Centromeres of the fission yeast Schizosaccharomyces pombe are highly variable genetic loci

Genomic and Epigenetic Foundations of Neocentromere Formation

Centromeres are essential to genome inheritance, serving as the site of kinetochore assembly and coordinating chromosome segregation during cell division. Abnormal centromere function is associated with birth defects, infertility, and cancer. Normally, centromeres are assembled and maintained at the same chromosomal location. However, ectopic centromeres form spontaneously at new genomic locations and contribute to genome instability and developmental defects as well as to acquired and congenital human disease. Studies in model organisms have suggested that certain regions of the genome, including pericentromeres, heterochromatin, and regions of open chromatin or active transcription, support neocentromere activation. However, there is no universal mechanism that explains neocentromere formation. This review focuses on recent technological and intellectual advances in neocentromere research and proposes future areas of study. Understanding neocentromere biology will provide a better perspective on chromosome and genome organization and functional context for information generated from the Human Genome Project, ENCODE, and other large genomic consortia. Expected final online publication date for the Annual Review of Genetics, Volume 55 is November 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

Schizosaccharomyces pombe Assays to Study Mitotic Recombination Outcomes

The fission yeast—Schizosaccharomyces pombe—has emerged as a powerful tractable system for studying DNA damage repair. Over the last few decades, several powerful in vivo genetic assays have been developed to study outcomes of mitotic recombination, the major repair mechanism of DNA double strand breaks and stalled or collapsed DNA replication forks. These assays have significantly increased our understanding of the molecular mechanisms underlying the DNA damage response pathways. Here, we review the assays that have been developed in fission yeast to study mitotic recombination.

Early Diverging Fungus Mucor circinelloides Lacks Centromeric Histone CENP-A and Displays a Mosaic of Point and Regional Centromeres

Centromeres are rapidly evolving across eukaryotes, despite performing a conserved function to ensure high-fidelity chromosome segregation. CENP-A chromatin is a hallmark of a functional centromere in most organisms. Due to its critical role in kinetochore architecture, the loss of CENP-A is tolerated in only a few organisms, many of which possess holocentric chromosomes. Here, we characterize the consequence of the loss of CENP-A in the fungal kingdom. Mucor circinelloides, an opportunistic human pathogen, lacks CENP-A along with the evolutionarily conserved CENP-C but assembles a monocentric chromosome with a localized kinetochore complex throughout the cell cycle. Mis12 and Dsn1, two conserved kinetochore proteins, were found to co-localize to a short region, one in each of nine large scaffolds, composed of an ∼200-bp AT-rich sequence followed by a centromere-specific conserved motif that echoes the structure of budding yeast point centromeres. Resembling fungal regional centromeres, these core centromere regions are embedded in large genomic expanses devoid of genes yet marked by Grem-LINE1s, a novel retrotransposable element silenced by the Dicer-dependent RNAi pathway. Our results suggest that these hybrid features of point and regional centromeres arose from the absence of CENP-A, thus defining novel mosaic centromeres in this early-diverging fungus.

Centromere mechanical maturation during mammalian cell mitosis

During mitosis, tension develops across the centromere as a result of spindle-based forces. Metaphase tension may be critical in preventing mitotic chromosome segregation errors, however, the nature of force transmission at the centromere and the role of centromere mechanics in controlling metaphase tension remains unknown. We combined quantitative, biophysical microscopy with computational analysis to elucidate the mechanics of the centromere in unperturbed, mitotic human cells. We discovered that the mechanical stiffness of the human centromere matures during mitotic progression, which leads to amplified centromere tension specifically at metaphase. Centromere mechanical maturation is disrupted across multiple aneuploid cell lines, leading to a weak metaphase tension signal. Further, increasing deficiencies in centromere mechanical maturation are correlated with rising frequencies of lagging, merotelic chromosomes in anaphase, leading to segregation defects at telophase. Thus, we reveal a centromere maturation process that may be critical to the fidelity of chromosome segregation during mitosis.

During mitosis, tension at the centromere occurs from the spindle but the role of centromere mechanics in controlling metaphase tension is poorly understood. Here, the authors report that mechanical stiffnness of the centromere matures during mitotic progression and is amplified specifically at metaphase.

Distinct 'safe zones' at the nuclear envelope ensure robust replication of heterochromatic chromosome regions

Chromosome replication and transcription occur within a complex nuclear milieu whose functional subdomains are beginning to be mapped out. Here we delineate distinct domains of the fission yeast nuclear envelope (NE), focusing on regions enriched for the inner NE protein, Bqt4, or the lamin interacting domain protein, Lem2. Bqt4 is relatively mobile around the NE and acts in two capacities. First, Bqt4 tethers chromosome termini and the mat locus to the NE specifically while these regions are replicating. This positioning is required for accurate heterochromatin replication. Second, Bqt4 mobilizes a subset of Lem2 molecules around the NE to promote pericentric heterochromatin maintenance. Opposing Bqt4-dependent Lem2 mobility are factors that stabilize Lem2 beneath the centrosome, where Lem2 plays a crucial role in kinetochore maintenance. Our data prompt a model in which Bqt4-rich nuclear subdomains are 'safe zones' in which collisions between transcription and replication are averted and heterochromatin is reassembled faithfully.

A Matter of Scale and Dimensions: Chromatin of Chromosome Landmarks in the Fungi

Chromatin and chromosomes of fungi are highly diverse and dynamic, even within species. Much of what we know about histone modification enzymes, RNA interference, DNA methylation, and cell cycle control was first addressed in Saccharomyces cerevisiae, Schizosaccharomyces pombe, Aspergillus nidulans, and Neurospora crassa. Here, we examine the three landmark regions that are required for maintenance of stable chromosomes and their faithful inheritance, namely, origins of DNA replication, telomeres and centromeres. We summarize the state of recent chromatin research that explains what is required for normal function of these specialized chromosomal regions in different fungi, with an emphasis on the silencing mechanism associated with subtelomeric regions, initiated by sirtuin histone deacetylases and histone H3 lysine 27 (H3K27) methyltransferases. We explore mechanisms for the appearance of "accessory" or "conditionally dispensable" chromosomes and contrast what has been learned from studies on genome-wide chromosome conformation capture in S. cerevisiae, S. pombe, N. crassa, and Trichoderma reesei. While most of the current knowledge is based on work in a handful of genetically and biochemically tractable model organisms, we suggest where major knowledge gaps remain to be closed. Fungi will continue to serve as facile organisms to uncover the basic processes of life because they make excellent model organisms for genetics, biochemistry, cell biology, and evolutionary biology.

