MCPH1 Lack of Function Enhances Mitotic Cell Sensitivity Caused by Catalytic Inhibitors of Topo II.

María Arroyo,Eduardo Martínez-Molina,Ana Cañuelo,Duncan J Clarke,Antonio Sánchez,Rosalía F Heredia-Molina,Juan Alberto Marchal

doi:10.3390/genes11040406

María Arroyo, Eduardo Martínez-Molina + Show 5 more

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https://doi.org/10.3390/genes11040406

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Journal: Genes	Publication Date: Apr 8, 2020
Citations: 2	License type: CC BY 4.0

Affiliation: University of Jaén, University of Minnesota

Abstract

The capacity of Topoisomerase II (Topo II) to remove DNA catenations that arise after replication is essential to ensure faithful chromosome segregation. Topo II activity is monitored during G2 by a specific checkpoint pathway that delays entry into mitosis until the chromosomes are properly decatenated. Recently, we demonstrated that the mitotic defects that are characteristic of cells depleted of MCPH1 function, a protein mutated in primary microcephaly, are not a consequence of a weakened G2 decatenation checkpoint response. However, the mitotic defects could be accounted for by a minor defect in the activity of Topo II during G2/M. To test this hypothesis, we have tracked at live single cell resolution the dynamics of mitosis in MCPH1 depleted HeLa cells upon catalytic inhibition of Topo II. Our analyses demonstrate that neither chromosome alignment nor segregation are more susceptible to minor perturbation in decatenation in MCPH1 deficient cells, as compared with control cells. Interestingly, MCPH1 depleted cells were more prone to mitotic cell death when decatenation was perturbed. Furthermore, when the G2 arrest that was induced by catalytic inhibition of Topo II was abrogated by Chk1 inhibition, the incidence of mitotic cell death was also increased. Taken together, our data suggest that the MCPH1 lack of function increases mitotic cell hypersensitivity to the catalytic inhibition of Topo II.

Highlights

DNA Topoisomerase II (Topo II) is essential in eukaryotic cells due to its capacity to remove the catenations that arise between DNA molecules after replication, a result of the helical conformation of the DNA [1,2]
The depletion of MCPH1 protein was achieved in these cells by RNA interference (RNAi) using previously characterized protocols [13,29] (Figure 1B)
Transfection with small interfering RNA (siRNA) was coupled with cell synchronization at G1/S using an excess of thymidine

Summary

Introduction

DNA Topoisomerase II (Topo II) is essential in eukaryotic cells due to its capacity to remove the catenations that arise between DNA molecules after replication, a result of the helical conformation of the DNA [1,2]. DNA tangles, Topo II performs a multistep process that is known as the strand passage reaction, which includes consecutive conformational changes. This reaction requires the hydrolysis of ATP in order to pass one double stranded DNA molecule through another via a transient double strand break (DSB) [6,7]. Topo II activity is monitored during the cell cycle by specific checkpoints to ensure the fidelity of cell division. One of these pathways acts in G2 and delays entry into mitosis until chromosomes are

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