HJURP is a CENP-A chromatin assembly factor sufficient to form a functional de novo kinetochore

Centromeres of higher eukaryotes are epigenetically marked by the centromere-specific CENP-A nucleosome. New CENP-A recruitment requires the CENP-A histone chaperone HJURP. In this paper, we show that a LacI (Lac repressor) fusion of HJURP drove the stable recruitment of CENP-A to a LacO (Lac operon) array at a noncentromeric locus. Ectopically targeted CENP-A chromatin at the LacO array was sufficient to direct the assembly of a functional centromere as indicated by the recruitment of the constitutive centromere-associated network proteins, the microtubule-binding protein NDC80, and the formation of stable kinetochore–microtubule attachments. An amino-terminal fragment of HJURP was able to assemble CENP-A nucleosomes in vitro, demonstrating that HJURP is a chromatin assembly factor. Furthermore, HJURP recruitment to endogenous centromeres required the Mis18 complex. Together, these data suggest that the role of the Mis18 complex in CENP-A deposition is to recruit HJURP and that the CENP-A nucleosome assembly activity of HJURP is responsible for centromeric chromatin assembly to maintain the epigenetic mark.     

How two become one: HJURP dimerization drives CENP‐A assembly

EMBO J 32 15, 2113–2124 doi:10.1038/emboj.2013.142; published online June142013Curr Biol 23 9, 764–769 doi:10.1016/j.cub.2013.03.037; published online May062013Curr Biol 23 9, 770–774 doi:10.1016/j.cub.2013.03.042; published online May062013CENP-A containing nucleosomes epigenetically specify centromere position on chromosomes. Deposition of CENP-A into chromatin is mediated by HJURP, a specific CENP-A chaperone. Paradoxically, HJURP binding sterically prevents dimerization of CENP-A, which is critical to form functional centromeric nucleosomes. A recent publication in The EMBO Journal (Zasadzińska et al, 2013) demonstrates that HJURP itself dimerizes through a C-terminal repeat region, which is essential for centromeric assembly of nascent CENP-A.CENP-A containing nucleosomes have a well-established role in the epigenetic specification of centromere position. However, the composition of the CENP-A nucleosome has been the subject of intense investigation and debate (as has been extensively reviewed, e.g., in Black and Cleveland, 2011). X-ray crystallography data, biochemical interaction experiments and in vivo mutational analysis provide strong evidence that CENP-A nucleosomes are octameric (CENP-A/H4/H2A/H2B)₂, analogous to their histone H3-containing counterparts (Tachiwana et al, 2011; Bassett et al, 2012). Alternatively, based primarily on AFM data and nucleosome crosslinking assays, a tetrameric CENP-A/H4/H2A/H2B ‘hemisome'' has been proposed to be present at centromeres, at least during part of the cell cycle (Dalal et al, 2007; Bui et al, 2012). Whether both nucleosome types exist under specific conditions remains an unresolved question. However, recent studies by the Maddox and Black labs have reported single-molecule fluorescence measurements of CENP-A nucleosomes and high-resolution DNA protection assays of centromeric chromatin, respectively, both of which indicate that octamers are the predominant species of CENP-A in vivo (Hasson et al, 2013; Padeganeh et al, 2013).HJURP is the centromeric histone chaperone that is responsible for timely assembly of CENP-A nucleosomes. HJURP binds to soluble CENP-A and is recruited to centromeric chromatin in early G1 phase, concurrently with nascent CENP-A (Stellfox et al, 2013). Importantly, HJURP facilitates CENP-A nucleosome formation in vitro and its transient targeting to non-centromeric chromatin is sufficient to stably deposit CENP-A at these sites in vivo (Barnhart et al, 2011). Together, these observations identify HJURP as a bona fide centromeric CENP-A histone assembly factor.However, there is an apparent discrepancy between the role of HJURP in CENP-A assembly and the octameric nature of CENP-A nucleosomes. The crystal structure of the human prenucleosomal complex clearly shows that HJURP binds to CENP-A/H4 dimers in a manner that precludes CENP-A/H4 hetero-tetramerization (Hu et al, 2011). Interestingly, however, mutational analysis of CENP-A has shown that tetramerization is crucial for centromere assembly (Bassett et al, 2012). Thus, a mechanism must exist to allow for