The yeast plasmid 2μ circle encodes components required for its high copy propagation

The yeast plasmid 2μ and certain hybrid plasmids constructed from it are maintained stably and at high copy number in yeast cells. By examining various mutant hybrid 2μ plasmids, we show that these properties require the integrity of four plasmid loci. Two of these, designated REPI and REP2, are active in trans and correspond to two open coding regions of 2μ. The other two loci are active only in cis and correspond to the origin of replication and to a region, designated REP3, located several hundred bp away from the origin and consisting of direct repeats of a 62 bp sequence. We propose that the REP loci constitute a copy control system that overrides normal cellular restriction on plasmid replication and amplifies the plasmid when copy number is low.     

Replication and recombination functions associated with the yeast plasmid, 2μ circle

By examining both the transformation efficiency of yeast of various plasmids containing defined regions of the 2μ circle genome and the characteristics of the resultant transformants, we have identified several regions of the 2μ circle genome which are involved in 2μ circle replication or recombination. First, by identifying those DNA fragments from the molecule which promote high frequency transformation of yeast, we have localized the origin of replication to a sequence partially within the large unique region, which, as determined by subsequent deletion analysis, extends from the middle of the inverted repeat region into the contiguous unique region. Second, by examining the relative efficiency of replication in yeast of hybrid plasmids containing either the entire 2μ circle genome or a fragment of 2μ circle encompassing the origin of replication, we have determined that efficient use of the 2μ circle origin requires some function or functions encoded in the molecule at a site away from the origin. Third, by examining the ability of a mutant 2μ circle molecule to undergo intramolecular recombination in yeast, we have identified a 2μ circle gene which codes for a product required for this process.     

Clonal lethality caused by the yeast plasmid 2μ DNA

Strains of Saccharomyces that carry the nib allele of a nuclear gene exhibit a “nibbled” colony morphology if they also harbor the plasmid 2μ DNA. I have found that the expression of the nibbled phenotype is correlated with the presence of a subpopulation of abnormally large cells that give rise to mortal clones. Large cells apparently become large as a consequence of a defect in DNA replication or nuclear division. Large nib cells contain twice as much 2μ DNA per microgram of total DNA as small nib cells do, and elevated 2μ DNA copy number is the cause, not the effect, of increased cell size. It appears that the NIB allele can prevent an increase in 2μ DNA copy number, but cannot produce a decrease once the copy number has exceeded the normal level. I propose, therefore, that the NIB gene product normally represses the amplification of 2μ DNA copy number, and that the nib allele is partially defective in this function.     

The 2 micron plasmid purloins the yeast cohesin complex: a mechanism for coupling plasmid partitioning and chromosome segregation?

The yeast 2 micron plasmid achieves high fidelity segregation by coupling its partitioning pathway to that of the chromosomes. Mutations affecting distinct steps of chromosome segregation cause the plasmid to missegregate in tandem with the chromosomes. In the absence of the plasmid stability system, consisting of the Rep1 and Rep2 proteins and the STB DNA, plasmid and chromosome segregations are uncoupled. The Rep proteins, acting in concert, recruit the yeast cohesin complex to the STB locus. The periodicity of cohesin association and dissociation is nearly identical for the plasmid and the chromosomes. The timely disassembly of cohesin is a prerequisite for plasmid segregation. Cohesin-mediated pairing and unpairing likely provides a counting mechanism for evenly partitioning plasmids either in association with or independently of the chromosomes.     

Enhanced stability of a 2μ-based recombinant plasmid in diploid yeast

Summary The stability of a 2-based recombinant plasmid, pJDB219, has been compared in glucose-limited chemostat cultures of two haploid strains ofSaccharomyces cerevisiae and a diploid derived from them. The stability of the recombinant plasmid differed in the two haploid hosts but was greatest in the diploid. Enhanced stability in the diploid is probably a function of both the increased copy number and reduced selective burden of the plasmid.     

YIpDCE1 – an integrating plasmid for dual constitutive expression in yeast

YIpDCE1 (Dual Constitutive Expression), a novel Saccharomyces cerevisiae integrating plasmid, constitutively expresses two genes under the control of separate phosphoglycerate kinase promoters. YIpDCE1 contains the complete ADE2 gene which can be used as a marker for selecting integrants at mutant ade2 loci commonly present in laboratory yeast strains. The YIpDCE1 plasmid can be inserted into the ade2-101 locus of the HF7c strain used in two hybrid screens. Thus it could be useful for analysis of two hybrid interactions that occur in the context of additional protein components (e.g. modifying enzymes such as kinases or phosphatases, or multimeric complexes consisting of three or four distinct protein components). YIpDCE1 has been used to create strains simultaneously overexpressing the permease (ftr1) and oxidase (fet3) components of the yeast high-affinity iron uptake system. This confers constitutive high-affinity iron uptake on the transformed strains, bypassing the normal regulatory mechanisms.     

