Negative regulation of condensin I by CK2-mediated phosphorylation

Condensin I, which plays an essential role in mitotic chromosome assembly and segregation in vivo, constrains positive supercoils into DNA in the presence of adenosine triphosphate in vitro. Condensin I is constitutively present in a phosphorylated form throughout the HeLa cell cycle, but the sites at which it is phosphorylated in interphase cells differ from those recognized by Cdc2 during mitosis. Immunodepletion, in vitro phosphorylation, and immunoblot analysis using a phospho-specific antibody suggested that the CK2 kinase is likely to be responsible for phosphorylation of condensin I during interphase. In contrast to the slight stimulatory effect of Cdc2-induced phosphorylation of condensin I on supercoiling, phosphorylation by CK2 reduced the supercoiling activity of condensin I. CK2-mediated phosphorylation of condensin I is spatially and temporally regulated in a manner different to that of Cdc2-mediated phosphorylation: CK2-dependent phosphorylation increases during interphase and decreases on chromosomes during mitosis. These findings are the first to demonstrate a negative regulatory mode for condensin I, a process that may influence chromatin structure during interphase and mitosis.     

Cell cycle-dependent phosphorylation, nuclear localization, and activation of human condensin

Condensin, one of the most abundant components of mitotic chromosomes, is a conserved protein complex composed of two structural maintenance of chromosomes (SMC) subunits (SMC2- and SMC4-type) and three non-SMC subunits, and it plays an essential role in mitotic chromosome condensation. Purified condensin reconfigures DNA structure using energy provided by ATP hydrolysis. To know the regulation of condensin in somatic cells, the expression level, subcellular localization, and phosphorylation status of human condensin were examined during the cell cycle. The levels of condensin subunits were almost constant throughout the cell cycle, and the three non-SMC subunits were phosphorylated at specific sites in mitosis and dephosphorylated upon the completion of mitosis. Subcellular fractionation studies revealed that a proportion of condensin was tightly bound to mitotic chromosomes and that this form was phosphorylated at specific sites. Condensin purified from mitotic cells had much stronger supercoiling activity than that purified from interphase cells. These results suggest that condensin functions in somatic cells are regulated by phosphorylation in two ways during the cell cycle; the phosphorylation of specific sites correlates with the chromosomal targeting of condensin, and its biochemical activity is stimulated by phosphorylation.     

SCFSlimb ubiquitin ligase suppresses condensin II–mediated nuclear reorganization by degrading Cap-H2

Condensin complexes play vital roles in chromosome condensation during mitosis and meiosis. Condensin II uniquely localizes to chromatin throughout the cell cycle and, in addition to its mitotic duties, modulates chromosome organization and gene expression during interphase. Mitotic condensin activity is regulated by phosphorylation, but mechanisms that regulate condensin II during interphase are unclear. Here, we report that condensin II is inactivated when its subunit Cap-H2 is targeted for degradation by the SCF^Slimb ubiquitin ligase complex and that disruption of this process dramatically changed interphase chromatin organization. Inhibition of SCF^Slimb function reorganized interphase chromosomes into dense, compact domains and disrupted homologue pairing in both cultured Drosophila cells and in vivo, but these effects were rescued by condensin II inactivation. Furthermore, Cap-H2 stabilization distorted nuclear envelopes and dispersed Cid/CENP-A on interphase chromosomes. Therefore, SCF^Slimb-mediated down-regulation of condensin II is required to maintain proper organization and morphology of the interphase nucleus.     

Disturbance in function and expression of condensin affects chromosome compaction in HeLa cells

Condensin, a major non-histone protein complex on chromosomes, is responsible for the formation of rod-shaped chromosome in mitosis. A heterodimer composed of SMC2 (structural maintenance of chromosomes) and SMC4 subunits constitutes the core part of condensin. Although extensive studies have been done in yeast, fruit fly and Xenopus to uncover the mechanisms and molecular nature of SMC proteins, little is known about the complex in mammalian cells. We have conducted a series of experiments to unveil the nature of condensin complex in human chromosome formation. The results show that overexpression of the C-terminal domain of SMC subunits disturbs chromosome condensation, leading to formation of swollen chromosomes, while knockdown of SMC subunits severely disturbs mitotic chromosome formation, resulting in chromatin bridges between daughter cells and multiple nuclei in single cells. The salt extraction assay indicates that a fraction of the condensin complex is bound to chromatin in interphase, but most of the condensin bind to chromatin at the onset of mitosis. Thus, disturbance in condensin function or expression affects chromosome condensation and influences mitotic progression.     

