Fe-S cluster coordination of the chromokinesin KIF4A alters its subcellular localization during mitosis.

Fe-S clusters act as co-factors of proteins with diverse functions, for example, in DNA repair. Downregulation of the cytosolic iron-sulfur protein assembly (CIA) machinery promotes genomic instability through the inactivation of multiple DNA repair pathways. Furthermore, CIA deficiencies are associated with so far unexplained mitotic defects. Here, we show that CIA2B (also known as FAM96B) and MMS19, constituents of the CIA targeting complex involved in facilitating Fe-S cluster insertion into cytosolic and nuclear target proteins, colocalize with components of the mitotic machinery. Downregulation of CIA2B and MMS19 impairs the mitotic cycle. We identify the chromokinesin KIF4A as a mitotic component involved in these effects. KIF4A binds a Fe-S cluster in vitro through its conserved cysteine-rich domain. We demonstrate in vivo that this domain is required for the mitosis-related KIF4A localization and for the mitotic defects associated with KIF4A knockout. KIF4A is the first identified mitotic component carrying such a post-translational modification. These findings suggest that the lack of Fe-S clusters in KIF4A upon downregulation of the CIA targeting complex contributes to the mitotic defects.

Reversal of histone H2B mono-ubiquitination is required for replication stress recovery.

Mono-ubiquitination of histone H2B (H2B-Ub1) is a conserved modification that plays central role in regulating numerous biological processes including the DNA damage response, gene transcription, and DNA replication. Previous studies have revealed that H2B-Ub1 promotes recovery from replication stress by mediating Rad53 phosphorylation (Rad53-P), and activation of the intra-S replication checkpoint, in order to limit fork progression, and associated DNA damage. Since such mono-ubiquitination is a reversible process, we examined the role of H2B-Ub1 deubiquitination during replication stress. Using an experimental system in yeast which mimics H2B-Ub1 accumulation, we show that cells become sensitive to the replication stress induced by HU. This stress response was accompanied by Rad53-P accumulation, and delayed recovery from intra-S checkpoint arrest. Furthermore, we show that similar effects were recapitulated by the accumulation of endogenous H2B-Ub1, induced by the co-inactivation of the deubiquitinating enzyme, Ubp10, and Spt16, a FACT histone chaperone family member. While it has been well established that H2B mono-ubiquitination plays an essential role in recovering from replication stress, our data reveal that H2B-Ub1 deubiquitination is also essential for this process.