The yeast genus Saccharomycopsis Schiönning

In order to eliminate the confusion resulting from the homonymsSaccharomycopsis Schiönning andSaccharomycopsis Guilliermond and to eliminate the usage of the nameEndomycopsis which has been perpetuated contrary to the International Code of Botanical Nomenclature, the authors in this article outline the history of the speciesSaccharomycopsis capsularis Schiönning andSaccharomycopsis guttulata (Robin)Schiönning and give their reasons for proposing the nameCyniclomyces nom. nov. for the genus to which the second species is assigned, a step which permits the use of the generic nameSaccharomycopsis Schiönning to designate the genus currently cited asEndomycopsis.

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Zusammenfassung Um Unklarheiten, herrührend von den HomonymenSaccharomycopsis Schiönning undSaccharomycopsis Guilliermond, zu beseitigen und um den fortgesetzten Gebrauch der BezeichnungEndomycopsis, welche im Gegensatz zum Internationalen Code der botanischen Nomenklatur steht, auszuschliessen, haben die Autoren dieses Artikels die Geschichte der ArtenSaccharomycopsis capsularis Schiönning undSaccharomycopsis guttulata (Robin)Schiönning dargelegt und ihre Gründe dafür angegeben, den NamenCyniclomyces nom. nov. für die Gattung zu gebrauchen, zu dem die zweite Art zugeteilt wird.Dieser Schritt würde den Gebrauch des GattungsnamenSaccharomycopsis Schiönning für die Gattung, die gegenwärtig alsEndymycopsis zitiert wird, zulassen.

     

Why is the initiation nick site of an AT-rich rolling circle plasmid at the tip of a GC-rich cruciform?

pT181 and other closely related rolling circle plasmids have the nicking site for initiation of replication between the arms of a GC-rich inverted repeat sequence adjacent to the binding site for the dimeric initiator protein. Replication is initiated by the initiator-induced extrusion of this sequence as a cruciform, creating a single-stranded region for nicking by the protein. Nicking is followed by assembly of the replisome without relaxation of the secondary structure. Following termination, the initiator protein is released with a short oligonucleotide attached to one subunit, which prevents it from being recycled, a necessary feature of the plasmid's replication control system. The modified initiator can cleave single-stranded substrates and can nick and relax supercoiled plasmid DNA weakly. Although it can bind to its recognition sequence in the leading strand origin, the modified protein cannot induce cruciform extrusion, and it is proposed that this inability is the key to understanding the biological rationale for having the nicking site at the tip of a cruciform: the need to provide the functional initiator with a catalytic advantage over the modified one sufficient to offset the numerical advantage and metabolic stability of the latter.     

The uptake of inorganic sulphate by a brewer’s yeast

The uptake of³⁵S-labelled inorganic sulphate by a brewer’s yeast has been examined. Optimum uptake by cell suspensions required the presence in the medium of glucose, ammonium ions and citrate. The omission of phosphate produced little or no effect. Ammonium ions could be replaced almost completely byL-glutamine but not by a number of amino acids. After one hour approximately 60% of the sulphate-sulphur accumulated appeared in protein. This was comparable to the rate of entry of methionine-sulphur into yeast protein. Sulphate uptake was inhibited by azide, 2,4-dinitrophenol, iodoacetate and mercuric ions. Arsenate was inhibitory at high concentrations but stimulated uptake at low concentrations. Selenate inhibited uptake competitively and appeared to have an affinity for the sites of uptake comparable with that of sulphate. Uptake was also partly suppressed byL-methionine,L-ethionine,L-cysteine andDL-homocysteine.     