13S condensin actively reconfigures DNA by introducing global positive writhe: implications for chromosome condensation.

Xenopus 13S condensin converts interphase chromatin into mitotic-like chromosomes, and, in the presence of ATP and a type I topoisomerase, introduces (+) supercoils into DNA. The specific production of (+) trefoil knots in the presence of condensin and a type II topoisomerase shows that condensin reconfigures DNA by introducing an ordered, global, (+) writhe. Knotting required ATP hydrolysis and cell cycle-specific phosphorylation of condensin. Condensin bound preferentially to (+) supercoiled DNA in the presence of ATP but not in its absence. Our results suggest a mechanism for the compaction of chromatin by condensin during mitosis.     

Chromatin-associated protein phosphatase 1 regulates aurora-B and histone H3 phosphorylation

Proper chromosome condensation requires the phosphorylation of histone and nonhistone chromatin proteins. We have used an in vitro chromosome assembly system based on Xenopus egg cytoplasmic extracts to study mitotic histone H3 phosphorylation. We identified a histone H3 Ser(10) kinase activity associated with isolated mitotic chromosomes. The histone H3 kinase was not affected by inhibitors of cyclin-dependent kinases, DNA-dependent protein kinase, p90(rsk), or cAMP-dependent protein kinase. The activity could be selectively eluted from mitotic chromosomes and immunoprecipitated by specific anti-X aurora-B/AIRK2 antibodies. This activity was regulated by phosphorylation. Treatment of X aurora-B immunoprecipitates with recombinant protein phosphatase 1 (PP1) inhibited kinase activity. The presence of PP1 on chromatin suggested that PP1 might directly regulate the X aurora-B associated kinase activity. Indeed, incubation of isolated interphase chromatin with the PP1-specific inhibitor I2 and ATP generated an H3 kinase activity that was also specifically immunoprecipitated by anti-X aurora-B antibodies. Nonetheless, we found that stimulation of histone H3 phosphorylation in interphase cytosol does not drive chromosome condensation or targeting of 13 S condensin to chromatin. In summary, the chromosome-associated mitotic histone H3 Ser(10) kinase is associated with X aurora-B and is inhibited directly in interphase chromatin by PP1.     

Three-step model for condensin activation during mitotic chromosome condensation

Chromosomes undergo a major structural reorganization during mitosis. The first step in this reorganization is the compaction of interphase chromatin into highly condensed mitotic chromosomes. An evolutionarily conserved multi-subunit ATPase, the condensin complex, plays a critical role in establishing chromosome architecture and promoting chromosome condensation in mitosis. How does condensin promote chromosome condensation and how, in turn, is the cell cycle machinery activating or restraining condensin activity during the cell cycle are fundamental questions for cell biology. In this review, we examine the role of post-translational modifications, and in particular multi-site phosphorylation, in the regulation of condensin activity during the cell cycle. Remarkably, inspection of phosphorylation sites identified through multiple proteome-wide mass spectrometry analyses reveals that the phosphorylation landscape of condensin is highly conserved evolutionarily and that several kinases regulate condensin in vivo. This analysis leads us to propose the ultrasensitive-kinase switch model, whereby the phosphorylation of condensin by multiple kinases allows the process of chromosome condensation to be maintained and even increased under fluctuating levels of cyclin-CDK activity during mitosis. Our model reconciles how chromosome condensation might be highly sensitive to low levels of CDK activity in early mitosis and subsequently insensitive to the declining levels CDK activity in late mitosis.     

Phosphorylation of CAP-G is required for its chromosomal DNA localization during mitosis

Condensin is a 5 subunit complex that plays an important role in the structure of chromosomes during mitosis. It is known that phosphorylation of condensin subunits by cdc2/cyclin B at the beginning of mitosis is important for condensin activity, but the sites of these phosphorylation events have not been identified nor has their role in regulating condensin function. Here we identify two threonine residues in the CAP-G subunit of condensin, threonines 308 and 332, that are targets of cdc2/cyclin B phosphorylation. Mutation of these threonines to alanines results in defects in CAP-G localization with chromosomes during mitosis. These results are the first to identify phosphorylation sites within the condensin complex that regulate condensin localization with chromosomal DNA.     

