Identification of an essential core element and stimulatory sequences in a Kluyveromyces lactis ARS element, KARS101

A Kluyveromyces lactis chromosomal sequence of 913 bp is sufficient for replication in Saccharomyces cerevisiae and K. lactis . This fragment contains a 12 bp sequence 5'-ATTTATTGTTTT-3' that is related to the S. cerevisiae ACS (ARS consensus sequence). This dodecamer was removed by site-directed mutagenesis and the effect on K. lactis and S. cerevisiae ARS (autonomous replicating sequence) activity was determined. The dodecamer is essential for S. cerevisiae ARS function but only contributes to K. lactis ARS activity; therefore, its role in K. lactis is unlikely to be the same as that of the essential S. cerevisiae ACS.
A 103 bp subclone was found to retain ARS activity in both yeasts, but the plasmid was very unstable in S. cerevisiae . Deletion and linker substitution mutagenesis of this fragment was undertaken to define the DNA sequence required for K. lactis ARS function and to test whether the sequence required for ARS activity in K. lactis and S. cerevisiae coincide. We found a 39 bp core region essential for K. lactis ARS function flanked by sequences that contribute to ARS efficiency. The instability of the plasmid in S. cerevisiae made a fine-structure analysis of the S. cerevisiae ARS element impossible. However, the sequences that promote high-frequency transformation in S. cerevisiae overlap the essential core of the K. lactis ARS element but have different end-points.     

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.     

Yeast DNA replication in vitro: initiation and elongation events mimic in vivo processes

An enzyme system prepared from Saccharomyces cerevisiae carries out the replication of exogenous yeast plasmid DNA. Replication in vitro mimics that in vivo in that DNA synthesis in extracts of strain cdc8, a temperature-sensitive DNA replication mutant, is thermolabile relative to the wild-type, and in that aphidicolin inhibits replication in vitro. Furthermore, only plasmids containing a functional yeast replicator, ARS, initiate replication at a specific site in vitro. Analysis of replicative intermediates shows that plasmid YRp7, which contains the chromosomal replicator ARS1, initiates bidirectional replication in a 100 bp region within the sequence required for autonomous replication in vivo. Plasmids containing ARS2, another chromosomal replicator, and the ARS region of the endogenous yeast plasmid 2 microns circle give similar results, suggesting that ARS sequences are specific origins of chromosomal replication. Used in conjunction with deletion mapping, the in vitro system allows definition of the minimal sequences required for the initiation of replication.     

DNA elements modulating the <Emphasis Type="Italic">KARS12</Emphasis> chromosomal replicator in <Emphasis Type="Italic">Kluyveromyces lactis</Emphasis>

Eukaryotic chromosomal DNA replication is initiated by a highly conserved set of proteins that interact with cis-acting elements on chromosomes called replicators. Despite the conservation of replication initiation proteins, replicator sequences show little similarity from species to species in the small number of organisms that have been examined. Examination of replicators in other species is likely to reveal common features of replicators. We have examined a Kluyeromyces lactis replicator, KARS12, that functions as origin of DNA replication on plasmids and in the chromosome. It contains a 50-bp region with similarity to two other K. lactis replicators, KARS101 and the pKD1 replication origin. Replacement of the 50-bp sequence with an EcoRI site completely abrogated the ability of KARS12 to support plasmid and chromosomal DNA replication origin activity, demonstrating this sequence is a common feature of K. lactis replicators and is essential for function, possibly as the initiator protein binding site. Additional sequences up to 1 kb in length are required for efficient KARS12 function. Within these sequences are a binding site for a global regulator, Abf1p, and a region of bent DNA, both of which contribute to the activity of KARS12. These elements may facilitate protein binding, protein/protein interaction and/or nucleosome positioning as has been proposed for other eukaryotic origins of DNA replication.     

