Construction of an autonomously replicating plasmid in n-alkane-assimilating yeast, Candida tropicalis

A transformation system using the autonomously replicating plasmid in the n-alkane-assimilating and asporogenic diploid yeast, Candida tropicalis, was developed. For the cloning of a DNA fragment containing a potential autonomously replicating sequence (ARS) from the genomic DNA of C. tropicalis, the ura3 mutant obtained using ethylmethane sulfonate as the host and the URA3 gene amplified by PCR using the C. tropicalis genomic DNA as a selectable marker were prepared. Comparison of ARSs among yeasts revealed that the consensus sequence found in S. cerevisiae was also present in C. tropicalis. The autonomously replicating plasmid containing the putative ARS as the shuttle vector, capable of replicating in both E. coli and C. tropicalis, was first constructed. The transformation system using this plasmid, in addition to the integrative transformation system, will be applicable to genetic studies of C. tropicalis.     

Analysis of DNA sequences homologous with the ARS core consensus in Saccharomyces cerevisiae

We have previously identified an autonomously replicating segment (ARS) near the 3' end of the histone H4 gene at the copy-I H3-H4 locus. We have now searched for additional autonomously replicating segments and sequences homologous with the ARS core consensus sequence near the copy-II histone H4 gene and both of the histone H3 genes. No new ARS elements were identified by functional cloning assays. However, several matches to the ARS core consensus element were found within the DNA sequences of the copy-I and copy-II genes. An exact match to the ARS core consensus was identified in the region downstream from the copy-I histone H3 gene and a set of sequences with weak homology was also located within the copy-II region. However, restriction fragments including these sequences did not demonstrate ARS activity on a plasmid in transformed cells.     

DNA transformations of Candida tropicalis with replicating and integrative vectors.

The alkane-assimilating yeast Candida tropicalis was used as a host for DNA transformations. A stable ade2 mutant (Ha900) obtained by UV-mutagenesis was used as a recipient for different vectors carrying selectable markers. A first vector, pMK16, that was developed for the transformation of C. albicans and carries an ADE2 gene marker and a Candida autonomously replicating sequence (CARS) element promoting autonomous replication, was compatible for transforming Ha900. Two transformant types were observed: (i) pink transformants which easily lose pMK16 under non-selective growth conditions; (ii) white transformants, in which the same plasmid exhibited a higher mitotic stability. In both cases pMK16 could be rescued from these cells in Escherichia coli. A second vector, pADE2, containing the isolated C. tropicalis ADE2, gene, was used to transform Ha900. This vector integrated in the yeast genome at homologous sites of the ade2 locus. Different integration types were observed at one or both ade2 alleles in single or in tandem repeats.     

Molecular cloning and analysis of autonomous replicating sequence of Candida maltosa.

A Candida maltosa chromosomal DNA fragment which confers high frequency transformation of C. maltosa and autonomous replication of recombinant plasmids was cloned and sequenced. Analysis of the nucleotide sequence of the cloned DNA revealed a sequence homologous for C. maltosa autonomously replicating sequence (ARS) elements. Vector pRJ1 for C. maltosa was constructed, which contained a 1.3 kb ARS sequence, pICEM-19H and the ADE1 gene of C. maltosa. Southern blot analysis suggested that the copy number of pRJ1 in C. maltosa was approximately 20 per genome. The sequence analysis also revealed an open reading frame, encoding a polypeptide with high homology (70%) to the RS15 protein of Brugia pagangi. This open reading frame has an intron with canonical sites for correct splicing in Saccharomyces cerevisiae.     

