RNAi knockdown of human kinetochore protein CENP-H

The inner kinetochore protein complex binds to centromeres during the whole cell cycle. It serves as the basis for the binding of further kinetochore proteins during mitosis. CENP-H is one of the inner kinetochore proteins which is conserved amongst many eukaryotes. By specific RNAi knockdown, we reduced the CENP-H protein level in human HEp-2 cells down to less than 5% of its normal value. In these CENP-H knocked-down cells, we observed severe mitotic phenotypes like misaligned chromosomes and multipolar spindles, however, no mitotic arrest. Strong reduction of CENP-H resulted in a slightly reduced CENP-C level at the kinetochores and normal localisation of hBubR1, indicating a functional mitotic checkpoint at the hBubR1 protein level. In CENP-H knocked-down human cells, the misaligned chromosomes contained only reduced levels of CENP-E. Our data clearly indicate that CENP-H has an important impact on the architecture and function of the human kinetochore complex.     

The constitutive centromere component CENP-50 is required for recovery from spindle damage

We identified CENP-50 as a novel kinetochore component. We found that CENP-50 is a constitutive component of the centromere that colocalizes with CENP-A and CENP-H throughout the cell cycle in vertebrate cells. To determine the precise role of CENP-50, we examined its role in centromere function by generating a loss-of-function mutant in the chicken DT40 cell line. The CENP-50 knockout was not lethal; however, the growth rate of cells with this mutation was slower than that of wild-type cells. We observed that the time for CENP-50-deficient cells to complete mitosis was longer than that for wild-type cells. Centromeric localization of CENP-50 was abolished in both CENP-H- and CENP-I-deficient cells. Coimmunoprecipitation experiments revealed that CENP-50 interacted with the CENP-H/CENP-I complex in chicken DT40 cells. We also observed severe mitotic defects in CENP-50-deficient cells with apparent premature sister chromatid separation when the mitotic checkpoint was activated, indicating that CENP-50 is required for recovery from spindle damage.     

CENP-H, a constitutive centromere component, is required for centromere targeting of CENP-C in vertebrate cells

CENP-H has recently been discovered as a constitutive component of the centromere that co-localizes with CENP-A and CENP-C throughout the cell cycle. The precise function, however, remains poorly understood. We examined the role of CENP-H in centromere function and assembly by generating a conditional loss-of-function mutant in the chicken DT40 cell line. In the absence of CENP-H, cell cycle arrest at metaphase, consistent with loss of centromere function, was observed. Immunocytochemical analysis of the CENP-H-deficient cells demonstrated that CENP-H is necessary for CENP-C, but not CENP-A, localization to the centromere. These findings indicate that centromere assembly in vertebrate cells proceeds in a hierarchical manner in which localization of the centromere-specific histone CENP-A is an early event that occurs independently of CENP-C and CENP-H.     

Dynamic changes in CCAN organization through CENP-C during cell-cycle progression

The kinetochore is a crucial structure for faithful chromosome segregation during mitosis and is formed in the centromeric region of each chromosome. The 16-subunit protein complex known as the constitutive centromere-associated network (CCAN) forms the foundation for kinetochore assembly on the centromeric chromatin. Although the CCAN can be divided into several subcomplexes, it remains unclear how CCAN proteins are organized to form the functional kinetochore. In particular, this organization may vary as the cell cycle progresses. To address this, we analyzed the relationship of centromeric protein (CENP)-C with the CENP-H complex during progression of the cell cycle. We find that the middle portion of chicken CENP-C (CENP-C^166–324) is sufficient for centromere localization during interphase, potentially through association with the CENP-L-N complex. The C-terminus of CENP-C (CENP-C^601–864) is essential for centromere localization during mitosis, through binding to CENP-A nucleosomes, independent of the CENP-H complex. On the basis of these results, we propose that CCAN organization changes dynamically during progression of the cell cycle.     

