Chromosomal DNA replication initiates at the same origins in meiosis and mitosis.

Autonomously replicating sequence (ARS) elements are identified by their ability to promote high-frequency transformation and extrachromosomal replication of plasmids in the yeast Saccharomyces cerevisiae. Six of the 14 ARS elements present in a 200-kb region of Saccharomyces cerevisiae chromosome III are mitotic chromosomal replication origins. The unexpected observation that eight ARS elements do not function at detectable levels as chromosomal replication origins during mitotic growth suggested that these ARS elements may function as chromosomal origins during premeiotic S phase. Two-dimensional agarose gel electrophoresis was used to map premeiotic replication origins in a 100-kb segment of chromosome III between HML and CEN3. The pattern of origin usage in premeiotic S phase was identical to that in mitotic S phase, with the possible exception of ARS308, which is an inefficient mitotic origin associated with CEN3. CEN3 was found to replicate during premeiotic S phase, demonstrating that the failure of sister chromatids to disjoin during the meiosis I division is not due to unreplicated centromeres. No origins were found in the DNA fragments without ARS function. Thus, in both mitosis and meiosis, chromosomal replication origins are coincident with ARS elements but not all ARS elements have chromosomal origin function. The efficiency of origin use and the patterns of replication termination are similar in meiosis and in mitosis. DNA replication termination occurs over a broad distance between active origins.     

Conservation of ARS elements and chromosomal DNA replication origins on chromosomes III of Saccharomyces cerevisiae and S. carlsbergensis.

DNA replication origins, specified by ARS elements in Saccharomyces cerevisiae, play an essential role in the stable transmission of chromosomes. Little is known about the evolution of ARS elements. We have isolated and characterized ARS elements from a chromosome III recovered from an alloploid Carlsberg brewing yeast that has diverged from its S. cerevisiae homeologue. The positions of seven ARS elements identified in this S. carlsbergensis chromosome are conserved: they are located in intergenic regions flanked by open reading frames homologous to those that flank seven ARS elements of the S. cerevisiae chromosome. The S. carlsbergensis ARS elements were active both in S. cerevisiae and S. monacensis, which has been proposed to be the source of the diverged genome present in brewing yeast. Moreover, their function as chromosomal replication origins correlated strongly with the activity of S. cerevisiae ARS elements, demonstrating the conservation of ARS activity and replication origin function in these two species.     

Linear derivatives of Saccharomyces cerevisiae chromosome III can be maintained in the absence of autonomously replicating sequence elements

Replication origins in Saccharomyces cerevisiae are spaced at intervals of approximately 40 kb. However, both measurements of replication fork rate and studies of hypomorphic alleles of genes encoding replication initiation proteins suggest the question of whether replication origins are more closely spaced than should be required. We approached this question by systematically deleting replicators from chromosome III. The first significant increase in loss rate detected for the 315-kb full-length chromosome occurred only after all five efficient chromosomal replicators in the left two-thirds of the chromosome (ARS305, ARS306, ARS307, ARS309, and ARS310) had been deleted. The removal of the inefficient replicator ARS308 from this originless region caused little or no additional increase in loss rate. Chromosome fragmentations that removed the normally inactive replicators on the left end of the chromosome or the replicators distal to ARS310 on the right arm showed that both groups of replicators contribute significantly to the maintenance of the originless chromosome. Surprisingly, a 142-kb derivative of chromosome III, lacking all sequences that function as autonomously replicating sequence elements in plasmids, replicated and segregated properly 97% of the time. Both the replication initiation protein ORC and telomeres or a linear topology were required for the maintenance of chromosome fragments lacking replicators.     

A replication map of a 61-kb circular derivative of Saccharomyces cerevisiae chromosome III.

