CENP-B: a major human centromere protein located beneath the kinetochore

The family of three structurally related autoantigens CENP-A (17 kD), CENP-B (80 kD), and CENP-C (140 kD) are the best characterized components of the human centromere, and they have been widely assumed to be components of the kinetochore. Kinetochore components are currently of great interest since this structure, which has long been known to be the site of microtubule attachment to the chromosome, is now believed to be a site of force production for anaphase chromosome movement. In the present study we have mapped the distribution of CENP-B in mitotic chromosomes by immunoelectron microscopy using two monospecific polyclonal antibodies together with a newly developed series of ultra-small 1-nm colloidal gold probes. We were surprised to find that greater than 95% of CENP-B is distributed throughout the centromeric heterochromatin beneath the kinetochore. This strongly supports other emerging evidence that CENP-B is specifically associated with alpha-satellite heterochromatin. Although in certain instances CENP-B can be seen to be concentrated immediately adjacent to the lower surface of the kinetochore, the outer plate remains virtually unlabeled. Similar analysis with a human autoimmune serum that recognizes all three CENP antigens reveals an additional unsuspected feature of kinetochore structure. In addition to recognizing antigens in the centromeric heterochromatin, the autoantiserum recognizes a concentration of antigens lateral to the kinetochore. This difference in staining pattern may reflect the presence of a "collar" of chromatin rich in CENP-C and/or CENP-A encircling the kinetochore plates.     

Microinjection of antibodies to centromere protein CENP-A arrests cells in interphase but does not prevent mitosis

Centromere protein CENP-A is a histone H3-like protein associated specifically with the centromere and represents one of the human autoantigens identified by sera taken from patients with the CREST variant of progressive systemic sclerosis. Injection of whole human autoimmune serum to the centromere into interphase cells disrupts some mitotic events. It has been assumed that this effect is due to CENP-E and CENP-C autoantigens, because of the effects of injecting monospecific sera to those proteins into culture cells. Here we have used an antibody raised against an N-terminal peptide of the human autoantigen CENP-A to determine its function in mitosis and during cell cycle progression. Affinity-purified anti-CENP-A antibodies injected into the nucleus during the early replication stages of the cell cycle caused cells to arrest in interphase before mitosis. These cells showed highly condensed small nuclei, a granular cytoplasm and loss of their division capability. On the other hand, microinjection of nocodazole-blocked HeLa cells in mitosis resulted in the typical punctate staining pattern of CENP-A for centromeres during different stages of mitosis and apparently normal cell division. This was corroborated by time-lapse imaging microscopy analysis of mid-interphase-injected cells, revealing that they undergo mitosis and divide properly. However, a significant delay throughout the progression of mitotic stages was observed. These results suggest that CENP-A is involved predominantly in an essential interphase event at the centromere before mitosis. This may include chromatin assembly at the kinetochore coordinate with late replication of satellite DNA to form an active centromere. Received: 3 August 1998 / Accepted: 18 September 1998     

CENP-E, a novel human centromere-associated protein required for progression from metaphase to anaphase.

We have identified a novel human centromere-associated protein by preparing monoclonal antibodies against a fraction of HeLa chromosome scaffold proteins enriched for centromere/kinetochore components. One monoclonal antibody (mAb177) specifically stains the centromere region of mitotic human chromosomes and binds to a novel, approximately 250-300 kd chromosome scaffold associated protein named CENP-E. In cells progressing through different parts of the cell cycle, the localization of CENP-E differed markedly from that observed for the previously identified centromere proteins CENP-A, CENP-B, CENP-C and CENP-D. In contrast to these antigens, no mAb177 staining is detected during interphase, and staining first appears at the centromere region of chromosomes during prometaphase. This association with chromosomes remains throughout metaphase but is redistributed to the midplate at or just after the onset of anaphase. By telophase, the staining is localized exclusively to the midbody. Microinjection of the mAb177 into metaphase cells blocks or significantly delays progression into anaphase, although the morphology of the spindle and the configuration of the metaphase chromosomes appear normal in these metaphase arrested cells. This demonstrates that CENP-E function is required for the transition from metaphase to anaphase.     

