The 2 μm D region plays a role in yeast plasmid maintenance

The yeast 2-μm plasmid Raf protein contributes to plasmid inheritance by stabilizing the Rep1 and Rep2 partitioning proteins

The yeast 2-μm plasmid is a remarkable genetic parasite, managing efficient maintenance at high-copy number with minimal impact on the host. Equal partitioning of the plasmid upon host cell division requires plasmid proteins Rep1 and Rep2 and the plasmid STB locus. The Rep proteins and the plasmid-encoded Raf protein also regulate plasmid gene transcription. In this study, protein interaction assays, sequence analyses and mutational approaches were used to identify domains and residues in Rep2 and Raf required for association with Rep1 and Rep2 and to delineate the Rep2 DNA-binding domain. Rep2 and Raf displayed similarities in interactions with Rep1 and Rep2, in having Rep1 promote their STB association in vivo, and in stabilizing Rep protein levels. Rep2 mutants impaired for self-association were competent for transcriptional repression while those deficient for Rep1 association were not. Surprisingly, Rep2 mutants impaired for either Rep1 interaction or self-association were able to maintain efficient plasmid inheritance provided Raf was present and competent for Rep protein interaction. Our findings provide insight into the Rep protein complexes required for partitioning and transcriptional repression, and suggest that in addition to its transcriptional function, Raf stabilization of Rep partitioning proteins contributes to the remarkable persistence of the 2-μm plasmid.

The 2-μm plasmid encoded protein Raf1 regulates both stability and copy number of the plasmid by blocking the formation of the Rep1-Rep2 repressor complex

The 2-μm plasmid of the budding yeast Saccharomyces cerevisiae achieves a high chromosome-like stability with the help of four plasmid-encoded (Rep1, Rep2, Raf1 and Flp) and several host-encoded proteins. Rep1 and Rep2 and the DNA locus STB form the partitioning system ensuring equal segregation of the plasmid. The Flp recombinase and its target sites FRTs form the amplification system which is responsible for the steady state plasmid copy number. In this work we show that the absence of Raf1 can affect both the plasmid stability and the steady sate copy number. We also show that the Rep proteins do bind to the promoter regions of the 2-μm encoded genes, as predicted by earlier models and Raf1 indeed blocks the formation of the Rep1–Rep2 repressor complex not by blocking the transcription of the REP1 and REP2 genes but by physically associating with the Rep proteins and negating their interactions. This explains the role of Raf1 in both the partitioning and the amplification systems as the Rep1–Rep2 complex is believed to modulate both these systems. Based on this study, we have provided, from a systems biology perspective, a model for the mechanism of the 2-μm plasmid maintenance.

The 2 micron plasmid: a selfish genetic element with an optimized survival strategy within Saccharomyces cerevisiae

Since its discovery in the early 70s, the 2 micron plasmid of Saccharomyces cerevisiae continues to intrigue researchers with its high protein-coding capacity and a selfish nature yet high stability, earning it the title of a 'miniaturized selfish genetic element'. It codes for four proteins (Rep1, Rep2, Raf1, and Flp) vital for its own survival and recruits several host factors (RSC2, Cohesin, Cse4, Kip1, Bik1, Bim1, and microtubules) for its faithful segregation during cell division. The plasmid maintains a high-copy number with the help of Flp-mediated recombination. The plasmids organize in the form of clusters that hitch-hike the host chromosomes presumably with the help of the plasmid-encoded Rep proteins and host factors such as microtubules, Kip1 motor, and microtubule-associated proteins Bik1 and Bim1. Although there is no known yeast cell phenotype associated with the 2 micron plasmid, excessive copies of the plasmid are lethal for the cells, warranting a tight control over the plasmid copy number. This control is achieved through a combination of feedback loops involving the 2 micron encoded proteins. Thus, faithful segregation and a concomitant tightly controlled plasmid copy number ensure an optimized benign parasitism of the 2 micron plasmid within budding yeast.

A circular plasmid from the yeast Torulaspora delbrueckii

A new member of the 2-micron family of plasmids, named pTD1, was found in the yeast Torulaspora delbrueckii, a widespread yeast associated with food. Nucleotide sequences revealed the presence of a pair of inverted repeats and three open reading frames, one of which is a homologue of the FLP recombinase gene of 2-micron plasmid. An ARS region was identified, by replication in Saccharomyces cerevisiae and T. delbrueckii, near one of the inverted repeats. By the use of pTD1 derivatives and auxotrophic mutant hosts an efficient host-vector system was established for T. delbrueckii. So far, the 2-micron family of plasmids is restricted to four closely related genera (Q6 group): Saccharomyces, Zygosaccharomyces, Kluyveromyces, and Torulaspora. After a survey of 2500 strains belonging to about 500 species (80 genera) of yeast, no circular plasmids were found in other genera.

