Identification of a centromeric activity in the autonomously replicating TRA region allows improvement of the host-vector system for Candida maltosa

A centromeric activity was identified in the previously isolated 3.8 kb DNA fragment that carries an autonomously replicating sequence (ARS) from the yeast Candida maltosa. Plasmids bearing duplicated copies of the centromeric DNA (dicentric plasmids) were physically unstable and structural rearrangements of the dicentric plasmids occurred frequently in the transformed cells. The centromeric DNA activity was dissociated from the ARS, which is 0.2 kb in size, and was delimited to a fragment at least 325 by in length. The centromeric DNA region included the consensus sequences of CDEI (centromeric DNA element I) and an AT-rich CDEII-like region of Saccharomyces cerevisiae but had no homology to the functionally critical CDEIII consensus. A plasmid bearing the whole 3.8 kb fragment was present in 1–2 copies per cell and was maintained stably even under non-selective culture conditions, while a plasmid having only the 0.2 kb ARS was unstable and accumulated to high copy numbers. The high-copy-number plasmid allowed us to overexpress a gene to a high level, which had never been attained before, under the control of both constitutive and inducible promoters in C. maltosa.     

Structure-function relationships in replication origins of the yeast Saccharomyces cerevisiae: higher-order structural organization of DNA in regions flanking the ARS consensus sequence

In order to better understand the involvement of the DNA molecule in the replication initiation process we have characterized the structure of the DNA at Autonomously Replicating Sequences (ARSs) in Saccharomyces cerevisiae. Using a new method for anti-bent DNA analysis, which allowed us to take into account the bending contribution of each successive base plate, we have investigated the higher-order structural organization of the DNA in the region which immediately surrounds the ARS consensus sequence (ACS). We have identified left- and right-handed anti-bent DNAs which flank this consensus sequence. The data show that this organization correlates with an active ACS. Analysis of the minimum nucleotide sequence providing ARS function to plasmids reveals an example where the critical nucleotides are restricted to the ACS and the right-handed anti-bent DNA domain, although most of the origins considered contained both left- and right-handed anti-bent DNAs. Moreover, mutational analysis shows that the right-handed form is necessary in order to sustain a specific DNA conformation which is correlated with the level of plasmid maintenance. A model for the role of these individual structural components of the yeast replication origin is presented. We discuss the possible role of the right-handed anti-bent DNA domain, in conjunction with the ACS, in the process of replication initiation, and potentialities offered by the combination of left- and right-handed structural components in origin function. Received: 29 October 1999 / Accepted: 14 March 2000     

DNA structures associated with autonomously replicating sequences from plants

DNA fragments capable of conferring autonomous replicating ability to plasmids inSaccharomyces cerevisiae were isolated from four different plant genomes and from the Ti plasmid ofAgrobacterium tumefaciens. The DNA structure of these autonomously replicating sequences (ARSs) as well as two from yeast were studied using retardation during polyacrylamide gel electrophoresis and computer analysis as measures of sequence-dependent DNA structures. Bent DNA was found to be associated with the ARS elements. An 11 bp ARS consensus sequence required for ARS function was also identified in the elements examined and was flanked by unusually straight structures which were rich in A+T content. These results show that the ARS elements from genomes of higher plants have structural and sequence features in common with ARS elements from yeast and higher animals.Supported by Grant 1RO1-GM41708-O1 from the National Institute of Health.     

Bent DNA functions as a replication enhancer in Saccharomyces cerevisiae.

Previous studies have demonstrated that bent DNA is a conserved property of Saccharomyces cerevisiae autonomously replicating sequences (ARSs). Here we showed that bending elements are contained within ARS subdomains identified by others as replication enhancers. To provide a direct test for the function of this unusual structure, we analyzed the ARS activity of plasmids that contained synthetic bent DNA substituted for the natural bending element in yeast ARS1. The results demonstrated that deletion of the natural bending locus impaired ARS activity which was restored to a near wild-type level with synthetic bent DNA. Since the only obvious common features of the natural and synthetic bending elements are the sequence patterns that give rise to DNA bending, the results suggest that the bent structure per se is crucial for ARS function.     

