CDK11 Promotes Centromeric Transcription to Maintain Centromeric Cohesion during Mitosis
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Abstract Actively-transcribing RNA polymerase (RNAP)II is remained on centromeres to maintain centromeric cohesion during mitosis although it is largely released from chromosome arms. This pool of RNAPII plays an important role in centromere functions. However, the mechanism of RNAPII retention on mitotic centromeres is poorly understood. We here demonstrate that Cdk11 depletion-induced centromeric cohesion defects are largely independent of Bub1. We further show that Cdk11 depletion and expression of its kinase-dead version significantly reduce both RNAPII and elongating RNAPII (pSer2) levels on centromeres, and also decrease centromeric transcription without altering the protein expression of cohesin and cohesion-regulators. Interestingly, enhanced centromeric transcription by THZ1 treatment or overexpression of CENP-B DNA-binding domain completely rescues Cdk11-depletion defects. These results suggest that Cdk11 promotes centromeric cohesion through facilitating centromeric transcription. Mechanistically, Cdk11 binds and phosphorylates RNAPII to promote transcription. Furthermore, mitosis-specific degradation of G2/M Cdk11-p58 recapitulates Cdk11-depletion defects. Altogether, our findings establish Cdk11 as an important regulator of centromeric transcription and as part of the mechanism for retaining RNAPII on centromeres during mitosis.Keywords:
Transcription
PLK1
Budding yeast
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Significance Bacteria use molecular partitioning systems based on the ATPase ParA to segregate chromosome centromeres before cell division, but how these machines target centromeres to specific locations is unclear. This study shows that, in Caulobacter crescentus , a multimeric complex composed of the PopZ protein directs the ParA machine to transfer centromeres to the cell pole. Spent ParA subunits released from the mitotic apparatus during segregation are recruited throughout a 3D PopZ matrix at the pole. ParA recruitment and sequestration by PopZ stimulates the cell-pole proximal recycling of ParA into a nucleoid-bound complex to ensure pole-specific centromere transfer. PopZ therefore utilizes a 3D scaffolding strategy to create a subcellular microdomain that directly regulates the function of the bacterial centromere segregation machine.
Caulobacter crescentus
Nucleoid
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PLK1
Polo-like kinase
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To observe the effect of polo-like kinase 1 (PLK1) gene depletion on mitosis phenotype and elucidate its vital role in gastric cancer cell line (MKN45) mitosis.The PLK1 expression in MKN45 cells was blocked by RNA interference (RNAi), the expression level of PLK1 mRNA and protein were measured by real-time quantitative PCR and Western blot, respectively. The morphological change of microtubules and mitosis phenotype in MKN45 cells were observed by immunofluorescence staining and laser confocal microscopy, the morphological changes of cells were observed by reverse microscopy, the variation of cell cycle distribution was detected by flow-cytometry.After RNAi targeting PLK1, PLK1 mRNA and protein level decreased obviously, the cell microtubules became obscure and lost cohesiveness, the mitosis phenotype also varied substantially (P < 0.05), more gastric cancer cells became rounded and showed G(2) phase cell DNA content (P < 0.05).PLK1 gene plays a key role in mitosis and its inhibition can lead to mitosis arrest in MKN45 cells.
PLK1
Polo-like kinase
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Aurora B kinase
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Chromosomes segregate at mitosis along microtubules attached to the kinetochore, an organelle that assembles at the centromere. Despite major advances in defining molecular components of the yeast segregation apparatus, including discrete centromere sequences and proteins of the kinetochore, relatively little is known of corresponding elements in more complex eukaryotes. We show here that human CENP-C, a human autoantigen previously localized to the kinetochore, assembles at centromeres of divergent species, and that the specificity of this targeting is maintained by an inherent destruction mechanism that prevents the accumulation of CENP-C and toxicity of mistargeted CENP-C. The N-terminus of CENP-C is not only required for CENP-C destruction but renders unstable proteins that otherwise possess long half-lives. The conserved targeting of CENP-C is underscored by the discovery of significant homology between regions of CENP-C and Mif2, a protein of Saccharomyces cerevisiae required for the correct segregation of chromosomes. Mutations in the Mif2 homology domain of CENP-C impair the ability of CENP-C to assemble at the kinetochore. Together, these data indicate that essential elements of the chromosome segregation apparatus are conserved in eukaryotes.
Organelle
Homology
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Proper chromosome segregation relies on a functional centromere-kinetochore interface. We showed that chromatin containing CENtromere Protein A (CENP-A) is essential for centromere assembly, but dispensable for chromosome segregation in the presence of CENP-B-bound DNA sequences. This demonstrates the existence of two contact points between the DNA and the kinetochore to mediate successful chromosome segregation.
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The centromere functions as a unique chromosomal attachment site for microtubules. Appropriate microtubule attachment is fundamental for organized chromosome behavior during mitosis and meiosis. Hence, centromeres must function both smoothly and stably. However, centromeric DNA sequences are poorly conserved between species despite common functions and similar centromeric protein composition, which leads us to the question: how are centromeres established and maintained? In this review, we summarize the recent progress in deciphering the mechanisms of centromere function. Specifically, we focus our attention on mechanisms closely-related to centromeric DNA and chromatin. By gathering such information, we hope to reveal a new dimension to the true nature of centromeres.
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SUMMARY The multi-task protein kinase Bub1 has long been considered important for chromosome alignment and spindle assembly checkpoint signaling during mitosis. However, recent studies provide surprising evidence that Bub1 may not be essential in human cells, with the underlying mechanism unknown. Here we show that Bub1 plays a redundant role with the non-essential CENP-U complex in recruiting Polo-like kinase 1 (Plk1) to the kinetochore. While disrupting either pathway of Plk1 recruitment does not affect the accuracy of whole chromosome segregation, loss of both pathways leads to a strong reduction in the kinetochore accumulation of Plk1 under a threshold level required for proper chromosome alignment and segregation. Thus, parallel recruitment of Plk1 to kinetochores by Bub1 and the CENP-U complex ensures high fidelity of mitotic chromosome segregation. This study may have implications for targeted treatment of cancer cells harboring mutations in either Bub1 or the CENP-U complex.
BUB1
PLK1
Spindle checkpoint
Aurora B kinase
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