CENP-A, -B, and -C chromatin complex that contains the I-type alpha-satellite array constitutes the prekinetochore in HeLa cells

CENP-A is a component of centromeric chromatin and defines active centromere regions by forming centromere-specific nucleosomes. We have isolated centromeric chromatin containing the CENP-A nucleosome, CENP-B, and CENP-C from HeLa cells using anti-CENP-A and/or anti-CENP-C antibodies and shown that the CENP-A/B/C complex is predominantly formed on alpha-satellite DNA that contains the CENP-B box (alphaI-type array). Mapping of hypersensitive sites for micrococcal nuclease (MNase) digestion indicated that CENP-A nucleosomes were phased on the alphaI-type array as a result of interactions between CENP-B and CENP-B boxes, implying a repetitive configuration for the CENP-B/CENP-A nucleosome complex. Molecular mass analysis by glycerol gradient sedimentation showed that MNase digestion released a CENP-A/B/C chromatin complex of three to four nucleosomes into the soluble fraction, suggesting that CENP-C is a component of the repetitive CENP-B/CENP-A nucleosome complex. Quantitative analysis by immunodepletion of CENP-A nucleosomes showed that most of the CENP-C and approximately half the CENP-B took part in formation of the CENP-A/B/C chromatin complex. A kinetic study of the solubilization of CENPs showed that MNase digestion first released the CENP-A/B/C chromatin complex into the soluble fraction, and later removed CENP-B and CENP-C from the complex. This result suggests that CENP-A nucleosomes form a complex with CENP-B and CENP-C through interaction with DNA. On the basis of these results, we propose that the CENP-A/B/C chromatin complex is selectively formed on the I-type alpha-satellite array and constitutes the prekinetochore in HeLa cells.     

CENP-B interacts with CENP-C domains containing Mif2 regions responsible for centromere localization

Recently, human artificial chromosomes featuring functional centromeres have been generated efficiently from naked synthetic alphoid DNA containing CENP-B boxes as a de novo mechanism in a human cultured cell line, but not from the synthetic alphoid DNA only containing mutations within CENP-B boxes, indicating that CENP-B has some functions in assembling centromere/kinetochore components on alphoid DNA. To investigate whether any interactions exist between CENP-B and the other centromere proteins, we screened a cDNA library by yeast two-hybrid analysis. An interaction between CENP-B and CENP-C was detected, and the CENP-C domains required were determined to overlap with three Mif2 homologous regions, which were also revealed to be involved in the CENP-C assembly of centromeres by expression of truncated polypeptides in cultured cells. Overproduction of truncated CENP-B containing no CENP-C interaction domains caused abnormal duplication of CENP-C domains at G2 and cell cycle delay at metaphase. These results suggest that the interaction between CENP-B and CENP-C may be involved in the correct assembly of CENP-C on alphoid DNA. In other words, a possible molecular linkage may exist between one of the kinetochore components and human centromere DNA through CENP-B/CENP-B box interaction.     

Injection of anticentromere antibodies in interphase disrupts events required for chromosome movement at mitosis

We have used autoantibodies to probe the function of three human centromere proteins in mitosis. These antibodies recognize three human polypeptides in immunoblots: CENP-A (17 kD), CENP-B (80 kD), and CENP-C (140 kD). Purified anticentromere antibodies (ACA-IgG) disrupt mitosis when introduced into tissue culture cells during interphase. We have identified two execution points for antibody inhibition. Antibodies injected into the nucleus greater than or equal to 3 h before mitosis prevent the chromosomes from undergoing normal prometaphase movements in the subsequent mitosis. Antibodies injected in the nucleus during late G2 cause cells to arrest in metaphase. Surprisingly, antibodies introduced subsequent to the beginning of prophase do not block mitosis. These results suggest that the CENP antigens are involved in two essential interphase events that are required for centromere action in mitosis. These may include centromere assembly coordinate with the replication of alpha-satellite DNA at the end of S phase and the structural maturation of the kinetochore that begins at prophase.     

Building the centromere: from foundation proteins to 3D organization

At each mitosis, accurate segregation of every chromosome is ensured by the assembly of a kinetochore at each centromeric locus. Six foundation kinetochore proteins that assemble hierarchically and co-dependently have been identified in vertebrates. CENP-A, Mis12, CENP-C, CENP-H and CENP-I localize to a core domain of centromeric chromatin. The sixth protein, CENP-B, although not essential in higher eukaryotes, has homologues in fission yeast that bind pericentric DNA and are essential for heterochromatin formation. Foundation kinetochore proteins have various roles and mutual interactions, and their associations with centromeric DNA and heterochromatin create structural domains that support the different functions of the centromere. Advances in molecular and microscopic techniques, coupled with rare centromere variants, have enabled us to gain fresh insights into the linear and 3D organization of centromeric chromatin.     

The Elusive Structure of Centro-Chromatin: Molecular Order or Dynamic Heterogenetity?