two trimeric HJURP/CENP-A/H4 complexes to coordinately assemble a tetrameric (CENP-A/H4)₂ particle.In this issue, a study by the Foltz lab sheds light on these paradoxical observations (Zasadzińska et al, 2013). Human HJURP contains two C-terminal repeat regions (HJURP C-terminal domains; HCTD). Expression of short fragments of HJURP containing either of these was sufficient to allow for centromere targeting. However, depletion of endogenous HJURP abolished centromere targeting of the C-terminally located HCTD2 fragment, without affecting the localization of the fragment containing HCTD1. These observations suggest that HCTD1 is required for centromere targeting, while HCTD2 allows for HJURP dimerization. Indeed, the authors go on to show that the latter fragment is both necessary and sufficient to form functional dimers of HJURP. RNAi replacement experiments show that HJURP lacking the HCTD2 dimerization domain is incapable of loading nascent CENP-A into centromeres. Importantly, Zasadzińska et al (2013) demonstrate that the defect in CENP-A loading can be directly attributed to a lack of HJURP dimerization. In an elegant experiment where the HCTD2 containing domain is replaced by an unrelated dimerization domain (that of bacterial LacI), CENP-A assembly is rescued to wild-type levels (Figure 1). This indicates that dimerization of HJURP is an essential step in centromeric chromatin assembly and provides a potential mechanism for the assembly of tetrameric (CENP-A/H4)₂ structures into chromatin as precursors to octameric nucleosomes.Open in a separate windowFigure 1Human HJURP contains separate protein domains that are responsible for CENP-A/H4 binding (blue), centromere targeting (brown) and dimerization (red). Full-length HJURP containing all these domains is capable of assembling CENP-A nucleosomes at centromeres (left). Zasadzińska et al (2013) now show that HJURP lacking the dimerization domain is still able to localize to centromeres, but is unable to assemble CENP-A nucleosomes (middle). However, replacement of the HJURP dimerization domain by an exogenous dimerization domain fully rescues the capability to form CENP-A nucleosomes at centromeres (right). These findings show that HJURP dimerization is an essential feature in the process of nucleosome formation, and explain how (CENP-A/H4)₂ tetramers can be formed by a chaperone that exclusively binds to CENP-A/H4 dimers.While the composition of the HJURP complex suggests a likely mechanism for the formation of octameric nucleosomes, this poses a new challenge to the field. Future studies will be needed to dissect how the shielded HJURP-bound state of CENP-A/H4 can transition to a tetramer on DNA. Interestingly, HJURP is not the only histone chaperone that exclusively binds to histone dimers. Crystal structures of trimeric complexes of both Asf1a/H3.1/H4 (English et al, 2006) as well as DAXX/H3.3/H4 (Elsässer et al, 2012) clearly show sterical incompatibility between chaperone binding and histone tetramerization. It follows that efficient chromatin assembly requires a mode for two histone chaperones to deposit histone dimers in a coordinated fashion, e.g., through dimerization as has been shown for Nap1 (McBryant and Peersen, 2004) and now for HJURP. However, dimerization does not appear to be a universal feature for histone chaperones, as a single CAF1 chaperone is able to bind two H3/H4 dimers as well as (H3/H4)₂ tetramers (Winkler et al, 2012). Thus, while deposition of H3.1/H4 at the replication fork may be driven by the high density of pre-assembly complexes, assembly of nucleosomes containing the replacement variant H3.3, H3.1 nucleosomes at DNA damage sites, and CENP-A at the centromere would require a more active form of coordination. Histone chaperone dimerization may therefore be a common feature in the pipeline to chromatin formation.In summary, Zasadzińska et al (2013) propose a solution to a paradox in the assembly pathway of CENP-A. They show that while each HJURP molecule can exclusively bind a single CENP-A/H4 dimer, HJURP itself dimerizes, ultimately allowing for the formation of tetrameric (CENP-A/H4)₂ structures in chromatin. Interestingly, exclusive dimer binding has been observed for a number of histone chaperones, suggesting that chaperone dimerization may be a more general process in the nucleosome assembly pathway.     

