Esperanto for histones: CENP-A, not CenH3, is the centromeric histone H3 variant.

The first centromeric protein identified in any species was CENP-A, a divergent member of the histone H3 family that was recognised by autoantibodies from patients with scleroderma-spectrum disease. It has recently been suggested to rename this protein CenH3. Here, we argue that the original name should be maintained both because it is the basis of a long established nomenclature for centromere proteins and because it avoids confusion due to the presence of canonical histone H3 at centromeres.

Scm3, an essential Saccharomyces cerevisiae centromere protein required for G2/M progression and Cse4 localization.

A universal mark of centromeric chromatin is its packaging by a variant of histone H3 known as centromeric H3 (CenH3). The mechanism by which CenH3s are incorporated specifically into centromere DNA or the specialized function they serve there is not known. In a genetic approach to identify factors involved in CenH3 deposition, we screened for dosage suppressors of a temperature-sensitive cse4 allele in Saccharomyces cerevisiae (Cse4 is the S.

The histone fold domain of Cse4 is sufficient for CEN targeting and propagation of active centromeres in budding yeast.

Centromere-specific H3-like proteins (CenH3s) are conserved across the eukaryotic kingdom and are required for packaging centromere DNA into a specialized chromatin structure required for kinetochore assembly. Cse4 is the CenH3 protein of the budding yeast Saccharomyces cerevisiae. Like all CenH3 proteins, Cse4 consists of a conserved histone fold domain (HFD) and a divergent N terminus (NT).

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.

The N terminus of the centromere H3-like protein Cse4p performs an essential function distinct from that of the histone fold domain.

Cse4p is an evolutionarily conserved histone H3-like protein that is thought to replace H3 in a specialized nucleosome at the yeast (Saccharomyces cerevisiae) centromere. All known yeast, worm, fly, and human centromere H3-like proteins have highly conserved C-terminal histone fold domains (HFD) but very different N termini. We have carried out a comprehensive and systematic mutagenesis of the Cse4p N terminus to analyze its function.

Analysis of primary structural determinants that distinguish the centromere-specific function of histone variant Cse4p from histone H3.

Cse4p is a variant of histone H3 that has an essential role in chromosome segregation and centromere chromatin structure in budding yeast. Cse4p has a unique 135-amino-acid N terminus and a C-terminal histone-fold domain that is more than 60% identical to histone H3 and the mammalian centromere protein CENP-A. Cse4p and CENP-A have biochemical properties similar to H3 and probably replace H3 in centromere-specific nucleosomes in yeasts and mammals, respectively.

Genetic evidence for interactions between yeast importin alpha (Srp1p) and its nuclear export receptor, Cse1p.

The yeast Srp1p protein functions as an import receptor for proteins bearing basic nuclear localization signals. Cse1p, the yeast homolog of mammalian CAS, recycles Srp1p back to the cytoplasm after import substrates have been released into the nucleoplasm. In this report we describe genetic interactions between SRP1 and CSE1.

Functional interaction between the CSE2 gene product and centromeres in Saccharomyces cerevisiae.

The cse2-1 allele was identified through a genetic screen for mutations affecting chromosome segregation in Saccharomyces cerevisiae. This mutation confers cold and temperature sensitivity and causes increases in mitotic chromosome non-disjunction and loss. The CSE2 gene encodes a 17 kDa protein with a basic region-leucine zipper motif.

A mutation in CSE4, an essential gene encoding a novel chromatin-associated protein in yeast, causes chromosome nondisjunction and cell cycle arrest at mitosis.

The centromere, a differentiated region of the eukaryotic chromosome, mediates the segregation of sister chromatids at mitosis. In this study, a Saccharomyces cerevisiae chromosome mis-segregation mutant, cse4-1, has been isolated and shown to increase the nondisjunction frequency of a chromosome bearing a mutant centromere DNA sequence. In addition, at elevated temperatures the cse4-1 allele causes a mitosis-specific arrest with a predominance of large budded cells containing single G2 nuclei and short bipolar mitotic spindles.

SCM2, a tryptophan permease in Saccharomyces cerevisiae, is important for cell growth.

SCM2, a novel gene encoding a yeast tryptophan permease, was cloned as a high-copy-number suppressor of cse2-1. The cse2-1 mutation causes cold sensitivity, temperature sensitivity and chromosome missegregation. However, only the cold-sensitive phenotype of cse2-1 cells is suppressed by SCM2 at high copy.

CSE1 and CSE2, two new genes required for accurate mitotic chromosome segregation in Saccharomyces cerevisiae.

By monitoring the mitotic transmission of a marked chromosome bearing a defective centromere, we have identified conditional alleles of two genes involved in chromosome segregation (cse). Mutations in CSE1 and CSE2 have a greater effect on the segregation of chromosomes carrying mutant centromeres than on the segregation of chromosomes with wild-type centromeres. In addition, the cse mutations cause predominantly nondisjunction rather than loss events but do not cause a detectable increase in mitotic recombination.

A mutation in PLC1, a candidate phosphoinositide-specific phospholipase C gene from Saccharomyces cerevisiae, causes aberrant mitotic chromosome segregation.