The centromere is an essential chromatin domain required for kinetochore recruitment and chromosome segregation in eukaryotes. To perform this role, centro-chromatin adopts a unique structure that provides access to kinetochore proteins and maintains stability under tension during mitosis. This is achieved by the presence of nucleosomes containing the H3 variant CENP-A, which also acts as the epigenetic mark defining the centromere. In this review, we discuss the role of CENP-A on the structure and dynamics of centromeric chromatin. We further discuss the impact of the CENP-A binding proteins CENP-C, CENP-N, and CENP-B on modulating centro-chromatin structure. Based on these findings we provide an overview of the higher order structure of the centromere.     

Identification of novel centromere/kinetochore-associated proteins using monoclonal antibodies generated against human mitotic chromosome scaffolds

We describe the generation of 11 monoclonal antibodies that bind to the centromere/kinetochore region of human mitotic chromosomes. These antibodies were raised against mitotic chromosome scaffolds and screened for centromere/kinetochore binding by indirect immunofluorescence against purified chromosomes. Immunoblot analyses with these antibodies revealed that all of the antigens are greater than 200 kD and are components of nuclei, chromosomes, and/or chromosome scaffolds. Comparison of the immunolocalization of the antigens with that observed for the centromere-associated protein CENP-B revealed that each of these centromere/kinetochore proteins lies more peripherally to the DNA than does CENP-B. In cells normally progressing through the cell cycle, these antigens displayed four distinct patterns of centromere/kinetochore association, corresponding to a minimum of four novel centromere/kinetochore-associated proteins.     

Visualization of centromere proteins CENP-B and CENP-C on a stable dicentric chromosome in cytological spreads

We have screened for the presence of two centromere autoantigens, CENP-B (80 kDa) and CENP-C (140 kDa) at the inactive centromere of a naturally occurring stable dicentric chromosome using specific antibodies that do not cross-react with any other chromosomal proteins. In order to discriminate between the active and inactive centromeres on this chromosome we have developed a modification of the standard methanol/acetic acid fixation procedure that allows us to obtain high-quality cytological spreads that retain antigenicity with the anti-centromere antibodies. We have noted three differences in the immunostaining patterns with specific anti-CENP-B and CENP-C antibodies. (1) The amount of detectable CENP-B varies from chromosome to chromosome. The amount of CENPC appears to be more or less the same on all chromosomes. (2) CENP-B is present at both active and inactive centromeres of stable dicentric autosomes. CENP-C is not detectable at the inactive centromeres. (3) While immunofluorescence with anti-CENP-C antibodies typically gives two discrete spots, staining with anti-CENP-B often appears as a single bright bar connecting both sister centromeres. This suggests that while CENP-C may be confined to the outer centromere in the kinetochore region, CENP-B may be distributed throughout the entire centromere. Our data suggest that CENP-C is likely to be a component of some invariant chromosomal substructure, such as the kinetochore. CENPB may be involved in some other aspect of centromere function, such as chromosome movement or DNA packaging.Abbreviations CENP centromere protein     

Incorporation of Drosophila CID/CENP-A and CENP-C into centromeres during early embryonic anaphase

The centromere/kinetochore complex is indispensable for accurate segregation of chromosomes during cell divisions when it serves as the attachment site for spindle microtubules. Centromere identity in metazoans is believed to be governed by epigenetic mechanisms, because the highly repetitive centromeric DNA is neither sufficient nor required for specifying the assembly site of the kinetochore. A candidate for an epigenetic mark is the centromere-specific histone H3 variant CENP-A that replaces H3 in alternating blocks of chromatin exclusively in active centromeres. CENP-A acts as an initiator of kinetochore assembly, but the detailed dynamics of the deposition of metazoan CENP-A and of other constitutive kinetochore components are largely unknown. Here we show by quantitative fluorescence measurements in living early embryos that functional fluorescent fusion proteins of the Drosophila CENP-A and CENP-C homologs are rapidly incorporated into centromeres during anaphase. This incorporation is independent of ongoing DNA synthesis and pulling forces generated by the mitotic spindle, but strictly coupled to mitotic progression. Thus, our findings uncover a strikingly dynamic behavior of centromere components in anaphase.     

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.     

Human centromere chromatin protein hMis12, essential for equal segregation,is independent of CENP-A loading pathway

Kinetochores are the chromosomal sites for spindle interaction and play a vital role for chromosome segregation. The composition of kinetochore proteins and their cellular roles are, however, poorly understood in higher eukaryotes. We identified a novel kinetochore protein family conserved from yeast to human that is essential for equal chromosome segregation. The human homologue hMis12 of yeast spMis12/scMtw1 retains conserved sequence features and locates at the kinetochore region indistinguishable from CENP-A, a centromeric histone variant. RNA interference (RNAi) analysis of HeLa cells shows that the reduced hMis12 results in misaligned metaphase chromosomes, lagging anaphase chromosomes, and interphase micronuclei without mitotic delay, while CENP-A is located at kinetochores. Further, the metaphase spindle length is abnormally extended. Spindle checkpoint protein hMad2 temporally localizes at kinetochores at early mitotic stages after RNAi. The RNAi deficiency of CENP-A leads to a similar mitotic phenotype, but the kinetochore signals of other kinetochore proteins, hMis6 and CENP-C, are greatly diminished. RNAi for hMis6, like that of a kinetochore kinesin CENP-E, induces mitotic arrest. Kinetochore localization of hMis12 is unaffected by CENP-A RNAi, demonstrating an independent pathway of CENP-A in human kinetochores.     