Assembly in G1 phase and long-term stability are unique intrinsic features of CENP-A nucleosomes

Centromeres are the site of kinetochore formation during mitosis. Centromere protein A (CENP-A), the centromere-specific histone H3 variant, is essential for the epigenetic maintenance of centromere position. Previously we showed that newly synthesized CENP-A is targeted to centromeres exclusively during early G1 phase and is subsequently maintained across mitotic divisions. Using SNAP-based fluorescent pulse labeling, we now demonstrate that cell cycle–restricted chromatin assembly at centromeres is unique to CENP-A nucleosomes and does not involve assembly of other H3 variants. Strikingly, stable retention is restricted to the CENP-A/H4 core of the nucleosome, which we find to outlast general chromatin across several cell divisions. We further show that cell cycle timing of CENP-A assembly is independent of centromeric DNA sequences and instead is mediated by the CENP-A targeting domain. Unexpectedly, this domain also induces stable transmission of centromeric nucleosomes, independent of the CENP-A deposition factor HJURP. This demonstrates that intrinsic properties of the CENP-A protein direct its cell cycle–restricted assembly and induces quantitative mitotic transmission of the CENP-A/H4 nucleosome core, ensuring long-term stability and epigenetic maintenance of centromere position.     

Assembly of Drosophila centromeric nucleosomes requires CID dimerization

Centromeres are essential chromosomal regions required for kinetochore assembly and chromosome segregation. The composition and organization of centromeric nucleosomes containing the essential histone H3 variant CENP-A (CID in Drosophila) is a fundamental, unresolved issue. Using immunoprecipitation of CID mononucleosomes and cysteine crosslinking, we demonstrate that centromeric nucleosomes contain CID dimers in vivo. Furthermore, CID dimerization and centromeric targeting require a residue implicated in formation of the four-helix bundle, which mediates intranucleosomal H3 dimerization and nucleosome integrity. Taken together, our findings suggest that CID nucleosomes are octameric in vivo and that CID dimerization is essential for correct centromere assembly.     

CENP-C recruits M18BP1 to centromeres to promote CENP-A chromatin assembly

Eukaryotic chromosomes segregate by attaching to microtubules of the mitotic spindle through a chromosomal microtubule binding site called the kinetochore. Kinetochores assemble on a specialized chromosomal locus termed the centromere, which is characterized by the replacement of histone H3 in centromeric nucleosomes with the essential histone H3 variant CENP-A (centromere protein A). Understanding how CENP-A chromatin is assembled and maintained is central to understanding chromosome segregation mechanisms. CENP-A nucleosome assembly requires the Mis18 complex and the CENP-A chaperone HJURP. These factors localize to centromeres in telophase/G1, when new CENP-A chromatin is assembled. The mechanisms that control their targeting are unknown. In this paper, we identify a mechanism for recruiting the Mis18 complex protein M18BP1 to centromeres. We show that depletion of CENP-C prevents M18BP1 targeting to metaphase centromeres and inhibits CENP-A chromatin assembly. We find that M18BP1 directly binds CENP-C through conserved domains in the CENP-C protein. Thus, CENP-C provides a link between existing CENP-A chromatin and the proteins required for new CENP-A nucleosome assembly.     

