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.     

The ARS consensus sequence is required for chromosomal origin function in Saccharomyces cerevisiae.

Replication origins have been mapped to positions that coincide, within experimental error (several hundred base pairs), with ARS elements. To determine whether the DNA sequences required for ARS function on plasmids are required for chromosomal origin function, the chromosomal copy of ARS306 was deleted and the chromosomal copy of ARS307 was replaced with mutant derivatives of ARS307 containing single point mutations in domain A within the ARS core consensus sequence. The chromosomal origin function of these derivatives was assayed by two-dimensional agarose gel electrophoresis. Deletion of ARS306 deleted the associated replication origin. The effects on chromosomal origin function of mutations in domain A paralleled their effects on ARS function, as measured by plasmid stability. These results demonstrate that chromosomal origin function is a property of the ARS element itself.     

A DNA unwinding element and an ARS consensus comprise a replication origin within a yeast chromosome.

We have defined a replication origin, ORI305, within chromosome III of Saccharomyces cerevisiae by means of mutational analysis. cis-acting elements required for origin activity in the chromosome, as assayed by two-dimensional gel electrophoresis of replication intermediates, are the same as those required for the function of an autonomously replicating sequence, ARS305, in a plasmid. Essential elements include (i) an 11 bp sequence that is a near match to the ARS consensus and (ii) a broad sequence directly 3' to the consensus near match. Origin function is inactivated by point mutations in the essential near match sequence, suggesting that the sequence contributes to specifying the origin in the chromosome. Other consensus near matches with different sequences are present but are not required. The essential 3'-flanking sequence exhibits DNA helical instability and is sensitive to deletion mutations that stabilize the DNA helix. The wild-type 3'-flanking sequence can be functionally substituted by dissimilar sequences that also exhibit helical instability. The requirement for DNA helical instability indicates that the essential 3'-flanking sequence serves as a DNA unwinding element in the chromosome.     

cis-acting components in the replication origin from ribosomal DNA of Saccharomyces cerevisiae.

The ribosomal DNA (rDNA) repeats of Saccharomyces cerevisiae contain an autonomously replicating sequence (ARS) that colocalizes with a chromosomal origin of replication. We show that a minimal sequence necessary for full ARS function corresponds to a 107-bp rDNA fragment which contains three 10-of-11-bp matches to the ARS consensus sequence. Point mutations in only one of the 10-of-11-bp matches, GTTTAT GTTTT, inactivate the rDNA ARS, indicating that this consensus sequence is essential. A perfect match to a revised ARS consensus is present but not essential. Sequences up to 9 bp 5' from the essential consensus are dispensable. A broad DNA region directly 3' to the essential consensus is required and is easily unwound as indicated by: (i) hypersensitivity to nicking of an approximately 100-bp region by mung bean nuclease in a negatively supercoiled plasmid and (ii) helical instability determined by thermodynamic analysis of the nucleotide sequence. A correlation between DNA helical instability and replication efficiency of wild-type and mutated ribosomal ARS derivatives suggests that a broad region 3' to the essential ARS consensus functions as a DNA unwinding element. Certain point mutations that do not stabilize the DNA helix in the 3' region but reduce ARS efficiency reveal an element distinct from, but overlapping, the DNA unwinding element. The nucleotide sequence of the functionally important constituents in the ARS appears to be conserved among the rDNA repeats in the chromosome.     

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.     

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.     

Domain B of ARS307 contains two functional elements and contributes to chromosomal replication origin function.

ARS307 is highly active as a replication origin in its native location on chromosome III of Saccharomyces cerevisiae. Its ability to confer autonomous replication activity on plasmids requires the presence of an 11-bp autonomously replicating sequence (ARS) consensus sequence (ACS), which is also required for chromosomal origin function, as well as approximately 100 bp of sequence flanking the ACS called domain B. To further define the sequences required for ARS function, a linker substitution mutagenesis of domain B was carried out. The mutations defined two sequences, B1 and B2, that contribute to ARS activity. Therefore, like ARS1, domain B of ARS307 is composed of functional subdomains. Constructs carrying mutations in the B1 element were used to replace the chromosomal copy of ARS307. These mutations caused a reduction in chromosomal origin activity, demonstrating that the B1 element is required for efficient chromosomal origin function.     

