Centromere formation: from epigenetics to self-assembly

This review is part of the Chromosome segregation and Aneuploidy series that focuses on the importance of chromosome segregation mechanisms in maintaining genome stability. Centromeres are specialized chromosomal domains that serve as the foundation for the mitotic kinetochore, the interaction site between the chromosome and the mitotic spindle. The chromatin of centromeres is distinguished from other chromosomal loci by the unique incorporation of the centromeric histone H3 variant, centromere protein A. Here, we review the genetic and epigenetic factors that control the formation and maintenance of centromeric chromatin and propose a chromatin self-assembly model for organizing the higher-order structure of the centromere.     

Epigenetic specification of centromeres by CENP-A

Centromeres are the chromosomal loci that direct the formation of the kinetochores. These macromolecular assemblies mediate the interaction between chromosomes and spindle microtubules and thereby power chromosome movement during cell division. They are also the sites of extensive regulation of the chromosome segregation process. Except in the case of budding yeast, centromere identity does not rely on DNA sequence but on the presence of a special nucleosome that contains a histone H3 variant known as CenH3 or CENP-A (Centromere Protein A). It has been therefore proposed that CENP-A is the epigenetic mark of the centromere. Upon DNA replication the mark is diluted two-fold and must be replenished to maintain centromere identity. What distinguishes CENP-A nucleosomes from those containing histone H3, how CENP-A nucleosomes are incorporated specifically into centromeric chromatin, and how this incorporation is coordinated with other cell cycle events are key issues that have been the focus of intensive research over the last decade. Here we review some of the highlights of this research.     

组蛋白变异体H2A.Z的研究进展

H2A.Z是组蛋白H2A的变异体之一,是高度保守的组蛋白变异体,参与保护常染色体,防止形成异染色质;并且与转录调节、抗沉默、沉默和基因组稳定性有关。组蛋白变异体H2A.Z可能与染色体形成独立的结构域,从而调节染色质结构功能。但是,H2A.Z对染色体结构功能的作用机制还不是很清楚。组蛋白变异体H2A.Z和它的表观遗传修饰对染色体动态结构和功能起重要的作用。该文将对组蛋白变异体H2A.Z进行综述。     

A network of players in H3 histone variant deposition and maintenance at centromeres

Centromeres are key chromosomal landmarks important for chromosome segregation and are characterized by distinct chromatin features. The centromeric histone H3 variant, referred to as CENP-A or CenH3^CENP-A in mammals, has emerged as a key determinant for centromeric structure, function and epigenetic inheritance. To regulate the correct incorporation and maintenance of histones at this locus, the cell employs an intricate network of molecular players, among which histone chaperones and chromatin remodelling factors have been identified over the past years. The mammalian centromere-specific chaperone HJURP represents an interesting paradigm to understand the functioning of this network. This review highlights and discusses the latest findings on centromeric histone H3 variant deposition and regulation to delineate the current view on centromere establishment, maintenance and propagation throughout the cell cycle. This article is part of a Special Issue entitled: Chromatin and epigenetic regulation of animal development.     

Histone Variant H2A.Z Regulates Centromere Silencing and Chromosome Segregation in Fission Yeast

The incorporation of histone variant H2A.Z into nucleosomes plays essential roles in regulating chromatin structure and gene expression. A multisubunit complex containing chromatin remodeling protein Swr1 is responsible for the deposition of H2A.Z in budding yeast and mammals. Here, we show that the JmjC domain protein Msc1 is a novel component of the fission yeast Swr1 complex and is required for Swr1-mediated incorporation of H2A.Z into nucleosomes at gene promoters. Loss of Msc1, Swr1, or H2A.Z results in loss of silencing at centromeres and defective chromosome segregation, although centromeric levels of CENP-A, a centromere-specific histone H3 variant that is required for setting up the chromatin structure at centromeres, remain unchanged. Intriguingly, H2A.Z is required for the expression of another centromere protein, CENP-C, and overexpression of CENP-C rescues centromere silencing defects associated with H2A.Z loss. These results demonstrate the importance of H2A.Z and CENP-C in maintaining a silenced chromatin state at centromeres.     

Centromeric chromatin exhibits a histone modification pattern that is distinct from both euchromatin and heterochromatin

Post-translational histone modifications regulate epigenetic switching between different chromatin states. Distinct histone modifications, such as acetylation, methylation and phosphorylation, define different functional chromatin domains, and often do so in a combinatorial fashion. The centromere is a unique chromosomal locus that mediates multiple segregation functions, including kinetochore formation, spindle-mediated movements, sister cohesion and a mitotic checkpoint. Centromeric (CEN) chromatin is embedded in heterochromatin and contains blocks of histone H3 nucleosomes interspersed with blocks of CENP-A nucleosomes, the histone H3 variant that provides a structural and functional foundation for the kinetochore. Here, we demonstrate that the spectrum of histone modifications present in human and Drosophila melanogaster CEN chromatin is distinct from that of both euchromatin and flanking heterochromatin. We speculate that this distinct modification pattern contributes to the unique domain organization and three-dimensional structure of centromeric regions, and/or to the epigenetic information that determines centromere identity.     

