DNA damage induces Yap5-dependent transcription of ECO1/CTF7 in Saccharomyces cerevisiae.

Michael G Mfarej,Robert V Skibbens,Marco Muzi-Falconi

doi:10.1371/journal.pone.0242968

Michael G Mfarej, Robert V Skibbens + Show 1 more

Open Access

https://doi.org/10.1371/journal.pone.0242968

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Journal: PloS one	Publication Date: Dec 29, 2020
Citations: 6	License type: CC BY 4.0

Affiliation: Lehigh University

Abstract

Yeast Eco1 (ESCO2 in humans) acetyltransferase converts chromatin-bound cohesins to a DNA tethering state, thereby establishing sister chromatid cohesion. Eco1 establishes cohesion during DNA replication, after which Eco1 is targeted for degradation by SCF E3 ubiquitin ligase. SCF E3 ligase, and sequential phosphorylations that promote Eco1 ubiquitination and degradation, remain active throughout the M phase. In this way, Eco1 protein levels are high during S phase, but remain low throughout the remaining cell cycle. In response to DNA damage during M phase, however, Eco1 activity increases—providing for a new wave of cohesion establishment (termed Damage-Induced Cohesion, or DIC) which is critical for efficient DNA repair. To date, little evidence exists as to the mechanism through which Eco1 activity increases during M phase in response to DNA damage. Possibilities include that either the kinases or E3 ligase, that target Eco1 for degradation, are inhibited in response to DNA damage. Our results reveal instead that the degradation machinery remains fully active during M phase, despite the presence of DNA damage. In testing alternate models through which Eco1 activity increases in response to DNA damage, the results reveal that DNA damage induces new transcription of ECO1 and at a rate that exceeds the rate of Eco1 turnover, providing for rapid accumulation of Eco1 protein. We further show that DNA damage induction of ECO1 transcription is in part regulated by Yap5—a stress-induced transcription factor. Given the role for mutated ESCO2 (homolog of ECO1) in human birth defects, this study highlights the complex nature through which mutation of ESCO2, and defects in ESCO2 regulation, may promote developmental abnormalities and contribute to various diseases including cancer.

Highlights

In order for a cell to divide, the cell division cycle must accomplish two major feats with high fidelity
Cells harboring Eco1-3V5, as the sole source of Eco1 protein, were synchronized in early S phase with hydroxyurea (HU), washed and incubated for three hours in fresh media supplemented with nocodazole (NZ) to achieve an M phase arrest (Fig 1A)
The results show that Eco1 levels are high during S phase and drop dramatically as cells progress into M phase (Fig 1C)

Summary

Introduction

In order for a cell to divide, the cell division cycle must accomplish two major feats with high fidelity. The genetic material must be accurately replicated during S phase. The cell must segregate the duplicated genetic material to each daughter cell during M phase. To identify over time the products of chromosome duplication, the cell tethers together sister chromatids during S phase.

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