A CENP-S/X complex assembles at the centromere in S and G2 phases of the human cell cycle.

The functional identity of centromeres arises from a set of specific nucleoprotein particle subunits of the centromeric chromatin fibre. These include CENP-A and histone H3 nucleosomes and a novel nucleosome-like complex of CENPs -T, -W, -S and -X. Fluorescence cross-correlation spectroscopy and Förster resonance energy transfer (FRET) revealed that human CENP-S and -X exist principally in complex in soluble form and retain proximity when assembled at centromeres. Conditional labelling experiments show that they both assemble de novo during S phase and G2, increasing approximately three- to fourfold in abundance at centromeres. Fluorescence recovery after photobleaching (FRAP) measurements documented steady-state exchange between soluble and assembled pools, with CENP-X exchanging approximately 10 times faster than CENP-S (t1/2 ∼ 10 min versus 120 min). CENP-S binding to sites of DNA damage was quite distinct, with a FRAP half-time of approximately 160 s. Fluorescent two-hybrid analysis identified CENP-T as a uniquely strong CENP-S binding protein and this association was confirmed by FRET, revealing a centromere-bound complex containing CENP-S, CENP-X and CENP-T in proximity to histone H3 but not CENP-A. We propose that deposition of the CENP-T/W/S/X particle reveals a kinetochore-specific chromatin assembly pathway that functions to switch centromeric chromatin to a mitosis-competent state after DNA replication. Centromeres shuttle between CENP-A-rich, replication-competent and H3-CENP-T/W/S/X-rich mitosis-competent compositions in the cell cycle.

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.

Centromeres: assembling and propagating epigenetic function.

The faithful replication of DNA and the accurate segregation of genomic material from one generation to the next is critical in the maintenance of genomic stability. This chapter will describe the structure and assembly of an epigenetically inherited locus, the centromere, and its role in the processes by which sister chromatids are evenly segregated to daughter cells. During the G2 phase of the cell cycle kinetochores are assembled upon the chromatids. During mitosis, kinetochores attach chromosome(s) to the mitotic spindle. The kinetochore structure serves as the interface between the mitotic spindle and the chromatids and it is at the kinetochore where the forces that drive chromatid separation are generated. Unattached chromosomes fail to satisfy the spindle assembly checkpoint (SAC), resulting in cell cycle arrest. The centromere is the locus upon which the kinetochore assembles, and centromeres themselves are determined by their unique protein composition. Apart from budding yeast, centromeres are not specified simply by DNA sequence, but rather through chromatin composition and architecture and are thus epigenetically determined. Centromeres are built on a specific nucleosome not found elsewhere in the genome, in which histone H3 is replaced with a homologue - CENP-A or CenH3. This domain is flanked by heterochromatin and is folded to provide a 3-dimensional cylinder-like structure at metaphase that establishes the kinetochore on the surface of the mitotic chromosomes. A large family of CENtromere Proteins (CENPs) associates with centromeric chromatin throughout the cell cycle and are required for kinetochore function. Unlike the bulk of histones, CENP-A is not assembled concurrently with DNA synthesis in S-phase but rather assembles into the centromere in the subsequent G1 phase. The assembly of CENP-A chromatin following DNA replication and the re-establishment of this network of constitutive proteins have emerged as critical mechanisms for understanding how the centromere is replicated during the cell cycle.