We identified a putative Saccharomyces cerevisiae homolog of a phosphoinositide-specific phospholipase C (PI-PLC) gene, PLC1, which encodes a protein most similar to the delta class of PI-PLC enzymes. The PLC1 gene was isolated during a study of yeast strains that exhibit defects in chromosome segregation. plc1-1 cells showed a 10-fold increase in aberrant chromosome segregation compared with the wild type.

Analysis of centromere function in Saccharomyces cerevisiae using synthetic centromere mutants.

We constructed Saccharomyces cerevisiae centromere DNA mutants by annealing and ligating synthetic oligonucleotides, a novel approach to centromere DNA mutagenesis that allowed us to change only one structural parameter at a time. Using this method, we confirmed that CDE I, II, and III alone are sufficient for centromere function and that A + T-rich sequences in CDE II play important roles in mitosis and meiosis. Analysis of mutants also showed that a bend in the centromere DNA could be important for proper mitotic and meiotic chromosome segregation.

In vivo genomic footprint of a yeast centromere.

We have used in vivo genomic footprinting to investigate the protein-DNA interactions within the conserved DNA elements (CDEI, CDEII, and CDEIII) in the centromere from chromosome III of the yeast Saccharomyces cerevisiae. The in vivo footprint pattern obtained from wild-type cells shows that some guanines within the centromere DNA are protected from methylation by dimethyl sulfate. These results are consistent with studies demonstrating that yeast cells contain sequence-specific centromere DNA-binding proteins.

Cis- and trans-acting factors involved in centromere function in Saccharomyces cerevisiae.

The function of centromeric DNA in the yeast Saccharomyces cerevisiae has been studied in detail. Twelve of the sixteen S. cerevisiae centromeres have been sequenced to date, and a consensus sequence has been identified.

Saccharomyces cerevisiae mutants defective in chromosome segregation.

We have devised a genetic screen to identify trans-acting factors involved in chromosome transmission in yeast. This approach was designed to potentially identify a subset of genes encoding proteins that interact with centromere DNA. It has been shown that mutations in yeast centromere DNA cause aberrant chromosome segregation during mitosis and meiosis.

Purification of the yeast centromere binding protein CP1 and a mutational analysis of its binding site.

CP1 is a yeast protein which binds to the highly conserved DNA element I (CDEI) of yeast centromeres. We have purified CP1 to near homogeneity; it is comprised of a single polypeptide of molecular weight 58,400. When bound to yeast CEN3 DNA, CP1 protects a 12-15-base pair region centered over CDEI.

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.

Chromatin structure of altered yeast centromeres.

We have investigated the chromatin structure of wild-type and mutationally altered centromere sequences in the yeast Saccharomyces cerevisiae by using an indirect end-labeling mapping strategy. Wild-type centromere DNA from chromosome III (CEN3) exhibits a nuclease-resistant chromatin structure 220-250 base pairs long, centered around the conserved centromere DNA element (CDE) III. A point mutation in CDE III that changes a central cytidine to a thymidine and completely disrupts centromere function has lost the chromatin conformation typically associated with the wild-type centromere.

Yeast centromeres.

Significant progress has been made toward understanding the roles played by conserved centromere DNA sequences in both mitotic and meiotic chromosome segregation. We are just beginning to formulate a picture of what a yeast kinetochore actually looks like and what components other than CEN DNA are necessary for function. In the next few years some of the genes encoding structural components of the kinetochore, and perhaps some involved in regulation of kinetochore function, will be cloned.

A genetic analysis of dicentric minichromosomes in Saccharomyces cerevisiae.

We have developed an assay in S. cerevisiae in which clones of cells that contain intact dicentric minichromosomes are visually distinct from those that have rearranged to monocentric minichromosomes. We find that the instability of dicentric minichromosomes is apparently due to mitotic nondisjunction accompanied by occasional structural rearrangements.

Alterations in the adenine-plus-thymine-rich region of CEN3 affect centromere function in Saccharomyces cerevisiae.

Centromere DNA from 11 of the 16 chromosomes of the yeast Saccharomyces cerevisiae have been analyzed and reveal three sequence elements common to each centromere, referred to as conserved centromere DNA elements (CDE). The adenine-plus-thymine (A + T)-rich central core element, CDE II, is flanked by two short conserved sequences, CDE I (8 base pairs [bp]) and CDE III (25 bp). Although no consensus sequence exists among the different CDE II regions, they do have three common features of sequence organization.

Single base-pair mutations in centromere element III cause aberrant chromosome segregation in Saccharomyces cerevisiae.

In this paper we show that a 211-base pair segment of CEN3 DNA is sufficient to confer wild-type centromere function in the yeast Saccharomyces cerevisiae. We used site-directed mutagenesis of the 211-base pair fragment to examine the sequence-specific functional requirements of a conserved 11-base pair segment of centromere DNA, element III (5'-TGATTTATCCGAA-3'). Element III is the most highly conserved of the centromeric DNA sequences, differing by only a single adenine X thymine base pair among the four centromere DNAs sequenced thus far.

Nucleotide sequence comparisons and functional analysis of yeast centromere DNAs.

We determined the nucleotide sequence of DNA segments containing functional centromeres (CEN3 and CEN11) isolated from yeast chromosomes III and XI. The two centromere regions differ in primary nucleotide sequence, but contain structural features in common. Both centromere regions contain an extremely A + T-rich core segment 87-88 bp in length, flanked by two short sequences (14 bp and 11 bp) that are identical in both DNAs.