The inefficient replication origin from yeast ribosomal DNA is naturally impaired in the ARS consensus sequence and in DNA unwinding.

Ribosomal DNA (rDNA) replication origins of Saccharomyces cerevisiae are known to function inefficiently, both in the context of the tandem rDNA repeats in the chromosome and as single copy autonomously replicating sequences (ARSs) in plasmids. Here we examined components of the rDNA ARS that might contribute to inefficient extrachromosomal replication. Like the efficient H4 ARS, the rDNA ARS requires a match to the 11 bp ARS consensus sequence (ACS) and a broad non-conserved region that may contain multiple elements, including a DNA unwinding element (DUE). Using a single-strand-specific nuclease hypersensitivity assay and by determining the superhelical density required for stable DNA unwinding, we found that the DNA of the rDNA ARS is not as easily unwound as the H4 ARS. Unwinding of the rDNA ARS required additional energy, similar to the unwinding of mutations in the H4 ARS that stabilize the double helix in the DUE region and impair replication. In vivo extrachromosomal replication of the rDNA ARS was cold sensitive, like H4 ARS mutants that require additional energy to unwind the DUE region but unlike the easily unwound, wild-type H4 ARS. Impairment of replication function at reduced temperature suggests that the elevated energy requirement for DNA unwinding inherent in the wild-type rDNA ARS contributes to inefficient replication function. We also examined the essential ACS match in the rDNA ARS, which is known to be imperfect at one position. A point mutation in the essential ACS that corrects the imperfect match increased the efficiency of extrachromosomal replication. Our results reveal that the essential ACS element and DNA unwinding in the rDNA ARS are naturally impaired, suggesting that inefficient function of the rDNA replication origin has a biological purpose.     

Difference in strength of autonomously replicating sequences among repeats in the rDNA region of Saccharomyces cerevisiae

The rDNA region of Saccharomyces cerevisiae contains 100-200 tandemly repeated copies of a 9 kb unit, each with a potential replication origin. In the present studies of cloned fragments from the region involved in the regulation of replication of rDNA, we detected differences in autonomously replicating sequence (ARS) activity for clones from the same yeast strain. One clone, which showed very low ARS activity, carried a point mutation, a C instead of T, in position 9 of the essential 11 bp consensus ARS as compared to clones carrying the normal 10-of-11-bp match to the consensus. The mutation could be traced back to genomic rDNA where it represents about one-third of the rDNA units in that strain. Differences in ARS activity have implications for understanding the regulation of replication of rDNA, and the ratio of active to inactive ARS in the rDNA region may be important for potential generation of extrachromosomal copies.     

The DNA unwinding element in a yeast replication origin functions independently of easily unwound sequences present elsewhere on a plasmid.

We have previously identified a DNA unwinding element (DUE) in autonomously replicating sequences (ARSs) and demonstrated a correlation between single-strand-specific nuclease hypersensitivity of the DUE and ARS-mediated plasmid replication in yeast. The DUE in the H4 ARS is the most easily unwound sequence in a supercoiled DNA molecule, in the context of the Ylp5 plasmid. To determine whether sequences which are more readily unwound than the ARS can influence replication activity, we have inserted such sequences, called 'torsional sinks', into the plasmids at a site distal to the ARS. We show that the torsional sink sequences effect reduction or elimination of the nuclease hypersensitivity of a variety of H4 ARS derivatives. However, we detect no difference in the in vivo replication activity of an individual ARS plasmid with or without a torsional sink. Thus, the function of the DUE in a yeast replication origin is unaffected by easily unwound sequences present elsewhere on the same plasmid.     

The localization of replication origins on ARS plasmids in S. cerevisiae

Replication intermediates from the yeast 2 microns plasmid and a recombinant plasmid containing the yeast autonomous replication sequence ARS1 have been analyzed by two-dimensional agarose gel electrophoresis. Plasmid replication proceeds through theta-shaped (Cairns) intermediates, terminating in multiply interlocked catenanes that are resolved during S phase to monomer plasmids. Restriction fragments derived from the Cairns forms contain replication forks and bubbles that behave differently from one another when subjected to high voltage and agarose concentrations. The two-dimensional gel patterns observed for different restriction fragments from these two plasmids indicate that in each plasmid there is a single, specific origin of replication that maps, within the limits of our resolution, to the ARS element. Our results strongly support the long-standing assumption that in Saccharomyces cerevisiae an ARS is an origin of replication.     