Physical separation and functional interaction of Kluyveromyces lactis and Saccharomyces cerevisiae ARS elements derived from killer plasmid DNA

Two DNA fragments which have autonomously replicating sequence (ARS) activity in both Saccharomyces cerevisiae and Kluyveromyces lactis have been isolated from the K. lactis kl killer plasmid. One fragment (Kla1) is 700 base pairs (bp) in length and plasmids carrying it are mitotically unstable in both hosts. In K. lactis, this instability leads to colonies having a 'nibbled' phenotype when grown on selective media and appears to be the result of inefficient plasmid segregation. The other fragment (Kla2) is an artificial junction fragment of 1100 bp which was produced during the cloning procedure. Kla2 has been divided into two sub-fragments Kla2A and Kla2B which have, respectively, ARS activity in K. lactis and S. cerevisiae but not the other species. This indicates that these two closely related yeasts have different sequence requirements for ARS activity. Kla2B contains a perfect match to the S. cerevisiae ARS consensus but Kla2A does not. Both Kla2A and Kla1 share a 10 bp sequence as the sole region of homology between them. This sequence, 5'TCATAATATA3', is tentatively offered as defining the ARS consensus sequence for K. lactis.     

Construction and characterization of a series of vectors for Schizosaccharomyces pombe

A set of vectors was created to allow cloning and expression studies in Schizosaccharomyces pombe. These vectors had a uniform backbone with an efficient Sz. pombe ARS, ARS3002, but different selectable markers--his3+, leu1+, ade6+ and ura4+. The vectors functioned efficiently as autonomously replicating plasmids that could also be converted into integrating vectors. The ura4+-containing vector was used to construct a Sz. pombe genomic library.     

Isolation and sequence analysis of a K. lactis chromosomal DNA element able to autonomously replicate in S. cerevisiae and K. lactis

We have undertaken a search for autonomously replicating (ARSs) from Kluyveromyces lactis chromosomal DNA able to sustain plasmid replication in K. lactis and in Saccharomyces cerevisiae. The discovery of such sequences might be interesting for the comparison of ARSs from different sources and possibly useful for the construction of multivalent vectors. HindIII fragments from K. lactis chromosomal DNA were inserted in the YIp5 plasmid (lacking an origin of replication) and the resulting chimaeric plasmids were selected for the ability to transform S. cerevisiae. Four plasmids were identified and further analysed. Two contained the same 1.8 kb K. lactis fragment and transformed both K. lactis and S. cerevisiae with the same efficiency and stability, whereas the third transformed only S. cerevisiae and the fourth transformed K. lactis with a higher efficiency than S. cerevisiae. A detailed study was performed on the 1.8 kb fragment which exhibited ARS function in both yeasts. The fragment was subcloned using different restriction enzymes and Bal31 exonuclease. Subclones were tested for ARS function. ARS activities in the two yeasts were localized in the same 100 bp region. Sequencing demonstrated the presence in this region of the dodecanucleotide 5'ATTTATTGTTTT3' differing from the ARS core consensus of S. cerevisiae only by a T insertion. A similar nucleotide sequence is present in the putative replication origin of the 2 mu-like plasmid pKD1 which stably replicates in K. lactis. Homologies with ARSs from S. cerevisiae were also found in the regions flanking the above-mentioned dodecanucleotide.     

Development of a transformation system for the multinuclear yeast Dipodascus (Endomyces) magnusii

We have developed the first system for genetic transformation of the multinuclear yeast Dipodascus magnusii. The system is based on a dominant selectable marker and an autonomously replicating sequence. We have constructed a plasmid vector which contains a marker conferring resistance to zeocin and the segment of non-transcribed spacer of D. magnusii ribosomal DNA which supports the autonomous replication of plasmid DNA in yeast cells. Plasmid DNA has been transferred into D. magnusii cells by electroporation. The DNA sequence which is described in this article has been deposited in the EMBL data library under Accession Number Y14587. © 1998 John Wiley & Sons, Ltd.     

Mutations in ARS1 increase the rate of simple loss of plasmids in Saccharomyces cerevisiae

Autonomously replicating sequence (ARS) elements are DNA sequences that promote extrachromosomal maintenance of plasmids in yeast. Mutations generated in vitro in the ARS1 region were examined for their effect on plasmid maintenance in a yeast centromeric plasmid. Our data show that mutations in the regions surrounding the ARS1 consensus sequence cause increases in the frequency of simple loss (1:0) events without affecting the rate of nondisjunction (2:0). Removal of the consensus sequence itself causes a drastic increase in the rate of simple loss. Sequences sensitive to mutagenesis were identified in each flanking region and differ with respect to their location and importance to ARS function. These results suggest that the role ARS1 plays in plasmid maintenance deals with the replication and/or localization of the plasmid in yeast.     