Characterization and dynamic analysis of <Emphasis Type="Italic">Arabidopsis</Emphasis> condensin subunits,AtCAP-H and AtCAP-H2

Condensin complexes are thought to play essential roles in mitotic chromosome assembly and segregation in eukaryotes. To date, two condensin complexes (condensin I and II) have been identified. Both complexes contain two structural maintenance of chromosome (SMC) subunits and three non-SMC subunits. In plants, little is known about the localization and function of all the condensin subunits. Here, we report the analyses on the localization of a non-SMC subunit of Arabidopsis condensin I and II, AtCAP-H, and AtCAP-H2, respectively. Our study indicated that localization of AtCAP-H and AtCAP-H2 is dynamically changed through the mitotic cell cycle using GFP-tagged AtCAP-H and AtCAP-H2 in tobacco cultured cells. They are localized at mitotic chromosomes from prometaphase to telophase. However, their localization in interphase is quite different. AtCAP-H was mainly found in the cytoplasm whereas AtCAP-H2 was mainly found in a nucleolus. It is revealed using GFP-tagged deletion mutant s of AtCAP-H that the kleisin- middle domain (GM domain) is a unique domain only in AtCAP-H, responsible for chromosomal localization. We propose that the GM domain of CAP-H is essential for its chromosomal localization at mitosis and thus proper function of CAP-H. Differences in localization of AtCAP-H and AtCAP-H2 at interphase also suggest their functional differentiation.     

A kinase-anchoring protein (AKAP)95 recruits human chromosome-associated protein (hCAP)-D2/Eg7 for chromosome condensation in mitotic extract

Association of the condensin multiprotein complex with chromatin is required for chromosome condensation at mitosis. What regulates condensin targeting to chromatin is largely unknown. We previously showed that the nuclear A kinase-anchoring protein, AKAP95, is implicated in chromosome condensation. We demonstrate here that AKAP95 acts as a targeting protein for human chromosome-associated protein (hCAP)-D2/Eg7, a component of the human condensin complex, to chromosomes. In HeLa cell mitotic extract, AKAP95 redistributes from the nuclear matrix to chromatin. When association of AKAP95 with chromatin is prevented, the chromatin does not condense. Condensation is rescued by a recombinant AKAP95 peptide containing the 306 COOH-terminal amino acids of AKAP95. Recombinant AKAP95 binds chromatin and elicits recruitment of Eg7 to chromosomes in a concentration-dependent manner. Amount of Eg7 recruited correlates with extent of chromosome condensation: resolution into distinct chromosomes is obtained only when near-endogenous levels of Eg7 are recruited. Eg7 and AKAP95 immunofluorescently colocalize to the central region of methanol-fixed metaphase chromosomes. GST pull-down data also suggest that AKAP95 recruits several condensin subunits. The results implicate AKAP95 as a receptor that assists condensin targeting to chromosomes.     

Condensin binding at distinct and specific chromosomal sites in the Saccharomyces cerevisiae genome

Mitotic chromosome condensation is chiefly driven by the condensin complex. The specific recognition (targeting) of chromosomal sites by condensin is an important component of its in vivo activity. We previously identified the rRNA gene cluster in Saccharomyces cerevisiae as an important condensin-binding site, but both genetic and cell biology data suggested that condensin also acts elsewhere. In order to characterize the genomic distribution of condensin-binding sites and to assess the specificity of condensin targeting, we analyzed condensin-bound sites using chromatin immunoprecipitation and hybridization to whole-genome microarrays. The genomic condensin-binding map shows preferential binding sites over the length of every chromosome. This analysis and quantitative PCR validation confirmed condensin-occupied sites across the genome and in the specialized chromatin regions: near centromeres and telomeres and in heterochromatic regions. Condensin sites were also enriched in the zones of converging DNA replication. Comparison of condensin binding in cells arrested in G(1) and mitosis revealed a cell cycle dependence of condensin binding at some sites. In mitotic cells, condensin was depleted at some sites while enriched at rRNA gene cluster, subtelomeric, and pericentromeric regions.     

Spatial and temporal regulation of Condensins I and II in mitotic chromosome assembly in human cells

Two different condensin complexes make distinct contributions to metaphase chromosome architecture in vertebrate cells. We show here that the spatial and temporal distributions of condensins I and II are differentially regulated during the cell cycle in HeLa cells. Condensin II is predominantly nuclear during interphase and contributes to early stages of chromosome assembly in prophase. In contrast, condensin I is sequestered in the cytoplasm from interphase through prophase and gains access to chromosomes only after the nuclear envelope breaks down in prometaphase. The two complexes alternate along the axis of metaphase chromatids, but they are arranged into a unique geometry at the centromere/kinetochore region, with condensin II enriched near the inner kinetochore plate. This region-specific distribution of condensins I and II is severely disrupted upon depletion of Aurora B, although their association with the chromosome arm is not. Depletion of condensin subunits causes defects in kinetochore structure and function, leading to aberrant chromosome alignment and segregation. Our results suggest that the two condensin complexes act sequentially to initiate the assembly of mitotic chromosomes and that their specialized distribution at the centromere/kinetochore region may play a crucial role in placing sister kinetochores into the back-to-back orientation.     