Mutational analysis of the consensus sequence of a replication origin from yeast chromosome III.

Yeast autonomously replicating sequence (ARS) elements contain an 11-base-pair core consensus sequence (5'-[A/T]TTTAT[A/G]TTT[A/T]-3') that is required for function. The contribution of each position within this sequence to ARS activity was tested by creating all possible single-base mutations within the core consensus sequence of ARS307 (formerly called the C2G1 ARS) and testing their effects on high-frequency transformation and on plasmid stability. Of the 33 mutations, 22 abolished ARS function as measured by high-frequency transformation, 7 caused more than twofold reductions in plasmid stability, and 4 had no effect on plasmid stability. Mutations that reduced or abolished ARS activity occurred at each position in the consensus sequence, demonstrating that each position of this sequence contributes to ARS function. Of the four mutations that had no effect on ARS activity, three created alternative perfect matches to the core consensus sequence, demonstrating that the alternate bases allowed by the consensus sequence are, indeed, interchangeable. In addition, a change from T to C at position 6 did not perturb wild-type efficiency. To test whether the essential region extends beyond the 11-base-pair consensus sequence, the effects on plasmid stability of point mutations one base 3' to the T-rich strand of the core consensus sequence (position 12) and deletion mutations that altered bases 5' to the T-rich strand of the core consensus sequence were examined. An A at position 12 or the removal of three T residues 5' to the core consensus sequence severely diminished ARS efficiency, showing that the region required for full ARS efficiency extends beyond the core consensus sequence in both directions.     

Genetic analysis of the mitotic transmission of minichromosomes

The fidelity of the mitotic transmission of minichromosomes in S. cerevisiae is monitored by a novel visual assay that allows one to detect changes in plasmid copy number in individual mitotic divisions. This assay is used to investigate the mitotic transmission of a plasmid containing a putative yeast origin of replication (ARS 1) and a centromere (CEN3). The rate of improper segregation for the minichromosome is 200-fold higher than observed for a normal chromosome. However, the replication of the minichromosome is stringently controlled; it overreplicates less than once per one thousand mitotic divisions. We also use this assay to isolate and characterize mutations in ARS 1 and CEN3. The mutations in ARS 1 define a new domain required for its optimal activity, and the mutations in CEN3 suggest that the integrity of element II is not essential for centromere function. Finally, the phenotypes of the mutations in ARS 1 and CEN3 are consistent with their function in replication and segregation, respectively.     

Fine-structure analysis of the DNA sequence requirements for autonomous replication of Saccharomyces cerevisiae plasmids.

An autonomously replicating segment, ARS, is located 293 base pairs downstream from the histone H4 gene at the copy-I H3-H4 locus. The sequences needed for autonomous replication were defined by deletion analysis to include an ARS consensus sequence and an additional 3'-flanking region. External deletions into the 3'-flanking yeast sequences resulted in a loss of replication function. However, disruptions of the required 3'-flanking domain by either 10-base-pair linker-scanning substitutions or larger internal deletions did not impair autonomous replication. Thus, replication is dependent upon a flanking chromosome domain, but not an exact DNA sequence. The extent of the yeast sequences required in the 3'-flanking domain is variable depending on the nature of neighboring plasmid vector sequences. That is, there are certain vector sequences that prohibit replication when they are placed too close to the ARS consensus. These results suggest that the functional 3'-flanking domain of the H4 ARS is a specific DNA or chromatin structure or both.     

A DNA replication origin and a replication fork barrier used in vivo in the circular plasmid pKD1

As in other yeasts, ARS-containing plasmids can be maintained extrachromosomally in Kluyveromyces lactis. Although some fragments of K. lactis DNA have ARS activity in both K. lactis and Saccharomyces cerevisiae, it appears that the sequences required for ARS activity in the two yeasts are different. As an approach to a better understanding of ARS structure and function in K. lactis, we analyzed the replication of the circular plasmid pKD1. We identified a 159-bp sequence able to promote autonomous replication of pKD1 in both yeasts; this fragments contains both a sequence related to the S. cerevisiae ARS consensus sequence and a region of 53% identity to the 40-bp sequence essential for K. lactis KARS101 function. By the analysis of in vivo replication intermediates we provide the first direct evidence that DNA replication initiates at or near the K. lactis ARS element. Replication terminates at the cisacting stability locus of pKD1, which functions as a replication fork barrier (RFB) and is necessary for proper plasmid segregation. RFB activity requires the pKDI gene products that are important for plasmid segregation, suggesting a link between DNA replication termination and plasmid segregation in a eukaryotic organism.     