Molecular basis for Cdk1‐regulated timing of Mis18 complex assembly and CENP‐A deposition

The centromere, a chromosomal locus that acts as a microtubule attachment site, is epigenetically specified by the enrichment of CENP‐A nucleosomes. Centromere maintenance during the cell cycle requires HJURP‐mediated CENP‐A deposition, a process regulated by the Mis18 complex (Mis18α/Mis18β/Mis18BP1). Spatial and temporal regulation of Mis18 complex assembly is crucial for its centromere association and function. Here, we provide the molecular basis for the assembly and regulation of the Mis18 complex. We show that the N‐terminal region of Mis18BP1 spanning amino acid residues 20–130 directly interacts with Mis18α/β to form the Mis18 complex. Within Mis18α/β, the Mis18α MeDiY domain can directly interact with Mis18BP1. Mis18α/β forms a hetero‐hexamer with 4 Mis18α and 2 Mis18β. However, only two copies of Mis18BP1 interact with Mis18α/β to form a hetero‐octameric assembly, highlighting the role of Mis18 oligomerization in limiting the number of Mis18BP1 within the Mis18 complex. Furthermore, we demonstrate the involvement of consensus Cdk1 phosphorylation sites on Mis18 complex assembly and thus provide a rationale for cell cycle‐regulated timing of Mis18 assembly and CENP‐A deposition.     

Structural basis for assembly of the CBF3 kinetochore complex

Eukaryotic chromosomes contain a specialised region known as the centromere, which forms the platform for kinetochore assembly and microtubule attachment. The centromere is distinguished by the presence of nucleosomes containing the histone H3 variant, CENP‐A. In budding yeast, centromere establishment begins with the recognition of a specific DNA sequence by the CBF3 complex. This in turn facilitates CENP‐A^Cse4 nucleosome deposition and kinetochore assembly. Here, we describe a 3.6 Å single‐particle cryo‐EM reconstruction of the core CBF3 complex, incorporating the sequence‐specific DNA‐binding protein Cep3 together with regulatory subunits Ctf13 and Skp1. This provides the first structural data on Ctf13, defining it as an F‐box protein of the leucine‐rich‐repeat family, and demonstrates how a novel F‐box‐mediated interaction between Ctf13 and Skp1 is responsible for initial assembly of the CBF3 complex.     

Acidic Nucleoplasmic DNA-binding Protein (And-1) Controls Chromosome Congression by Regulating the Assembly of Centromere Protein A (CENP-A) at Centromeres

The centromere is an epigenetically designated chromatin domain that is essential for the accurate segregation of chromosomes during mitosis. The incorporation of centromere protein A (CENP-A) into chromatin is fundamental in defining the centromeric loci. Newly synthesized CENP-A is loaded at centromeres in early G₁ phase by the CENP-A-specific histone chaperone Holliday junction recognition protein (HJURP) coupled with other chromatin assembly factors. However, it is unknown whether there are additional HJURP-interacting factor(s) involving in this process. Here we identify acidic nucleoplasmic DNA-binding protein 1 (And-1) as a new factor that is required for the assembly of CENP-A nucleosomes. And-1 interacts with both CENP-A and HJURP in a prenucleosomal complex, and the association of And-1 with CENP-A is increased during the cell cycle transition from mitosis to G₁ phase. And-1 down-regulation significantly compromises chromosome congression and the deposition of HJURP-CENP-A complexes at centromeres. Consistently, overexpression of And-1 enhances the assembly of CENP-A at centromeres. We conclude that And-1 is an important factor that functions together with HJURP to facilitate the cell cycle-specific recruitment of CENP-A to centromeres.     

HJURP uses distinct CENP-A surfaces to recognize and to stabilize CENP-A/histone H4 for centromere assembly

Centromeres are defined by the presence of chromatin containing the histone H3 variant, CENP-A, whose assembly into nucleosomes requires the chromatin assembly factor HJURP. We find that whereas surface-exposed residues in the CENP-A targeting domain (CATD) are the primary sequence determinants for HJURP recognition, buried CATD residues that generate rigidity with H4 are also required for efficient incorporation into centromeres. HJURP contact points adjacent to the CATD on the CENP-A surface are not used for binding specificity but rather to transmit stability broadly throughout the histone fold domains of both CENP-A and H4. Furthermore, an intact CENP-A/CENP-A interface is a requirement for stable chromatin incorporation immediately upon HJURP-mediated assembly. These data offer insight into the mechanism by which HJURP discriminates CENP-A from bulk histone complexes and chaperones CENP-A/H4 for a substantial portion of the cell cycle prior to mediating chromatin assembly at the centromere.     