Transformation of Kluyveromyces fragilis

For the transformation of the yeast species Kluyveromyces fragilis, we have constructed a vector containing a bacterial kanamycin resistance (Kmr) gene, the TRP1 gene of Saccharomyces cerevisiae, and an autonomously replicating sequence of Kluyveromyces lactis called KARS2 . By utilizing the method based on treatment by alkali cations and with the Kmr gene as the selective marker, a wild-type strain of K. fragilis was transformed to resistance against the antibiotic G418 . In the transformed cell the plasmid replicates autonomously. The same plasmid could also be used to transform S. cerevisiae trp1 mutant to Trp+. Thus, KARS2 of K. lactis enables the vector to replicate in K. fragilis, K. lactis, and S. cerevisiae, whereas ARS1 of S. cerevisiae allows autonomous replication only in S. cerevisiae.     

Analysis of chromosome III replicators reveals an unusual structure for the ARS318 silencer origin and a conserved WTW sequence within the origin recognition complex binding site

Saccharomyces cerevisiae chromosome III encodes 11 autonomously replicating sequence (ARS) elements that function as chromosomal replicators. The essential 11-bp ARS consensus sequence (ACS) that binds the origin recognition complex (ORC) has been experimentally defined for most of these replicators but not for ARS318 (HMR-I), which is one of the HMR silencers. In this study, we performed a comprehensive linker scan analysis of ARS318. Unexpectedly, this replicator depends on a 9/11-bp match to the ACS that positions the ORC binding site only 6 bp away from an Abf1p binding site. Although a largely inactive replicator on the chromosome, ARS318 becomes active if the nearby HMR-E silencer is deleted. We also performed a multiple sequence alignment of confirmed replicators on chromosomes III, VI, and VII. This analysis revealed a highly conserved WTW motif 17 to 19 bp from the ACS that is functionally important and is apparent in the 228 phylogenetically conserved ARS elements among the six sensu stricto Saccharomyces species.     

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.     

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.     

Deletion mutations affecting autonomously replicating sequence ARS1 of Saccharomyces cerevisiae.

DNAs that contain specific yeast chromosomal sequences called ARSs transform Saccharomyces cerevisiae at high frequency and can replicate extrachromosomally as plasmids when introduced into S. cerevisiae by transformation. To determine the boundaries of the minimal sequences required for autonomous replication in S. cerevisiae, we have carried out in vitro mutagenesis of the first chromosomal ARS described, ARS1. Rather than identifying a distinct and continuous segment that mediates the ARS+ phenotype, we find three different functional domains within ARS1. We define domain A as the 11-base-pair (bp) sequence that is also found at most other ARS regions. It is necessary but not sufficient for high-frequency transformation. Domain B, which cannot mediate high-frequency transformation, or replicate by itself, is required for efficient, stable replication of plasmids containing domain A. Domain B, as we define it, is continuous with domain A in ARS1, but insertions of 4 bp between the two do not affect replication. The extent of domain B has an upper limit of 109 bp and a lower limit of 46 bp in size. There is no obvious sequence homology between domain B of ARS1 and any other ARS sequence. Finally, domain C is defined on the basis of our deletions as at least 200 bp flanking domain A on the opposite side from domain B and is also required for the stability of domain A in S. cerevisiae. The effect of deletions of domain C can be observed only in the absence of domain B, at least by the assays used in the current study, and the significance of this finding is discussed.     

DNA sequence and functional analysis of homologous ARS elements of Saccharomyces cerevisiae and S. carlsbergensis.

ARS elements of Saccharomyces cerevisiae are the cis-acting sequences required for the initiation of chromosomal DNA replication. Comparisons of the DNA sequences of unrelated ARS elements from different regions of the genome have revealed no significant DNA sequence conservation. We have compared the sequences of seven pairs of homologous ARS elements from two Saccharomyces species, S. cerevisiae and S. carlsbergensis. In all but one case, the ARS308-ARS308(carl) pair, significant blocks of homology were detected. In the cases of ARS305, ARS307, and ARS309, previously identified functional elements were found to be conserved in their S. carlsbergensis homologs. Mutation of the conserved sequences in the S. carlsbergensis ARS elements revealed that the homologous sequences are required for function. These observations suggested that the sequences important for ARS function would be conserved in other ARS elements. Sequence comparisons aided in the identification of the essential matches to the ARS consensus sequence (ACS) of ARS304, ARS306, and ARS310(carl), though not of ARS310.     