Centrochromatin of Fungi

The centromere is an essential chromosomal locus that dictates the nucleation point for assembly of the kinetochore and subsequent attachment of spindle microtubules during chromosome segregation. Research over the last decades demonstrated that centromeres are defined by a combination of genetic and epigenetic factors. Recent work showed that centromeres are quite diverse and flexible and that many types of centromere sequences and centromeric chromatin ("centrochromatin") have evolved. The kingdom of the fungi serves as an outstanding example of centromere plasticity, including organisms with centromeres as diverse as 0.15-300 kb in length, and with different types of chromatin states for most species examined thus far. Some of the species in the less familiar taxa provide excellent opportunities to help us better understand centromere biology in all eukaryotes, which may improve treatment options against fungal infection, and biotechnologies based on fungi. This review summarizes the current knowledge of fungal centromeres and centrochromatin, including an outlook for future research.

Centromeres of the Yeast Komagataella phaffii (Pichia pastoris) Have a Simple Inverted-Repeat Structure

Centromere organization has evolved dramatically in one clade of fungi, the Saccharomycotina. These yeasts have lost the ability to make normal eukaryotic heterochromatin with histone H3K9 methylation, which is a major component of pericentromeric regions in other eukaryotes. Following this loss, several different types of centromere emerged, including two types of sequence-defined (“point”) centromeres, and the epigenetically defined “small regional” centromeres of Candida albicans. Here we report that centromeres of the methylotrophic yeast Komagataella phaffii (formerly called Pichia pastoris) are structurally defined. Each of its four centromeres consists of a 2-kb inverted repeat (IR) flanking a 1-kb central core (mid) region. The four centromeres are unrelated in sequence. CenH3 (Cse4) binds strongly to the cores, with a decreasing gradient along the IRs. This mode of organization resembles Schizosaccharomyces pombe centromeres but is much more compact and lacks the extensive flanking heterochromatic otr repeats. Different isolates of K. phaffii show polymorphism for the orientation of the mid regions, due to recombination in the IRs. CEN4 is located within a 138-kb region that changes orientation during mating-type switching, but switching does not induce recombination of centromeric IRs. Our results demonstrate that evolutionary transitions in centromere organization have occurred in multiple yeast clades.

No longer a nuisance: long non-coding RNAs join CENP-A in epigenetic centromere regulation

Centromeres represent the basis for kinetochore formation, and are essential for proper chromosome segregation during mitosis. Despite these essential roles, centromeres are not defined by specific DNA sequences, but by epigenetic means. The histone variant CENP-A controls centromere identity epigenetically and is essential for recruiting kinetochore components that attach the chromosomes to the mitotic spindle during mitosis. Recently, a new player in centromere regulation has emerged: long non-coding RNAs transcribed from repetitive regions of centromeric DNA function in regulating centromeres epigenetically. This review summarizes recent findings on the essential roles that transcription, pericentromeric transcripts, and centromere-derived RNAs play in centromere biology.

Mechanisms and dynamics of heterochromatin formation during mammalian development: closed paths and open questions

Early embryonic development in mammals is characterized by major changes in the components of the chromatin and its remodeling. The embryonic chromatin and the nuclear organization in the mouse preimplantation embryo display particular features that are dramatically different from somatic cells. These include the highly specific organization of the pericentromeric heterochromatin within the nucleus and the suggested lack of conventional heterochromatin. We postulate that the plasticity of the cells in the early embryo relies on the distinctive heterochromatin features that prevail during early embryogenesis. Here, we review some of these features and discuss recent findings on the mechanisms driving heterochromatin formation after fertilization, in particular, the emerging role of RNA as a regulator of heterochromatic loci also in mammals. Finally, we believe that there are at least three major avenues that should be addressed in the coming years: (i) Is heterochromatin a driving force in development? (ii) Does it have a role in lineage allocation? (iii) How can heterochromatin "regulate" epigenetic reprogramming?

The process of kinetochore assembly in yeasts

High fidelity chromosome segregation is essential for efficient transfer of the genetic material from the mother to daughter cells. The kinetochore (KT), which connects the centromere DNA to the spindle apparatus, plays a pivotal role in this process. In spite of considerable divergence in the centromere DNA sequence, basic architecture of a KT is evolutionarily conserved from yeast to humans. However, the identification of a large number of KT proteins paved the way of understanding conserved and diverged regulatory steps that lead to the formation of a multiprotein KT super-complex on the centromere DNA in different organisms. Because it is a daunting task to summarize the entire spectrum of information in a minireview, we focus here on the recent understanding in the process of KT assembly in three yeasts: Saccharomyces cerevisiae, Schizosaccharomyces pombe and Candida albicans. Studies in these unicellular organisms suggest that although the basic process of KT assembly remains the same, the dependence of a conserved protein for its KT localization may vary in these organisms.

Centromere-associated repeat arrays on Trypanosoma brucei chromosomes are much more extensive than predicted

BACKGROUND

African trypanosomes belong to a eukaryotic lineage which displays many unusual genetic features. The mechanisms of chromosome segregation in these diploid protozoan parasites are poorly understood. Centromeres in Trypanosoma brucei have been localised to chromosomal regions that contain an array of ~147 bp AT-rich tandem repeats. Initial estimates from the genome sequencing project suggested that these arrays ranged from 2 - 8 kb. In this paper, we show that the centromeric repeat regions are much more extensive.

RESULTS

We used a long-range restriction endonuclease mapping approach to more accurately define the sizes of the centromeric repeat arrays on the 8 T. brucei chromosomes where unambiguous assembly data were available. The results indicate that the sizes of the arrays on different chromosomes vary from 20 to 120 kb. In addition, we found instances of length heterogeneity between chromosome homologues. For example, values of 20 and 65 kb were obtained for the arrays on chromosome 1, and 50 and 75 kb for chromosome 5.

