends over tens of micrometers and remains robust for hours, is formed. Here, we found that a TNT develops from a double filopodial bridge (DFB) created by the physical contact of two filopodia through helical deformation of the DFB. The transition of a DFB to a close-ended TNT is most likely triggered by disruption of the adhesion of two filopodia by mechanical energy accumulated in a twisted DFB when one of the DFB ends is firmly attached through intercellular cadherin-cadherin interactions. These studies pinpoint the mechanistic questions about TNTs and elucidate a formation mechanism.

AB - Membrane nanotubes or tunneling nanotubes (TNTs) that connect cells have been recognized as a previously unidentified pathway for intercellular transport between distant cells. However, it is unknown how this delicate structure, which extends over tens of micrometers and remains robust for hours, is formed. Here, we found that a TNT develops from a double filopodial bridge (DFB) created by the physical contact of two filopodia through helical deformation of the DFB. The transition of a DFB to a close-ended TNT is most likely triggered by disruption of the adhesion of two filopodia by mechanical energy accumulated in a twisted DFB when one of the DFB ends is firmly attached through intercellular cadherin-cadherin interactions. These studies pinpoint the mechanistic questions about TNTs and elucidate a formation mechanism.

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Formation of cellular close-ended tunneling nanotubes through mechanical deformation

Abstract

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