Effects of excess centromeres and excess telomeres on chromosome loss rates.

The linear chromosomes of eukaryotes contain specialized structures to ensure their faithful replication and segregation to daughter cells. Two of these structures, centromeres and telomeres, are limited, respectively, to one and two copies per chromosome. It is possible that the proteins that interact with centromere and telomere DNA sequences are present in limiting amounts and could be competed away from the chromosomal copies of these elements by additional copies introduced on plasmids. We have introduced excess centromeres and telomeres into Saccharomyces cerevisiae and quantitated their effects on the rates of loss of chromosome III and chromosome VII by fluctuation analysis. We show that (i) 600 new telomeres have no effect on chromosome loss; (ii) an average of 25 extra centromere DNA sequences increase the rate of chromosome III loss from 0.4 x 10(-4) events per cell division to 1.3 x 10(-3) events per cell division; (iii) centromere DNA (CEN) sequences on circular vectors destabilize chromosomes more effectively than do CEN sequences on 15-kb linear vectors, and transcribed CEN sequences have no effect on chromosome stability. We discuss the different effects of extra centromere and telomere DNA sequences on chromosome stability in terms of how the cell recognizes these two chromosomal structures.     

Dicentric chromosome formation and epigenetics of centromere formation in plants

Plant centromeres are generally composed of tandem arrays of simple repeats that form a complex chromosome locus where the kinetochore forms and microtubules attach during mitosis and meiosis. Each chromosome has one centromere region, which is essential for accurate division of the genetic material. Recently, chromosomes containing two centromere regions (called dicentric chromosomes) have been found in maize and wheat. Interestingly, some dicentric chromosomes are stable because only one centromere is active and the other one is inactivated. Because such arrays maintain their typical structure for both active and inactive centromeres, the specification of centromere activity has an epigenetic component independent of the DNA sequence. Under some circumstances, the inactive centromeres may recover centromere function, which is called centromere reactivation. Recent studies have highlighted the important changes, such as DNA methylation and histone modification, that occur during centromere inactivation and reactivation.     

Identification and characterization of the centromere from chromosome XIV in Saccharomyces cerevisiae.

A functional centromere located on a small DNA restriction fragment from Saccharomyces cerevisiae was identified as CEN14 by integrating centromere-adjacent DNA plus the URA3 gene by homologous recombination into the yeast genome and then by localizing the URA3 gene to chromosome XIV by standard tetrad analysis. DNA sequence analysis revealed that CEN14 possesses sequences (elements I, II, and III) that are characteristic of other yeast centromeres. Mitotic and meiotic analyses indicated that the CEN14 function resides on a 259-base-pair (bp) RsaI-EcoRV restriction fragment, containing sequences that extend only 27 bp to the right of the element I to III region. In conjunction with previous findings on CEN3 and CEN11, these results indicate that the specific DNA sequences required in cis for yeast centromere function are contained within a region about 150 bp in length.     

Centromere function on minichromosomes isolated from budding yeast.

Centromeres are a complex of centromere DNA (CEN DNA) and specific factors that help mediate microtubule-dependent movement of chromosomes during mitosis. Minichromosomes can be isolated from budding yeast in a way that their centromeres retain the ability to bind microtubules in vitro. Here, we use the binding of these minichromosomes to microtubules to gain insight into the properties of centromeres assembled in vivo. Our results suggest that neither chromosomal DNA topology nor proximity of telomeres influence the cell's ability to assemble centromeres with microtubule-binding activity. The microtubule-binding activity of the minichromosome's centromere is stable in the presence of competitor CEN DNA, suggesting that the complex between the minichromosome CEN DNA and proteins directly bound to it is very stable. The efficiency of centromere binding to microtubules is dependent upon the concentration of microtubule polymer and is inhibited by ATP. These properties are similar to those exhibited by mechanochemical motors. The binding of minichromosomes to microtubules can be inactivated by the presence of 0.2 M NaCl and then reactivated by restoring NaCl to 0.1 M. In 0.2 M NaCl, some centromere factor(s) bind to microtubules, whereas other(s) apparently remain bound to the minichromosome's CEN DNA. Therefore, the yeast centromere appears to consist of two domains: the first consists of a stable core containing CEN DNA and CEN DNA-binding proteins; the second contains a microtubule-binding component(s). The molecular functions of this second domain are discussed.     