Prediction of Saccharomyces cerevisiae replication origins

Background  

Autonomously replicating sequences (ARSs) function as replication origins in Saccharomyces cerevisiae. ARSs contain the 17 bp ARS consensus sequence (ACS), which binds the origin recognition complex. The yeast genome contains more than 10,000 ACS matches, but there are only a few hundred origins, and little flanking sequence similarity has been found. Thus, identification of origins by sequence alone has not been possible.     

The basidiomycete Lentinus edodes linear mitochondrial DNA plasmid contains a segment exhibiting a high autonomously replicating sequence activity in Saccharomyces cerevisiae.

A linear DNA plasmid, designated pLLE1, has been isolated from a mitochondrial fraction of a strain of Lentinus edodes. pLLE1(11.0 kbp) was sensitive to the 3'----5'-acting exonuclease III and resistant to the 5'----3'-acting lambda exonuclease. It showed no homology with mitochondrial and nuclear genomic DNAs of plasmidless strain as well as the pLLE1-harboring host strain of L. edodes. The 1434-bp fragment (sequences) capable of autonomous replication in the yeast Saccharomyces cerevisiae (ARSs) was cloned from pLLE1 DNA with YIp32 (pBR322 containing yeast LEU2 DNA), which displayed a high ARS activity. The cloned 1434-bp fragment was shown to lie near to the end of pLLE1 DNA (nucleotides about 800-2200) and contained three consecutive ARS consensus sequences (A/T)TTTAT(A/G)TTT(A/T) of S. cerevisiae and dispersive eight ARS consensus-like sequences. The subcloned 366-bp fragment containing the three ARSs retained original ARS activity of the 1434-bp fragment.     

Cloning of DNA sequences from Methanococcus vannielii capable of autonomous replication in yeast

Total DNA of the archaebacterium Methanococcus vannielii was digested with BamHI or BamHI/HindIII, cloned with plasmid Yip5 and analyzed for sequences capable of autonomous replication (ARSs) in the eukaryote Saccharomyces cerevisiae. Two recombinant plasmids were isolated which contained 3.3 kb and 8 kb fragments of methanogen derived DNA with ARS activity. They exhibited low transformation efficiencies for yeast and promoted slow growth of yeast transformants.Abbreviations Ap ampicillin - ARS autonomously replicating sequence - EtBr ethidium bromide - kb kilobase(s) - Mc. Methanococcus - R resistance - RE replication enhancer - RS replication sequence - Tc tetracycline     

Molecular cloning and characterization of ARS elements from the mud loach (Misgurnus mizolepis)

Autonomously replicating sequences (ARSs) are thought to occur within, or adjacent to, the matrix attachment regions (MARs). To identify fish ARSs, MARs of the mud loach fish were obtained from nuclear matrices using a modified LIS method. These DNA fragments were screened for their ability to act as ARSs by being cloned into the ARS cloning vector, pURY19, and transformed into Saccharomyces cerevisiae. Sixteen ARSs were isolated, most of which were more efficient in transformation than the positive control vector, pURY19-2 microm, which contained the 2 microm circle origin of yeast. In particular, one clone, pURY19-ARS223, was 18 times more efficient in back-transforming E. coli than the positive control vector. Therefore, ARS223, which has strong ARS activity in yeast, could be a good candidate for inclusion in expression vehicles that are used to transfect fish cell lines or embryos. A DNA sequence analysis showed that the essential ARS elements contain potential ARS consensus sequences, and are predicted to have hairpin loop structures, or curved or kinked DNA. In addition, the MAR-Finder program suggested that ARSs also contain MAR motifs. These include AT tracts, ORI patterns, kinked DNA, ATC tracts, and Topoisomerase II consensus sequences. The in vitro matrix binding assay confirmed that all of the cloned ARSs could associate with the nuclear matrix. This indicates that ARSs elements may be located in or near the MARs. This is the first study that has identified and characterized ARSs in fish.     