Using two-dimensional agarose gel electrophoresis, we determined the replication map of a 61-kb circular derivative of Saccharomyces cerevisiae chromosome III. The three sites of DNA replication initiation on the ring chromosome are specific and coincide with ARS elements. The three origins are active to different degrees; two are used > 90% of the time, whereas the third is used only 10-20% of the time. The specificity of these origins is shown by the fact that only ARS elements were competent for origin function, and deletion of one of the ARS elements removed the corresponding replication origin. The activity of the least active origin was not increased by deletion of the nearby highly active origin, demonstrating that the highly active origin does not repress function of the relatively inactive origin. Replication termination on the ring chromosome does not occur at specific sites but rather occurs over stretches of DNA ranging from 3 to 10 kb. A new region of termination was created by altering the sites of initiation. The position of the new termination site indicates that termination is not controlled by specific cis-acting DNA sequences, but rather that replication termination is determined primarily by the positions at which replication initiates. In addition, two sites on the ring chromosome were found to slow the progression of replication forks through the molecule: one is at the centromere and one at the 3' end of a yeast transposable element.     

Roles for internal and flanking sequences in regulating the activity of mating-type-silencer-associated replication origins in Saccharomyces cerevisiae

ARS301 and ARS302 are inactive replication origins located at the left end of budding yeast (Saccharomyces cerevisiae) chromosome III, where they are associated with the HML-E and -I silencers of the HML mating type cassette. Although they function as replication origins in plasmids, they do not serve as origins in their normal chromosomal locations, because they are programmed to fire so late in S phase that they are passively replicated by the replication fork from neighboring early-firing ARS305 before they have a chance to fire on their own. We asked whether the nucleotide sequences required for plasmid origin function of these silencer-associated chromosomally inactive origins differ from the sequences needed for plasmid origin function by nonsilencer-associated chromosomally active origins. We could not detect consistent differences in sequence requirements for the two types of origins. Next, we asked whether sequences within or flanking these origins are responsible for their chromosomal inactivity. Our results demonstrate that both flanking and internal sequences contribute to chromosomal inactivity, presumably by programming these origins to fire late in S phase. In ARS301, the function of the internal sequences determining chromosomal inactivity is dependent on the checkpoint proteins Mec1p and Rad53p.     

Time of replication of ARS elements along yeast chromosome III.

The replication of putative replication origins (ARS elements) was examined for 200 kilobases of chromosome III of Saccharomyces cerevisiae. By using synchronous cultures and transfers from dense to light isotope medium, the temporal pattern of mitotic DNA replication of eight fragments that contain ARSs was determined. ARS elements near the telomeres replicated late in S phase, while internal ARS elements replicated in the first half of S phase. The results suggest that some ARS elements in the chromosome may be inactive as replication origins. The actively expressed mating type locus, MAT, replicated early in S phase, while the silent cassettes, HML and HMR, replicated late. Unexpectedly, chromosome III sequences were found to replicate late in G1 at the arrest induced by the temperature-sensitive cdc7 allele.     

ARS replication during the yeast S phase

A 1.45 kb circular plasmid derived from yeast chromosome IV contains the autonomous replication element called ARS1. Isotope density transfer experiments show that each plasmid molecule replicates once each S phase, with initiation depending on two genetically defined steps required for nuclear DNA replication. A density transfer experiment with synchronized cells demonstrates that the ARS1 plasmid population replicates early in the S phase. The sequences adjacent to ARS1 on chromosome IV also initiate replication early, suggesting that the ARS1 plasmid contains information which determines its time of replication. The times of replication for two other yeast chromosome sequences, ARS2 and a sequence referred to as 1OZ, indicate that the temporal order of replication is ARS1 leads to ARS2 leads to 1OZ. These experiments show directly that specific chromosome regions replicate at specific times during the yeast S phase. If ARS elements are origins of chromosome replication, then the experiment reveals times of activation for two origins.     

A reorganized Candida albicans DNA sequence promoting homologous non-integrative genetic transformation

In order to develop plasmids adequate for non-integrative genetic transformation of Candida albicans, a DNA fragment of 15.3 kb was cloned from this organism on the basis of its capacity to convert the integrative Saccharomyces cerevisiae vector YIp5 into a non-integrative one. Southern hybridization analysis, carried out with a labelled DNA probe of 3.6 kb derived from the cloned fragment, showed that it consisted of C. albicans DNA, the hybridization pattern indicating that the corresponding sequences were homologous to several chromosomal regions. The size of the C. albicans DNA promoting autonomous replication in S. cerevisiae was substantially reduced by subcloning. A 5.1 kb subfragment, defined by BamHI and SalI restriction sites, retained autonomous replication sequences (ARS) functional in the heterologous S. cerevisiae system and in C. albicans, when inserted in plasmid constructions that carried a S. cerevisiae trichodermin-resistance gene (tcm1) as selection marker. C. albicans transformants were both of the integrative and the non-integrative type and the plasmids recovered from the latter very often carried a reorganized ARS, indicating that recombination of the inserted ARS DNA had occurred in the homologous host. Successive reorganizations of the ARS insert in C. albicans eventually led to a more stable and much smaller fragment of 687 bp that was subsequently recovered unchanged from transformants. Sequence analysis of the 687 bp fragment revealed four 11-base blocks, rich in A+T, that carried the essential consensus sequence considered relevant for yeast ARS elements in addition to other features also described as characteristic of yeast replication origins.     