The Aspergillus nidulans CENP-E kinesin motor KipA interacts with the fungal homologue of the centromere-associated protein CENP-H at the kinetochore

Chromosome segregation is an essential process for nuclear and cell division. The microtubule cytoskeleton, molecular motors and protein complexes at the microtubule plus ends and at kinetochores play crucial roles in the segregation process. Here we identified KatA (KipAtarget protein, homologue of CENP-H) as a kinesin-7 (KipA, homologue of human CENP-E) interacting protein in Aspergillus nidulans. KatA located at the kinetochore during the whole cell cycle and colocalized with KipA and partially with the putative microtubule polymerase AlpA (XMAP215) during mitosis. Deletion of katA was lethal at 37°C and caused severe growth and morphology defects at room temperature. KipA was shown before to play an important role in growth directionality determination and our new results suggest a second function of KipA in the interaction between the microtubule plus ends and the kinetochores during mitosis.     

Mitotic Protein CSPP1 Interacts with CENP-H Protein to Coordinate Accurate Chromosome Oscillation in Mitosis

Mitotic chromosome segregation is orchestrated by the dynamic interaction of spindle microtubules with the kinetochores. During chromosome alignment, kinetochore-bound microtubules undergo dynamic cycles between growth and shrinkage, leading to an oscillatory movement of chromosomes along the spindle axis. Although kinetochore protein CENP-H serves as a molecular control of kinetochore-microtubule dynamics, the mechanistic link between CENP-H and kinetochore microtubules (kMT) has remained less characterized. Here, we show that CSPP1 is a kinetochore protein essential for accurate chromosome movements in mitosis. CSPP1 binds to CENP-H in vitro and in vivo. Suppression of CSPP1 perturbs proper mitotic progression and compromises the satisfaction of spindle assembly checkpoint. In addition, chromosome oscillation is greatly attenuated in CSPP1-depleted cells, similar to what was observed in the CENP-H-depleted cells. Importantly, CSPP1 depletion enhances velocity of kinetochore movement, and overexpression of CSPP1 decreases the speed, suggesting that CSPP1 promotes kMT stability during cell division. Specific perturbation of CENP-H/CSPP1 interaction using a membrane-permeable competing peptide resulted in a transient mitotic arrest and chromosome segregation defect. Based on these findings, we propose that CSPP1 cooperates with CENP-H on kinetochores to serve as a novel regulator of kMT dynamics for accurate chromosome segregation.     

CENP-I is essential for centromere function in vertebrate cells

We identified a novel essential centromere protein, CENP-I, which shows sequence similarity with fission yeast Mis6 protein, and we showed that CENP-I is a constitutive component of the centromere that colocalizes with CENP-A, -C, and -H throughout the cell cycle in vertebrate cells. To determine the precise function of CENP-I, we examined its role in centromere function by generating a conditional loss-of-function mutant in the chicken DT40 cell line. In the absence of CENP-I, cells arrested at prometaphase with misaligned chromosomes for long periods of time. Eventually, cells exited mitosis without undergoing cytokinesis. Immunocytochemical analysis of CENP-I-deficient cells demonstrated that both CENP-I and CENP-H are necessary for localization of CENP-C but not CENP-A to the centromere.     

CENP-A is required for accurate chromosome segregation and sustained kinetochore association of BubR1

CENP-A is an evolutionarily conserved, centromere-specific variant of histone H3 that is thought to play a central role in directing kinetochore assembly and in centromere function. Here, we have analyzed the consequences of disrupting the CENP-A gene in the chicken DT40 cell line. In CENP-A-depleted cells, kinetochore protein assembly is impaired, as indicated by mislocalization of the inner kinetochore proteins CENP-I, CENP-H, and CENP-C as well as the outer components Nuf2/Hec1, Mad2, and CENP-E. However, BubR1 and the inner centromere protein INCENP are efficiently recruited to kinetochores. Following CENP-A depletion, chromosomes are deficient in proper congression on the mitotic spindle and there is a transient delay in prometaphase. CENP-A-depleted cells further proceed through anaphase and cytokinesis with unequal chromosome segregation, suggesting that some kinetochore function remains following substantial depletion of CENP-A. We furthermore demonstrate that CENP-A-depleted cells exhibit a specific defect in maintaining kinetochore localization of the checkpoint protein BubR1 under conditions of checkpoint activation. Our data thus point to a specific role for CENP-A in assembly of kinetochores competent in the maintenance of mitotic checkpoint signaling.     