Systematic mapping of autonomously replicating sequences on chromosome V of Saccharomyces cerevisiae using a novel strategy

We have developed a new procedure for easy and rapid identification of autonomously replicating sequences (ARSs) and have applied it to the analysis of chromosome V of Saccharomyces cerevisiae. The procedure makes use of the ordered λ phage clone bank of this chromosome that we have constructed, and includes transposition of a mini-transposon and selection of transposon-containing derivatives, isolation of their DNA and circularization at their cos-ends, transformation of yeast cells with the circularized DNA, and scoring transformation frequency. The transposon used was derived from Tn5supF, contained the yeast LEU2 gene, and was placed, together with the hyperactive transposase gene, on a mini-F plasmid for stable maintenance in Escherichia coli K-12. Sixteen regions of chromosome V showing ARS activity were identified, of which 12 were newly found in this work. Thus, the procedure will be useful for systematic genomic scale analysis of ARSs in yeast and related organisms in which ordered clone banks have been established. The average distance between adjacent ARS-containing regions was approximately 40 kb. Two-dimensional gel electrophoretic analysis of chromosome replication indicated that one of the newly identified ARSs was functional as an actual in situ replication origin, at least under the conditions employed.     

Efficient electropulse transformation of intact Candida maltosa cells by different homologous vector plasmids.

Conditions for efficient and quick transformation by electroporation were developed in Candida maltosa. To investigate the efficiency of transformation with integrative as well as with autonomously replicating plasmids, a series of vectors was constructed for homologous transformation of this species. Transformants were obtained with different plasmids as covalently closed circular molecules and as linearized DNA. The influence of recipient strain and plasmid type as well as of cell number and parameters of the supplied electrical pulse on the transformation efficiency have been investigated. A maximum of 7000 transformants per 100 ng of plasmid DNA was reached. The efficiency of transformation was compared with that of the LiCl method.     

Large circular and linear rDNA plasmids in Candida albicans

Although plasmids containing rRNA genes (rDNA) are commonly found in fungi, they have not been reported in Candida. We discovered that the yeast opportunistic pathogen Candida albicans contains two types of rDNA plasmids which differ in their structure and number of rDNA repeats. A large circular plasmid of unknown size consists of multiple rDNA repeats, each of which includes an associated autonomously replicating sequence (ARS). In contrast, a linear plasmid, which is represented by a series of molecules with a spread of sizes ranging from 50-150 kbp, carries a limited number of rDNA units and associated ARSs, as well as telomeres. The number of linear plasmids per cell is growth cycle-dependent, accumulating in abundance in actively growing cells. We suggest that the total copy number of rDNA is better controlled when a portion of copies are on a linear extrachromosomal plasmid, thus allowing a rapid shift in the number of corresponding genes and, as a result, better adaptation to the environment. This is the first report of a linear rDNA plasmid in yeast, as well as of the coexistence of circular and linear plasmids. In addition, this is a first report of naturally occurring plasmids in C. albicans.     

Novel episomal vectors and a highly efficient transformation procedure for the fission yeast Schizosaccharomyces japonicus