The human immunoglobulin κ locus on yeast artificial chromosomes (YACs)

The human immunoglobulin κ locus is a duplicated structure. Contigs of 600 kb with 40 Vκ genes and 440 kb with 36 Vκ genes had been established for the Cκ proximal (p) and distal (d) copies, respectively. In addition the human genome contains more than 24 dispersed Vκ genes, called orphons. In the present study, 22 κ-locus derived YACs were analyzed in detail, while 30 orphon-derived YACs were characterized only with respect to some parameters. The κ-locus derived YACs allowed three gaps to be closed which previously could not be bridged by cosmid and phage λ cloning. At the 5′ side, the p contig was extended in the YACs by 50 kb and the d contig by 16 kb. At the 3′side, the d contig was extended by 11.5 kb. Beyond the 3′ end of the d contig a new Vκ gene was found, which is located, according to pulsed field gel electrophoresis (PFGE) experiments, at a distance of at least 140 kb from the last Vκ gene of the contig. This Vκ gene, which was termed Z0, occurred on three YACs, albeit at distances smaller than 140 kb; this was probably due to deletions in the YACs caused by abundant repetitive sequences at the borders of the locus. According to its sequence and to the restriction map of its surroundings, Z0 is an orphon gene of the so-called Z family, of which several members are known to be dispersed throughout the genome. The possibility that Z0 has been the parent of the other Z orphons is discussed.     

The preparation and properties of yeast β-fructofuranosidase chemically attached to polystyrene

1. A process is described for the chemical attachment of an enzyme to the surface of a polystyrene matrix. 2. By this process yeast beta-fructofuranosidase was chemically attached to the surface of both polystyrene beads and polystyrene tubes. 3. The kinetics of sucrose hydrolysis by beta-fructofuranosidase and polystyrene-supported beta-fructofuranosidase were compared. 4. The pH-activity curve of the polystyrene-supported enzyme shows a marked difference from that of the free enzyme in solution. 5. The inhibitor dissociation constant with respect to tris is increased, whereas the inhibitor dissociation constant with respect to aniline is decreased when the enzyme is attached to polystyrene. 6. Differences between the properties of the bound and free enzyme are discussed in terms of a micro-environmental effect arising from the hydrophobic nature of the polystyrene support.     

Control of cell type in yeast by the mating type locus: The α1-α2 hypothesis

We have extended the genetic analysis of four mutants carrying defective MATα alleles in order to determine how the mating type locus controls yeast cell types: a, a, and $\text{a}\text{α}$. First, we have mapped the defect in the mutant VC73 to the mating type locus by diploid and tetraploid segregation analysis. Second, we have determined that the mutations in these strains define two complementation groups, MATα1 and MATα2. The MATα1 gene is proposed to be a positive regulator of α mating functions. The MATα2 gene product is proposed to have two roles, as a negative regulator of a-specific mating functions and as a regulator of $\text{a}\text{α}$ cell functions (required for sporulation, for inhibition of mating and other processes). This view of MATα leads to the prediction that matα1^?matα2^? mutants should have the mating ability of an a cell and that matα1^?matα2^?/MATα strains should mate as α and be unable to sporulate. Such double mutants have been constructed and behave as predicted. We therefore propose that a-specific mating functions in MATa cells are constitutively expressed due to the absence of the MATα2 gene product and that α-specific mating functions are not expressed due to the absence of the MATα1 gene product.     

The BRCT domain and the specific loop 1 of human Polμ are targets of Cdk2/cyclin A phosphorylation

Human family X polymerases contribute both to genomic stability and variability through their specialized functions in DNA repair. Polμ participates in the repair of spontaneous double strand breaks (DSB) by non homologous end-joining (NHEJ), and also in the V(D)J recombination process after programmed DSBs. Polμ plays this dual role due to its template-dependent and terminal transferase (template-independent) polymerization activities. In this study we evaluated if Polμ could be regulated by Cdk phosphorylation along the cell cycle. In vitro kinase assays showed that the S phase-associated Cdk2/cyclin A complex was able to phosphorylate Polμ. We identified Ser¹², Thr²¹ (located in the BRCT domain) and Ser³⁷² (located in loop1) as the target residues. Mutation of these residues to alanine indicated that Ser³⁷² is the main phosphorylation site. Mobilization of loop1, which mediates DNA end micro-synapsis, is crucial both for terminal transferase and NHEJ. Interestingly, the phospho-mimicking S372E mutation specifically impaired these activities. Our evidences suggest that Polμ could be regulated in vivo by phosphorylation of the BRCT domain (Ser¹²/Thr²¹) and of Ser³⁷², affecting the function of loop1. Consequently, Polμ’s most distinctive activities would be turned off at specific cell-cycle phases (S and G2), when these promiscuous functions might be harmful to the cell.