A conserved feature of virtually all higher eukaryotes is that the centromeres are embedded in heterochromatin. Here we provide evidence that this tight association between pericentric heterochromatin and the centromere is essential for proper metaphase exit and progression into telophase. Analysis of chromosome rearrangements that separate pericentric heterochromatin and centromeres indicates that they must remain associated in order to balance Cohesin/DNA catenation-based binding forces and centromere-based pulling forces during the metaphase-anaphase transition. In addition, a centromere embedded in heterochromatin facilitates nuclear envelope assembly around the entire complement of segregating chromosomes. Because the nuclear envelope initially forms on pericentric heterochromatin, nuclear envelope formation proceeds from the pole, thus providing time for incorporation of lagging and trailing chromosome arms into the newly formed nucleus. Additional analysis of noncanonical mitoses provides further insights into the functional significance of the tight association between heterochromatin and centromeres.
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Article Synopsis
- This study explores how different genomic regions are positioned within the nuclei of human cells, focusing on their relationship with nucleoli and heterochromatin.
- By using a technique called Tyramide Signal Amplification-sequencing (TSA-seq), researchers found that smaller chromosomes tend to be closer to nucleoli, especially chromosome arms shorter than 36-46 Mbp.
- They also discovered that certain genomic regions are associated with the nuclear lamina and have distinct patterns of gene expression and DNA replication, challenging previous ideas about genome organization by highlighting the complexity and variability in how DNA is organized within the nucleus.
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