The maintenance of self-replicating plasmids in Saccharomyces cerevisiae: mathematical modelling, computer simulations and experimental tests

A distributive model has been constructed to describe the maintenance of the native 2 microns and 2 micron-based plasmids in the yeast Saccharomyces cerevisiae. This model includes elements which represent the influence of selection, segregation, replication and amplification on plasmid stability. A computer program has been written in TURBO PASCAL to implement the model and a number of simulation experiments have been carried out. These simulations permitted the choice of a form of the model which is compatible with the available experimental evidence. The form chosen involves an amplification system in which the RAF gene product binds to the Rep1/Rep2 dimer to prevent the latter acting to repress the activity of the FLP gene. At the same time an upper limit (or 'ceiling') was imposed on the number of plasmid molecules able to replicate. Maternal bias was accommodated by 'tagging' a small proportion of molecules for inheritance by the mother nucleus and these tags being removed (or 'cleared') by the Rep1/Rep2 dimers. This final form of the model makes specific predictions about the stability of 2 microns and YEp plasmids in yeast populations and about the distribution of plasmid copy number between cells in such populations. The predictions on stability have been subjected to experimental test and results provide good support for the model.

Use of a cis-acting mutation to study the role of FLP-mediated recombination in the maintenance of native yeast 2 micrometer plasmids

The 2 micrometer plasmid encodes a mechanism that ensures the partitioning of the plasmid at cell division. Little is known about the detailed mechanism of this partitioning system; for example, is there equal or unequal distribution of the plasmid molecules at mitosis? The plasmid also encodes a site-specific recombination system that is thought to be involved in plasmid copy-number amplification, although to date there has been no direct evidence that the recombination process itself is important for maintenance. We have identified a natural 2 micrometer variant that has a cis-acting mutation in the FLP-mediated recombination system. We show that this plasmid is unable to amplify in vivo. Our results demonstrate that the average copy number per cell is not affected for the mutant but there is a large clonal variation. This is a direct demonstration that plasmid partitioning results in an unequal distribution of plasmids and that FLP-mediated amplification compensates for this and therefore has an important role in maintenance.

Enhanced stability of YEp plasmids in lager brewing yeasts is related to lager brewing yeast 2-microns DNA

YEp plasmid stability in the presence of either Saccharomyces cerevisiae laboratory strain 2-microns DNA, or lager brewing yeast 2-microns DNA in the same genetic background, was compared under non-selective culture conditions. It was found that YEp plasmids were more stably maintained in the presence of lager 2-microns DNA under these conditions. By construction of laboratory-lager 2-microns DNA hybrid plasmids, an 867 bp StuI fragment of lager 2-microns DNA was shown to be responsible for the enhanced stability of the YEp plasmid. Nucleotide substitutions at two sites were found by sequencing this region. It was also confirmed that increasing cell ploidy enhanced YEp stability under non-selective conditions.

kfrA gene of broad host range plasmid RK2 encodes a novel DNA-binding protein

The korABF operon of broad host range IncP plasmid RK2 encodes proteins that coordinate expression of many other operons and that aid plasmid stability by providing at least part of a partitioning apparatus. The kfrA gene lies downstream from this operon and its transcription is repressed by all except one of the proteins encoded by this operon (KorA, KorFI, KorFII and KorB). We report here that transcription from the kfrA promoter is autoregulated by the kfrA gene product. We have purified KfrA, which is an acidic polypeptide of 308 amino acid residues, and show that it is a site-specific DNA-binding protein whose operator overlaps the primary kfrA promoter. Deletion analysis suggests that this activity is critically dependent on the N-terminal section of KfrA, which appears to contain an alpha-helix-beta-turn-alpha-helix motif. Circular dichroism confirmed the structural prediction that KfrA is almost entirely alpha-helical. The position of predicted turns suggests that, while amino acid residues 1 to 80 may form a globular domain of four or five helices, residues 80 to 280 of KfrA may adopt an extended coiled-coil domain containing a heptad repeat segment, which is probably responsible for formation of the multimers detected by crosslinking. The possibility that this unusual structure serves a second function, for example in providing a bridge to host structures required for plasmid partitioning, is discussed.

A new system for amplifying 2 microns plasmid copy number in Saccharomyces cerevisiae

The yeast 2 microns plasmid is found in the nucleus of almost all Saccharomyces cerevisiae strains. Its replication is very similar to that of chromosomal DNA. Although the plasmid does not encode essential genes it is stably maintained in the yeast population and exhibits only a small, though detectable, loss rate. This stability is achieved by a plasmid-encoded copy-number control system which ensures constant plasmid levels. For the investigation of 2 microns replication, a yeast strain that is absolutely dependent on this plasmid was constructed. This was achieved by disruption of the chromosomal CDC9 gene, coding for DNA ligase and providing this essential gene on a 2 microns-derived plasmid. This plasmid is absolutely stable under all growth conditions tested. Using the temperature-sensitive mutant allele cdc9-1 we have developed an artificial control system which allows one to change the copy number of 2 microns-derived plasmids solely by changing the incubation temperature.

