Drosophila ARSs contain the yeast ARS consensus sequence and a replication enhancer.

A number of restriction fragments that function as autonomously replicating sequences (ARSs) in yeast have been isolated from Drosophila melanogaster DNA. The behaviour in yeast of plasmids containing Drosophila ARS elements was studied and compared to that exhibited by the archetypal yeast ARS-1 plasmid. ARS functions were localised by subcloning and BAL-31 deletion analysis. These studies demonstrated the structural and functional complexity of Drosophila ARSs. Each Drosophila ARS element has at least two domains, one essential for replication (the replication sequence, RS) and a second (the replication enhancer, RE) which is essential for maximum function of the RS. The RS of three Drosophila ARSs was shown to contain a sequence identical to an 11 bp yeast ARS consensus sequence (5' A/T TTTATPuTTT A/T 3'). These observations lend support to the hypothesis that heterologous ARS elements may be of biological significance.     

Localization and sequence analysis of chloroplast DNA sequences of Chlamydomonas reinhardii that promote autonomous replication in yeast

Four distinct chloroplast DNA segments from Chlamydomonas reinhardii of 400, 415, 730 and 2300 bp which promote autonomous replication in yeast have been mapped on the chloroplast genome. Plasmids carrying these chloroplast DNA fragments are unstable in yeast when the cells are grown under non-selective conditions. Sequence analysis of three of these chloroplast ARS regions (autonomously replicating sequences in yeast) reveals a high AT content, numerous short direct and inverted repeats and the presence of at least one element in each region that is related to the yeast ARS consensus sequence. A/T TTTATPuTTT A/T. These three chloroplast regions share, in addition, two common elements of 10 and 11 bp which may play a role in promoting autonomous replication.     

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.     

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.     

A Petunia hybrida chloroplast DNA region, close to one of the inverted repeats, shows sequence homology with the Euglena gracilis chloroplast DNA region that carries the putative replication origin

Summary Three distinct chloroplast (cp) DNA fragments from Petunia hybrida, which promote autonomous replication in yeast, were mapped on the chloroplast genome. Sequence analysis revealed that these fragments (called ARS A, B and C) have a high AT content, numerous short direct and inverted repeats and at least one yeast ARS consensus sequence 5A/TTTTATPuTTTA/T, essential for yeast ARS activity. ARS A and B also showed the presence of (semi-)conserved sequences, present in all Chlamydomanas reinhardii cpDNA regions that promote autonomous replication in yeast (ARS sequences) or in C. reinhardii (ARC sequences). A 431 bp BamHI/EcoRI fragment, close to one of the inverted repeats and adjacent to the ARS B subfragment contains an AT-rich stretch of about 100 nucleotides that show extensive homology with an Euglena gracilis cpDNA fragment which is part of the replication origin region. This conserved region contains direct and inverted repeats, stem-and-loop structures can be folded and it contains an ARS consensus sequence. In the near vicinity a GC-rich block is present. All these features make this cpDNA region the best candidate for being the origin of replication of P. hybrida cpDNA.     

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.     

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.     

Bending of DNA segments with Saccharomyces cerevisiae autonomously replicating sequence activity, isolated from basidiomycete mitochondrial linear plasmids

Summary Previous studies have indicated that DNA bending is a general structural feature of sequences (ARSs) from cellular DNAs of yeasts and nuclear and mitochondrial genomic DNAs of other eukaryotes that are capable of autonomous replication in Saccharomyces cerevisiae. Here we showed that bending activity is also tightly associated with S. cerevisiae ARS function of segments cloned from mitochondrial linear DNA plasmids of the basidiomycetes Pleurotus ostreatus and Lentinus edodes. Two plasmids, designated pLPO2-like (9.4 kb), and pLPO3 (6.6 kb) were isolated from a strain of P. ostreatus. A 1029 by fragment with high-level ARS activity was cloned from pLPO3 and it contained one ARS consensus sequence (A/T)TTTAT(A/G)TTT(A/T) indispensable for activity and seven dispersed ARS consensus-like (10/11 match) sequences. A discrete bent DNA region was found to lie around 500 by upstream from the ARS consensus sequence (T-rich strand). Removal of the bent DNA region impaired ARS function. DNA bending was also implicated in the ARS function associated with a 1430 by fragment containing three consecutive ARS consensus sequences which had been cloned from the L. edodes plasmid pLLE1 (11.0 kb): the three consecutive ARSs responsible for high-level ARS function occurred in, and immediately adjacent to, a bent DNA region. A clear difference exists between the two plasmid-derived ARS fragments with respect to the distance between the bent DNA region and the ARS consensus sequence(s).     

