An epigenetic regulator emerges as microtubule minus-end binding and stabilizing factor in mitosis

AA Hyman; AK Dunsch; B Neumann; C Feller; C Gilissen; CA Schatz; CE Richardson; CL Rieder; DA Koolen; E Karsenti; G Goshima; H Wang; H Yokoyama; H Yokoyama; I Peset; J Dias; J Scrofani; JD Marcette; JM Gottesfeld; K Jiang; KC Lam; M Piel; M Wuhr; M Zollino; MC Hendershott; MJ Kruhlak; N Galjart; N Tanaka; P Kalab; S Mendjan; S Meunier; S Meunier; S Nagae; SJ Raja; SS Goodwin; T Chelmicki; T Sardon; TJ Maresca; US Tulu; W Meng; Y Cai; Y Masui

An epigenetic regulator emerges as microtubule minus-end binding and stabilizing factor in mitosis

Authors: AA Hyman
AK Dunsch
B Neumann
C Feller
C Gilissen
CA Schatz
CE Richardson
CL Rieder
DA Koolen
E Karsenti
G Goshima
H Wang
H Yokoyama
H Yokoyama
I Peset
J Dias
J Scrofani
JD Marcette
JM Gottesfeld
K Jiang
KC Lam
M Piel
M Wuhr
M Zollino
MC Hendershott
MJ Kruhlak
N Galjart
N Tanaka
P Kalab
S Mendjan
S Meunier
S Meunier
S Nagae
SJ Raja
SS Goodwin
T Chelmicki
T Sardon
TJ Maresca
US Tulu
W Meng
Y Cai
Y Masui
Publication date: 1 January 2015
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

The evolutionary conserved NSL complex is a prominent epigenetic regulator controlling expression of thousands of genes. Here we uncover a novel function of the NSL complex members in mitosis. As the cell enters mitosis, KANSL1 and KANSL3 undergo a marked relocalisation from the chromatin to the mitotic spindle. By stabilizing microtubule minus ends in a RanGTP-dependent manner, they are essential for spindle assembly and chromosome segregation. Moreover, we identify KANSL3 as a microtubule minus-end-binding protein, revealing a new class of mitosis-specific microtubule minus-end regulators. By adopting distinct functions in interphase and mitosis, KANSL proteins provide a link to coordinate the tasks of faithful expression and inheritance of the genome during different phases of the cell cycle