Nonhistone Scm3 binds to AT-rich DNA to organize atypical centromeric nucleosome of budding yeast

The molecular architecture of centromere-specific nucleosomes containing histone variant CenH3 is controversial. We have biochemically reconstituted two distinct populations of nucleosomes containing Saccharomyces cerevisiae CenH3 (Cse4). Reconstitution of octameric nucleosomes containing histones Cse4/H4/H2A/H2B is robust on noncentromere DNA, but inefficient on AT-rich centromere DNA. However, nonhistone Scm3, which is required for Cse4 deposition in?vivo, facilitates in?vitro reconstitution of Cse4/H4/Scm3 complexes on AT-rich centromere sequences. Scm3 has a nonspecific DNA binding domain that shows preference for AT-rich DNA and a histone chaperone domain that promotes specific loading of Cse4/H4. In live cells, Scm3-GFP is enriched at centromeres in all cell cycle phases. Chromatin immunoprecipitation confirms that Scm3 occupies centromere DNA throughout the cell cycle, even when Cse4 and H4 are temporarily dislodged in S phase. These findings suggest a model in which centromere-bound Scm3 aids recruitment of Cse4/H4 to assemble and maintain an H2A/H2B-deficient centromeric nucleosome.     

Molecular underpinnings of centromere identity and maintenance

Centromeres direct faithful chromosome inheritance at cell division but are not defined by a conserved DNA sequence. Instead, a specialized form of chromatin containing the histone H3 variant, CENP-A, epigenetically specifies centromere location. We discuss current models where CENP-A serves as the marker for the centromere during the entire cell cycle in addition to generating the foundational chromatin for the kinetochore in mitosis. Recent elegant experiments have indicated that engineered arrays of CENP-A-containing nucleosomes are sufficient to serve as the site of kinetochore formation and for seeding centromeric chromatin that self-propagates through cell generations. Finally, recent structural and dynamic studies of CENP-A-containing histone complexes - before and after assembly into nucleosomes - provide models to explain underlying molecular mechanisms at the centromere.     

Posttranslational modifications of CENP-A: marks of distinction

Centromeres are specialized chromosome domain that serve as the site for kinetochore assembly and microtubule attachment during cell division, to ensure proper segregation of chromosomes. In higher eukaryotes, the identity of active centromeres is marked by the presence of CENP-A (centromeric protein-A), a histone H3 variant. CENP-A forms a centromere-specific nucleosome that acts as a foundation for centromere assembly and function. The posttranslational modification (PTM) of histone proteins is a major mechanism regulating the function of chromatin. While a few CENP-A site-specific modifications are shared with histone H3, the majority are specific to CENP-A-containing nucleosomes, indicating that modification of these residues contribute to centromere-specific function. CENP-A undergoes posttranslational modifications including phosphorylation, acetylation, methylation, and ubiquitylation. Work from many laboratories have uncovered the importance of these CENP-A modifications in its deposition at centromeres, protein stability, and recruitment of the CCAN (constitutive centromere-associated network). Here, we discuss the PTMs of CENP-A and their biological relevance.     

Scm3 is a centromeric nucleosome assembly factor

The Cse4 nucleosome at each budding yeast centromere must be faithfully assembled each cell cycle to specify the site of kinetochore assembly and microtubule attachment for chromosome segregation. Although Scm3 is required for the localization of the centromeric H3 histone variant Cse4 to centromeres, its role in nucleosome assembly has not been tested. We demonstrate that Scm3 is able to mediate the assembly of Cse4 nucleosomes in vitro, but not H3 nucleosomes, as measured by a supercoiling assay. Localization of Cse4 to centromeres and the assembly activity depend on an evolutionarily conserved core motif in Scm3, but localization of the CBF3 subunit Ndc10 to centromeres does not depend on this motif. The centromere targeting domain of Cse4 is sufficient for Scm3 nucleosome assembly activity. Assembly does not depend on centromeric sequence. We propose that Scm3 plays an active role in centromeric nucleosome assembly.     

