The MCM2-3-5 proteins: are they replication licensing factors?

DNA replication occurs only once in each normal mitotic cell cycle. To explain this strict control, a 'licensing factor' was proposed to enter the nucleus periodically as the nuclear envelope disintegrates and reassembles at the end of mitosis. Inactivation of licensing factor immediately following initiation of DNA synthesis would prevent reinitiation until after the next mitosis. The MCM2-3-5 proteins of Saccharomyces cerevisiae may be yeast's equivalent of licensing factor: they are present in the nucleus only between M and S phase, bind to chromatin and are important for the initiation of DNA replication.

The yeast Mcm1 protein is regulated posttranscriptionally by the flux of glycolysis.

Mcm1 is a multifunctional protein which plays a role both in the initiation of DNA replication and in the transcriptional regulation of diverse genes in Saccharomyces cerevisiae. The mcm1-1 mutation results in instability of minichromosomes and alpha-specific sterility. Second-site suppressors that restore minichromosome stability but not fertility to the mcm1-1 mutant were isolated. Two of the suppressors, pgm1-1 and pgm1-2, are mutant alleles of PGM1 which encodes a glycolytic enzyme, phosphoglycerate mutase. We show that the pgm1-1 mutation suppresses the minichromosome maintenance (Mcm) defect by increasing the protein activity or level of Mcm1-1 posttranscriptionally. This increase in the intracellular Mcm1-1 activity is sufficient to suppress the Mcm defect but only minimally suppresses the mating defect. Mutations in genes encoding other glycolytic enzymes, such as eno2::URA3, can also suppress the Mcm phenotype of mcm1-1. Suppression by these glycolytic enzyme mutations correlates with a reduced rate of glycolysis rather than a reduced rate of cell growth. This study suggests that in response to changes in their nutritional states yeast cells may attain homeostasis by modulating the activity of global regulators like Mcm1, which plays a central role in the regulation of energy-expensive anabolic processes.

Physical interactions among Mcm proteins and effects of Mcm dosage on DNA replication in Saccharomyces cerevisiae.

Mcm2, Mcm3, and Mcm5/Cdc46 are conserved proteins essential for the initiation of DNA synthesis at replication origins in Saccharomyces cerevisiae. The accumulation of these proteins in the nucleus before the onset of DNA synthesis suggests that they play a role in restricting DNA synthesis to once per cell cycle. In this work, we show that Mcm2, Mcm3, and Mcm5 self-interact and interact with one another to form complexes. Mcm2 and Mcm3 are abundant proteins, present in approximately 4 X 10(4) and 2 X 10(5) copies per cell, respectively. Reducing the dosage of Mcm2 by half results in diminished usage of specific replication origins. These results together suggest that a significant molar excess of Mcm proteins relative to replication origins is required for the proper initiation of all replication origins.

The phenotype of the minichromosome maintenance mutant mcm3 is characteristic of mutants defective in DNA replication.

MCM3 is an essential gene involved in the maintenance of minichromosomes in yeast cells. It encodes a protein of 971 amino acids that shows striking homology to the Mcm2 protein. We have mapped the mcm3-1 mutation of the left arm of chromosome V approximately 3 kb centromere proximal of anp1. The mcm3-1 mutant was found to be thermosensitive for growth. Under permissive growth conditions, it was defective in minichromosome maintenance in an autonomously replicating sequence-specific manner and showed an increase in chromosome loss and recombination. Under nonpermissive conditions, mcm3-1 exhibited a cell cycle arrest phenotype, arresting at the large-bud stage with an undivided nucleus that had a DNA content of nearly 2n. These phenotypes are consistent with incomplete replication of the genome of the mcm3-1 mutant, possibly as a result of limited replication initiation at selective autonomously replicating sequences leading to cell cycle arrest before mitosis. The phenotype exhibited by the mcm3 mutant is very similar to that of mcm2, suggesting that the Mcm2 and Mcm3 protein may play interacting roles in DNA replication.

Isolation and characterization of the centromere from chromosome V (CEN5) of Saccharomyces cerevisiae.

We have cloned a functional centromeric DNA sequence from Saccharomyces cerevisiae. Using the 2 mu chromosome-loss mapping technique and meiotic tetrad analysis, we have identified this DNA sequence as the centromere of chromosome V (CEN5). The CEN5 sequence has been localized on an 1,100-base-pair BamHI-BglII restriction fragment. Plasmids containing CEN5 and an autonomously replicating sequence are mitotically stable in S. cerevisiae and segregate in a Mendelian fashion during meiosis.