The functional region of CENP-H interacts with the Nuf2 complex that localizes to centromere during mitosis

CENP-H is a constitutive centromere component that localizes to the centromere throughout the cell cycle. Because CENP-H is colocalized with CENP-A and CENP-C, it is thought to be an inner centromere protein. We previously generated a conditional loss-of-function mutant of CENP-H and showed that CENP-H is required for targeting of CENP-C to the centromere in chicken DT40 cells. In the present study, we used this mutant to identify the functional region of chicken CENP-H necessary for centromere targeting and cell viability. This region was found by yeast two-hybrid analysis to interact with Hec1, which is a member of the Nuf2 complex that transiently localizes to the centromere during mitosis. Coimmunoprecipitation experiments revealed that CENP-H interacts with the Nuf2 complex in chicken DT40 cells. Photobleaching experiments showed that both Hec1 and CENP-H form stable associations with the centromeres during mitosis, suggesting that Hec1 acts as a structural component of centromeres during mitosis. On the basis of these results and previously published data, we propose that the Nuf2 complex functions as a connector between the inner and outer kinetochores.     

The fate of metaphase kinetochores is weighed in the balance of SUMOylation during S phase

Genetic evidence suggests that conjugation of Small Ubiquitin-like Modifier proteins (SUMOs) plays an important role in kinetochore function, although the mechanism underlying these observations are poorly defined. we found that depletion of the SUMO protease SENP6 from HeLa cells causes chromosome misalignment, prolonged mitotic arrest and chromosome missegregation. Many inner kinetochore proteins (IKPs) were mis-localized in SENP6-depleted cells. This gross mislocalization of IKPs is due to proteolytic degradation of CENP-I and CENP-H via the SUMO targeted Ubiquitin Ligase (STUbL) pathway. Our findings show that SENP6 is a key regulator of inner kinetochore assembly that antagonizes the cellular STUbL pathway to protect IKPs from degradation during S phase. Here, we will briefly review the implications of our findings and present new data on how SUMOylation during S phase can control chromosome alignment in the subsequent metaphase.Key words: SUMO, kinetochore, mitosis, SENP6, CENP-H, CENP-I     

The human Mis12 complex is required for kinetochore assembly and proper chromosome segregation

During cell division, kinetochores form the primary chromosomal attachment sites for spindle microtubules. We previously identified a network of 10 interacting kinetochore proteins conserved between Caenorhabditis elegans and humans. In this study, we investigate three proteins in the human network (hDsn1Q9H410, hNnf1PMF1, and hNsl1DC31). Using coexpression in bacteria and fractionation of mitotic extracts, we demonstrate that these proteins form a stable complex with the conserved kinetochore component hMis12. Human or chicken cells depleted of Mis12 complex subunits are delayed in mitosis with misaligned chromosomes and defects in chromosome biorientation. Aligned chromosomes exhibited reduced centromere stretch and diminished kinetochore microtubule bundles. Consistent with this, localization of the outer plate constituent Ndc80HEC1 was severely reduced. The checkpoint protein BubR1, the fibrous corona component centromere protein (CENP) E, and the inner kinetochore proteins CENP-A and CENP-H also failed to accumulate to wild-type levels in depleted cells. These results indicate that a four-subunit Mis12 complex plays an essential role in chromosome segregation in vertebrates and contributes to mitotic kinetochore assembly.     

A Highlights from MBoC Selection: Slk19 clusters kinetochores and facilitates chromosome bipolar attachment

In all eukaryotic cells, DNA is packaged into multiple chromosomes that are linked to microtubules through a large protein complex called a kinetochore. Previous data show that the kinetochores are clustered together during most of the cell cycle, but the mechanism and the biological significance of kinetochore clustering are unknown. As a kinetochore protein in budding yeast, the role of Slk19 in the stability of the anaphase spindle has been well studied, but its function in chromosome segregation has remained elusive. Here we show that Slk19 is required for kinetochore clustering when yeast cells are treated with the microtubule-depolymerizing agent nocodazole. We further find that slk19Δ mutant cells exhibit delayed kinetochore capture and chromosome bipolar attachment after the disruption of the kinetochore–microtubule interaction by nocodazole, which is likely attributed to defective kinetochore clustering. In addition, we show that Slk19 interacts with itself, suggesting that the dimerization of Slk19 may mediate the interaction between kinetochores for clustering. Therefore Slk19 likely acts as kinetochore glue that clusters kinetochores to facilitate efficient and faithful chromosome segregation.     