An autonomously replicating sequence of pSRI plasmid is effective in two yeast species, Zygosaccharomyces rouxii and Saccharomyces cerevisiae

The autonomously replicating sequences (ARSs) of pSR1, a cryptic circular DNA plasmid detected in a strain of Zygosaccharomyces rouxii, were delimited by subcloning and deletion analysis and by the isolation of nucleotide substitution mutations. A 30 base-pair (bp) sequence from inverted repeat 1 (IR1) and presumably the same region from IR2 of pSR1 functions as an ARS in the native host, Z. rouxii, and in a heterologous host, Saccharomyces cerevisiae. Thus, pSR1 has two ARSs per molecule, either of which is sufficient for replication of the plasmid molecule in both hosts. These hosts, however, respond differently to nucleotide substitutions in the 30 bp sequence, suggesting that the sequences required for ARS function in the two organisms are not exactly the same. In addition, a 137 bp sequence that overlaps the 30 bp sequence by 11 bp also functions as an ARS in Z. rouxii but not in S. cerevisiae. However, this 137 bp sequence enhances the stability of plasmids carrying the pSR1 ARS in S. cerevisiae. The 30 bp and 137 bp sequences each contain a single copy of the 11 bp ARS consensus sequence, which is essential for ARS function in S. cerevisiae. Small insertions between the 11 bp overlapping region and the 11 bp ARS consensus sequence showed that a proper distance between these two 11 bp sequences is essential for the ARS function of the 30 bp sequence. Point mutations that inactivate ARS function show that the ARS consensus sequence, as well as a short A:T segment in the overlapping sequence, is required for the ARS function of the 30 bp sequence.     

Transformation of Kluyveromyces lactis with the kanamycin (G418) resistance gene of Tn903

Direct selection of Kluyveromyces lactis resistant to the antibiotic G418 following transformation with the kanamycin resistance gene of Tn903 required the development of a procedure for producing high yields of viable spheroplasts and for the isolation of autonomous replication sequences (ARS). To obtain high yields of viable spheroplasts, cells were treated with (1) a thiol-reducing agent (L-cysteine), and (2) a high concentration of an osmotic stabilizer, 1.5 M sorbitol. Several ARS-containing plasmids were selected from a K. lactis recombinant DNA library in K. lactis and in Saccharomyces cerevisiae. Two of four ARS clones selected in K. lactis promoted transformation frequencies of 5-10 X 10(2) G418-resistant cells/micrograms of plasmid DNA. This frequency of transformation was at least twice as high as with ARS clones selected in S. cerevisiae. The stability of ARS-containing plasmids varied; after 20 generations of growth in the presence of G418, 16-38% of the cells remained resistant to the drug. In the absence of selection pressure less than 5% of the cells retained the drug-resistance phenotype. Plasmids containing the ARS1 or 2 mu replicon of S. cerevisiae failed to transform K. lactis for G418 resistance. Inclusion of S. cerevisiae centromere, CEN4, in a K. lactis ARS recombinant plasmid did not increase the stability of the plasmid in K. lactis, and marker genes on the vector segregated predominantly 4-:0+ through meiosis. We conclude that neither the ARS sequences or the centromere of S. cerevisiae was functioning in K. lactis.     