CONCLUSIONS

Our results show that centromeric repeat arrays on T. brucei chromosomes are more similar in size to those of higher eukaryotes than previously suspected. This information provides a firmer framework for investigating aspects of chromosome segregation and will allow epigenetic features associated with the process to be more accurately mapped.

Analysis of small RNA in fission yeast; centromeric siRNAs are potentially generated through a structured RNA

The formation of heterochromatin at the centromeres in fission yeast depends on transcription of the outer repeats. These transcripts are processed into siRNAs that target homologous loci for heterochromatin formation. Here, high throughput sequencing of small RNA provides a comprehensive analysis of centromere-derived small RNAs. We found that the centromeric small RNAs are Dcr1 dependent, carry 5'-monophosphates and are associated with Ago1. The majority of centromeric small RNAs originate from two remarkably well-conserved sequences that are present in all centromeres. The high degree of similarity suggests that this non-coding sequence in itself may be of importance. Consistent with this, secondary structure-probing experiments indicate that this centromeric RNA is partially double-stranded and is processed by Dicer in vitro. We further demonstrate the existence of small centromeric RNA in rdp1Delta cells. Our data suggest a pathway for siRNA generation that is distinct from the well-documented model involving RITS/RDRC. We propose that primary transcripts fold into hairpin-like structures that may be processed by Dcr1 into siRNAs, and that these siRNAs may initiate heterochromatin formation independent of RDRC activity.

Conservation and divergence of centromere specification in yeast

Centromeres are specialized structures on eukaryotic chromosomes that couple chromosome movements to spindle microtubule movements and allow accurate chromosome segregation during cell division. In spite of these vital functions, recent evidence strongly suggests that epigenetic regulation rather than the primary DNA sequence of the centromere plays a dominant role in the specification of centromeres. The key determinant of centromere identity is the centromere-specific histone H3 variant CENP-A (also known as CenH3). This review highlights exciting new findings examining the mechanism of centromere specification in distinct yeast species, which provides insights into CENP-A nucleosome assembly and establishment of centromere identity.

The epigenetic basis for centromere identity

The centromere serves as the control locus for chromosome segregation at mitosis and meiosis. In most eukaryotes, including mammals, the location of the centromere is epigenetically defined. The contribution of both genetic and epigenetic determinants to centromere function is the subject of current investigation in diverse eukaryotes. Here we highlight key findings from several organisms that have shaped the current view of centromeres, with special attention to experiments that have elucidated the epigenetic nature of their specification. Recent insights into the histone H3 variant, CENP-A, which assembles into centromeric nucleosomes that serve as the epigenetic mark to perpetuate centromere identity, have added important mechanistic understanding of how centromere identity is initially established and subsequently maintained in every cell cycle.

Dynamic transcriptome of Schizosaccharomyces pombe shown by RNA-DNA hybrid mapping

We have determined the high-resolution strand-specific transcriptome of the fission yeast S. pombe under multiple growth conditions using a novel RNA-DNA hybridization mapping (HybMap) technique. HybMap uses an antibody against an RNA-DNA hybrid to detect RNA molecules hybridized to a high-density DNA oligonucleotide tiling microarray. HybMap showed exceptional dynamic range and reproducibility, and allowed us to identify strand-specific coding, noncoding and structural RNAs, as well as previously unknown RNAs conserved in distant yeast species. Notably, we found that virtually the entire euchromatic genome (including intergenics) is transcribed, with heterochromatin dampening intergenic transcription. We identified features including large numbers of condition-specific noncoding RNAs, extensive antisense transcription, new properties of antisense transcripts and induced divergent transcription. Furthermore, our HybMap data informed the efficiency and locations of RNA splicing genome-wide. Finally, we observed strand-specific transcription islands around tRNAs at heterochromatin boundaries inside centromeres. Here, we discuss these new features in terms of organism fitness and transcriptome evolution.

RNAi-mediated chromatin silencing in fission yeast

In the fission yeast Schizosaccharomyces pombe, the RNAi pathway plays an important role in the formation and maintenance of heterochromatin. Heterochromatin, or silent chromatin, is an epigenetically inherited attribute of eukaryotic chromosomes which is required for gene regulation, chromosome segregation and maintenance of genome stability. In S. pombe, heterochromatin forms on related repetitive DNA sequences at specific loci. These repetitive sequences, in concert with the RNAi machinery, are thought to attract several proteins including chromatin-modifying enzymes which act to promote heterochromatin formation. The purification of complexes participating in heterochromatin formation has allowed us to begin to analyse in detail the processes involved. In the future this will help us to understand how the RNAi machinery acts to induce the chromatin modifications which lead to heterochromatin assembly in fission yeast.

Centromere size and position in Candida albicans are evolutionarily conserved independent of DNA sequence heterogeneity

The centromere regions (CEN) of all eight chromosomes in Candida albicans have been characterized in terms of nucleotide sequence and size. The boundaries of each of the eight CEN DNA regions were mapped by chromatin immunoprecipitation-PCR using polyclonal rabbit antibodies generated against C. albicans centromere-specific protein CaCse4p (CENP-A homolog). A single 3-4.5 kb unique DNA sequence on each chromosome was found to be bound to CaCse4p. Sequence analysis revealed that the eight CEN regions in C. albicans lack any conserved DNA sequence motifs common to the group; all are quite different in overall DNA sequence. In contrast to centromeres in many organisms, the C. albicans centromeres are generally free of repeated DNA elements and transposons. However, a few small inverted repeats and long terminal repeats do occur in the centromeric and pericentric regions on a few chromosomes. We also characterized the CEN DNAs in four groups of phylogenetically divergent C. albicans strains, estimated to be separated from each other by 1-3 million years. The same eight different and unique 3-4.5 kb DNA sequences are utilized as centromeres in all of these strains. The chromosomal locations and the sizes of CEN DNAs have remained conserved, in agreement with the idea that CEN function in C. albicans is templated by heritable epigenetic mechanisms.