Centromere/kinetochore localization of human centromere protein A (CENP-A) exogenously expressed as a fusion to green fluorescent protein

Three human centromere proteins, CENP-A, CENP-B and CENP-C, are a set of autoantigens specifically recognized by anticentromere antibodies often produced by patients with scleroderma. Microscopic observation has indicated that CENP-A and CENP-C localize to the inner plate of metaphase kinetochore, while CENP-B localizes to the centromere heterochromatin beneath the kinetochore. The antigenic structure, called "prekinetochore", is also present in interphase nuclei, but little is known about its molecular organization and the relative position of these antigens. Here, to visualize prekinetochore in living cells, we first obtained a stable human cell line, MDA-AF8-A2, in which human CENP-A is exogenously expressed as a fusion to a green fluorescent protein of Aequorea victoria. Simultaneous staining with anti-CENP-B and anti-CENP-C antibodies showed that the recombinant CENP-A colocalized with the endogenous CENP-C and constituted small discrete dots attaching to larger amorphous mass of CENP-B heterochromatin. When the cell growth was arrested in G1/ S phase with hydroxyurea, CENP-B heterochromatin was sometimes highly extended, while the relative location between GFP-fused CENP-A and the endogenous CENP-C was not affected. These results indicated that the fluorescent CENP-A faithfully localizes to the centromere/kinetochore throughout the cell cycle. We then obtained several mammalian cell lines where the same GFP-fused human CENP-A construct was stably expressed and their centromere/kinetochore is fluorescent throughout the cell cycle. These cell lines will further be used for visualizing the prekinetochore locus in interphase nuclei as well as analyzing kinetochore dynamics in the living cells.     

The Toxoplasma gondii kinetochore is required for centrosome association with the centrocone (spindle pole)

The kinetochore is a multi‐protein structure assembled on eukaryotic centromeres mediating chromosome attachment to spindle microtubules. Here we identified the kinetochore proteins Nuf2 and Ndc80 in the apicomplexan parasite Toxoplasma gondii. Localization revealed that kinetochores remain clustered throughout the cell cycle and colocalize with clustered centromeres at the centrocone, a structure containing the spindle pole embedded in the nuclear envelope. Pharmacological disruption of microtubules resulted in partial loss of some kinetochore and centromere clustering, indicating microtubules are necessary but not strictly required for kinetochore clustering. Generation of a TgNuf2 conditional knock‐down strain revealed it is essential for chromosome segregation, but dispensable for centromere clustering. The centromeres actually remained associated with the centrocone suggesting microtubule binding is not required for their interaction with the spindle pole. The most striking observation upon TgNuf2 depletion was that the centrosome behaved normally, but that it lost its association with the centrocone. This suggests that microtubules are essential to maintain contact between the centrosome and chromosomes, and this interaction is critical for the partitioning of the nuclei into the two daughter parasites. Finally, genetic complementation experiments with mutated TgNuf2 constructs highlighted an apicomplexan‐specific motif with a putative role in nuclear localization.     

Vertebrate kinetochore protein architecture: protein copy number

To define the molecular architecture of the kinetochore in vertebrate cells, we measured the copy number of eight kinetochore proteins that link kinetochore microtubules (MTs [kMTs]) to centromeric DNA. We used a fluorescence ratio method and chicken DT40 cell lines in which endogenous loci encoding the analyzed proteins were deleted and complemented using integrated green fluorescent protein fusion transgenes. For a mean of 4.3 kMTs at metaphase, the protein copy number per kMT is between seven and nine for members of the MT-binding KNL-1/Mis12 complex/Ndc80 complex network. It was between six and nine for four members of the constitutive centromere-associated network: centromere protein C (CENP-C), CENP-H, CENP-I, and CENP-T. The similarity in copy number per kMT for all of these proteins suggests that each MT end is linked to DNA by six to nine fibrous unit attachment modules in vertebrate cells, a conclusion that indicates architectural conservation between multiple MT-binding vertebrate and single MT-binding budding yeast kinetochores.     