Critical histone post-translational modifications for centromere function and propagation

The centromere is a critical genomic region that enables faithful chromosome segregation during mitosis, and must be distinguishable from other genomic regions to facilitate establishment of the kinetochore. The centromere-specific histone H3-variant CENP-A forms a special nucleosome that functions as a marker for centromere specification. In addition to the CENP-A nucleosomes, there are additional H3 nucleosomes that have been identified in centromeres, both of which are predicted to exhibit specific features. It is likely that the composite organization of CENP-A and H3 nucleosomes contributes to the formation of centromere-specific chromatin, termed ‘centrochromatin’. Recent studies suggest that centrochromatin has specific histone modifications that mediate centromere specification and kinetochore assembly. We use chicken non-repetitive centromeres as a model of centromeric activities to characterize functional features of centrochromatin. This review discusses our recent progress, and that of various other research groups, in elucidating the functional roles of histone modifications in centrochromatin.     

The unconventional structure of centromeric nucleosomes

The centromere is a defining feature of the eukaryotic chromosome, required for attachment to spindle microtubules and segregation to the poles at both mitosis and meiosis. The fundamental unit of centromere identity is the centromere-specific nucleosome, in which the centromeric histone 3 (cenH3) variant takes the place of H3. The structure of the cenH3 nucleosome has been the subject of controversy, as mutually exclusive models have been proposed, including conventional and unconventional left-handed octamers (octasomes), hexamers with non-histone protein constituents, and right-handed heterotypic tetramers (hemisomes). Hemisomes have been isolated from native centromeric chromatin, but traditional nucleosome assembly protocols have generally yielded partially unwrapped left-handed octameric nucleosomes. In budding yeast, topology analysis and high-resolution mapping has revealed that a single right-handed cenH3 hemisome occupies the ~80-bp Centromere DNA Element II (CDEII) of each chromosome. Overproduction of cenH3 leads to promiscuous low-level incorporation of octasome-sized particles throughout the yeast genome. We propose that the right-handed cenH3 hemisome is the universal unit of centromeric chromatin, and that the inherent instability of partially unwrapped left-handed cenH3 octamers is an adaptation to prevent formation of neocentromeres on chromosome arms.     

着丝粒核小体结构研究进展

着丝粒是构成真核生物染色体的必需元件。在细胞有丝分裂或减数分裂时,微管通过动粒与染色体着丝粒连接,参与细胞分裂的染色体分离与分配过程,使染色体平均分配到子细胞中。构成着丝粒的基本单位是着丝粒特异的核小体,与常规核小体不同的是着丝粒核小体中的组蛋白H3被其变种——着丝粒组蛋白H3所替换。最近几年,着丝粒核小体的结构成为细胞生物学研究的热点之一。该文综述了最近在多种真核生物研究中,通过体外和体内实验,提出的着丝粒核小体结构的八聚体、六聚体、同型四聚体以及半八聚体模型,并对着丝粒核小体结构的动态模型与功能的关系进行了探讨。     

Tetrameric structure of centromeric nucleosomes in interphase Drosophila cells

Centromeres, the specialized chromatin structures that are responsible for equal segregation of chromosomes at mitosis, are epigenetically maintained by a centromere-specific histone H3 variant (CenH3). However, the mechanistic basis for centromere maintenance is unknown. We investigated biochemical properties of CenH3 nucleosomes from Drosophila melanogaster cells. Cross-linking of CenH3 nucleosomes identifies heterotypic tetramers containing one copy of CenH3, H2A, H2B, and H4 each. Interphase CenH3 particles display a stable association of approximately 120 DNA base pairs. Purified centromeric nucleosomal arrays have typical “beads-on-a-string” appearance by electron microscopy but appear to resist condensation under physiological conditions. Atomic force microscopy reveals that native CenH3-containing nucleosomes are only half as high as canonical octameric nucleosomes are, confirming that the tetrameric structure detected by cross-linking comprises the entire interphase nucleosome particle. This demonstration of stable half-nucleosomes in vivo provides a possible basis for the instability of centromeric nucleosomes that are deposited in euchromatic regions, which might help maintain centromere identity.     