Size threshold for Saccharomyces cerevisiae chromosomes: generation of telocentric chromosomes from an unstable minichromosome.

A 9-kilobase pair CEN4 linear minichromosome constructed in vitro transformed Saccharomyces cerevisiae with high frequency but duplicated or segregated inefficiently in most cells. Stable transformants were only produced by events which fundamentally altered the structure of the minichromosome: elimination of telomeres, alteration of the centromere, or an increase of fivefold or greater in its size. Half of the stable transformants arose via homologous recombination between an intact chromosome IV and the CEN4 minichromosome. This event generated a new chromosome from each arm of chromosome IV. The other "arm" of each new chromosome was identical to one "arm" of the unstable minichromosome. Unlike natural yeast chromosomes, these new chromosomes were telocentric: their centromeres were either 3.9 or 5.4 kilobases from one end of the chromosome. The mitotic stability of the telocentric chromosome derived from the right arm of chromosome IV was determined by a visual assay and found to be comparable to that of natural yeast chromosomes. Both new chromosomes duplicated, paired, and segregated properly in meiosis. Moreover, their structure, as deduced from mobilities in orthogonal field gels, did not change with continued mitotic growth or after passage through meiosis, indicating that they did not give rise to isochromosomes or suffer large deletions or additions. Thus, in S. cerevisiae the close spacing of centromeres and telomeres on a DNA molecule of chromosomal size does not markedly alter the efficiency with which it is maintained. Taken together these data suggest that there is a size threshold below which stable propagation of linear chromosomes is no longer possible.     

CSE4 genetically interacts with the Saccharomyces cerevisiae centromere DNA elements CDE I and CDE II but not CDE III. Implications for the path of the centromere dna around a cse4p variant nucleosome

Each Saccharomyces cerevisiae chromosome contains a single centromere composed of three conserved DNA elements, CDE I, II, and III. The histone H3 variant, Cse4p, is an essential component of the S. cerevisiae centromere and is thought to replace H3 in specialized nucleosomes at the yeast centromere. To investigate the genetic interactions between Cse4p and centromere DNA, we measured the chromosome loss rates exhibited by cse4 cen3 double-mutant cells that express mutant Cse4 proteins and carry chromosomes containing mutant centromere DNA (cen3). When compared to loss rates for cells carrying the same cen3 DNA mutants but expressing wild-type Cse4p, we found that mutations throughout the Cse4p histone-fold domain caused surprisingly large increases in the loss of chromosomes carrying CDE I or CDE II mutant centromeres, but had no effect on chromosomes with CDE III mutant centromeres. Our genetic evidence is consistent with direct interactions between Cse4p and the CDE I-CDE II region of the centromere DNA. On the basis of these and other results from genetic, biochemical, and structural studies, we propose a model that best describes the path of the centromere DNA around a specialized Cse4p-nucleosome.     

Replication forks pause at yeast centromeres.

The 120 bp of yeast centromeric DNA is tightly complexed with protein to form a nuclease-resistant core structure 200 to 240 bp in size. We have used two-dimensional agarose gel electrophoresis to analyze the replication of the chromosomal copies of yeast CEN1, CEN3, and CEN4 and determine the fate of replication forks that encounter the protein-DNA complex at the centromere. We have shown that replication fork pause sites are coincident with each of these centromeres and therefore probably with all yeast centromeres. We have analyzed the replication of plasmids containing mutant derivatives of CEN3 to determine whether the replication fork pause site is a result of an unusual structure adopted by centromere DNA or a result of the protein-DNA complex formed at the centromere. The mutant centromere derivatives varied in function as well as the ability to form the nuclease-resistant core structure. The data obtained from analysis of these derivatives indicate that the ability to cause replication forks to pause correlates with the ability to form the nuclease-resistant core structure and not with the presence or absence of a particular DNA sequence. Our findings further suggest that the centromere protein-DNA complex is present during S phase when replication forks encounter the centromere and therefore may be present throughout the cell cycle.     