The OBF1 protein and its DNA-binding site are important for the function of an autonomously replicating sequence in Saccharomyces cerevisiae.

The autonomously replicating sequence ARS121 was cloned as a 480-base-pair (bp) long DNA fragment that confers on plasmids autonomous replication in Saccharomyces cerevisiae. This fragment contains two OBF1-binding sites (sites I and II) of different affinities, as identified by a gel mobility shift assay and footprint analysis. Nucleotide substitutions (16 to 18 bp) within either of the two sites obliterated detectable in vitro OBF1 binding to the mutagenized site. Linker substitution (6 bp) mutations within the high-affinity site I showed effects similar to those of the complete substitution, whereas DNA mutagenized outside the binding site bound OBF1 normally. We also tested the mitotic stability of centromeric plasmids bearing wild-type and mutagenized copies of ARS121. Both deletion of the sites and the extensive base alterations within either of the two OBF1-binding sites reduced the percentage of plasmid-containing cells in the population from about 88% to 50 to 63% under selective growth and from about 46% to 15 to 20% after 10 to 12 generations of nonselective growth. Furthermore, linker (6 bp) substitutions within site I, the high-affinity binding site, showed similar deficiencies in plasmid stability. In contrast, plasmids containing linker substitutions in sequences contiguous to site I displayed wild-type stability. In addition, plasmid copy number analysis indicated that the instability probably resulted not from nondisjunction during mitosis but rather from inefficient plasmid replication. The results strongly support the notion that the OBF1-binding sites and the OBF1 protein are important for normal ARS function as an origin of replication.

A lesion in the DNA replication initiation factor Mcm10 induces pausing of elongation forks through chromosomal replication origins in Saccharomyces cerevisiae.

We describe a new minichromosome maintenance factor, Mcm10, and show that this essential protein is involved in the initiation of DNA replication in Saccharomyces cerevisiae. The mcm10 mutant has an autonomously replicating sequence-specific minichromosome maintenance defect and arrests at the nonpermissive temperature with dumbbell morphology and 2C DNA content. Mcm10 is a nuclear protein that physically interacts with several members of the MCM2-7 family of DNA replication initiation factors. Cloning and sequencing of the MCM10 gene show that it is identical to DNA43, a gene identified independently for its putative role in replicating DNA. Two-dimensional DNA gel analysis reveals that the mcm10-1 lesion causes a dramatic reduction in DNA replication initiation at chromosomal origins, including ORI1 and ORI121. Interestingly, the mcm10-1 lesion also causes replication forks to pause during elongation through these same loci. This novel phenotype suggests a unique role for the Mcm10 protein in the initiation of DNA synthesis at replication origins.

Chromosome loss, hyperrecombination, and cell cycle arrest in a yeast mcm1 mutant.

The original mcm1-1 mutant was identified by its inability to propagate minichromosomes in an ARS-specific manner, suggesting that it is defective in the initiation of DNA synthesis at ARSs. This mutant is also defective in expression of alpha-mating-type-specific genes. Further genetic and biochemical studies confirmed that Mcm1 is a transcription factor that mediates the transcriptional regulation of a number of genes, including genes outside of the mating type complement, by interacting with different cofactors. Although MCM1 is an essential gene, none of the previously characterized mcm1 mutants exhibits significant growth defects. To assess which of the many roles of Mcm1 is essential for growth, we constructed and characterized a temperature-sensitive conditional mutant of mcm1, mcm1-110L. This mutant exhibits a temperature-dependent cell-cycle arrest, with a large, elongated bud and a single, undivided nucleus that has a DNA content of close to 2n. In addition, it shows elevated levels of chromosome loss and recombination. In spite of the severity of the mcm1-110L mutation, this mutant still retains an ARS-specific pattern of minichromosome instability. All of these phenotypes are precisely those exhibited by mutants in three MCM genes, MCM2, MCM3, and MCM5/CDC46, that have been shown to play interacting roles in the early steps of DNA replication.

Mcm2 and Mcm3 are constitutive nuclear proteins that exhibit distinct isoforms and bind chromatin during specific cell cycle stages of Saccharomyces cerevisiae.

