The centromeric K-type repeat and the central core are together sufficient to establish a functional Schizosaccharomyces pombe centromere.

The DNA requirements for centromere function in fission yeast have been investigated using a minichromosome assay system. Critical elements of Schizosaccharomyces pombe centromeric DNA are portions of the centromeric central core and sequences within a 2.1-kilobase segment found on all three chromosomes as part of the K-type (K/K"/dg) centromeric repeat. The S. pombe centromeric central core contains DNA sequences that appear functionally redundant, and the inverted repeat motif that flanks the central core in all native fission yeast centromeres is not essential for centromere function in circular minichromosomes. Tandem copies of centromeric repeat K", in conjunction with the central core, exert an additive effect on centromere function, increasing minichromosome mitotic stability with each additional copy. Centromeric repeats B and L, however, and parts of the central core and its core-associated repeat are dispensable and cannot substitute for K-type sequences. Several specific protein binding sites have been identified within the centromeric K-type repeat, consistent with a recently proposed model for centromere/kinetochore function in S. pombe.     

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

Gross variations in the structure of the centromere of Schizosaccharomyces pombe chromosome III (cen3) were apparent following characterization of this centromeric DNA in strain Sp223 and comparison of the structure with that of cen3 in three other commonly used laboratory strains. Further differences in centromere structure were revealed when the structure of the centromere of S. pombe chromosome II (cen2) was compared among common laboratory strains and when the structures of cen2 and cen3 from our laboratory strains were compared with those reported from other laboratories. Differences observed in cen3 structure include variations in the arrangement of the centromeric K repeats and an inverted orientation of the conserved centromeric central core. In addition, we have identified two laboratory strains that contain a minimal cen2 repeat structure that lacks the tandem copies of the cen2-specific block of K-L-B-J repeats characteristic of Sp223 cen2. We have also determined that certain centromeric DNA structural motifs are relatively conserved among the four laboratory strains and eight additional wild-type S. pombe strains isolated from various food and beverage sources. We conclude that in S. pombe, as in higher eukaryotes, the centromere of a particular chromosome is not a defined genetic locus but can contain significant variability. However, the basic DNA structural motif of a central core immediately flanked by inverted repeats is a common parameter of the S. pombe centromere.     

Identification of DNA regions required for mitotic and meiotic functions within the centromere of Schizosaccharomyces pombe chromosome I.

We have determined the structural organization and functional roles of centromere-specific DNA sequence repeats in cen1, the centromere region from chromosome I of the fission yeast Schizosaccharomyces pombe. cen1 is composed of various classes of repeated sequences designated K', K"(dgl), L, and B', arranged in a 34-kb inverted repeat surrounding a 4- to 5-kb nonhomologous central core. Artificial chromosomes containing various portions of the cen1 region were constructed and assayed for mitotic and meiotic centromere function in S. pombe. Deleting K' and L from the distal portion of one arm of the inverted repeat had no effect on mitotic centromere function but resulted in greatly increased precocious sister chromatid separation in the first meiotic division. A centromere completely lacking K' and L, but containing the central core, one copy of B' and K" in one arm, and approximately 2.5 kb of the core-proximal portion of B' in the other arm, was also fully functional mitotically but again did not maintain sister chromatid attachment in meiosis I. However, deletion of K" from this minichromosome resulted in complete loss of centromere function. Thus, one copy of at least a portion of the K" (dgl) repeat is absolutely required but is not sufficient for S. pombe centromere function. The long centromeric inverted-repeat region must be relatively intact to maintain sister chromatid attachment in meiosis I.     

Physical mapping of origins of replication in the fission yeast Schizosaccharomyces pombe.

We isolated four fragments from the Schizosaccharomyces pombe genome that mediate autonomous replication. A two-dimensional gel analysis revealed that in each case initiation could be mapped to within the S. pombe sequences. In three of the fragments, initiation could be mapped to one discrete location. In the fourth fragment, subcloning and two-dimensional gel analysis suggested that two discrete origins of replication were located within 3 kb of each other. When in proximity, usually only one of these origins fired, suggesting origin interference. Two-dimensional gel analysis of the four origin fragments at their genomic locations demonstrated that each is used in the chromosomes, but in only a subset of cells or cell divisions. The S. pombe genome appears to contain many discrete origins, not all of which fire in any given cell and some of which are closely spaced. Not I/Sfi I mapping of the five origins from this and a previous study indicates that they are randomly distributed throughout the genome and appear to be representative of chromosomal origins of replication in this organism. We compare the features of S. pombe replication origins with those of S. cerevisiae and animal cells.     