The centromere of budding yeast

Stable maintenance of genetic information during meiosis and mitosis is dependent on accurate chromosome transmission. The centromere is a key component of the segregational machinery that couples chromosomes with the spindle apparatus. Most of what is known about the structure and function of the centromeres has been derived from studies on yeast cells. In Saccharomyces cerevisiae, the centromere DNA requirements for mitotic centromere function have been defined and some of the proteins required for an active complex have been identified. Centromere DNA and the centromere proteins form a complex that has been studied extensively at the chromatin level. Finally, recent findings suggest that assembly and activation of the centromere are integrated in tethe cell cycle.     

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.     

Chromatin conformation of yeast centromeres

The centromere region of Saccharomyces cerevisiae chromosome III has been replaced by various DNA fragments from the centromere regions of yeast chromosomes III and XI. A 289-base pair centromere (CEN3) sequence can stabilize yeast chromosome III through mitosis and meiosis. The orientation of the centromeric fragments within chromosome III has no effect on the normal mitotic or meiotic behavior of the chromosome. The structural integrity of the centromere region in these genomic substitution strains was examined by mapping nucleolytic cleavage sites within the chromatin DNA. A nuclease-protected centromere core of 220-250 base pairs was evident in all of the genomic substitution strains. The position of the protected region is determined strictly by the centromere DNA sequence. These results indicate that the functional centromere core is contained within 220- 250 base pairs of the chromatin DNA that is structurally distinct from the flanking nucleosomal chromatin.     

Mutations in Cen3 Cause Aberrant Chromosome Segregation during Meiosis in Saccharomyces Cerevisiae

We investigated the structural requirements of the centromere from chromosome III (CEN3) of Saccharomyces cerevisiae by analyzing the ability of chromosomes with CEN3 mutations to segregate properly during meiosis. We analyzed diploid cells in which one or both copies of chromosome III carry a mutant centromere in place of the wild-type centromere and found that some alterations in the length, base composition and primary sequence characteristics of the central A+T-rich region (CDE II) of the centromere had a significant effect on the ability of the chromosome to segregate properly through meiosis. Chromosomes containing mutations which delete a portion of CDE II showed a high rate of premature disjunction at meiosis I. Chromosomes containing point mutations in CDE I or lacking CDE I appeared to segregate properly through meiosis; however, plasmids carrying centromeres with CDE I completely deleted showed an increased frequency of segregation to nonsister spores.     

Nucleosome depletion alters the chromatin structure of Saccharomyces cerevisiae centromeres.

Saccharomyces cerevisiae centromeric DNA is packaged into a highly nuclease-resistant chromatin core of approximately 200 base pairs of DNA. The structure of the centromere in chromosome III is somewhat larger than a 160-base-pair nucleosomal core and encompasses the conserved centromere DNA elements (CDE I, II, and III). Extensive mutational analysis has revealed the sequence requirements for centromere function. Mutations affecting the segregation properties of centromeres also exhibit altered chromatin structures in vivo. Thus the structure, as delineated by nuclease digestion, correlated with functional centromeres. We have determined the contribution of histone proteins to this unique structural organization. Nucleosome depletion by repression of either histone H2B or H4 rendered the cell incapable of chromosome segregation. Histone repression resulted in increased nuclease sensitivity of centromere DNA, with up to 40% of CEN3 DNA molecules becoming accessible to nucleolytic attack. Nucleosome depletion also resulted in an alteration in the distribution of nuclease cutting sites in the DNA surrounding CEN3. These data provide the first indication that authentic nucleosomal subunits flank the centromere and suggest that nucleosomes may be the central core of the centromere itself.     