Plasticity of fission yeast CENP-A chromatin driven by relative levels of histone H3 and H4

The histone H3 variant CENP-A assembles into chromatin exclusively at centromeres. The process of CENP-A chromatin assembly is epigenetically regulated. Fission yeast centromeres are composed of a central kinetochore domain on which CENP-A chromatin is assembled, and this is flanked by heterochromatin. Marker genes are silenced when placed within kinetochore or heterochromatin domains. It is not known if fission yeast CENP-A(Cnp1) chromatin is confined to specific sequences or whether histone H3 is actively excluded. Here, we show that fission yeast CENP-A(Cnp1) can assemble on noncentromeric DNA when it is inserted within the central kinetochore domain, suggesting that in fission yeast CENP-A(Cnp1) chromatin assembly is driven by the context of a sequence rather than the underlying DNA sequence itself. Silencing in the central domain is correlated with the amount of CENP-A(Cnp1) associated with the marker gene and is also affected by the relative level of histone H3. Our analyses indicate that kinetochore integrity is dependent on maintaining the normal ratio of H3 and H4. Excess H3 competes with CENP-A(Cnp1) for assembly into central domain chromatin, resulting in less CENP-A(Cnp1) and other kinetochore proteins at centromeres causing defective kinetochore function, which is manifest as aberrant mitotic chromosome segregation. Alterations in the levels of H3 relative to H4 and CENP-A(Cnp1) influence the extent of DNA at centromeres that is packaged in CENP-A(Cnp1) chromatin and the composition of this chromatin. Thus, CENP-A(Cnp1) chromatin assembly in fission yeast exhibits plasticity with respect to the underlying sequences and is sensitive to the levels of CENP-A(Cnp1) and other core histones.

The role of heterochromatin in centromere function

Chromatin at centromeres is distinct from the chromatin in which the remainder of the genome is assembled. Two features consistently distinguish centromeres: the presence of the histone H3 variant CENP-A and, in most organisms, the presence of heterochromatin. In fission yeast, domains of silent "heterochromatin" flank the CENP-A chromatin domain that forms a platform upon which the kinetochore is assembled. Thus, fission yeast centromeres resemble their metazoan counterparts where the kinetochore is embedded in centromeric heterochromatin. The centromeric outer repeat chromatin is underacetylated on histones H3 and H4, and methylated on lysine 9 of histone H3, which provides a binding site for the chromodomain protein Swi6 (orthologue of Heterochromatin Protein 1, HP1). The remarkable demonstration that the assembly of repressive heterochromatin is dependent on the RNA interference machinery provokes many questions about the mechanisms of this process that may be tractable in fission yeast. Heterochromatin ensures that a high density of cohesin is recruited to centromeric regions, but it could have additional roles in centromere architecture and the prevention of merotely, and it might also act as a trigger for kinetochore assembly. In addition, we discuss an epigenetic model for ensuring that CENP-A is targeted and replenished at the kinetochore domain.

The Function of Nuclear Architecture: A Genetic Approach

Eukaryotic genomes are distributed on linear chromosomes that are grouped together in the nucleus, an organelle separated from the cytoplasm by a characteristic double membrane studded with large proteinaceous pores. The chromatin within chromosomes has an as yet poorly characterized higher-order structure, but in addition to this, chromosomes and specific subchromosomal domains are nonrandomly positioned in nuclei. This review examines functional implications of the long-range organization of the genome in interphase nuclei. A rigorous test of the physiological importance of nuclear architecture is achieved by introducing mutations that compromise both structure and function. Focussing on such genetic approaches, we address general concepts of interphase nuclear order, the role of the nuclear envelope (NE) and lamins, and finally the importance of spatial organization for DNA replication and heritable gene expression.

Centromeres: moving chromosomes through space and time

Centromeres have played a pivotal role in the evolution of the eukaryote genome. Their indispensable involvement in chromosome segregation and the evolution of linkage groups throughout all eukaryotic lineages intuitively suggests conserved structure and function. Unexpectedly, recent molecular and biochemical analyses of centromeres have revealed highly divergent patterns in both DNA sequence and organization. Unlike the microtubules with which they interact, centromeres have undergone rapid diversification during evolution while retaining the same functional attributes. The most recent evidence indicates that centromeres may be species-specific entities composed of highly variable DNA families that interact with an array of non-histone proteins before attachment to the microtubules.

A new role for the transcriptional corepressor SIN3; regulation of centromeres

Centromeres play a vital role in maintaining the genomic stability of eukaryotes by coordinating the equal distribution of chromosomes to daughter cells during mitosis and meiosis. Fission yeast (S. pombe) centromeres consist of a 4-9 kb central core region and 30-100 kb of flanking inner (imr/B) and outer (otr/K) repeats. These sequences direct a laminar kinetochore structure similar to that of human centromeres. Centromeric heterochromatin is generally underacetylated. We have previously shown that inhibition of histone deacetylases (HDACs) caused hyperacetylation of centromeres and defective chromosome segregation. SIN3 is a HDAC corepressor that has the ability to mediate HDAC targeting in the repression of promoters. In this study, we have characterized S. pombe sin three corepressors (Pst1p and Pst2p) to investigate whether SIN3-HDAC is required in the regulation of centromeres. We show that only pst1-1 and not pst2Delta cells displayed anaphase defects and thiabendazole sensitivity. pst1-1 cells showed reduced centromeric silencing, increased histone acetylation in centromeric chromatin, and defective centromeric sister chromatid cohesion. The HDAC Clr6p and Pst1p coimmunoprecipitated, and Pst1p colocalized with centromeres, particularly in binucleate cells. These data are consistent with a model in which Pst1p-Clr6p temporally associate with centromeres to carry out the initial deacetylation necessary for subsequent steps in heterochromatin formation.

cis-acting DNA from fission yeast centromeres mediates histone H3 methylation and recruitment of silencing factors and cohesin to an ectopic site

BACKGROUND

Metazoan centromeres are generally composed of large repetitive DNA structures packaged in heterochromatin. Similarly, fission yeast centromeres contain large inverted repeats and two distinct silenced domains that are both required for centromere function. The central domain is flanked by outer repetitive elements coated in histone H3 methylated on lysine 9 and bound by conserved heterochromatin proteins. This centromeric heterochromatin is required for cohesion between sister centromeres. Defective heterochromatin causes premature sister chromatid separation and chromosome missegregation. The role of cis-acting DNA sequences in the formation of centromeric heterochromatin has not been established.