Identification of a centromeric activity in the autonomously replicating TRA region allows improvement of the host-vector system for Candida maltosa

A centromeric activity was identified in the previously isolated 3.8 kb DNA fragment that carries an autonomously replicating sequence (ARS) from the yeast Candida maltosa. Plasmids bearing duplicated copies of the centromeric DNA (dicentric plasmids) were physically unstable and structural rearrangements of the dicentric plasmids occurred frequently in the transformed cells. The centromeric DNA activity was dissociated from the ARS, which is 0.2 kb in size, and was delimited to a fragment at least 325 by in length. The centromeric DNA region included the consensus sequences of CDEI (centromeric DNA element I) and an AT-rich CDEII-like region of Saccharomyces cerevisiae but had no homology to the functionally critical CDEIII consensus. A plasmid bearing the whole 3.8 kb fragment was present in 1–2 copies per cell and was maintained stably even under non-selective culture conditions, while a plasmid having only the 0.2 kb ARS was unstable and accumulated to high copy numbers. The high-copy-number plasmid allowed us to overexpress a gene to a high level, which had never been attained before, under the control of both constitutive and inducible promoters in C. maltosa.     

Transformation of the methylotrophic yeast Hansenula polymorpha by autonomous replication and integration vectors

Summary A high frequency transformation system for the methylotrophic yeast Hansenula polymorpha has been developed. This system depends on complementation of isolated uracil auxotrophs by the URA3 gene of Saccharomyces cerevisiae. Maintenance of the uracil prototrophy is based on integration of plasmid YIp5 at random sites within the H. polymorpha genome and on autonomously replicating plasmids containing ARS1 of S. cerevisiae or related sequences cloned from the host DNA. The sequence of one autonomously replicating sequence (HARS1) from H. polymorpha has been determined showing an AT-rich region of 9 bp with some similarity to the consensus sequence of known eukaryotic replication origins. Mitotic loss of autonomously replicating sequences is high; selection for stable uracil prototrophs yields multiple tandem arrangement of the transformed DNA with no detectable loss of the phenotype on non-selective medium. These features offer the possibility for extensive gene expression in H. polymorpha.     

Yeast ARS function and nuclear matrix association coincide in a short sequence from the human HPRT locus

Summary A sequence that supports extrachromosomal replication of plasmids in yeast has been identified within the first intron of the human hypoxanthine-guanine phosphori bosyltransferase (HPRT) gene. This represents the first isolation of such an autonomously replicating sequence (ARS) from an exactly known position in the human genome. This ARS shares similarities of imparted yeast phenotype and DNA sequence with other heterologus ARSs. In addition, this sequence is found to be a matrix association region (MAR) on the basis of specific binding to nuclear matrices prepared from several mammalian cell types. It also exhibits anomalous electrophoretic behavior, characteristic of bent DNA, on polyacrylamide gels. The coincidence of these properties supports the possibility that this region may play a role in DNA replication within its normal chromosomal context.     

Characterization of a chloroplast DNA sequence from Chlorella ellipsoidea that promotes autonomous replication in yeast

Summary An EcoRI 2.7 kbp fragment from Chlorella ellipsoidea chloroplast DNA (cpDNA) cloned in YIp5 was shown to promote autonomous replication in Saccharomyces cerevisiae. The fragment was localized in the small single copy region close to the inverted repeat. The ARS activity (autonomously replicating sequences in yeast) was found to be confined within a subclone of a ca. 300 bp HindIII fragment. Sequence analysis of this fragment revealed its high AT content and the presence of several direct and inverted repeats and a few elements that were related to the yeast ARS consensus sequence. Electron microscopic studies revealed that this sequence did not coincide with the primary replication origin of chloroplast DNA. The functioning of this sequence as a possible origin of plasmid replication in vivo is discussed. This is the first report on Chlorella cpDNA sequence. re]19850821 rv]19851211 ac]19851216     