The Mcm2-7 proteins are a family of conserved proteins whose functions are essential for the initiation of DNA synthesis in all eukaryotes. These patients are constitutively present in high abundance in actively proliferating cells. In Saccharomyces cerevisiae, the intracellular concentrations of Mcms are between 100 and 500 times the number of replication origins. However, these proteins are limiting for the initiation of DNA synthesis at replication origins. Our studies indicate that only a small fraction of Mcm2 and Mcm3 tightly associates with chromatin, from late M phase to the beginning of the S phase. The rest of the Mcm2 and Mcm3 proteins are disturbed to both the cytoplasm and nucleoplasm in relatively constant levels throughout the cell cycle. We also show that S. cerevisiae Mcm3 is a phosphoprotein that exists in multiple isoforms and that distinct isoforms of Mcm2 and Mcm3 can be detected at specific stages of the cell cycle. These results suggest that the localization and function of the Mcm proteins are regulated by posttranslational phosphorylation in a manner that is consistent with a role for the Mcm proteins in restricting DNA replication to once per cell cycle.

A family of Saccharomyces cerevisiae repetitive autonomously replicating sequences that have very similar genomic environments.

We have characterized a family of moderately repetitive autonomously replicating sequences (ARSs) in Saccharomyces cerevisiae. Restriction mapping, deletion studies and hybridization studies suggest that these ARSs, which are probably less than 350 base-pairs in size, share one common feature: each is located close to, but not within, a repetitive sequence (131) of approximately 10(3) to approximately 1.5 X 10(3) base-pairs in length. These ARSs can be divided into two classes (X and Y) by their sequence homology and genomic environments. Each of the class X ARSs is embedded within a repetitive sequence (X) of variable length (approximately 0.3 X 10(3) to approximately 3.75 X 10(3) base-pairs); each of the class Y ARSs is embedded within a highly conserved repetitive sequence (Y) of approximately 5.2 X 10(3) base-pairs in length. Both of these sequences are located directly adjacent to the 131 sequence.

A mutant that affects the function of autonomously replicating sequences in yeast.

We previously reported the isolation of a series of mcm mutants that are defective in the maintenance of minichromosomes in yeast. These minichromosomes are circular plasmids, each containing an autonomously replicating sequence (ARS) and a centromere. One of the mcm mutants, mcm2, has the following phenotype: at room temperature it affects the stability of only some minichromosomes depending on the ARS present, while at high temperature it affects all minichromosomes tested irrespective of the ARS present. Here we show that the mcm defect as well as its temperature-dependent specificity for ARSs can be demonstrated with circular as well as linear plasmids that do not contain centromeric sequences. Larger chromosomes containing multiple ARSs are also unstable in this mutant. Further analyses indicate that the mcm2 mutation causes the loss, rather than the aberrant segregation, of the circular minichromosomes. In addition, this mutation appears to stimulate mitotic recombination frequencies. These properties of the mcm2 mutant are consistent with the idea that the mcm2 mutation results in a defect in the initiation of DNA replication at ARSs, the putative chromosomal replication origins in yeast.

Saccharomyces cerevisiae protein involved in plasmid maintenance is necessary for mating of MAT alpha cells.

We previously reported the isolation of yeast mutants that seem to affect the function of certain autonomously replicating sequences (ARSs). These mutants are known as mcm for their defect in the maintenance of minichromosomes. We have now characterized in more detail one ARS-specific mutation, mcm1-1. This Mcm1 mutant has a second phenotype; MAT alpha mcm1-1 strains are sterile. MCM1 is non-allelic to other known alpha-specific sterile mutations and, unlike most genes required for mating, it is essential for growth. The alpha-specific sterile phenotype of the mcm1-1 mutant is manifested by its failure to produce a normal amount of the mating pheromone, alpha-factor. In addition, transcripts of the MF alpha 1 and STE3 genes, which encode the alpha-factor precursor and the alpha-factor receptor, respectively, are greatly reduced in this mutant. These and other properties of the mcm1-1 mutant suggest that the MCM1 protein may act as a transcriptional activator of alpha-specific genes. We have cloned, mapped and sequenced the wild-type and mutant alleles of MCM1, which is located on the right arm of chromosome XIII near LYS7. The MCM1 gene product is a protein of 286 amino acid residues and contains an unusual region in which 19 out of 20 residues are either aspartic or glutamic acid, followed by a series of glutamine tracts. MCM1 has striking homology to ARG80, a regulatory gene of the arginine metabolic pathway located about 700 base-pairs upstream from MCM1. A substitution of leucine for proline at amino acid position 97, immediately preceding the polyanionic region, was shown to be responsible for both the alpha-specific sterile and minichromosome-maintenance defective phenotypes of the mcm1-1 mutant.