The effect on chromosome stability of deleting replication origins.

The observed spacing between chromosomal DNA replication origins in Saccharomyces cerevisiae is at least four times shorter than should be necessary to ensure complete replication of chromosomal DNA during the S phase. To test whether all replication origins are required for normal chromosome stability, the loss rates of derivatives of chromosome III from which one or more origins had been deleted were measured. In the case of a 61-kb circular derivative of the chromosome that has two highly active origins and one origin that initiates only 10 to 20% of the time, deletion of either highly active origin increased its rate of loss two- to fourfold. Deletion of both highly active origins caused the ring chromosome to be lost in approximately 20% of cell divisions. This very high rate of loss demonstrates that there are no efficient cryptic origins on the ring chromosome that are capable of ensuring its replication in the absence of the origins that are normally used. Deletion of the same two origins from the full-length chromosome III, which contains more than six replication origins, had no effect on its rate of loss. These results suggest that the increase in the rate of loss of the small circular chromosome from which a single highly active origin was deleted was caused by the failure of the remaining highly active origin to initiate replication in a small fraction (approximately 0.003) of cell cycles.     

Control of ATP-Dependent Binding of Saccharomyces cerevisiae Origin Recognition Complex to Autonomously Replicating DNA Sequences

Eukaryotic origin recognition complexes (ORCs) play pivotal roles in the initiation of chromosomal DNA replication. ORC from the yeast, Saccharomyces cerevisiae, recognizes and binds replication origins in the late G1 phase and the binding has profound implications in the progression of the cell cycle to the S-phase. Therefore, we have quantitatively analyzed the mechanism of recognition and interaction of the yeast ORC with various elements of a yeast origin of DNA replication, the autonomously replicating sequence 1 (ARS1). ORC bound all four individual A and B elements of ARS1 with reasonably high affinities. However, the highest affinity binding was observed with a DNA sequence containing both the A and B1 elements. In addition, ATP and ADP significantly modulated the binding of ORC to the combined elements as well as modulating the binding of ORC to the element A alone or in combination with the B1 element. However, binding of ORC to individual B1, B2, and B3 elements was not responsive to nucleotides. Thus, the consensus ARS sequence in element A appeared to play a pivotal role in the ATP-dependent binding of ORC to ARS1 and likely in other ARSs or origins of DNA replication.     

Multiple DNA elements in ARS305 determine replication origin activity in a yeast chromosome.

A yeast autonomously replicating sequence, ARS305, shares essential components with a chromosome III replicator, ORI305. Known components include an ARS consensus sequence (ACS) element, presumed to bind the origin recognition complex (ORC), and a broad 3'-flanking sequence which contains a DNA unwinding element. Here linker substitution mutagenesis of ARS305 and analysis of plasmid mitotic stability identified three short sequence elements within the broad 3'-flanking sequence. The major functional element resides directly 3' of the ACS and the two remaining elements reside further downstream, all within non-conserved ARS sequences. To determine the contribution of the elements to replication origin function in the chromosome, selected linker mutations were transplaced into the ORI305 locus and two-dimensional gel electrophoresis was used to analyze replication bubble formation and fork directions. Mutation of the major functional element identified in the plasmid mitotic stability assay inactivated replication origin function in the chromosome. Mutation of each of the two remaining elements diminished both plasmid ARS and chromosomal origin activities to similar levels. Thus multiple DNA elements identified in the plasmid ARS are determinants of replication origin function in the natural context of the chromosome. Comparison with two other genetically defined chromosomal replicators reveals a conservation of functional elements known to bind ORC, but no two replicators are identical in the arrangement of elements downstream of ORC binding elements or in the extent of functional sequences adjacent to the ACS.     