Two compound replication origins in Saccharomyces cerevisiae contain redundant origin recognition complex binding sites

While many of the proteins involved in the initiation of DNA replication are conserved between yeasts and metazoans, the structure of the replication origins themselves has appeared to be different. As typified by ARS1, replication origins in Saccharomyces cerevisiae are <150 bp long and have a simple modular structure, consisting of a single binding site for the origin recognition complex, the replication initiator protein, and one or more accessory sequences. DNA replication initiates from a discrete site. While the important sequences are currently less well defined, metazoan origins appear to be different. These origins are large and appear to be composed of multiple, redundant elements, and replication initiates throughout zones as large as 55 kb. In this report, we characterize two S. cerevisiae replication origins, ARS101 and ARS310, which differ from the paradigm. These origins contain multiple, redundant binding sites for the origin recognition complex. Each binding site must be altered to abolish origin function, while the alteration of a single binding site is sufficient to inactivate ARS1. This redundant structure may be similar to that seen in metazoan 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.     

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.     

In vitro deletion analysis of ARS elements spanning the replication origin in the 5'' non-transcribed spacer of Tetrahymena thermophila ribosomal DNA.

Two adjacent but non-overlapping restriction fragments that encompass the replication origin of the macronuclear copy of rDNA from Tetrahymena thermophila allow autonomous replication of plasmids in the yeast Saccharomyces cerevisiae; i.e. they function as autonomously replicating segments (ARS). Deletions generated in vitro into these fragments yield an 82 bp segment from each as the smallest sequence specifying ARS function. These 82 bp segments are at the 5' end of a 220 bp region of homology between the two original ARS restriction fragments. A 39 bp region of almost complete sequence identity between the two 82 bp fragments is suggested to be a core sequence element necessary for ARS function. This 39 bp sequence contains a region identical or nearly identical to the 11 bp yeast ARS consensus sequence (T/ATTTATPuTTTA/T) which is suggested to be essential for ARS function. Detailed comparisons of the 82 bp segments and of the 39 bp core with other ARS sequences reveal no extensive homologies aside from the consensus.     

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.     

Analysis of the interactions of functional domains of a nuclear origin of replication from Saccharomyces cerevisiae.

We have determined that ARS121 is an efficient origin of replication on chromosome X of Saccharomyces cerevisiae. This origin is comprised of at least three distinct functional domains. One of these domains is the ARS121 core sequence (approximately 35 bp-long), which is essential for origin activity. This essential core contains an 11 bp sequence resembling (2 bp mismatch) the ARS consensus. Another important domain is an enhancer of DNA replication, which binds the OBF1 protein. The third domain, ATR (A/T-rich, approximately 72 bp), is auxiliary and works in either orientation, but only when located 3' to the essential core. When fused to the ARS121 core both the enhancer and the ATR domain act synergistically to enhance the activity of the origin. Furthermore, when fused to the essential core sequences of heterologous ARSs, ARS1 and ARS307, the auxiliary domains also appeared to stimulate synergistically origin function. These results suggest that (i) in order to elicit maximal origin activity all three domains have to interact and (ii) activation of the essential core sequences at different origins of replication may share a common mechanism.     

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.     

Single-strand-binding factor(s) which interact with ARS1 of Saccharomyces cerevisiae

Since plasmids containing autonomously replicating sequence(s) (ARS) can transform Saccharomyces cerevisiae cells at high frequency, ARS are considered to be the replication origins of chromosomes. To study the mechanism of initiation of eukaryotic chromosomal replication, we examined protein factors which interact with the ARS1 region located near the centromere of chromosome IV in S. cerevisiae. Using the gel-shift assay, we found protein factors which bound to a single-stranded, 97-bp fragment of the ARS1 region containing the core consensus. Competition experiments with various oligodeoxyribonucleotides (oligos) suggest that a site recognized by the factor(s) was within the element containing the core consensus and adjacent close matches to the core consensus of the minus strand. Indeed, when the oligo containing the minus strand of this element was used as a probe, two oligo-protein complexes were detected. Mutations in the core consensus reduced these binding activities. When the plus-strand oligo of the same region was used as a probe, a retarded band was also detected, but with less specific binding. Considering the fact that the core consensus and close matches to the core consensus are important for ARS function, these results imply that the protein factors detected in this experiment may participate in DNA replication.