RESULTS

A deletion strategy was used to identify centromeric sequences that allow heterochromatin formation in fission yeast. Fragments from the outer repeats are sufficient to cause silencing of an adjacent gene when inserted at a euchromatic chromosomal locus. This silencing is accompanied by the local de novo methylation of histone H3 on lysine 9, recruitment of known heterochromatin components, Swi6 and Chp1, and the provision of a new strong cohesin binding site. In addition, we demonstrate that the chromodomain of Chp1 binds to MeK9-H3 and that Chp1 itself is required for methylation of histone H3 on lysine 9.

CONCLUSIONS

A short sequence, reiterated at fission yeast centromeres, can direct silent chromatin assembly and cohesin recruitment in a dominant manner. The heterochromatin formed at the euchromatic locus is indistinguishable from that found at endogenous centromeres. Recruitment of Rad21-cohesin underscores the link between heterochromatin and chromatid cohesion and indicates that these centromeric elements act independently of kinetochore activity to recruit cohesin.

Domain organization at the centromere and neocentromere

Recent data indicate that the eukaryotic centromere and pericentromeric regions are organized into definable functional and structural domains. Studies in different organisms point to a model of conserved pattern of organization for these domains.

Functional redundancies, distinct localizations and interactions among three fission yeast homologs of centromere protein-B

Several members of protein families that are conserved in higher eukaryotes are known to play a role in centromere function in the fission yeast Schizosaccharomyces pombe, including two homologs of the mammalian centromere protein CENP-B, Abp1p and Cbh1p. Here we characterize a third S. pombe CENP-B homolog, Cbh2p (CENP-B homolog 2). cbh2Delta strains exhibited a modest elevation in minichromosome loss, similar to cbh1Delta or abp1Delta strains. cbh2Delta cbh1Delta strains showed little difference in growth or minichromosome loss rate when compared to single deletion strains. In contrast, cbh2Delta abp1Delta strains displayed dramatic morphological and chromosome segregation defects, as well as enhancement of the slow-growth phenotype of abp1Delta strains, indicating partial functional redundancy between these proteins. Both cbh2Delta abp1Delta and cbh1Delta abp1Delta strains also showed strongly enhanced sensitivity to a microtubule-destabilizing drug, consistent with a mitotic function for these proteins. Cbh2p was localized to the central core and core-associated repeat regions of centromeric heterochromatin, but not at several other centromeric and arm locations tested. Thus, like its mammalian counterpart, Cbh2p appeared to be localized exclusively to a portion of centromeric heterochromatin. In contrast, Abp1p was detected in both centromeric heterochromatin and in chromatin at two of three replication origins tested. Cbh2p and Abp1p homodimerized in the budding yeast two-hybrid assay, but did not interact with each other. These results suggest that indirect cooperation between different CENP-B-like DNA binding proteins with partially overlapping chromatin distributions helps to establish a functional centromere.

Genetic and physical mapping of two centromere-proximal regions of chromosome IV in Aspergillus nidulans

Chromosome IV is the smallest chromosome of Aspergillus nidulans. The centromere-proximal portion of the chromosome was mapped physically using overlapping clones of a cosmid genomic library. Two contiguous segments of a physical map, based on restriction mapping of cosmid clones, were generated, together covering more than 0.4 Mb DNA. A reverse genetic mapping approach was used to establish a correlation between physical and genetic maps; i.e., marker genes were integrated into physically mapped segments and subsequently mapped by mitotic and meiotic recombination. The resulting data, together with additional classical genetic mapping, lead to a substantial revision of the genetic map of the chromosome, including the position of the centromere. Comparison of physical and genetic maps indicates that meiotic recombination is low in subcentromeric DNA, its frequency being reduced from 1 crossover per 0.8 Mb to approximately 1 crossover per 5 Mb per meiosis. The portion of the chromosome containing the functional centromere was not mapped because repeat-rich regions hindered further chromosome walking. The size of the missing segment was estimated to be between 70 and 400 kb.

Only centromeres can supply the partition system required for ARS function in the yeast Yarrowia lipolytica

Autonomously replicating sequences (ARSs) in the yeast Yarrowia lipolytica require two components: an origin of replication (ORI) and centromere (CEN) DNA, both of which are necessary for extrachromosomal maintenance. To investigate this cooperation in more detail, we performed a screen for genomic sequences able to confer high frequency of transformation to a plasmid-borne ORI. Our results confirm a cooperation between ORI and CEN sequences to form an ARS, since all sequences identified in this screen displayed features of centromeric DNA and included the previously characterized CEN1-1, CEN3-1 and CEN5-1 fragments. Two new centromeric DNAs were identified as they are unique, map to different chromosomes (II and IV) and induce chromosome breakage after genomic integration. A third sequence, which is adjacent to, but distinct from the previously characterized CEN1-1 region was isolated from chromosome I. Although these CEN sequences do not share significant sequence similarities, they display a complex pattern of short repeats, including conserved blocks of 9 to 14 bp and regions of dyad symmetry. Consistent with their A+T-richness and strong negative roll angle, Y. lipolytica CEN-derived sequences, but not ORIs, were capable of binding isolated Drosophila nuclear scaffolds. However, a Drosophila scaffold attachment region that functions as an ARS in other yeasts was unable to confer autonomous replication to an ORI-containing plasmid. Deletion analysis of CEN1-1 showed that the sequences responsible for the induction of chromosome breakage could be eliminated without compromising extrachromosomal maintenance. We propose that, while Y. lipolytica CEN DNA is essential for plasmid maintenance, this function can be supplied by several sub-fragments which, together, form the active chromosomal centromere. This complex organization of Y. lipolytica centromeres is reminiscent of the regional structures described in the yeast Schizosaccharomyces pombe or in multicellular eukaryotes.

Investigation of Schizosaccharomyces pombe as a cloning host for human telomere and alphoid DNA

The fission yeast Schizosaccharomyces pombe (Sch. pombe) has been proposed as a possible cloning host for both mammalian artificial chromosomes (MACs) and mammalian genomic libraries, due to the large size of its chromosomes and its similarity to higher eukaryotic cells. Here, it was investigated for its ability to form telomeres from human telomere sequence and to stably maintain long stretches of alphoid DNA. Using linear constructs terminating in the telomere repeat, T2AG3, human telomere DNA was shown to efficiently seed telomere formation in Sch. pombe. Much of the human telomeric sequence was removed on addition of Sch. pombe telomeric sequence, a process similar to that described in S. cerevisiae. To investigate the stability of alphoid DNA in fission yeast, bacterial artificial chromosomes (BACs) containing 130 and 173 kb of alphoid DNA were retrofitted with the Sch. pombe ars1 element and ura4+ marker using Cre-lox recombination. These alphoid BACs were found to be highly unstable in Sch. pombe deleting down to less than 40 kb, whilst control BACs of 96 and 202 kb, containing non-repetitive DNA, were unrearranged. Alphoid DNA has been shown to be sufficient for human centromere function, and this marked instability excludes Sch. pombe as a useful cloning host for mammalian artificial chromosomes. In addition, regions containing repetitive DNA from mammalian genomes may not be truly represented in libraries constructed in Sch. pombe.

