Atg11 promotes Kar9-mediated alignment of the mitotic spindle

Abstract

AbstractAsymmetric spindle pole body (SPB) inheritance requires a cascade of events that involve kinases, phosphatases and structural scaffold proteins including molecular motors and microtubule-associated proteins. Higher levels of an SPB component Spc72 and the spindle positioning factor Kar9 at the old SPB, which migrates to the daughter cell, ensure asymmetric SPB inheritance. In this study, by analyzing the protein interaction network of autophagy (Atg)-related proteins with those that constitute the chromosome segregation machinery, and growth inhibition kinetics in the presence of a microtubule poison, we identified Atg11 as a potential regulator of chromosome transmission from a cohort of 35 autophagy mutants in Saccharomyces cerevisiae. Cells lacking Atg11 did not show kinetochore defects but displayed a high rate of chromosome loss and delayed anaphase onset. Atg11 positively interacted with Kar9 and Kip2 and negatively with Dyn1 and Kar3 in mediating proper positioning and alignment of the mitotic spindle that was found to be under the surveillance of the spindle positioning checkpoint. Indeed, atg11Δ cells displayed an inverted SPB inheritance. Our experiments further revealed that via the Kar9 pathway, Atg11 promotes asymmetric localization of Spc72 and Kar9 on the old SPB. Atg11 physically interacted with Spc72 and transiently localized close to the old SPB during metaphase-to-anaphase progression. Thus, we uncover an autophagy-independent role of Atg11 in spindle alignment. This study emphasizes the importance of screens to identify factors mediating the complex and intricate crosstalk between biological processes fundamental to genomic integrity.