Chromosome condensation and sister chromatid pairing in budding yeast

We have developed a fluorescent in situ hybridization (FISH) method to examine the structure of both natural chromosomes and small artificial chromosomes during the mitotic cycle of budding yeast. Our results suggest that the pairing of sister chromatids: (a) occurs near the centromere and at multiple places along the chromosome arm as has been observed in other eukaryotic cells; (b) is maintained in the absence of catenation between sister DNA molecules; and (c) is independent of large blocks of repetitive DNA commonly associated with heterochromatin. Condensation of a unique region of chromosome XVI and the highly repetitive ribosomal DNA (rDNA) cluster from chromosome XII were also examined in budding yeast. Interphase chromosomes were condensed 80-fold relative to B form DNA, similar to what has been observed in other eukaryotes, suggesting that the structure of interphase chromosomes may be conserved among eukaryotes. While additional condensation of budding yeast chromosomes were observed during mitosis, the level of condensation was less than that observed for human mitotic chromosomes. At most stages of the cell cycle, both unique and repetitive sequences were either condensed or decondensed. However, in cells arrested in late mitosis (M) by a cdc15 mutation, the unique DNA appeared decondensed while the repetitive rDNA region appeared condensed, suggesting that the condensation state of separate regions of the genome may be regulated differently. The ability to monitor the pairing and condensation of sister chromatids in budding yeast should facilitate the molecular analysis of these processes as well as provide two new landmarks for evaluating the function of important cell cycle regulators like p34 kinases and cyclins. Finally our FISH method provides a new tool to analyze centromeres, telomeres, and gene expression in budding yeast.     

Yeast centromere DNA is in a unique and highly ordered structure in chromosomes and small circular minichromosomes

We have examined the chromatin structure of the centromere regions of chromosomes III and XI in yeast by using cloned functional centromere DNAs (CEN3 and CEN11) as labeled probes. When chromatin from isolated nuclei is digested with micrococcal nuclease and the resulting DNA fragments separated electrophoretically and blotted to nitrocellulose filters, the centromeric nucleosomal sub-units are resolved into significantly more distinct ladders than are those from the bulk of the chromatin. A discrete protected region of 220–250 bp of CEN sequence flanked by highly nuclease-sensitive sites was revealed by mapping the exact nuclease cleavage sites within the centromeric chromatin. On both sides of this protected region, highly phased and specific nuclease cutting sites exist at nucleosomal intervals (160 bp) for a total length of 12–15 nucleosomal subunits. The central protected region in the chromatin of both centromeres spans the 130 bp segment that exhibits the highest degree of sequence homology (71%) between functional CEN3 and CEN11 DNAs. This unique chromatin structure is maintained on CEN sequences introduced into yeast on autonomously replicating plasmids, but is not propagated through foreign DNA sequences flanking the inserted yeast DNA.     

Mutational analysis of centromere DNA from chromosome VI of Saccharomyces cerevisiae.

Saccharomyces cerevisiae centromeres have a characteristic 120-base-pair region consisting of three distinct centromere DNA sequence elements (CDEI, CDEII, and CDEIII). We have generated a series of 26 CEN mutations in vitro (including 22 point mutations, 3 insertions, and 1 deletion) and tested their effects on mitotic chromosome segregation by using a new vector system. The yeast transformation vector pYCF5 was constructed to introduce wild-type and mutant CEN DNAs onto large, linear chromosome fragments which are mitotically stable and nonessential. Six point mutations in CDEI show increased rates of chromosome loss events per cell division of 2- to 10-fold. Twenty mutations in CDEIII exhibit chromosome loss rates that vary from wild type (10(-4)) to nonfunctional (greater than 10(-1)). These results directly identify nucleotides within CDEI and CDEIII that are required for the specification of a functional centromere and show that the degree of conservation of an individual base does not necessarily reflect its importance in mitotic CEN function.     