Fission yeast mutants that alleviate transcriptional silencing in centromeric flanking repeats and disrupt chromosome segregation

In the fission yeast Schizosaccharomyces pombe genes are transcriptionally silenced when placed within centromeres, within or close to the silent mating-type loci or adjacent to telomeres. Factors required to maintain mating-type silencing also affect centromeric silencing and chromosome segregation. We isolated mutations that alleviate repression of marker genes in the inverted repeats flanking the central core of centromere I. Mutations csp1 to 13 (centromere: suppressor of position effect) defined 12 loci. Ten of the csp mutants have no effect on mat2/3 or telomere silencing. All csp mutants allow some expression of genes in the centromeric flanking repeat, but expression in the central core is undetectable. Consistent with defective centromere structure and function, chromosome loss rates are elevated in all csp mutants. Mutants csp1 to 6 are temperature-sensitive lethal and csp3 and csp6 cells are defective in mitosis at 36 degrees. csp7 to 13 display a high incidence of lagging chromosomes on late anaphase spindles. Thus, by screening for mutations that disrupt silencing in the flanking region of a fission yeast centromere a novel collection of mutants affecting centromere architecture and chromosome segregation has been isolated.

The Schizosaccharomyces pombe hst4(+) gene is a SIR2 homologue with silencing and centromeric functions

Although silencing is a significant form of transcriptional regulation, the functional and mechanistic limits of its conservation have not yet been established. We have identified the Schizosaccharomyces pombe hst4(+) gene as a member of the SIR2/HST silencing gene family that is defined in organisms ranging from bacteria to humans. hst4Delta mutants grow more slowly than wild-type cells and have abnormal morphology and fragmented DNA. Mutant strains show decreased silencing of reporter genes at both telomeres and centromeres. hst4(+) appears to be important for centromere function as well because mutants have elevated chromosome-loss rates and are sensitive to a microtubule-destabilizing drug. Consistent with a role in chromatin structure, Hst4p localizes to the nucleus and appears concentrated in the nucleolus. hst4Delta mutant phenotypes, including growth and silencing phenotypes, are similar to those of the Saccharomyces cerevisiae HSTs, and at a molecular level, hst4(+) is most similar to HST4. Furthermore, hst4(+) is a functional homologue of S. cerevisiae HST3 and HST4 in that overexpression of hst4(+) rescues the temperature-sensitivity and telomeric silencing defects of an hst3Delta hst4Delta double mutant. These results together demonstrate that a SIR-like silencing mechanism is conserved in the distantly related yeasts and is likely to be found in other organisms from prokaryotes to mammals.

Action at the ends of microtubules

Microtubule-based motility in the cell is directly associated with changes in microtubule numbers through nucleation and growth and shrinkage of the polymer from the ends. Recent analysis of spindle pole bodies and kinetochores in yeast reveal how the cell builds specialized structures for association with the ends of microtubules.

Construction of mammalian artificial chromosomes: prospects for defining an optimal centromere

Two reports have shown that mammalian artificial chromosomes (MAC) can be constructed from cloned human centromere DNA and telomere repeats, proving the principle that chromosomes can form from naked DNA molecules transfected into human cells. The MACs were mitotically stable, low copy number and bound antibodies associated with active centromeres. As a step toward second-generation MACs, yeast and bacterial cloning systems will have to be adapted to achieve large MAC constructs having a centromere, two telomeres, and genomic copies of mammalian genes. Available construction techniques are discussed along with a new P1 artificial chromosome (PAC)-derived telomere vector (pTAT) that can be joined to other PACs in vitro, avoiding a cloning step during which large repetitive arrays often rearrange. The PAC system can be used as a route to further define the optimal DNA elements required for efficient MAC formation, to investigate the expression of genes on MACs, and possibly to develop efficient MAC-delivery protocols.

Centromeres: proteins, protein complexes, and repeated domains at centromeres of simple eukaryotes

Similarities exist among components of simple and complex centromeres that may not have been expected on the basis of wide variation in size and sequence organization of centromeric DNAs among eukaryotes. Support is growing in systems from fungi to Drosophila for a model of centromere assembly and activation that is dependent on a particular underlying chromatin structure but not necessarily on a specific DNA sequence.

Transient inhibition of histone deacetylation alters the structural and functional imprint at fission yeast centromeres

Histone acetylation may act to mark and maintain transcriptionally active or inactive chromosomal domains through the cell cycle and in different lineages. A novel role for histone acetylation in centromere regulation has been identified. Exposure of fission yeast cells to TSA, a specific inhibitor of histone deacetylase, interferes with repression of marker genes in centromeric heterochromatin, causes chromosome loss, and disrupts the localization of Swi6p, a component of centromeric heterochromatin. Transient TSA treatment induces a heritable hyperacetylated state in centromeric chromatin that is propagated in lineages in the absence of drug. This state is linked in cis to the treated centromere locus and correlates with inheritance of functionally defective centromeres and persistent chromosome segregation problems. Thus, assembly of fully functional centromeres is partly imprinted in the underacetylated or transcriptionally silent state of centromeric chromatin.