Sequence analysis of three fragments of maize nuclear DNA which replicate autonomously in yeast

There maize nuclear DNA fragments were isolated on the basis of their ability to confer replication on chimeric plasmids in yeast. These Eco RI fragments of 2.5, 2.8 and 5.5 kb are repeated elements within the maize genome. The 2.5 and 2.8 kb fragments represent a family of elements repeated 11 000 times in the maize haploid genome, while the 5.5 kb fragment is part of another family of 28 000 elements. These fragments were subcloned to further define the unique region of ARS activity. The sequence of each 550–650 bp ARS subclone is reported here, and compared to the flanking regions which do not show ARS activity. The ARS elements are 65–70% A+T as compared to 50–55% for the maize genome as a whole. There is approximately 15% sequence divergence, as well as variation of ARS efficiency, among family members. ARS subclones contain the proposed yeast consensus sequence.     

An ARS element from Drosophila melanogaster telomeres contains the yeast ARS core and bent replication enhancer.

We have sequenced the 0.7-kb-long fragment of Drosophila DNA which ensures the autonomous replication of plasmids in yeast. Deletion mapping has shown the ARS element to consist of at least two domains: the core having the consensus 11-bp sequence TAAATATAAAT and the enhancer which is no more than 90 bp long and is located at the 3'-end of the A-rich core strand. Neither domain per se ensures plasmid replication in yeast. A comparison of the enhancer sequence with the sequences of 14 different ARS elements failed to reveal significant homology areas. Most probably the ARS flanks that are adjacent to the core and act as enhancer do not carry any consensus. They may determine a peculiar structural feature of DNA (for example bends) which are necessary for the protein-ARS interaction.     

Isolation and characterization of an autonomously replicating sequence from Ustilago maydis.

DNA fragments that function as autonomously replicating sequences (ARSs) have been isolated from Ustilago maydis. When inserted into an integrative transforming vector, the fragments increased the frequency of U. maydis transformation several-thousandfold. ARS-containing plasmids were transmitted in U. maydis as extrachromosomal elements through replication. They were maintained at a level of about 25 copies per cell but were mitotically unstable. One ARS characterized in detail, which we called UARS1, was localized to a 1.7-kilobase fragment. UARS1 contained a cluster of active sequences. This element could be reduced further into three separate subfragments, each of which retained ARS activity. The smallest one was 383 base pairs (bp) long. Although not active itself in yeast, this small fragment contained seven 8-bp direct repeats, two contiguous 30-bp direct repeats, and five 11-bp units in both orientations with sequences similar but not identical to the consensus sequence found to be crucial for ARS activity in Saccharomyces cerevisiae.     

Sequence analysis of ARS elements in fission yeast.

Chromosomal DNA of Schizosaccharomyces pombe contains sequences with properties analogous to ARS elements of Saccharomyces cerevisiae. Following Sau3A fragmentation of the S. pombe genome we have recovered a number of such fragments in an M13-based shuttle vector, suitable for subsequent sequence analysis. The complete nucleotide sequence has been obtained for eight ARS+ inserts derived from the Sau3A cloning and for the ARS present in pFL20 isolated previously by Losson and Lacroute (Cell, 32, 371-377, 1983). The Sau3A clones are single fragments between 0.8 and 1.8 kb. No ARS+ clones smaller than this were recovered even though the average size Sau3A fragment in S. pombe is approximately 200-300 bp. The sequence analysis revealed that all clones are AT-rich (69-75% A + T residues), and all contain a particularly AT-rich 11 bp core element represented by the consensus sequence 5' (A/T)PuTT-TATTTA(A/T) 3'. Deletion mapping indicates that the consensus in all cases is in the vicinity of a functional ARS domain. However precise excision of the consensus by in vitro mutagenesis has little effect on ARS activity as judged by the transformation assay. We argue that the association of the consensus with the ARS domain occurs too reproducibly to be explained by chance alone. We suggest that although it may not be essential for the extrachromosomal maintenance of plasmids in S. pombe, the consensus does have a function in situ in the chromosome and thus is always present as a cryptic sequence in the isolated ARS element.     