Human CENP-A contains a histone H3 related histone fold domain that is required for targeting to the centromere

Centromeres are the differentiated chromosomal domains that specify the mitotic behavior of chromosomes. To examine the molecular basis for the specification of centromeric chromatin, we have cloned a human cDNA that encodes the 17-kD histone-like centromere antigen, CENP-A. Two domains are evident in the 140 aa CENP-A polypeptide: a unique NH2- terminal domain and a 93-amino acid COOH-terminal domain that shares 62% identity with nucleosomal core protein, histone H3. An epitope tagged derivative of CENP-A was faithfully targeted to centromeres when expressed in a variety of animal cells and this targeting activity was shown to reside in the histone-like COOH-terminal domain of CENP-A. These data clearly indicate that the assembly of centromeres is driven, at least in part, by the incorporation of a novel core histone into centromeric chromatin.     

Focus on the centre: the role of chromatin on the regulation of centromere identity and function

The centromere is a specialised chromosomal structure that regulates faithful chromosome segregation during cell division, as it dictates the site of assembly of the kinetochore, a critical structure that mediates binding of chromosomes to the spindle, monitors bipolar attachment and pulls chromosomes to the poles during anaphase. Identified more than a century ago as the primary constriction of condensed metaphase chromosomes, the centromere remained elusive to molecular characterisation for many years owed to its unusual enrichment in highly repetitive satellite DNA sequences, except in budding yeast. In the last decade, our understanding of centromere structure, organisation and function has increased tremendously. Nowadays, we know that centromere identity is determined epigenetically by the formation of a unique type of chromatin, which is characterised by the presence of the centromere‐specific histone H3 variant CenH3, originally called CENP‐A, which replaces canonical histone H3 at centromeres. CenH3‐chromatin constitutes the physical and functional foundation for kinetochore assembly. This review explores recent studies addressing the structural and functional characterisation of CenH3‐chromatin, its assembly and propagation during mitosis, and its contribution to kinetochore assembly.     

How to build a centromere: from centromeric and pericentromeric chromatin to kinetochore assembly.

The assembly of the centromere, a specialized region of DNA along with a constitutive protein complex which resides at the primary constriction and is the site of kinetochore formation, has been puzzling biologists for many years. Recent advances in the fields of chromatin, microscopy, and proteomics have shed a new light on this complex and essential process. Here we review recently discovered mechanisms and proteins involved in determining mammalian centromere location and assembly. The centromeric core protein CENP-A, a histone H3 variant, is hypothesized to designate centromere localization by incorporation into centromere-specific nucleosomes and is essential for the formation of a functional kinetochore. It has been found that centromere localization of centromere protein A (CENP-A), and therefore centromere determination, requires proteins involved in histone deacetylation, as well as base excision DNA repair pathways and proteolysis. In addition to the incorporation of CENP-A at the centromere, the formation of heterochromatin through histone methylation and RNA interference is also crucial for centromere formation. The assembly of the centromere and kinetochore is complex and interdependent, involving epigenetics and hierarchical protein-protein interactions.     

Histone-histone interactions and centromere function

Cse4p is a structural component of the core centromere of Saccharomyces cerevisiae and is a member of the conserved CENP-A family of specialized histone H3 variants. The histone H4 allele hhf1-20 confers defects in core centromere chromatin structure and mitotic chromosome transmission. We have proposed that Cse4p and histone H4 interact through their respective histone fold domains to assemble a nucleosome-like structure at centromeric DNA. To test this model, we targeted random mutations to the Cse4p histone fold domain and isolated three temperature-sensitive cse4 alleles in an unbiased genetic screen. Two of the cse4 alleles contain mutations at the Cse4p-H4 interface. One of these requires two widely separated mutations demonstrating long-range cooperative interactions in the structure. The third cse4 allele is mutated at its helix 2-helix 3 interface, a region required for homotypic H3 fold dimerization. Overexpression of wild-type Cse4p and histone H4 confer reciprocal allele-specific suppression of cse4 and hhf1 mutations, providing strong evidence for Cse4p-H4 protein interaction. Overexpression of histone H3 is dosage lethal in cse4 mutants, suggesting that histone H3 competes with Cse4p for histone H4 binding. However, the relative resistance of the Cse4p-H4 pathway to H3 interference argues that centromere chromatin assembly must be highly regulated.     

Co-localization of CENP-C and CENP-H to discontinuous domains of CENP-A chromatin at human neocentromeres

Background  

Mammalian centromere formation is dependent on chromatin that contains centromere protein (CENP)-A, which is the centromere-specific histone H3 variant. Human neocentromeres have acquired CENP-A chromatin epigenetically in ectopic chromosomal locations on low-copy complex DNA. Neocentromeres permit detailed investigation of centromeric chromatin organization that is not possible in the highly repetitive alpha satellite DNA present at endogenous centromeres.     