Schizosaccharomyces japonicus is a fission yeast for which new genetic tools have recently been developed. Here, we report novel plasmid vectors with high transformation efficiency and an electroporation method for Sz. japonicus. We isolated 44 replicating segments from 12 166 transformants of Sz. japonicus genomic fragments and found a chromosomal fragment, RS1, as a new replicating sequence that conferred high transformation activity to Sz. japonicus cells. This sequence was cloned into a pUC19 vector with ura4⁺ of Sz. pombe (pSJU11) or the kan gene on the kanMX6 module (pSJK11) as selection markers. These plasmids transformed Sz. japonicus cells in the early‐log phase by electroporation at a frequency of 123 cfu/µg for pSJK11 and 301 cfu/µg for pSJU11, which were higher than previously reported autonomously replicating sequences. Although a portion of plasmids remained in host cells by integration into the chromosome via RS1 segment, the plasmids could be recovered from transformants. The plasmid copy number was estimated to be 1.88 copies per cell by Southern blot analysis using a Sz. pombe ura4⁺ probe. The plasmid containing ade6⁺ suppressed the auxotrophic growth of the ade6‐domE mutant, indicating that the plasmid would be useful for suppressor screening and complementation assays in Sz. japonicus. Furthermore, pSJU11 transformed Sz. pombe cells with the same frequency as the pREP2 plasmid. This study is a report to demonstrate practical use of episomal plasmid vectors for genetic research in Sz. japonicus. RS1 has been submitted to the DDBJ/EMBL/GenBank database (Accession No. AB547343). Copyright © 2010 John Wiley & Sons, Ltd.     

Cloning and characterization of the Yarrowia lipolytica squalene synthase (SQS1) gene and functional complementation of the Saccharomyces cerevisiae erg9 mutation

The squalene synthase (SQS) gene encodes a key regulatory enzyme, farnesyl-diphosphate farnesyltransferase (EC 2.5.1.21), in sterol biosynthesis. The SQS1 gene was isolated from a subgenomic library of the industrially important yeast Yarrowia lipolytica, using PCR-generated probes. Probes were based on conserved regions of homologues from different organisms. The complete nucleotide sequence of the coding region and the corresponding amino acid sequence were determined. The sequences showed extensive homologies with squalene synthase genes and enzymes from a number of other organisms and extreme amino acid conservation within the binding and catalytic domains. Direct cloning of a 4.3 kb genomic Y. lipolytica fragment, also comprising its own promoter and terminator sequences, into autonomously replicating plasmid YEp352 and subsequent transformation of a Saccharomyces cerevisiae mutant strain with relevant erg9: ura3-1 markers, resulted in functional complementation of these deficiencies, although Northern blot analyses did not reveal a unique full-length messenger. The availability of the Y. lipolytica SQS1 gene (GenBank Accession No. AF092497) offers prospects for metabolic engineering of the isoprenoid and sterol biosynthetic pathways.     

Isolation and structural analysis of efficient autonomously replicating sequences (ARSs) of the yeast Candida utilis

The industrially important yeast Candida utilis is widely used in production of food and medical materials, but its host-vector system has not been well developed. We screened for compact and efficient ARSs to construct practically useful vectors. The C. utilis strain AHU3053 was found to be efficiently transformed by the conventional lithium acetate method and was used as the host. The C. utilis IAM4264 genomic library was constructed by inserting the partial Sau3AI digests in pRI51, which has a kanMX gene expressible in C. utilis. By examining 98 C. utilis G418-resistant transformants, five plasmids had the highest ARS activity. By trimming of the inserts, the 1490 and 552 bp fragments with transformation activity of over 10(3)/microg DNA were obtained from ARS3 and ARS4, respectively. Although several sequences identical to S. cerevisiae ARS consensus sequences (ACSs) were found in ARS3 and ARS4, our deletion analysis indicated that these were not essential for the activity. Because the minimal functional ARS fragment was also several-fold larger than that of S. cerevisiae, the C. utilis ARSs have some unique characteristics resembling the Sz. pombe ARSs. These ARSs were functional in other C. utilis strains tested and useful for constructing practical vectors.     

Creation of ARS activity in yeast through iteration of non-functional sequences

Replication origins in Saccharomyces cerevisiae have been identified through the cloning of autonomous replication sequence (ARS) elements that allow the extrachromosomal maintenance of plasmid molecules. ARS activity requires a close match to an 11 bp consensus sequence and A + T-rich flanking DNA. ARS elements with a wide range of capacities for promoting plasmid maintenance have been described. We determined the ARS activity of plasmids with inserts consisting of repetitions of a 64 bp 100% A + T sequence that has sequence similarities to known ARS elements. An insert with approximately four repeats did not yield transformants, but inserts with either eight or eleven repeats did. The cooperative production of ARS activity did not require a contiguous arrangement since a plasmid containing two inserts of four repeats each, separated by about 1 kb, was functional. Our results show that a change from non-function to function can be accomplished by the cumulative action of individually inactive sequences. We conclude that the probability of replication initiation is too low with only four repeats to allow plasmid maintenance, but the overall probability is increased by further sequence iteration to provide origin activity. We suggest that chromosomes may contain stretches with dispersed, weak origin elements, each undetected by the conventional ARS assay, that in sum provide origin function.     

