Abstract
Dyskerin is a highly conserved, nucleolar RNA-binding protein with established roles in small nuclear ribonucleoprotein biogenesis, telomerase and telomere maintenance and precursor rRNA processing. Telomerase is functional during S phase and the bulk of rRNA maturation occurs during G1 and S phases; both processes are inactivated during mitosis. Yet, we show that during the course of cell cycle progression, human dyskerin expression peaks during G2/M in parallel with the upregulation of pro-mitotic factors. Dyskerin redistributed from the nucleolus in interphase cells to the perichromosomal region during prometaphase, metaphase and anaphase. With continued anaphase progression, dyskerin also localized to the cytoplasm within the mid-pole region. Loss of dyskerin function via siRNA-mediated depletion promoted G2/M accumulation and this was accompanied by an increased mitotic index and activation of the spindle assembly checkpoint. Live cell imaging further revealed an array of mitotic defects including delayed prometaphase progression, a significantly increased incidence of multi-polar spindles, and anaphase bridges culminating in micronucleus formation. Together, these findings suggest that dyskerin is a highly dynamic protein throughout the cell cycle and increases the repertoire of fundamental cellular processes that are disrupted by absence of its normal function.
Highlights
Dyskerin is an evolutionarily conserved protein that binds to and stabilizes small non-coding RNAs that are characterized by the H/ACA secondary structure [1]
In late G2 (8.5 hours after release from the block), dyskerin expression began to rise before peaking in early mitosis
While cyclin B1 and p-H3S10 levels decreased in late mitosis, dyskerin expression persisted at relatively high levels, even upon mitotic exit into G1
Summary
Dyskerin is an evolutionarily conserved protein that binds to and stabilizes small non-coding RNAs that are characterized by the H/ACA secondary structure [1]. Through binding to specific H/ACA RNAs, dyskerin plays critical roles in multiple important cellular processes. Most H/ACA small nucleolar RNAs (snoRNAs) direct the pseudouridination and post-transcriptional processing of precursor rRNA [1]. Dyskerin is a pseudouridine synthase and, in a ribonucleoprotein (RNP) complex containing three other conserved proteins, catalyzes the conversion of specific uridine residues to pseudouridines in nascent rRNA. Yeast, and Drosophila dyskerin-null mutants are lethal [2,3,4]. Pseudouridination is severely impaired in these mutants, suggesting the importance of dyskerin-mediated rRNA processing for normal growth and survival
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