Functional conservation of multiple elements in yeast chromosomal replicators.

Replicators that control the initiation of DNA replication in the chromosomes of Saccharomyces cerevisiae retain their function when cloned into plasmids, where they are commonly referred to as autonomously replicating sequences (ARSs). Previous studies of the structure of ARS1 in both plasmid and chromosome contexts have shown that it contains one essential DNA element, A, that includes a match to the ARS consensus sequence (ACS), and three additional elements, B1, B2, and B3, that are also important for ARS function. Elements A and B3 are bound by a candidate initiator protein called the origin recognition complex and ARS-binding factor 1, respectively. Although the A and B3 elements have been found in other ARSs, sequence comparisons among ARSs have failed to identify B1- and B2-like elements. To assess the generality of the modular nature of yeast replicators, linker substitution mutagenesis of another yeast chromosomal replicator, ARS307, was performed. Three DNA sequence elements were identified in ARS307, and they were demonstrated to be functionally equivalent to the A, B1, and B2 elements present in ARS1. Despite the lack of DNA sequence similarity, the B1 and B2 elements at each ARS were functionally conserved. Single-base substitutions in the core of the ARS1 B1 and B2 elements identified critical nucleotides required for the function of the B1 element. In contrast, no single-point mutations were found to affect B2 function. The results suggest that multiple DNA sequence elements might be a general and conserved feature of replicator sequences in S. cerevisiae.     

The function of the nuclear matrix attachment region of silkworm rDNA as an autonomously replicating sequence in plasmid and chromosomal replication origin in yeast

Nuclear matrix attachment regions (MARs) play a crucial role in chromatin architecture, gene expression, and DNA replication. Although it is well known that yeast autonomously replicating sequences (ARSs) bind nuclear matrix and MARs also function as ARS elements in yeast, whether a heterologous MAR or ARS element acts as a replication origin in the chromosome has not been elucidated. We previously identified a MAR (rMAR) located in the nontranscribed spacer (NTS) of silkworm Attacus ricini rDNA. We report here that this rMAR contains 10 copies of ARS consensus sequence (ACS) and several DNA unwinding regions. The rMAR employs ARS activity in yeast and a rARS element locates in the 3(') region of the rMAR. Furthermore, we have also revealed that either the rMAR or the rARS element functions as a replication origin in the chromosome. Our results provide the first direct evidence to demonstrate that heterologous rMAR and rARS display chromosomal origin activity, suggesting that the chromosome structure and replication origin of rDNA reserve some common features during evolution.     

Interaction of the H4 autonomously replicating sequence core consensus sequence and its 3''-flanking domain.

Yeast autonomously replicating sequence (ARS) elements are composed of a conserved 11-base-pair (bp) core consensus sequence and a less well defined 3'-flanking region. We have investigated the relationship between the H4 ARS core consensus sequence and its 3'-flanking domain. The minimal sequences necessary and sufficient for function were determined by combining external 3' and 5' deletions to produce a nested set of ARS fragments. Sequences 5' of the core consensus were dispensable for function, but at least 66 bp of 3'-flanking domain DNA was required for full ARS function. The importance of the relative orientation of the core consensus element with respect to the 3'-flanking domain was tested by precisely inverting 14 bp of DNA including the core consensus sequence by oligonucleotide mutagenesis. This core inversion mutant was defective for all ARS function, showing that a fixed relative orientation of the core consensus and 3'-flanking domain is required for function. The 3'-flanking domain of the minimal functional H4 ARS fragment contains three sequences with a 9-of-11-bp match to the core consensus. The role of these near-match sequences was tested by directed mutagenesis. When all near-match sequences with an 8-of-11-bp match or better were simultaneously disrupted by point mutations, the resulting ARS construct retained full replication function. Therefore, multiple copies of a sequence closely related to the core consensus element are not required for H4 ARS function.