The evolutionary life cycle of the resilient centromere

The centromere is a chromosomal structure that is essential for the accurate segregation of replicated eukaryotic chromosomes to daughter cells. In most centromeres, the underlying DNA is principally made up of repetitive DNA elements, such as tandemly repeated satellite DNA and retrotransposable elements. Paradoxically, for such an essential genomic region, the DNA is rapidly evolving both within and between species. In this review, we show that the centromere locus is a resilient structure that can undergo evolutionary cycles of birth, growth, maturity, death and resurrection. The birth phase is highlighted by examples in humans and other organisms where centromere DNA deletions or chromosome rearrangements can trigger the epigenetic assembly of neocentromeres onto genomic sites without typical features of centromere DNA. In addition, functional centromeres can be generated in the laboratory using various methodologies. Recent mapping of the foundation centromere mark, the histone H3 variant CENP-A, onto near-complete genomes has uncovered examples of new centromeres which have not accumulated centromere repeat DNA. During the growth period of the centromere, repeat DNA begins to appear at some, but not all, loci. The maturity stage is characterised by centromere repeat accumulation, expansions and contractions and the rapid evolution of the centromere DNA between chromosomes of the same species and between species. This stage provides inherent centromere stability, facilitated by repression of gene activity and meiotic recombination at and around the centromeres. Death to a centromere can result from genomic instability precipitating rearrangements, deletions, accumulation of mutations and the loss of essential centromere binding proteins. Surprisingly, ancestral centromeres can undergo resurrection either in the field or in the laboratory, via as yet poorly understood mechanisms. The underlying principle for the preservation of a centromeric evolutionary life cycle is to provide resilience and perpetuity for the all-important structure and function of the centromere.     

Human artificial chromosomes with alpha satellite-based de novo centromeres show increased frequency of nondisjunction and anaphase lag

Human artificial chromosomes have been used to model requirements for human chromosome segregation and to explore the nature of sequences competent for centromere function. Normal human centromeres require specialized chromatin that consists of alpha satellite DNA complexed with epigenetically modified histones and centromere-specific proteins. While several types of alpha satellite DNA have been used to assemble de novo centromeres in artificial chromosome assays, the extent to which they fully recapitulate normal centromere function has not been explored. Here, we have used two kinds of alpha satellite DNA, DXZ1 (from the X chromosome) and D17Z1 (from chromosome 17), to generate human artificial chromosomes. Although artificial chromosomes are mitotically stable over many months in culture, when we examined their segregation in individual cell divisions using an anaphase assay, artificial chromosomes exhibited more segregation errors than natural human chromosomes (P < 0.001). Naturally occurring, but abnormal small ring chromosomes derived from chromosome 17 and the X chromosome also missegregate more than normal chromosomes, implicating overall chromosome size and/or structure in the fidelity of chromosome segregation. As different artificial chromosomes missegregate over a fivefold range, the data suggest that variable centromeric DNA content and/or epigenetic assembly can influence the mitotic behavior of artificial chromosomes.     

Functional selection for the centromere DNA from yeast chromosome VIII.

Centromeres are essential components of eucaryotic chromosomes. In budding yeast, up to now, 15 of the 16 centromere DNAs have been isolated. Here we report the functional isolation and characterization of CEN8, the last of the yeast centromeres missing. The centromere consensus sequence for the 16 chromosomes in this organism is presented.     

A dicentric chromosome of Drosophila melanogaster showing alternate centromere inactivation

Dicentric chromosomes are rarely found, because they interfere with normal cell division causing chromosome instability. By in situ hybridization of region-specific heterochromatic yeast artificial chromosomes we have found that the artificially generated C(1)A chromosome of Drosophila melanogaster has two potential centromeres: one carries all the sequences of the centromere of the Y chromosome and the other carries only a part of the Y centromeric region that is rich in telomere-related sequences. Immunostaining with anti-Bub1 (a kinetochore-specific marker) shows that, in spite of the differences in sequence, both centromeres can be active although as a rule only one at a time. In a small fraction of the chromosomes centromere inactivation is incomplete, giving rise to true dicentric chromosomes. The centromere inactivation is clonally inherited, providing a new example of epigenetic chromosome imprinting and the possibility of genetically dissecting this process. The involvement of telomere-related sequences in centromere function is discussed. Received: 15 September 1999; in revised form: 21 November 1999 / Accepted: 24 December 1999