Centromeric DNA from Saccharomyces uvarum is functional in Saccharomyces cerevisiae

Previous comparisons of centromeric DNA sequences in laboratory strains of Saccharomyces cerevisiae have revealed conserved sequences within 120 base pairs (bp) which appear to be essential for centromere function. We wanted to find out whether centromeric DNA in Saccharomyces strains with different degrees of DNA sequence divergence carry the same conserved sequences or not. Bam HI DNA fragments from two S. cerevisiae strains and one Saccharomyces uvarum strain were cloned into a centromere selection vector and tested for centromere function in a S. cerevisiae laboratory strain. Fragments having centromere function were obtained at approximately equal frequencies from all three strains. Two of the S. uvarum centromeric DNAs and two of the S. cerevisiae centromeric DNAs were sequenced and shown to carry in a 120 bp region sequences essentially like those of centromeric DNA in S. cerevisiae laboratory strains. DNA hybridization to separated chromosomal DNAs revealed that the two newly determined S. cerevisiae centromeric DNA sequences belong to chromosomes V and XIII, respectively. On leave from: Department of Cell and Tumor Biology, Roswell Park Memorial Institute, Buffalo, NY 14263, USA; On leave from: The Biological Laboratories, University of Leiden, The Netherlands     

An autonomously replicating sequence from HeLa DNA shows a similar organization to the yeast ARS1 element

Summary A HeLa DNA fragment, which may function as an anchorage point to the nuclear matrix for human chromosomes 1 and 2, also functions as an autonomously replicating sequence (ARS) in the yeast Saccharomyces cerevisiae. In the present report we show that this DNA fragment contains both bent DNA and an A-T rich region which appear to be associated with the ARS function. More interestingly, DNA sequence analysis shows that the spatial distribution of these features is strikingly similar to that found in the yeast ARS1 element.     

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.     

In addition to the ARS core, the ARS box is necessary for autonomously replicating sequences

Summary Autonomously replicating sequences (ARSs) were cloned from nuclear and mitochondrial DNA of D. melanogaster using YIp5, which is composed of pBR322 and the yeast ura3 gene, as the cloning vector and YNN27, a Ura^- yeast strain as the recipient. The nucleotide sequences of six ARSs, two from nuclear bulk, two from the nuclear 1.688 satellite, and two from mitochondorial DNA, were determined. The relationship between the transformation frequency and the inclusion of the ARS core, 5 _T ^A TT-TAT _A ^G TTT _T ^A 3, of these fragments was analysed. All the ARSs contained an ARS core or a single base change of it. However, not all the fragments that contained a single base change of the ARS core were able to transform the recipient cells, suggesting that certain bases in the ARS core were not exchangeable. It is suggested by transformation experiments with subfragments that in addition to an ARS core, an ARS box which is located within 25 bp upstream of the ARS core and whose sequence is composed of 5TNT _G ^A AA 3, is necessary for autonomous replication.     

Isolation and nucleotide sequence of an autonomously replicating sequence (ARS) element functional in Candida albicans and Saccharomyces cerevisiae

