Lymphocytes can self-steer passively with wind vane uropods

Marie Pierre Valignat; Paulin Nègre; Sophie Cadra; Annemarie C. Lellouch; François Gallet; Sylvie Hénon; Olivier Theodoly

doi:10.1038/ncomms6213

Lymphocytes can self-steer passively with wind vane uropods

Marie Pierre Valignat
, Paulin Nègre
, Sophie Cadra
, Annemarie C. Lellouch
, François Gallet
, Sylvie Hénon
, Olivier Theodoly^*

^*Corresponding author for this work

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

30 Citations (Scopus)

Abstract

A wide variety of cells migrate directionally in response to chemical or mechanical cues, however the mechanisms involved in cue detection and translation into directed movement are debatable. Here we investigate a model of lymphocyte migration on the inner surface of blood vessels. Cells orient their migration against fluid flow, suggesting the existence of an adaptive mechano-tranduction mechanism. We find that flow detection may not require molecular mechano-sensors of shear stress, and detection of flow direction can be achieved by the orientation in the flow of the non-adherent cell rear, the uropod. Uropods act as microscopic wind vanes that can transmit detection of flow direction into cell steering via the on-going machinery of polarity maintenance, without the need for novel internal guidance signalling triggered by flow. Contrary to chemotaxis, which implies active regulation of cue-dependent signalling, upstream flow mechanotaxis of lymphocytes may only rely on a passive self-steering mechanism.

Original language	English
Article number	5213
Journal	Nature Communications
Volume	5
DOIs	https://doi.org/10.1038/ncomms6213
Publication status	Published - 17 Oct 2014
Externally published	Yes

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title = "Lymphocytes can self-steer passively with wind vane uropods",

abstract = "A wide variety of cells migrate directionally in response to chemical or mechanical cues, however the mechanisms involved in cue detection and translation into directed movement are debatable. Here we investigate a model of lymphocyte migration on the inner surface of blood vessels. Cells orient their migration against fluid flow, suggesting the existence of an adaptive mechano-tranduction mechanism. We find that flow detection may not require molecular mechano-sensors of shear stress, and detection of flow direction can be achieved by the orientation in the flow of the non-adherent cell rear, the uropod. Uropods act as microscopic wind vanes that can transmit detection of flow direction into cell steering via the on-going machinery of polarity maintenance, without the need for novel internal guidance signalling triggered by flow. Contrary to chemotaxis, which implies active regulation of cue-dependent signalling, upstream flow mechanotaxis of lymphocytes may only rely on a passive self-steering mechanism.",

author = "Valignat, \{Marie Pierre\} and Paulin N{\`e}gre and Sophie Cadra and Lellouch, \{Annemarie C.\} and Fran{\c c}ois Gallet and Sylvie H{\'e}non and Olivier Theodoly",

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T1 - Lymphocytes can self-steer passively with wind vane uropods

AU - Valignat, Marie Pierre

AU - Nègre, Paulin

AU - Cadra, Sophie

AU - Lellouch, Annemarie C.

AU - Gallet, François

AU - Hénon, Sylvie

AU - Theodoly, Olivier

PY - 2014/10/17

Y1 - 2014/10/17

N2 - A wide variety of cells migrate directionally in response to chemical or mechanical cues, however the mechanisms involved in cue detection and translation into directed movement are debatable. Here we investigate a model of lymphocyte migration on the inner surface of blood vessels. Cells orient their migration against fluid flow, suggesting the existence of an adaptive mechano-tranduction mechanism. We find that flow detection may not require molecular mechano-sensors of shear stress, and detection of flow direction can be achieved by the orientation in the flow of the non-adherent cell rear, the uropod. Uropods act as microscopic wind vanes that can transmit detection of flow direction into cell steering via the on-going machinery of polarity maintenance, without the need for novel internal guidance signalling triggered by flow. Contrary to chemotaxis, which implies active regulation of cue-dependent signalling, upstream flow mechanotaxis of lymphocytes may only rely on a passive self-steering mechanism.

AB - A wide variety of cells migrate directionally in response to chemical or mechanical cues, however the mechanisms involved in cue detection and translation into directed movement are debatable. Here we investigate a model of lymphocyte migration on the inner surface of blood vessels. Cells orient their migration against fluid flow, suggesting the existence of an adaptive mechano-tranduction mechanism. We find that flow detection may not require molecular mechano-sensors of shear stress, and detection of flow direction can be achieved by the orientation in the flow of the non-adherent cell rear, the uropod. Uropods act as microscopic wind vanes that can transmit detection of flow direction into cell steering via the on-going machinery of polarity maintenance, without the need for novel internal guidance signalling triggered by flow. Contrary to chemotaxis, which implies active regulation of cue-dependent signalling, upstream flow mechanotaxis of lymphocytes may only rely on a passive self-steering mechanism.

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U2 - 10.1038/ncomms6213

DO - 10.1038/ncomms6213

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SN - 2041-1723

VL - 5

JO - Nature Communications

JF - Nature Communications

M1 - 5213

ER -

Lymphocytes can self-steer passively with wind vane uropods

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