A single-stranded DNA binding protein from S. cerevisiae specifically recognizes the T-rich strand of the core sequence of ARS elements and discriminates against mutant sequences.

A protein named ssARS-T binding protein has been purified from yeast that specifically binds to the T-rich strand of the consensus core sequence of yeast autonomously replicating sequence (ARS) elements. As assayed from gel mobility shift experiments the ssARS-T protein shows characteristics of a sequence specific single-stranded DNA binding protein. The complementary A-rich strand of the ARS core sequence is bound much more weakly and no binding can be detected for the double-stranded form of the core sequence. Three single base substitutions in the core sequence that are known to abolish ARS function in vivo also lead to weaker binding of the core sequence to the ssARS-T protein in vitro. The strong correlation between the binding of mutated sequences in vitro and the ARS properties of these sequences in vivo points to an essential function of the ssARS-T protein during replication initiation in yeast ARS elements.     

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.     

Location and characterization of autonomously replicating sequences from chromosome VI of Saccharomyces cerevisiae.

We have reported the isolation of linking clones of HindIII and EcoRI fragments, altogether spanning a 230-kb continuous stretch of chromosome VI. The presence or absence of autonomously replicating sequence (ARS) activities in all of these fragments has been determined by using ARS searching vectors containing CEN4. Nine ARS fragments were identified, and their positions were mapped on the chromosome. Structures essential for and/or stimulative to ARS activity were determined for the ARS fragments by deletions and mutations. The organization of functional elements composed of core and stimulative sequences was found to be variable. Single core sequences were identified in eight of nine ARSs. The remaining ARS (ARS603) essential element is composed of two core-like sequences. The lengths of 3'- and 5'-flanking stimulative sequences required for the full activity of ARSs varied from ARS to ARS. Five ARSs required more than 100 bp of the 3'-flanking sequence as stimulative sequences, while not more than 79 bp of the 3' sequence was required by the other three ARSs. In addition, five ARSs had stimulative sequences varying from 127 to 312 bp in the 5'-flanking region of the core sequence. In general, these stimulative activities were correlated with low local delta Gs of unwinding, suggesting that the low local delta G of an ARS is an important element for determining the efficiency of initiation of replication of ARS plasmids.     

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.     

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.     

Characterization of human chromosomal DNA sequences which replicate autonomously in Saccharomyces cerevisiae.

We have characterised two restriction fragments, isolated from a "shotgun" collection of human DNA, which function as autonomously replicating sequences (ARSs) in Saccharomyces cerevisiae. Functional domains of these fragments have been defined by subcloning and exonuclease (BAL 31) deletion analysis. Both fragments contain two spatially distinct domains. One is essential for high frequency transformation and is termed the Replication Sequence (RS) domain, the other, termed the Replication Enhancer (RE) domain, has no inherent replication competence but is essential for ensuring maximum function of the RS domain. The nucleotide sequence of these domains reveals several conserved sequences one of which is strikingly similar to the yeast ARS consensus sequence.     

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

Centromere DNA from 11 of the 16 chromosomes of the yeast Saccharomyces cerevisiae have been analyzed and reveal three sequence elements common to each centromere, referred to as conserved centromere DNA elements (CDE). The adenine-plus-thymine (A + T)-rich central core element, CDE II, is flanked by two short conserved sequences, CDE I (8 base pairs [bp]) and CDE III (25 bp). Although no consensus sequence exists among the different CDE II regions, they do have three common features of sequence organization. First, the CDE II regions are similar in length, ranging from 78 to 86 bp measured from CDE I to the left boundary of CDE III. Second, the base composition is always greater than 90% A + T. Finally, the A and T residues in these segments are often arranged in runs of A and runs of T residues, sometimes with six or seven bases in a stretch. We constructed insertion, deletion, and replacement mutations in the CDE II region of the centromere from chromosome III, CEN3, designed to investigate the length and sequence requirements for function of the CDE II region of the centromere. We analyzed the effect of these altered centromeres on plasmid and chromosome segregation in S. cerevisiae. Our results show that increasing the length of CDE II from 84 to 154 bp causes a 100-fold increase in chromosome nondisjunction. Deletion mutations removing segments of the A + T-rich CDE II DNA also cause aberrant segregation. In some cases partial function could be restored by replacing the deleted DNA with fragments whose primary sequence or base composition is very different from that of the wild-type CDE II DNA. In addition, we found that identical mutations introduced into different positions in CDE II have very similar effects.