Role of the nuclear membrane protein Emerin in front-rear polarity of the nucleus

Paulina Nastały,Gururaj Rao Kidiyoor,Orso Maria Romano,Tobias Lendenmann,Galina V Beznoussenko,Aldo Ferrari,Paolo Maiuri,Dimos Poulikakos,Divya Purushothaman,Alexander A Mironov,Stefania Lavore,Stefano Marchesi,Alessandro Poli,Marco Cosentino Lagomarsino

doi:10.1038/s41467-020-15910-9

Abstract

Cell polarity refers to the intrinsic asymmetry of cells, including the orientation of the cytoskeleton. It affects cell shape and structure as well as the distribution of proteins and organelles. In migratory cells, front-rear polarity is essential and dictates movement direction. While the link between the cytoskeleton and nucleus is well-studied, we aim to investigate if front-rear polarity can be transmitted to the nucleus. We show that the knock-down of emerin, an integral protein of the nuclear envelope, abolishes preferential localization of several nuclear proteins. We propose that the frontally biased localization of the endoplasmic reticulum, through which emerin reaches the nuclear envelope, is sufficient to generate its observed bias. In primary emerin-deficient myoblasts, its expression partially rescues the polarity of the nucleus. Our results demonstrate that front-rear cell polarity is transmitted to the nucleus and that emerin is an important determinant of nuclear polarity.

Highlights

Cell polarity refers to the intrinsic asymmetry of cells, including the orientation of the cytoskeleton
While the connection between the cytoskeleton and the nucleus is well-studied[24,50], it is unknown if part of the front-rear cell polarity is somehow transmitted to the nucleus
This study demonstrates that front-rear cell polarity is transmitted from the cytoskeleton to the nuclear envelope and, defines a nuclear polarity

Summary

Introduction

Cell polarity refers to the intrinsic asymmetry of cells, including the orientation of the cytoskeleton. 1234567890():,; Cell polarity is defined as an intrinsic asymmetry observed in the structural orientation of the cytoskeleton, mainly due to actin filaments and microtubules[1] It is manifested in cell shape and structure as well as distribution of proteins and cellular organelles. Various migratory cell types display a characteristic morphology with a protruding front, at the opposite of a retracting trailing edge[3] This so-called, frontrear polarity is essential and dictates the direction of movement[4,5]. Seminal studies reported a tension-induced basal-to-apical polarization of lamin A/C in mouse embryonic fibroblasts[6,7] It has not been further investigated how much this impacts other nuclear envelope (NE) proteins or the nuclear interior. Our findings reveal that the asymmetric organization of the cell can be transmitted to the nucleus

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