Tetrameric Structure of Centromeric Nucleosomes in Interphase Drosophila Cells

Centromeres, the specialized chromatin structures that are responsible for equal segregation of chromosomes at mitosis, are epigenetically maintained by a centromere-specific histone H3 variant (CenH3). However, the mechanistic basis for centromere maintenance is unknown. We investigated biochemical properties of CenH3 nucleosomes from Drosophila melanogaster cells. Cross-linking of CenH3 nucleosomes identifies heterotypic tetramers containing one copy of CenH3, H2A, H2B, and H4 each. Interphase CenH3 particles display a stable association of approximately 120 DNA base pairs. Purified centromeric nucleosomal arrays have typical “beads-on-a-string” appearance by electron microscopy but appear to resist condensation under physiological conditions. Atomic force microscopy reveals that native CenH3-containing nucleosomes are only half as high as canonical octameric nucleosomes are, confirming that the tetrameric structure detected by cross-linking comprises the entire interphase nucleosome particle. This demonstration of stable half-nucleosomes in vivo provides a possible basis for the instability of centromeric nucleosomes that are deposited in euchromatic regions, which might help maintain centromere identity.     

Premitotic assembly of human CENPs -T and -W switches centromeric chromatin to a mitotic state

Centromeres are differentiated chromatin domains, present once per chromosome, that direct segregation of the genome in mitosis and meiosis by specifying assembly of the kinetochore. They are distinct genetic loci in that their identity in most organisms is determined not by the DNA sequences they are associated with, but through specific chromatin composition and context. The core nucleosomal protein CENP-A/cenH3 plays a primary role in centromere determination in all species and directs assembly of a large complex of associated proteins in vertebrates. While CENP-A itself is stably transmitted from one generation to the next, the nature of the template for centromere replication and its relationship to kinetochore function are as yet poorly understood. Here, we investigate the assembly and inheritance of a histone fold complex of the centromere, the CENP-T/W complex, which is integrated with centromeric chromatin in association with canonical histone H3 nucleosomes. We have investigated the cell cycle regulation, timing of assembly, generational persistence, and requirement for function of CENPs -T and -W in the cell cycle in human cells. The CENP-T/W complex assembles through a dynamic exchange mechanism in late S-phase and G2, is required for mitosis in each cell cycle and does not persist across cell generations, properties reciprocal to those measured for CENP-A. We propose that the CENP-A and H3-CENP-T/W nucleosome components of the centromere are specialized for centromeric and kinetochore activities, respectively. Segregation of the assembly mechanisms for the two allows the cell to switch between chromatin configurations that reciprocally support the replication of the centromere and its conversion to a mitotic state on postreplicative chromatin.     

Histone H3 localizes to the centromeric DNA in budding yeast

During cell division, segregation of sister chromatids to daughter cells is achieved by the poleward pulling force of microtubules, which attach to the chromatids by means of a multiprotein complex, the kinetochore. Kinetochores assemble at the centromeric DNA organized by specialized centromeric nucleosomes. In contrast to other eukaryotes, which typically have large repetitive centromeric regions, budding yeast CEN DNA is defined by a 125 bp sequence and assembles a single centromeric nucleosome. In budding yeast, as well as in other eukaryotes, the Cse4 histone variant (known in vertebrates as CENP-A) is believed to substitute for histone H3 at the centromeric nucleosome. However, the exact composition of the CEN nucleosome remains a subject of debate. We report the use of a novel ChIP approach to reveal the composition of the centromeric nucleosome and its localization on CEN DNA in budding yeast. Surprisingly, we observed a strong interaction of H3, as well as Cse4, H4, H2A, and H2B, but not histone chaperone Scm3 (HJURP in human) with the centromeric DNA. H3 localizes to centromeric DNA at all stages of the cell cycle. Using a sequential ChIP approach, we could demonstrate the co-occupancy of H3 and Cse4 at the CEN DNA. Our results favor a H3-Cse4 heterotypic octamer at the budding yeast centromere. Whether or not our model is correct, any future model will have to account for the stable association of histone H3 with the centromeric DNA.