Sequence diversity of yeast 2 microns RAF gene and its co-evolution with STB and REP1

Despite the extensive study of yeast 2 microns plasmid, the exact function of plasmid-encoded RAF gene is not clear. Variants of 2 microns plasmids from industrial Saccharomyces cerevisiae yeasts were isolated and characterized. Sequencing of RAF alleles revealed about 8% nucleotide and 10% amino acid diversities between 2 microns variants of closely related strains, RAF sequence variations were correlated with STB-REP1 sequence diversity. We also used restriction fragment length polymorphism linkage to screen a large number of yeast strains from different fermentation industries. The results clearly show a tight linkage of STB-REP1-RAF variations. Thus, our observations suggest that plasmid-borne cis- and trans-acting elements co-evolved to form an optimal molecular parasite and that RAF may play a role in active plasmid partitioning.

The 2-micron plasmid as a nonselectable, stable, high copy number yeast vector

The endogenous 2-microns plasmid of Saccharomyces cerevisiae has been used extensively for the construction of yeast cloning and expression plasmids because it is a native yeast plasmid that is able to be maintained stably in cells at high copy number. Almost invariably, these plasmid constructs, containing some or all 2-microns sequences, exhibit copy number levels lower than 2-microns and are maintained stably only under selective conditions. We were interested in determining if there was a means by which 2-microns could be utilized for vector construction, without forfeiting either copy number or nonselective stability. We identified sites in the 2-microns plasmid that could be used for the insertion of genetic sequences without disrupting 2-microns coding elements and then assessed subsequent plasmid constructs for stability and copy number in vivo. We demonstrate the utility of a previously described 2-microns recombination chimera, pBH-2L, for the manipulation and transformation of 2-microns as a pure yeast plasmid vector. We show that the HpaI site near the STB element in the 2-microns plasmid can be utilized to clone yeast DNA of at least 3.9 kb with no loss of plasmid stability. Additionally, the copy number of these constructs is as high as levels reported for the endogenous 2-microns.

Plasmid functions involved in the stable propagation of the pKD1 circular plasmid in Kluyveromyces lactis

Plasmid factors involved in the stable propagation of pKD1-derived vectors in Kluyveromyces lactis transformants have been identified. Three genes (A, B and C) have been found to be present in pKD1: the interruption of the B and C genes led to high plasmid instability. Stability could be restored in trans when host cells contained pKD1 as the resident plasmid (pKD1+ strains). The A gene, which codes for a site-specific recombinase, did not affect plasmid partitioning. Vectors bearing only the pKD1 replication origin (or a chromosomal ARS), and no other pKD1 sequence, were very unstable both in the presence and absence of the resident plasmid in host cells. These vectors could be stabilized in pKD1+ strains, but not in pKD1 degree strains, by the insertion of a 200 bp-long pKD1 sequence. This sequence, called the cis-acting stability locus (CSL), together with the products of the B and C genes, ensured plasmid partitioning at cell division. Possible hairpin structures and direct repeats were regularly spaced within the CSL. This region, and the corresponding cis-acting stabilizing elements of other yeast plasmids, did not have sequence homology but shared some structural regularities.

Functional analysis of the 3'-terminal sequence of the maize controlling element (Ac) by internal replacement and deletion mutagenesis

Using deletion analysis of the Ac transposable element, we have shown that replacement of internal sequences from base pairs 181-3559 does not abolish transposition. We have done sequential deletion analysis of the 3'-end of the Ac element and found that deletion of the major transposase binding sites (AAACGG) abolishes transposition. But, surprisingly, we found a 3'-terminal deletion of the transposase binding sites which also contained a 71-bp internal sequence between base pairs 3559 and 3630 retained transposition ability. This 71-bp internal sequence did not have a transposase (ORFa) binding motif. These data suggest that two different domains may be involved in the minimal sequence necessary for transposition. Finally, we have identified functional prokaryotic promoter sequences and ARS sequences within the 5' and 3'-termini of Ac, but cannot ascribe any function to these sequences.

Copy number control and compatibility of nuclear plasmids in Dictyostelium discoideum

Copy number of the endogenous nuclear plasmids of Dictyostelium discoideum is a plasmid-specific trait. Copy number is stable over time, is constant relative to ploidy level, is independent of host cell genetic background, and is independent of the presence of a second unrelated plasmid in the same nucleus. Unrelated plasmids are compatible with one another within a single nucleus. Pairwise combinations of Ddp1, Ddp2, and Ddp5 were stably maintained over many generations in the absence of selection. In contrast, one of the D. discoideum plasmids (Ddp2) was incompatible with a recombinant plasmid derived from it (p7d2). In the absence of selection for retention of p7d2, transformants contain either one or the other but not both plasmids. The plasmids are stably maintained in host cells with differing genetic backgrounds, although plasmid-free colonies were detected at a frequency of about 1-2% in populations of some strains after 50 generations growth following a previous cloning.

A novel class of vector for yeast transformation

We have constructed a set of hybrid yeast Escherichia coli vectors which utilise the site specific recombination function of the Saccharomyces cerevisiae 2 microns plasmid to completely eliminate the bacterial moiety upon introduction into yeast. A number of these plasmids have been shown to exhibit high inheritable stability in both laboratory and industrial strains during non-selective growth. These plasmids are beneficial for the genetic modification of industrial yeast, particularly those used in the production of food and beverages, and are of benefit in the study of plasmid maintenance and heterologous gene expression.