Identification of the sequences required for chromosomal replicator function in Kluyveromyces lactis

The analysis of replication intermediates of a Kluyveromyces lactis chromosomal autonomous replicating sequence (ARS), KARS101, has shown that it is active as a chromosomal replicator. KARS101 contains a 50 bp sequence conserved in two other K. lactis ARS elements. The deletion of the conserved sequence in KARS101 completely abolished replicator activity, in both the plasmids and the chromosome. Gel shift assays indicated that this sequence binds proteins present in K. lactis nuclear extracts, and a 40 bp sequence, previously defined as the core essential for K. lactis ARS function, is required for efficient binding. Reminiscent of the origin replication complex (ORC), the binding appears to be ATP dependent. A similar pattern of protection of the core was seen with in vitro footprinting. KARS101 also functions as an ARS sequence in Saccharomyces cerevisiae. A comparative study using S. cerevisiae nuclear extracts revealed that the sequence required for binding is a dodecanucleotide related to the S. cerevisiae ARS consensus sequence and essential for S. cerevisiae ARS activity.     

Nuclear mitochondrial DNA activates replication in Saccharomyces cerevisiae

The nuclear genome of eukaryotes is colonized by DNA fragments of mitochondrial origin, called NUMTs. These insertions have been associated with a variety of germ-line diseases in humans. The significance of this uptake of potentially dangerous sequences into the nuclear genome is unclear. Here we provide functional evidence that sequences of mitochondrial origin promote nuclear DNA replication in Saccharomyces cerevisiae. We show that NUMTs are rich in key autonomously replicating sequence (ARS) consensus motifs, whose mutation results in the reduction or loss of DNA replication activity. Furthermore, 2D-gel analysis of the mrc1 mutant exposed to hydroxyurea shows that several NUMTs function as late chromosomal origins. We also show that NUMTs located close to or within ARS provide key sequence elements for replication. Thus NUMTs can act as independent origins, when inserted in an appropriate genomic context or affect the efficiency of pre-existing origins. These findings show that migratory mitochondrial DNAs can impact on the replication of the nuclear region they are inserted in.     

Influence of a replication enhancer on the hierarchy of origin efficiencies within a cluster of DNA replication origins.

DNA replication origins in animal cells sometimes occur in clusters. Often one of the multiple origins within these clusters fires more frequently than the others. The reason for this hierarchy remains unknown. Similar origin clusters occur in the fission yeast, Schizosaccharomyces pombe. One such cluster is located near the ura4 gene on chromosome III and contains three origins: ars3002, ars3003, and ars3004. In their natural chromosomal context (ars3003 is about 2.5 kb upstream of ars3002 and ars3004 is adjacent to ars3002 on the downstream side) their initiation frequencies display a striking hierarchy: ars3002 > ars3003 > ars3004. Here, we describe experiments that reveal a 400 bp replication enhancer within ars3004, adjacent to ars3002. The enhancer is essential for ars3004 origin function in a plasmid, but even with the enhancer ars3004 is an inefficient origin. The enhancer is not essential for ars3002 plasmid origin activity, but dramatically stimulates this activity, converting ars3002 from an inefficient plasmid origin to a very efficient one. It also stimulates the plasmid origin activity of ars3001 and ars3003 at all tested positions and orientations on both sides of each autonomously replicating sequence (ARS) element. If ars3002 is redefined to include the enhancer, then the relative activities of the three ARS elements as single origins within separate plasmids or as origins when all three ARS elements are present in a single plasmid is the same as the chromosomal hierarchy. Thus, this replication enhancer defines the relative activities of the three origins in the ura4 origin region. Similar enhancers may affect relative activities in the origin clusters of animal cells.     

Ease of DNA unwinding is a conserved property of yeast replication origins.