Summary An 8.6-kb fragment was isolated from an EcoRI digest of Candida albicans ATCC 10261 genomic DNA which conferred the property of autonomous replication in Saccharomyces cervisiae on the otherwise non-replicative plasmid pMK155 (5.6 kb). The DNA responsible for the replicative function was subcloned as a 1.2-kb fragment onto a non-replicative plasmid (pRC3915) containing the C. albicans URA3 and LEU2 genes to form plasmid pRC3920. This plasmid was capable of autonomous replication in both S. cerevisiae and C. albicans and transformed S. cerevisiae AH22 (leu2 ^–) to Leu⁺ at a frequency of 2.15 × 10³ transformants per pg DNA, and transformed C. albicans SGY-243 (ura3) to Ura⁺ at a frequency of 1.91 × 10³ transformants per g DNA. Sequence analysis of the cloned DNA revealed the presence of two identical regions of eleven base pairs (5TTTTATGTTTT3) which agreed with the consensus of autonomously replicating sequence (ARS) cores functional in S. cerevisiae. In addition there were two 10/11 and numerous 9/11 matches to the core consensus. The two 11/11 matches to the consensus, CaARS1 and CaARS2, were located on opposite strands in a non-coding AT-rich region and were separated by 107 bp. Also present on the C. albicans DNA, 538 by from the ARS cores, was a gene for 5S rRNA which showed sequence homology with several other yeast 5S rRNA genes. A sub-fragment (494 bp) containing the 5S rRNA gene (but not the region containing the ARS cores) hybridized to genomic DNAs from a number of yeast species, including S. cerevisiae, C. tropicalis, C. pseudotropicalis, C. parapsilosis, C. kruseii, C. (Torulopsis) glabrata and Neurospora crassa. The 709-bp ARS element (but not the 5S rRNA gene) was necessary for high-frequency transformation and autonomous plasmid replication in both S. cerevisiae and C. albicans.EMBL/GenBank database accession number: X16634 (5S rRNA)     

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.     

Characterisation of an autonomously replicating sequence from the fission yeast Schizosaccharomyces pombe

Summary A DNA sequence has been isolated from Schizosaccharomyces pombe which promotes high frequency transformation of plasmids in the same organism. It is closely linked to the DNA ligase gene CDC17 and has therefore been named ARS17 although in structure it differs substantially from ARS elements in Saccharomyces cerevisiae. ARS17 spans some 1.8 kb of DNA and deletion of any part of this region affects activity. Moreover, there does not appear to be any short sequence which is, by itself, sufficient for high frequency transformation. ARS17 lies between and partly overlaps two divergently transcribed genes and it is extremely AT rich. It lacks the consensus sequence found in S. cerevisiae ARSs and it has no ARS activity in S. cerevisiae.     

Isolation and characterization of sequences from mouse chromosomal DNA with ARS function in yeasts.

Fragments of chromosomal DNA from a variety of eucaryotes can act as ARSs (autonomously replicating sequence) in yeasts. ARSs enable plasmids to be maintained in extrachromosomal form, presumably because they function as initiation sites for DNA replication. We isolated eight different sequences from mouse chromosomal DNA which function as ARSs in Saccharomyces cerevisiae (bakers' yeast). Although the replication efficiency of the different mouse ARSs in yeasts appears to vary widely, about one-half of them functions as well as the yeast chromosomal sequence ARS1. Moreover, five of the ARSs also promote self replication of plasmids in Schizosaccharomyces pombe (fission yeast). Each of the ARSs was cloned into plasmids suitable for transformation of mouse tissue culture cells. Plasmids were introduced into thymidine kinase (TK)-deficient mouse L cells by the calcium phosphate precipitation technique in the absence of carrier DNA. In some experiments, the ARS plasmid contained the herpes simplex virus type 1 TK gene; in other experiments (cotransformations), the TK gene was carried on a separate plasmid used in the same transformation. In contrast to their behavior in yeasts, none of the ARS plasmids displayed a significant increase in transformation frequency in mouse cells compared with control plasmids. Moreover, only 1 of over 100 cell lines contained the original plasmid in extrachromosomal form. The majority of cell lines produced by transformation with an ARS TK plasmid contained multiple copies of plasmid integrated into chromosomal DNA. In most cases, results with plasmids used in cotransformations were similar to those for plasmids carrying TK. However, cell lines produced by cotransformations with plasmids containing any one of three of the ARSs (m24, m25, or m26) often contained extrachromosomal DNAs.