The mitotic spindle is constructed from microtubules (MTs) nucleated from centrosomes, chromosome proximal regions, and preexisting spindle MTs. Augmin, a recently identified protein complex, is a critical factor in spindle MT-based MT generation in Drosophila S2 cells. Previously, we identified one subunit of human augmin. Here, by using mass spectrometry, we identified the full human augmin complex of 8 subunits and show that it interacts with the ␥-tubulin ring complex (␥-TuRC). Unlike augmin-depleted S2 cells, in which the defect in spindle-mediated MT generation is mostly compensated by centrosomal MTs, augmin knockdown alone in HeLa cells triggers the spindle checkpoint, reduces tension on sister kinetochores, and severely impairs metaphase progression. Human augmin knockdown also reduces the number of central spindle MTs during anaphase and causes late-stage cytokinesis failure. A link between augmin and ␥-TuRC is likely critical for these functions, because a ␥-TuRC mutant that attenuates interaction with augmin does not restore function in vivo. These results demonstrate that MT generation mediated by augmin and ␥-TuRC is critical for chromosome segregation and cytokinesis in human cells.centrosome ͉ mitosis ͉ RNAi ͉ spindle checkpoint P roper segregation of sister chromatids during cell division relies on the assembly of a bipolar spindle during mitosis. Sister kinetochores associate with microtubules (MTs) from opposite poles in metaphase. When all of the kinetochores are attached to MTs and under tension, the spindle checkpoint is satisfied and the anaphase segregation of sister chromatids takes place (1, 2). Beginning at anaphase, spindle MTs reorganize to form a bundled and antiparallel MT structure between the segregating chromatids, a structure referred to as the central spindle.
Heterochromatin protein 1 (HP1) has an essential role in heterochromatin formation and mitotic progression through its interaction with various proteins. We have identified a unique HP1alpha-binding protein, POGZ (pogo transposable element-derived protein with zinc finger domain), using an advanced proteomics approach. Proteins generally interact with HP1 through a PxVxL (where x is any amino-acid residue) motif; however, POGZ was found to bind to HP1alpha through a zinc-finger-like motif. Binding by POGZ, mediated through its zinc-finger-like motif, competed with PxVxL proteins and destabilized the HP1alpha-chromatin interaction. Depletion experiments confirmed that the POGZ HP1-binding domain is essential for normal mitotic progression and dissociation of HP1alpha from mitotic chromosome arms. Furthermore, POGZ is required for the correct activation and dissociation of Aurora B kinase from chromosome arms during M phase. These results reveal POGZ as an essential protein that links HP1alpha dissociation with Aurora B kinase activation during mitosis.
Human inactive X chromosome (Xi) forms a compact structure called the Barr body, which is enriched in repressive histone modifications such as trimethylation of histone H3 Lys9 (H3K9me3) and Lys27 (H3K27me3). These two histone marks are distributed in distinct domains, and X-inactive specific transcript (XIST) preferentially colocalizes with H3K27me3 domains. Here we show that Xi compaction requires HBiX1, a heterochromatin protein 1 (HP1)-binding protein, and structural maintenance of chromosomes hinge domain-containing protein 1 (SMCHD1), both of which are enriched throughout the Xi chromosome. HBiX1 localization to H3K9me3 and XIST-associated H3K27me3 (XIST-H3K27me3) domains was mediated through interactions with HP1 and SMCHD1, respectively. Furthermore, HBiX1 was required for SMCHD1 localization to H3K9me3 domains. Depletion of HBiX1 or SMCHD1, but not Polycomb repressive complex 2 (PRC2), resulted in Xi decompaction, similarly to XIST depletion. Thus, the molecular network involving HBiX1 and SMCHD1 links the H3K9me3 and XIST-H3K27me3 domains to organize the compact Xi structure.
Progress in development of biophysical analytic approaches has recently crossed paths with macromolecule condensates in cells. These cell condensates, typically termed liquid-like droplets, are formed by liquid-liquid phase separation (LLPS). More and more cell biologists now recognize that many of the membrane-less organelles observed in cells are formed by LLPS caused by interactions between proteins and nucleic acids. However, the detailed biophysical processes within the cell that lead to these assemblies remain largely unexplored. In this review, we evaluate recent discoveries related to biological phase separation including stress granule formation, chromatin regulation, and processes in the origin and evolution of life. We also discuss the potential issues and technical advancements required to properly study biological phase separation.
A significant amount of RNA is present in the nucleus of mammalian cells but only a small proportion of it is destined for the cytoplasm and subsequent translation, leaving much RNA to associate with chromatin. Historically nuclear RNA was thought to interact with proteins to form a filamentous nuclear matrix, but this idea became less popular as more dynamic models of chromatin behavior became more prevalent. Using new molecular and imaging approaches it is becoming clear that RNA should be considered as an integral component of nuclear organisation; it is transcriptionally responsive and interacts with abundant nuclear RNA binding proteins. We suggest that these protein/RNA structures form a dynamic nuclear mesh that can regulate interphase chromatin structure.
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