Kluyveromyces marxianus small DNA fragments contain both autonomous replicative and centromeric elements that also function in Kluyveromyces lactis

Two fragments containing both an autonomous replicating sequence (ARS) and a centromere have been isolated and sequenced from the yeast Kluyveromyces marxianus. The ARS and centromeric core sequences are only 500 bp apart, but ARS activity could be separated from the centromeric sequences. Centromeric sequences are organized in a similar way to those of budding yeasts: two well-conserved elements: CDEI (5′ TCACGTG 3′) and CDEIII (5′ TNTTCCGAAAGTWAAA 3′), are separated by a 165 bp AT-rich (± 90%) CDEII element whose length is twice that of Saccharomyces cerevisiae CDEII but almost identical to that of K. lactis. The ARS-core consensus sequence (5′ TTTATTGTT 3′) is also similar to that of K. lactis. Both ARS and centromeric elements function in this strain, albeit inefficiently, but not in S. cerevisiae. A third ARS-containing fragment with a different organization has been isolated and sequenced. The nucleotide sequences of DNA fragments reported in this paper will appear in the EMB data library under the accession numbers: Z31562, Z31563, Z31564.     

Replication of minichromosomes in Saccharomyces cerevisiae is sensitive to histone gene copy number and strain ploidy

We have characterized a defect in the mitotic transmission of plasmid minichromosomes in yeast strains deleted for the more highly expressed pair of histone H3 and H4 genes. Several observations indicate that an impairment in DNA replication contributes to the decrease in minichromosome stability. First, the maintenance of ARS plasmids that lack centromeres was also defective. Second, the addition of multiple ARS elements suppressed the defect in plasmid maintenance. Third, a synergistic increase in plasmid loss rate was seen when a plasmid containing an inefficient mutated ARS was tested in a strain deleted for histone genes, implying an interaction between ARS activity and the histone gene deletion. These results support the existence of a histone-dependent step in the initiation of DNA replication. We find that the stability of native chromosomes is not affected in strains deleted for histone genes. We propose that reduced histone H3 and H4 protein decreases the efficiency of initiation at ARS elements on plasmids and chromosomes, but that the presence of multiple origins on chromosomes compensates for the reduced efficiency. We find that decreased minichromosome stability is suppressed by increases in strain ploidy. The greater stability due to ploidy increases is not due to a relative increase in the expression of histone genes. We discuss models for the effect of strain ploidy on minichromosome maintenance.     

A positive selection for plasmid loss in Saccharomyces cerevisiae using galactose-inducible growth inhibitory sequences

Counter-selections for the loss of introduced plasmid sequences are useful for gene manipulations in yeast. We have used GAL10 promoter-mediated overexpression of GIN sequences, which inhibit the growth of cells, to develop a novel counter-selection system. Yeast cells carrying a GIN sequence grow normally on glucose medium but are unable to grow on galactose medium, whereas derivatives that have lost the GIN sequence are able to grow in the presence of galactose. We constructed autonomously replicating, integrating, and disruption plasmids carrying GIN sequences and tested their use to select for loss of the plasmid. The results showed that the GIN sequences provide a selection for efficient loss of plasmids or integrated constructs from yeast during growth on galactose medium, indicating that this system can be used for plasmid shuffling, gene replacements and marker gene recycling. This counter-selection system has wide application, because any Gal+ strain and a wide variety of marker genes can be used. In addition, counter-selection systems using growth-inhibitory sequences should be applicable to other yeasts and possibly to other organisms.