Structure of centromere chromatin: from nucleosome to chromosomal architecture

The centromere is essential for the segregation of chromosomes, as it serves as attachment site for microtubules to mediate chromosome segregation during mitosis and meiosis. In most organisms, the centromere is restricted to one chromosomal region that appears as primary constriction on the condensed chromosome and is partitioned into two chromatin domains: The centromere core is characterized by the centromere-specific histone H3 variant CENP-A (also called cenH3) and is required for specifying the centromere and for building the kinetochore complex during mitosis. This core region is generally flanked by pericentric heterochromatin, characterized by nucleosomes containing H3 methylated on lysine 9 (H3K9me) that are bound by heterochromatin proteins. During mitosis, these two domains together form a three-dimensional structure that exposes CENP-A-containing chromatin to the surface for interaction with the kinetochore and microtubules. At the same time, this structure supports the tension generated during the segregation of sister chromatids to opposite poles. In this review, we discuss recent insight into the characteristics of the centromere, from the specialized chromatin structures at the centromere core and the pericentromere to the three-dimensional organization of these regions that make up the functional centromere.     

Centromeres: unique chromatin structures that drive chromosome segregation

Fidelity during chromosome segregation is essential to prevent aneuploidy. The proteins and chromatin at the centromere form a unique site for kinetochore attachment and allow the cell to sense and correct errors during chromosome segregation. Centromeric chromatin is characterized by distinct chromatin organization, epigenetics, centromere-associated proteins and histone variants. These include the histone H3 variant centromeric protein A (CENPA), the composition and deposition of which have been widely investigated. Studies have examined the structural and biophysical properties of the centromere and have suggested that the centromere is not simply a 'landing pad' for kinetochore formation, but has an essential role in mitosis by assembling and directing the organization of the kinetochore.     

Dramatic replacement of histone variants during genome remodeling in nuclear-transferred embryos

The genome of differentiated somatic nuclei is remodeled to a totipotent state when they are transplanted into enucleated oocytes. To clarify the mechanism of this genome remodeling, we analyzed changes in the composition of core histone variants in nuclear-transferred embryos, since recent evidence has revealed that chromatin structure can be remodeled as a result of variant histone replacement. We found that the donor cell-derived histone H3 variants H3.1, H3.2, and H3.3, as well as H2A and H2A.Z, were rapidly eliminated from the chromatin of nuclei transplanted into enucleated oocytes. Accompanying this removal, oocyte-stored histone H3 variants and H2A.X were incorporated into the transplanted nuclei, while the incorporation of H2A and H2A.Z was minimal or not detected. The incorporation of these variant histones was DNA replication-independent. These results suggest that most core histone H2A and H3 components are dynamically exchanged between donor nuclei and recipient cytoplasm, which further suggests that replacement of donor cell histones with oocyte-stored histones may play a key role in genome remodeling in nuclear-transferred embryos. In addition, the incorporation patterns of all of the histone variants in the nuclear-transferred embryos were virtually the same as in the fertilized embryos. Only the incorporation pattern of H3.1 differed; it was incorporated into the transplanted donor nuclei, but not in the pronuclei of fertilized embryos. This result suggests that the incorporation of H3.1 has a detrimental effect on the process of genome remodeling and contributes to the low success rate of somatic nuclear cloning.     

Dramatic replacement of histone variants during genome remodeling in nuclear-transferred embryos

The genome of differentiated somatic nuclei is remodeled to a totipotent state when they are transplanted into enucleated oocytes. To clarify the mechanism of this genome remodeling, we analyzed changes in the composition of core histone variants in nuclear-transferred embryos, since recent evidence has revealed that chromatin structure can be remodeled as a result of variant histone replacement. We found that the donor cell-derived histone H3 variants H3.1, H3.2, and H3.3, as well as H2A and H2A.Z, were rapidly eliminated from the chromatin of nuclei transplanted into enucleated oocytes. Accompanying this removal, oocyte-stored histone H3 variants and H2A.X were incorporated into the transplanted nuclei, while the incorporation of H2A and H2A.Z was minimal or not detected. The incorporation of these variant histones was DNA replication-independent. These results suggest that most core histone H2A and H3 components are dynamically exchanged between donor nuclei and recipient cytoplasm, which further suggests that replacement of donor cell histones with oocyte-stored histones may play a key role in genome remodeling in nuclear-transferred embryos. In addition, the incorporation patterns of all of the histone variants in the nuclear-transferred embryos were virtually the same as in the fertilized embryos. Only the incorporation pattern of H3.1 differed; it was incorporated into the transplanted donor nuclei, but not in the pronuclei of fertilized embryos. This result suggests that the incorporation of H3.1 has a detrimental effect on the process of genome remodeling and contributes to the low success rate of somatic nuclear cloning.