Cdc14p/FEAR Pathway Controls Segregation of Nucleolus in S. cerevisiae by Facilitating Condensin Targeting to rDNA Chromatin in Anaphase

The condensin complex is the chief molecular machine of mitotic chromosome condensation. Nucleolar concentration of condensin in mitosis was previously shown to correlate with proficiency of rDNA condensation and segregation. To uncover the mechanisms facilitating this targeting we conducted a screen for mutants that impair mitotic condensin congression to the nucleolus. Mutants in the cdc14, esp1 and cdc5 genes, which encode FEAR-network components, showed the most prominent defects in mitotic condensin localization. We established that Cdc14p activity released by the FEAR pathway was required for proper condensin-to-rDNA targeting in anaphase. The MEN pathway was dispensable for condensin-to-rDNA targeting, however MEN-mediated release of Cdc14p later in anaphase allowed for proper, albeit delayed, condensin targeting to rDNA and successful segregation of nucleolus in the slk19 FEAR mutant. Although condensin was physically dislodged from rDNA in the cdc14 mutant, it was properly assembled, phosphorylated and chromatin-bound, suggesting that condensin was mistargeted but active. This study identifies a novel pathway promoting condensin targeting to a specific chromosomal address, the rDNA locus.     

Functional characterization of individual genomic condensin-binding sites in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> using minichromosome mitotic segregation stability assay

Proper chromatin compaction in mitosis (condensation) is required for equal chromosome distribution and the precise inheritance of genetic information. A protein complex called condensin is responsible for mitotic chromosome condensation, chromosome individualization, the timely separation of sister chromatids in mitosis, and proper tension in the mitotic spindle. The mitotic function of condensin depends on the recognition of specific binding sites in the chromosome. The mechanism for binding condensin to individual sites of mitotic chromosomes, as well as the molecular anatomy of these sites, remains to be elucidated. Even less is known about the process that translates condensin binding to individual sites into the segregation of chromosomes in anaphase. In the present work, by using minichromosome assay, we analyze seven individual condensin-binding sites in S. cerevisiae identified in the whole-genome ChIP-on-chip screening. This approach allowed us to estimate the individual contribution of condensin-binding sites to the segregation fidelity of minichromosomes.     

Chromosome morphogenesis: condensin-dependent cohesin removal during meiosis

During meiosis, segregation of homologous chromosomes necessitates the coordination of sister chromatid cohesion, chromosome condensation, and recombination. Cohesion and condensation require the SMC complexes, cohesin and condensin, respectively. Here we use budding yeast Saccharomyces cerevisiae to show that condensin and Cdc5, a Polo-like kinase, facilitate the removal of cohesin from chromosomes prior to the onset of anaphase I when homologs segregate. This cohesin removal is critical for homolog segregation because it helps dissolve the recombination-dependent links between homologs that form during prophase I. Condensin enhances the association of Cdc5 with chromosomes and its phosphorylation of cohesin, which in turn likely stimulates cohesin removal. Condensin/Cdc5-dependent removal of cohesin underscores the potential importance of crosstalk between chromosome structural components in chromosome morphogenesis and provides a mechanism to couple chromosome morphogenesis with other meiotic events.     

Condensins: organizing and segregating the genome

Condensins are multi-subunit protein complexes that play a central role in mitotic chromosome assembly and segregation. The complexes contain 'structural maintenance of chromosomes' (SMC) ATPase subunits, and induce DNA supercoiling and looping in an ATP-hydrolysis-dependent manner in vitro. Vertebrate cells have two different condensin complexes, condensins I and II, each containing a unique set of regulatory subunits. Condensin II participates in an early stage of chromosome condensation within the prophase nucleus. Condensin I gains access to chromosomes only after the nuclear envelope breaks down, and collaborates with condensin II to assemble metaphase chromosomes with fully resolved sister chromatids. The complexes also play critical roles in meiotic chromosome segregation and in interphase processes such as gene repression and checkpoint responses. In bacterial cells, ancestral forms of condensins control chromosome dynamics. Dissecting the diverse functions of condensins is likely to be central to our understanding of genome organization, stability and evolution.