Autonomously replicating sequence (ARS) elements function as plasmid replication origins. Our studies of the H4 ARS and ARS307 have established the requirement for a DNA unwinding element (DUE), a broad easily-unwound sequence 3' to the essential consensus that likely facilitates opening of the origin. In this report, we examine the intrinsic ease of unwinding a variety of ARS elements using (1) a single-strand-specific nuclease to probe for DNA unwinding in a negatively-supercoiled plasmid, and (2) a computer program that calculates DNA helical stability from the nucleotide sequence. ARS elements that are associated with replication origins on chromosome III are nuclease hypersensitive, and the helical stability minima correctly predict the location and hierarchy of the hypersensitive sites. All well-studied ARS elements in which the essential consensus sequence has been identified by mutational analysis contain a 100-bp region of low helical stability immediately 3' to the consensus, as do ARS elements created by mutation within the prokaryotic M13 vector. The level of helical stability is, in all cases, below that of ARS307 derivatives inactivated by mutations in the DUE. Our findings indicate that the ease of DNA unwinding at the broad region directly 3' to the ARS consensus is a conserved property of yeast replication origins.     

Functional equivalency and diversity of cis-acting elements among yeast replication origins.

The DNA replication origins of the yeast Saccharomyces cerevisiae require several short functional elements, most of which are not conserved in sequence. To better characterize ARS305, a replicator from a chromosomal origin, we swapped functional DNA elements of ARS305 with defined elements of ARS1. ARS305 contains elements that are functionally exchangeable with ARS1 A and B1 elements, which are known to bind the origin recognition complex; however, the ARS1 A element differs in that it does not require a 3' box adjacent to the essential autonomously replicating sequence consensus. At the position corresponding to ARS1 B3, ARS305 has a novel element, B4, that can functionally substitute for every type of short element (B1, B2, and B3) in the B domain. Unexpectedly, the replacement of element B4 by ARS1 B3, which binds ABF1p and is known as a replication enhancer, inhibited ARS305 function. ARS305 has no short functional element at or near positions corresponding to the B2 elements in ARS1 and ARS307 but contains an easily unwound region whose functional importance was supported by a broad G+C-rich substitution mutation. Surprisingly, the easily unwound region can functionally substitute for the ARS1 B2 element, even though ARS1 B2 was found to possess a distinct DNA sequence requirement. The functionally conserved B2 element in ARS307 contains a known sequence requirement, and helical stability analysis of linker and minilinker mutations suggested that B2 also contains a DNA unwinding element (DUE). Our findings suggest that yeast replication origins employ a B2 element or a DUE to mediate a common function, DNA unwinding during initiation, although not necessarily through a common mechanism.     

A yeast replication origin consists of multiple copies of a small conserved sequence

Autonomously replicating sequences (ARSs) of the yeast S. cerevisiae function as replication origins on plasmids and probably also on chromosomes. ARS function requires a copy of the ARS core consensus (5'-[A/T]TTTAT[A/G]TTT[A/T]-3') and additional sequences 3' to the T-rich strand of the consensus. Our analysis of an ARS from chromosome III, the C2G1 ARS, suggests that ARS function depends on the presence of an exact match to the core consensus and the presence of additional near matches in the 3' flanking region. We have demonstrated that ARS function can be mediated by multiple matches to the core consensus by constructing synthetic ARS elements from oligonucleotides containing copies of the consensus sequence. We find that two copies of the core consensus are sufficient for ARS activity and that an artificial ARS as efficient as a natural chromosomal ARS can be constructed from multiple core consensus elements in a specific orientation.     

Replicator dominance in a eukaryotic chromosome.

Replicators are genetic elements that control initiation at an origin of DNA replication (ori). They were first identified in the yeast Saccharomyces cerevisiae as autonomously replicating sequences (ARSs) that confer on a plasmid the ability to replicate in the S phase of the cell cycle. The DNA sequences required for ARS function on a plasmid have been defined, but because many sequences that participate in ARS activity are not components of chromosomal replicators, a mutational analysis of the ARS1 replicator located on chromosome IV of S. cerevisiae was performed. The results of this analysis indicate that four DNA elements (A, B1, B2 and B3) are either essential or important for ori activation in the chromosome. In a yeast strain containing two closely spaced and identical copies of the ARS1 replicator in the chromosome, only one is active. The mechanism of replicator repression requires the essential A element of the active replicator. This element is the binding site for the origin recognition complex (ORC), a putative initiator protein. The process that determines which replicator is used, however, depends entirely upon flanking DNA sequences.