A recombinationally repressed region between mat2 and mat3 loci shares homology to centromeric repeats and regulates directionality of mating-type switching in fission yeast

Cells of the fission yeast Schizosaccharomyces pombe switch mating type by replacing genetic information at the transcriptionally active mat1 locus with sequences copied from one of two closely linked silent loci, mat2-P or mat3-M. By a process referred to as directionality of switching, cells predominantly switch to the opposite mat1 allele; the mat1-P allele preferentially recombines with mat3, while mat1-M selects the mat2. In contrast to efficient recombination at mat1, recombination within the adjoining mat2-mat3 interval is undetectable. We defined the role of sequences between mat2 and mat3, designated the K-region, in directionality as well as recombinational suppression. Cloning and sequencing analysis revealed that a part of the K-region is homologous to repeat sequences present at centromeres, which also display transcriptional and recombinational suppression. Replacement of 7.5 kb of the K-region with the ura4+ gene affected directionality in a variegated manner. Analysis of the swi6-mod locus, which was previously shown to affect directionality, in K delta::ura4+ strains suggested the existence of at least two overlapping directionality mechanisms. Our work furthers the model that directionality is regulated by cell-type-specific organization of the heterochromatin-like structure in the mating-type region and provides evidence that the K-region contributes to silencing of the mat2-mat3 interval.

Mis6, a fission yeast inner centromere protein, acts during G1/S and forms specialized chromatin required for equal segregation

Disorder in sister chromatid separation can lead to genome instability and cancer. A temperature-sensitive S. pombe mis6-302 frequently loses a minichromosome at 26 degrees C and abolishes equal segregation of regular chromosomes at 36 degrees C. The mis6+ gene is essential for viability, and its deletion results in missegregation identical to mis6-302. Mis6 acts before or at the onset of S phase, and mitotic missegregation defects are produced only after the passage of G1/S at 36 degrees C. Mis6 locates at the centromeres throughout the cell cycle. In the mutant, positioning of the centromeres becomes abnormal, and specialized chromatin in the inner centromeres, which give the smear micrococcal nuclease pattern in wild type, is disrupted. The ability to establish correct biorientation of sister centromeres in metaphase cells requires the Mis6-containing chromatin and originates during the passage of G1/S.

Autonomous plasmid replication in Aspergillus nidulans: AMA1 and MATE elements

With few exceptions, in eukaryotic organisms the presence of a chromosomal replicator on a circular vector molecule is not sufficient to confer on it the ability to persist and replicate extrachromosomally. However, it is possible to isolate from genomes of some filamentous fungi DNA fragments which can provide extrachromosomal maintenance of plasmids. In Aspergillus nidulans, two functional classes of such sequences can be distinguished: effective plasmid replicators (e.g., AMA1) and transformation enhancers (e.g., ANS1 or MATEs), which apparently are able to initiate aberrant replication, leading to vector rearrangement and multimerization and eventually resulting in chromosomal integration. We discuss the similarity of these events to DNA amplification in other eukaryotes. A model is suggested which accounts for the formation of effective replicating plasmids as a result of sequence amplification. The model is based on the observation that in some organisms, including A. nidulans and Schizosaccharomyces pombe, duplication of an inefficient replicator enhances its efficiency dramatically. Some structural traits of transformation enhancers in A. nidulans imply a role for topoisomerases in amplification and replication of circular DNA molecules. We discuss practical applications of replicative vectors for gene cloning and expression studies.

A functional neo-centromere formed through activation of a latent human centromere and consisting of non-alpha-satellite DNA

We recently described a human marker chromosome containing a functional neo-centromere that binds anti-centromere antibodies, but is devoid of centromeric alpha-satellite repeats and derived from a hitherto non-centromeric region of chromosome 10q25. Chromosome walking using cloned single-copy DNA from this region enabled us to identify the antibody-binding domain of this centromere. Extensive restriction mapping indicates that this domain has an identical genomic organization to the corresponding normal chromosomal region, suggesting a mechanism for the origin of this centromere through the activation of a latent centromere that exists within 10q25.

A centromere DNA-binding protein from fission yeast affects chromosome segregation and has homology to human CENP-B

Genetic and biochemical strategies have been used to identify Schizosaccharomyces pombe proteins with roles in centromere function. One protein, identified by both approaches, shows significant homology to the human centromere DNA-binding protein, CENP-B, and is identical to Abp1p (autonomously replicating sequence-binding protein 1) (Murakami, Y., J.A. Huberman, and J. Hurwitz. 1996. Proc. Natl. Acad. Sci. USA. 93:502-507). Abp1p binds in vitro specifically to at least three sites in centromeric central core DNA of S. pombe chromosome II (cc2). Overexpression of abp1 affects mitotic chromosome stability in S. pombe. Although inactivation of the abp1 gene is not lethal, the abp1 null strain displays marked mitotic chromosome instability and a pronounced meiotic defect. The identification of a CENP-B-related centromere DNA-binding protein in S. pombe strongly supports the hypothesis that fission yeast centromeres are structurally and functionally related to the centromeres of higher eukaryotes.

Mutations in the fission yeast silencing factors clr4+ and rik1+ disrupt the localisation of the chromo domain protein Swi6p and impair centromere function

Transcriptional silencing is known to occur at centromeres, telomeres and the mating type region in the nucleus of fission yeast, Schizosaccharomyces pombe. Mating-type silencing factors have previously been shown also to affect transcriptional repression within centromeres and to some extent at telomeres. Mutations in the clr4+, rik1+ and swi6+ genes dramatically reduce silencing at certain centromeric regions and cause elevated chromosome loss rates. Recently, Swi6p was found to co-localise with the three silent chromosomal regions. Here the involvement of clr4+, rik1+ and swi6+ in centromere function is investigated in further detail. Fluorescence in situ hybridisation (FISH) was used to show that, as in swi6 mutant cells, centromeres lag on late anaphase spindles in clr4 and rik1 mutant cells. This phenotype is consistent with a role for these three gene products in fission yeast centromere function. The Swi6 protein was found to be delocalised from all three silent chromosomal regions, and dispersed within the nucleus, in both clr4 and rik1 mutant cells. The phenotypic similarity observed in all three mutants is consistent with the products of both the clr4+ and rik1+ genes being required to recruit Swi6p to the centromere and other silent regions. Mutations in clr4, rik1 and swi6 also result in elevated sensitivity to reagents which destabilise microtubules and show a synergistic interaction with a mutation in the beta-tubulin gene (nda3). These observations suggest that clr4+ and rik1+ must play a role in the assembly of Swi6p into a transcriptionally silent, inaccessible chromatin structure at fission yeast centromeres which is required to facilitate interactions with spindle microtubules and to ensure normal chromosome segregation.