Fission yeast homologs of human CENP-B have redundant functions affecting cell growth and chromosome segregation

Two functionally important DNA sequence elements in centromeres of the fission yeast Schizosaccharomyces pombe are the centromeric central core and the K-type repeat. Both of these DNA elements show internal functional redundancy that is not correlated with a conserved DNA sequence. Specific, but degenerate, sequences in these elements are bound in vitro by the S. pombe DNA-binding proteins Abp1p (also called Cbp1p) and Cbhp, which are related to the mammalian centromere DNA-binding protein CENP-B. In this study, we determined that Abp1p binds to at least one of its target sequences within S. pombe centromere II central core (cc2) DNA with an affinity (K(s) = 7 x 10(9) M(-1)) higher than those of other known centromere DNA-binding proteins for their cognate targets. In vivo, epitope-tagged Cbhp associated with centromeric K repeat chromatin, as well as with noncentromeric regions. Like abp1(+)/cbp1(+), we found that cbh(+) is not essential in fission yeast, but a strain carrying deletions of both genes (Deltaabp1 Deltacbh) is extremely compromised in growth rate and morphology and missegregates chromosomes at very high frequency. The synergism between the two null mutations suggests that these proteins perform redundant functions in S. pombe chromosome segregation. In vitro assays with cell extracts with these proteins depleted allowed the specific assignments of several binding sites for them within cc2 and the K-type repeat. Redundancy observed at the centromere DNA level appears to be reflected at the protein level, as no single member of the CENP-B-related protein family is essential for proper chromosome segregation in fission yeast. The relevance of these findings to mammalian centromeres is discussed.     

Functional analysis of a centromere from fission yeast: a role for centromere-specific repeated DNA sequences.

A circular minichromosome carrying functional centromere sequences (cen2) from Schizosaccharomyces pombe chromosome II behaves as a stable, independent genetic linkage group in S. pombe. The cen2 region was found to be organized into four large tandemly repeated sequence units which span over 80 kilobase pairs (kb) of untranscribed DNA. Two of these units occurred in a 31-kb inverted repeat that flanked a 7-kb central core of nonhomology. The inverted repeat region had centromere function, but neither the central core alone nor one arm of the inverted repeat was functional. Deletion of a portion of the repeated sequences that flank the central core had no effect on mitotic segregation functions or on meiotic segregation of a minichromosome to two of the four haploid progeny, but drastically impaired centromere-mediated maintenance of sister chromatid attachment in meiosis I. This requirement for centromere-specific repeated sequences could not be satisfied by introduction of random DNA sequences. These observations suggest a function for the heterochromatic repeated DNA sequences found in the centromere regions of higher eucaryotes.     

Physical location of a HSP70 gene homologue on the centromere of chromosome 1B of wheat ( Triticum aestivum L.)

Cereal centromeres consist of a complex organization of repetitive DNA sequences. Several repetitive DNA sequences are common amongst members of the Triticeae family, and others are unique to particular species. The organization of these repetitive elements and the abundance of other types of DNA sequences in cereal centromeres are largely unknown. In this study, we have used wheat-rye translocation lines to physically map 1BL.1RS centromeric breakpoints and molecular probes to obtain further information on the nature of other types of centromeric DNA sequences. Our results, using the rye-specific centromeric sequence, pAWRC.1, indicate that 1BL.1RS contains a small portion of the centromere from 1R of rye. Further studies used molecular markers to identify centromeric segments on wheat group-1 chromosomes. Selected RFLP markers, clustered around the centromere of wheat homoeologous group-1S chromosomes, were chosen as probes during Southern hybridization. One marker, PSR161, identified a small 1BS segment in all 1BL.1RS lines. This segment maps proximal to pAWRC.1 in 1BL.1RS and on the centromere of 1B. Sequence analysis of PSR161 showed high homology to HSP70 genes and Northern hybridization showed that this gene is constitutively expressed in leaf tissue and induced by heat shock and light stimuli. The significance of this work with respect to centromere organization and the possible significance of this HSP70 gene homologue are discussed. Received: 12 March 2001 / Accepted: 14 June 2001     

Composite motifs and repeat symmetry in S. pombe centromeres: direct analysis by integration of NotI restriction sites

S. pombe centromeres are large and complex. We introduced a method that enables us to characterize directly centromere DNAs. Genomic DNA fragments containing cen1, cen2, or cen3, respectively, are made by cleaving NotI sites integrated on target sites and are partially restricted for long-range mapping in PFG electrophoresis. The 40 kb long cen1 consists of two inverted approximately 10 kb motifs, each containing centromeric elements dg and dh, flanked by a central region. In cen2, three motifs are arranged in inverted and direct orientations with flanking domains, making up the approximately 70 kb long repetitious region. In cen3, approximately 15 copies of dg-dh constitute a region longer than 100 kb. A set of inverted motifs with an approximately 15 kb central region might be a prototype for the S. pombe centromeres. The motifs appear to play a role in chromosome stability and segregation. Their action may be additive, and the mutual directions of dg and dh inside a motif may not be essential for function.     