Scc1/Rad21/Mcd1 is required for sister chromatid cohesion and kinetochore function in vertebrate cells.

Proteolytic cleavage of the cohesin subunit Scc1 is a consistent feature of anaphase onset, although temporal differences exist between eukaryotes in cohesin loss from chromosome arms, as distinct from centromeres. We describe the effects of genetic deletion of Scc1 in chicken DT40 cells. Scc1 loss caused premature sister chromatid separation but did not disrupt chromosome condensation. Scc1 mutants showed defective repair of spontaneous and induced DNA damage. Scc1-deficient cells frequently failed to complete metaphase chromosome alignment and showed chromosome segregation defects, suggesting aberrant kinetochore function. Notably, the chromosome passenger INCENP did not localize normally to centromeres, while the constitutive kinetochore proteins CENP-C and CENP-H behaved normally. These results suggest a role for Scc1 in mitotic regulation, along with cohesion.     

A coordinated interdependent protein circuitry stabilizes the kinetochore ensemble to protect CENP-A in the human pathogenic yeast Candida albicans

Unlike most eukaryotes, a kinetochore is fully assembled early in the cell cycle in budding yeasts Saccharomyces cerevisiae and Candida albicans. These kinetochores are clustered together throughout the cell cycle. Kinetochore assembly on point centromeres of S. cerevisiae is considered to be a step-wise process that initiates with binding of inner kinetochore proteins on specific centromere DNA sequence motifs. In contrast, kinetochore formation in C. albicans, that carries regional centromeres of 3-5 kb long, has been shown to be a sequence independent but an epigenetically regulated event. In this study, we investigated the process of kinetochore assembly/disassembly in C. albicans. Localization dependence of various kinetochore proteins studied by confocal microscopy and chromatin immunoprecipitation (ChIP) assays revealed that assembly of a kinetochore is a highly coordinated and interdependent event. Partial depletion of an essential kinetochore protein affects integrity of the kinetochore cluster. Further protein depletion results in complete collapse of the kinetochore architecture. In addition, GFP-tagged kinetochore proteins confirmed similar time-dependent disintegration upon gradual depletion of an outer kinetochore protein (Dam1). The loss of integrity of a kinetochore formed on centromeric chromatin was demonstrated by reduced binding of CENP-A and CENP-C at the centromeres. Most strikingly, Western blot analysis revealed that gradual depletion of any of these essential kinetochore proteins results in concomitant reduction in cellular protein levels of CENP-A. We further demonstrated that centromere bound CENP-A is protected from the proteosomal mediated degradation. Based on these results, we propose that a coordinated interdependent circuitry of several evolutionarily conserved essential kinetochore proteins ensures integrity of a kinetochore formed on the foundation of CENP-A containing centromeric chromatin.     

In vivo functional dissection of human inner kinetochore protein CENP-C

CENP-C is a fundamental component of the inner kinetochore plate and contributes to the formation of functional centromeres in eukaryotic organisms. Recruitment of CENP-C to kinetochore requires other centromere proteins, particularly CENP-A, CENP-H, and CENP-I. However, how CENP-C is correctly localized at the kinetochore is not clearly determined, mainly due to the functional variety of its domains, which hints at a complex recruitment mechanism. Here, by both immunofluorescent labeling and chromatin/immunoprecipitation we could show that human CENP-C contains two distinct domains, one in the central region, between amino acids 426 and 537, and the second one in the carboxyl terminal region, between amino acids 638 and 943, which are both capable of localizing at centromeres and binding alpha-satellite DNA. The presence of two domains that iterate the same function despite being significantly different in their amino acid sequence and structure suggests that CENP-C may target the centromere by establishing multiple contacts with both the DNA and protein constituents of the kinetochore.