Analysis of extrachromosomal structures containing human centromeric alphoid satellite DNA sequences in mouse cells

Yeast artificial chromosomes (YACs) spanning the centromeric region of the human Y chromosome were introduced into mouse LA-9 cells by spheroplast fusion in order to determine whether they would form mammalian artificial chromosomes. In about 50% of the cell lines generated, the YAC DNA was associated with circular extrachromosomal structures. These episomes were only present in a proportion of the cells, usually at high copy number, and were lost rapidly in the absence of selection. These observations suggest that, despite the presence of centromeric sequences, the structures were not segregating efficiently and thus were not forming artificial chromosomes. However, extrachromosomal structures containing alphoid DNA appeared cytogenetically smaller than those lacking it, as long as yeast DNA was also absent. This suggests that alphoid DNA can generate the condensed chromatin structure at the centromere.

Molecular mapping of the centromeres of tomato chromosomes 7 and 9

The centromeres of two tomato chromosomes have been precisely localized on the molecular linkage map through dosage analysis of trisomic stocks. To map the centromeres of chromosomes 7 and 9, complementary telo-, secondary, and tertiary trisomic stocks were used to assign DNA markers to their respective chromosome arms and thus to localize the centromere at the junction of the short and long arms. It was found that both centromeres are situated within a cluster of cosegregating markers. In an attempt to order the markers within the centric clusters, genetic maps of the centromeric regions of chromosomes 7 and 9 were constructed from F2 populations of 1620 Lycopersicon esculentum x L. pennellii (E x P) plants and 1640 L. esculentum x L. pimpinellifolium (E x PM) plants. Despite the large number of plants analyzed, very few recombination events were detected in the centric regions, indicating a significant suppression of recombination at this region of the chromosome. The fact that recombination suppression is equally strong in crosses between closely related (E x PM) and remotely related (E x P) parents suggests that centromeric suppression is not due to DNA sequence mismatches but to some other mechanism. The greatest number of centromeric markers was resolved in the L. esculentum x L. pennellii F2 population. The centromere of chromosome 7 is surrounded by eight cosegregating markers: three on the short arm, five on the long arm. Similarly, the centric region of chromosome 9 contains ten cosegregating markers including one short arm marker and nine long arm markers. The localization of centromeres to precise intervals on the molecular linkage map represents the first step towards the characterization and ultimate isolation of tomato centromeres.

Characterization and genetic mapping of simple repeat sequences in the tomato genome

Tomato genomic libraries were screened for the presence of simple sequence repeats (SSRs) with seventeen synthetic oligonucleotide probes, consisting of 2- to 5-basepair motifs repeated in tandem. GAn and GTn sequences were found to occur most frequently in the tomato genome (every 1.2 Mb), followed by ATTn and GCCn (every 1.4 Mb and 1.5 Mb, respectively). In contrast, only ATn and GAn microsatellites (n > 7) were found to be frequent in the GenBank database, suggesting that other motifs may be preferentially located away from genes. Polymorphism of microstellites was measured by PCR amplification of individual loci of by Southern hybridization, using a set of ten tomato cultivars. Surprisingly, only two of the nine microsatellite clones surveyed (five GTn, three GAn and one ATTn), showed length variation among these accessions. Polymorphism was also very limited between Lycopersicon esculentum and L. pennelli, two distant species. Southern analysis using the seventeen oligonucleotide probes identified GATAn and GAAAn as useful motifs for the detection of multiple polymorphic fragments among tomato cultivars. To determine the structure of microsatellite loci, a GAn probe was used for hybridization at low stringency on a small insert genomic library, and randomly selected clones were analyzed. GAn based motifs of increasing complexity were found, indicating that simple dinucleotide sequences may have evolved into larger tandem repeats such as minisatellites as a result of basepair substitution, replication slippage, and possibly unequal crossing-over. Finally, we genetically mapped loci corresponding to two amplified microsatellites, as well as nine large hypervariable fragments detected by Southern hybridization with a GATA8 probe. All loci are located around putative tomato centromeres. This may contribute to understanding of the structure of centromeric regions in tomato.

Elements of chromosome structure and function in fission yeast

The investigation of fission yeast chromosome structure and function has moved rapidly over the past 10 years. The isolation of replication origins, telomeres and centromeres has allowed the development of minichromosomes, a yeast artificial chromosome (YAC)-like cloning system and investigations into chromosome segregation and behaviour during mitosis and meiosis. Many mutants have been isolated which are defective in chromosome segregation. The development of the fluorescent in-situ hybridization (FISH) technique for use in S. pombe has allowed the localization of centromeres and telomeres throughout mitosis and meiosis. In combination with indirect immunofluorescence to detect spindle and chromosomal proteins, the FISH technique should further advance our understanding of fission yeast chromosome structure and function. The recent discovery of a heterochromatin-like structure mediating transcriptional repression at centromeres reinforces the notion that fission yeast centromeres are similar to those of larger eukaryotes. Further characterization of such phenomena will accelerate the genetic dissection of this important chromosomal element.

A large circular minichromosome of Schizosaccharomyces pombe requires a high dose of type II DNA topoisomerase for its stabilization

We have constructed circular minichromosomes, ranging in size from 36 to 110 kb, containing the centromeric repeats of Schizosaccharomyces pombe cen3. Comparison of their mitotic stability showed that the circular minichromosomes became more unstable with increasing in size, however, a linear cen3 minichromosome, which is almost the same size as the largest circular one tested, does not show such instability. High levels of expression of the top2+ (type II DNA topoisomerase; topo II) but not top1+ gene (type I DNA topoisomerase) suppressed the instability of the largest circular minichromosome, whereas partial inactivation of topo II dramatically destabilized the minichromosome. A mutant topo II, defective in nuclear localization but still retaining its in vitro relaxation activity, did not stabilize the circular minichromosome. These results indicate that endogenous type II DNA topoisomerase is insufficient for accurate segregation of the circular minichromosome. In addition, the replication of the minichromosomal DNA appears to proceed normally, because the presence of the unstable minichromosome did not cause G2 delay. A likely cause of the instability is intertwining of the minichromosome DNA possibly occurring after DNA replication. An interaction between topo II and the centromeric repeats is implied by the finding that multiple copies of the centromeric repeat, dg-dh, affect stability of the minichromosome similarly to top2+ gene dosage.