A novel cis-acting centromeric DNA element affects S. pombe centromeric chromatin structure at a distance

The chromatin structure of the central core region of Schizosaccharomyces pombe centromeric DNA is unusual. This distinctive chromatin structure is associated only with central core sequences in a functional context and is modulated by a novel cis-acting DNA element (centromere enhancer) within the functionally critical K centromeric repeat, which is found in multiple copies in all three S. pombe centromeres. The centromere enhancer alters central core chromatin structure from a distance and in an orientation-independent manner without altering the nucleosomal packaging of sequences between the enhancer and the central core. These findings suggest a functionally relevant structural interaction between the enhancer and the centromeric central core brought about by DNA looping.     

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.     

Structural organization and functional analysis of centromeric DNA in the fission yeast Schizosaccharomyces pombe.

Centromeric DNA in the fission yeast Schizosaccharomyces pombe was isolated by chromosome walking and by field inversion gel electrophoretic fractionation of large genomic DNA restriction fragments. The centromere regions of the three chromosomes were contained on three SalI fragments (120 kilobases [kb], chromosome III; 90 kb, chromosome II; and 50 kb, chromosome I). Each fragment contained several repetitive DNA sequences, including repeat K (6.4 kb), repeat L (6.0 kb), and repeat B, that occurred only in the three centromere regions. On chromosome II, these repeats were organized into a 35-kb inverted repeat that included one copy of K and L in each arm of the repeat. Site-directed integration of a plasmid containing the yeast LEU2 gene into K repeats at each of the centromeres or integration of an intact K repeat into a chromosome arm had no effect on mitotic or meiotic centromere function. The centromeric repeat sequences were not transcribed and possessed many of the properties of constitutive heterochromatin. Thus, S. pombe is an excellent model system for studies on the role of repetitive sequence elements in centromere function.     

Identification of a predominant replication origin in fission yeast.

We have identified five autonomously replicating sequences (ARSs) in a 100 kbp region of the Schizosaccharomyces pombe chromosome II. Analyses of replicative intermediates of the chromosome DNA by neutral/neutral two-dimensional gel electrophoresis demonstrated that at least three of these ARS loci operate as chromosomal replication origins. One of the loci,ori2004, was utilized in almost every cell cycle, while the others were used less frequently. The frequency of initiation from the respective chromosomal replication origin was found to be roughly proportional to the efficiency of autonomous replication of the corresponding ARS plasmid. Replication from ori2004 was initiated within a distinct region almost the same as that for replication of the ARS plasmid. These results showed that the ori2004 region of approximately 3 kbp contains all the cis elements essential for initiation of chromosome replication.     

Centromeres of budding and fission yeasts

Centromeres of the budding yeast Saccharomyces cerevisiae are structurally relatively simple, are specified by only about 125 base pairs of DNA, and contain no repeated DNA sequences. The centromere regions in the fission yeast Schizosaccharomyces pombe span many kilobase pairs of DNA and contain repeated DNA sequences that appear to be necessary for full centromere function. A portion of the repeated sequences is organized into a large inverted repeated structure in the centromere region of each S. pombe chromosome. Fission yeast provides an excellent model system for studying the role of repeated DNA sequences in centromere function.     

Specific initiation at an origin of replication from Schizosaccharomyces pombe.

Using a genetic assay for efficient autonomous replication, we have isolated from Schizosaccharomyces pombe a 6.2-kb fragment which shows the properties expected of an origin of DNA replication in S. pombe. A 2.8-kb subclone of the fragment has the same replication properties. Two-dimensional gel analysis of replication intermediates throughout plasmids carrying the 6.2- or 2.8-kb fragments shows that replication initiates only in a specific region, which can be localized to within several hundred base pairs, in the fragments. This region is also a site of replication initiation in the S. pombe chromosome where the fragments normally reside. These results provide strong evidence that initiation of replication in S. pombe is localized and mediated by specific DNA sequence signals.     

An origin of replication and a centromere are both needed to establish a replicative plasmid in the yeast Yarrowia lipolytica.