Meiotic disjunction of homologs in Saccharomyces cerevisiae is directed by pairing and recombination of the chromosome arms but not by pairing of the centromeres.

We explored the behavior of meiotic chromosomes in Saccharomyces cerevisiae by examining the effects of chromosomal rearrangements on the pattern of disjunction and recombination of chromosome III during meiosis. The segregation of deletion chromosomes lacking part or all (telocentric) of one arm was analyzed in the presence of one or two copies of a normal chromosome III. In strains containing one normal and any one deletion chromosome, the two chromosomes disjoined in most meioses. In strains with one normal chromosome and both a left and right arm telocentric chromosome, the two telocentrics preferentially disjoined from the normal chromosome. Homology on one arm was sufficient to direct chromosome disjunction, and two chromosomes could be directed to disjoin from a third. In strains containing one deletion chromosome and two normal chromosomes, the two normal chromosomes preferentially disjoined, but in 4-7% of the tetrads the normal chromosomes cosegregated, disjoining from the deletion chromosome. Recombination between the two normal chromosomes or between the deletion chromosome and a normal chromosome increased the probability that these chromosomes would disjoin, although cosegregation of recombinants was observed. Finally, we observed that a derivative of chromosome III in which the centromeric region was deleted and CEN5 was integrated at another site on the chromosome disjoined from a normal chromosome III with fidelity. These studies demonstrate that it is not pairing of the centromeres, but pairing and recombination along the arms of the homologs, that directs meiotic chromosome segregation.

Resolution of dicentric chromosomes by Ty-mediated recombination in yeast.

We have integrated a plasmid containing a yeast centromere, CEN5, into the HIS4 region of chromosome III by transformation. Of the three transformant colonies examined, none contained a dicentric chromosome, but all contained a rearranged chromosome III. In one transformant, rearrangement occurred by homologous recombination between two Ty elements; one on the left arm and the other on the right arm of chromosome III. This event produced a ring chromosome (ring chromosome III) of about 60 kb consisting of CEN3 and all other sequences between the two Ty elements. In addition, a linear chromosome (chromosome IIIA) consisting of sequences distal to the two Ty elements including CEN5, but lacking 60 kb of sequences from the centromeric region, was produced. Two other transformants also contain a similarly altered linear chromosome III as well as an apparently normal copy of chromosome III. These results suggest that dicentric chromosomes cannot be maintained in yeast and that dicentric structures must be resolved for the cell to survive.--The meiotic segregation properties of ring chromosome III and linear chromosome IIIA were examined in diploid cells which also contained a normal chromosome III. Chromosome IIIA and normal chromosome III disjoined normally, indicating that homology or parallel location of the centromeric regions of these chromosomes are not essential for proper meiotic segregation. In contrast, the 60-kb ring chromosome III, which is homologous to the centromeric region of the normal chromosome III, did not appear to pair with fidelity with chromosome III.

Mutants of S. cerevisiae defective in the maintenance of minichromosomes.

We have isolated yeast mutants that are defective in the maintenance of circular minichromosomes. The minichromosomes are mitotically stable plasmids, each of which contains a different ARS (autonomously replicating sequence), a centrometeric sequence, CEN5, and two yeast genes, LEU2 and URA3. Forty minichromosome maintenance-defective (Mcm-) mutants were characterized. They constitute 16 complementation groups. These mutants can be divided into two classes, specific and nonspecific, by their differential ability to maintain minichromosomes with different ARSs. The specific class of mutants is defective only in the maintenance of minichromosomes that carry a particular group of ARSs irrespective of the centromeric sequence present. The nonspecific class of mutants is defective in the maintenance of all minichromosomes tested irrespective of the ARS or centromeric sequence present. The specific class may include mutants that do not initiate DNA replication effectively at specific ARSs present on the minichromosomes; the nonspecific class may include mutants that are affected in the segregation and/or replication of circular plasmids in general.