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.     

The CCAN recruits CENP-A to the centromere and forms the structural core for kinetochore assembly

CENP-A acts as an important epigenetic marker for kinetochore specification. However, the mechanisms by which CENP-A is incorporated into centromeres and the structural basis for kinetochore formation downstream of CENP-A remain unclear. Here, we used a unique chromosome-engineering system in which kinetochore proteins are targeted to a noncentromeric site after the endogenous centromere is conditionally removed. Using this system, we created two distinct types of engineered kinetochores, both of which were stably maintained in chicken DT40 cells. Ectopic targeting of full-length HJURP, CENP-C, CENP-I, or the CENP-C C terminus generated engineered kinetochores containing major kinetochore components, including CENP-A. In contrast, ectopic targeting of the CENP-T or CENP-C N terminus generated functional kinetochores that recruit the microtubule-binding Ndc80 complex and chromosome passenger complex (CPC), but lack CENP-A and most constitutive centromere-associated network (CCAN) proteins. Based on the analysis of these different engineered kinetochores, we conclude that the CCAN has two distinct roles: recruiting CENP-A to establish the kinetochore and serving as a structural core to directly recruit kinetochore proteins.     

Induced ectopic kinetochore assembly bypasses the requirement for CENP-A nucleosomes

Accurate chromosome segregation requires assembly of the multiprotein kinetochore complex at centromeres. Although prior work identified the centromeric histone H3-variant CENP-A as the important upstream factor necessary for centromere specification, in human cells CENP-A is not sufficient for kinetochore assembly. Here, we demonstrate that two constitutive DNA-binding kinetochore components, CENP-C and CENP-T, function to direct kinetochore formation. Replacing the DNA-binding regions of CENP-C and CENP-T with alternate chromosome-targeting domains recruits these proteins to ectopic loci, resulting in CENP-A-independent kinetochore assembly. These ectopic kinetochore-like foci are functional based on the stoichiometric assembly of multiple kinetochore components, including the microtubule-binding KMN network, the presence of microtubule attachments, the microtubule-sensitive recruitment of the spindle checkpoint protein Mad2, and the segregation behavior of foci-containing chromosomes. We additionally find that CENP-T phosphorylation regulates the mitotic assembly of both endogenous and ectopic kinetochores. Thus, CENP-C and CENP-T form a critical regulated platform for vertebrate kinetochore assembly.     

Centromere Architecture Breakdown Induced by the Viral E3 Ubiquitin Ligase ICP0 Protein of Herpes Simplex Virus Type 1

The viral E3 ubiquitin ligase ICP0 protein has the unique property to temporarily localize at interphase and mitotic centromeres early after infection of cells by the herpes simplex virus type 1 (HSV-1). As a consequence ICP0 induces the proteasomal degradation of several centromeric proteins (CENPs), namely CENP-A, the centromeric histone H3 variant, CENP-B and CENP-C. Following ICP0-induced centromere modification cells trigger a specific response to centromeres called interphase Centromere Damage Response (iCDR). The biological significance of the iCDR is unknown; so is the degree of centromere structural damage induced by ICP0. Interphase centromeres are complex structures made of proximal and distal protein layers closely associated to CENP-A-containing centromeric chromatin. Using several cell lines constitutively expressing GFP-tagged CENPs, we investigated the extent of the centromere destabilization induced by ICP0. We show that ICP0 provokes the disappearance from centromeres, and the proteasomal degradation of several CENPs from the NAC (CENP-A nucleosome associated) and CAD (CENP-A Distal) complexes. We then investigated the nucleosomal occupancy of the centromeric chromatin in ICP0-expressing cells by micrococcal nuclease (MNase) digestion analysis. ICP0 expression either following infection or in cell lines constitutively expressing ICP0 provokes significant modifications of the centromeric chromatin structure resulting in higher MNase accessibility. Finally, using human artificial chromosomes (HACs), we established that ICP0-induced iCDR could also target exogenous centromeres. These results demonstrate that, in addition to the protein complexes, ICP0 also destabilizes the centromeric chromatin resulting in the complete breakdown of the centromere architecture, which consequently induces iCDR.