Two DNA fragments displaying ARS activity on plasmids in the yeast Yarrowia lipolytica have previously been cloned and shown to harbor centromeric sequences (P. Fournier, A. Abbas, M. Chasles, B. Kudla, D. M. Ogrydziak, D. Yaver, J.-W. Xuan, A. Peito, A.-M. Ribet, C. Feynerol, F. He, and C. Gaillardin, Proc. Natl. Acad. Sci. USA 90:4912-4916, 1993; and P. Fournier, L. Guyaneux, M. Chasles, and C. Gaillardin, Yeast 7:25-36, 1991). We have used the integration properties of centromeric sequences to show that all Y. lipolytica ARS elements so far isolated are composed of both a replication origin and a centromere. The sequence and the distance between the origin and centromere do not seem to play a critical role, and many origins can function in association with one given centromere. A centromeric plasmid can therefore be used to clone putative chromosomal origins coming from several genomic locations, which confer the replicative property on the plasmid. The DNA sequences responsible for initiation in plasmids are short (several hundred base pairs) stretches which map close to or at replication initiation sites in the chromosome. Their chromosomal deletion abolishes initiation, but changing their chromosomal environment does not.     

Centromeric DNA from Saccharomyces uvarum is functional in Saccharomyces cerevisiae

Previous comparisons of centromeric DNA sequences in laboratory strains of Saccharomyces cerevisiae have revealed conserved sequences within 120 base pairs (bp) which appear to be essential for centromere function. We wanted to find out whether centromeric DNA in Saccharomyces strains with different degrees of DNA sequence divergence carry the same conserved sequences or not. Bam HI DNA fragments from two S. cerevisiae strains and one Saccharomyces uvarum strain were cloned into a centromere selection vector and tested for centromere function in a S. cerevisiae laboratory strain. Fragments having centromere function were obtained at approximately equal frequencies from all three strains. Two of the S. uvarum centromeric DNAs and two of the S. cerevisiae centromeric DNAs were sequenced and shown to carry in a 120 bp region sequences essentially like those of centromeric DNA in S. cerevisiae laboratory strains. DNA hybridization to separated chromosomal DNAs revealed that the two newly determined S. cerevisiae centromeric DNA sequences belong to chromosomes V and XIII, respectively. On leave from: Department of Cell and Tumor Biology, Roswell Park Memorial Institute, Buffalo, NY 14263, USA; On leave from: The Biological Laboratories, University of Leiden, The Netherlands     

Structure, divergence, and distribution of the CRR centromeric retrotransposon family in rice

The centromeric retrotransposon (CR) family in the grass species is one of few Ty3-gypsy groups of retroelements that preferentially transpose into highly specialized chromosomal domains. It has been demonstrated in both rice and maize that CRR (CR of rice) and CRM (CR of maize) elements are intermingled with centromeric satellite DNA and are highly concentrated within cytologically defined centromeres. We collected all of the CRR elements from rice chromosomes 1, 4, 8, and 10 that have been sequenced to high quality. Phylogenetic analysis revealed that the CRR elements are structurally diverged into four subfamilies, including two autonomous subfamilies (CRR1 and CRR2) and two nonautonomous subfamilies (noaCRR1 and noaCRR2). The CRR1/CRR2 elements contain all characteristic protein domains required for retrotransposition. In contrast, the noaCRR elements have different structures, containing only a gag or gag-pro domain or no open reading frames. The CRR and noaCRR elements share substantial sequence similarity in regions required for DNA replication and for recognition by integrase during retrotransposition. These data, coupled with the presence of young noaCRR elements in the rice genome and similar chromosomal distribution patterns between noaCRR1 and CRR1/CRR2 elements, suggest that the noaCRR elements were likely mobilized through the retrotransposition machinery from the autonomous CRR elements. Mechanisms of the targeting specificity of the CRR elements, as well as their role in centromere function, are discussed.     

Pericentromeric regions containing 1.688 satellite DNA sequences show anti-kinetochore antibody staining in prometaphase chromosomes of Drosophila melanogaster

A striking characteristic of the centromeric heterochromatin of Drosophila melanogaster is that each chromosome carries different satellite DNA sequences. Here we show that while the major component of the 1.688 satellite DNA family expands across the centromere of the X chromosome the rest of the minor variants are located at pericentromeric positions in the large autosomes. Immunostaining of prometaphase chromosomes with the kinetocore-specific anti-BUB1 antibody reveals the transient presence of this centromeric protein in all the regions containing the 1.688 satellite.