Sequence organization and expression of a yeast plasmid DNA

Yeast 2 microm plasmid copy number is elevated by a mutation in the nuclear gene UBC4

The copy number of the Saccharomyces cerevisiae endogenous 2 microm plasmid is under strict control to ensure efficient propagation to the daughter cell without significantly reducing the growth rate of the mother or the daughter cell. A recessive mutation has been identified that resulted in an elevated but stable 2 microm plasmid copy number, which could be complemented by a genomic DNA clone containing the UBC4 gene, encoding an E2 ubiquitin-conjugating enzyme. A ubc4::URA3 deletion resulted in the same elevated 2 microm plasmid copy number. An analysis of the endogenous 2 microm transcripts revealed that the steady-state abundance of REP1, REP2, FLP and RAF were all increased 4-5-fold in the mutant. Analysis of the mutant ubc4 allele identified a single base pair mutation within the UBC4 coding region, which would generate a glutamic acid to lysine amino acid substitution within a region of conserved tertiary structure located within the first alpha-helix of Ubc4p. These investigations represent the first molecular characterization of a mutation within a Saccharomyces cerevisiae nuclear gene shown to affect 2 microm steady-state plasmid copy number and implicate the ubiquitin-dependent proteolytic pathway in host control of 2 microm plasmid copy number.

Sensitivity to the Yeast Plasmid 2mu DNA is conferred by the nuclear allele nibl

Two strains of Saccharomyces carlsbergensis that lacked the plasmid 2mu DNA responded differently when the plasmid was introduced into them. In one strain, cells lacking 2mu DNA ("cir0") produced the normal "smooth" colony morphology, but cells bearing 2mu DNA ("cir+") produced heterogeneous "nibbled" colonies. In the second strain, both cir+ and cir0 strains exhibited a smooth colony morphology. Crosses between these strains revealed that a single recessive nuclear gene, called nibl, conferred the nibbled colony morphology in the presence of 2mu DNA. By a series of backcrosses, nibl was introduced into a Saccharomyces cerevisiae background. nibl caused a nibbled colony morphology in this background just as it did in S. carlsbergensis. nibl was mapped to the left arm of chromosome XVI. Twelve independent smooth revertants were isolated from two nibl [cir+] strains. Seven were analyzed, and all were found to be chromosome VII disomes. Chromosome VII disomy and suppression of the nibbled phenotype cosegregated in crosses. Thus, chromosome VII disomy can suppress the nibbled phenotype. The results of other experiments (C. Holm, Cell 29:585-594, 1982) indicate that the nibbled colony morphology is the result of lethal sectoring and that the lethality is caused by a high copy number of 2mu DNA. I suggest, therefore, that the product of the nibl gene may play a role in controlling the copy number of 2mu DNA. Possible models for the suppression of the nibbled phenotype by chromosome VII disomy are discussed.

2-micrometers DNA-like plasmids in the osmophilic haploid yeast Saccharomyces rouxii

DNA plasmids were detected in two independent strains of Saccharomyces rouxii among 100 yeast strains other than Saccharomyces cerevisiae tested. The plasmids, pSR1 and pSR2, had almost the same mass (approximately 4 X 10(6) daltons) as 2-micrometers DNA of S. cerevisiae. pSR1 and pSR2 gave identical restriction maps with restriction endonucleases BamHI, EcoRI, HincII, HindIII, and XhoI, and both lacked restriction sites for PstI, SalI, and SmaI. These maps, however, differed significantly from that of S. cerevisiae 2-micrometers DNA. Restriction analysis also revealed two isomeric forms of each plasmid and suggested the presence of a pair of inverted repeat sequences in the molecules where intramolecular recombination took place. DNA-DNA hybridization between the pSR1 and pSR2 DNAs indicated significant homology between their base sequences, whereas no homology was detected between pSR1 and pJDB219, a chimeric plasmid constructed from a whole molecule of 2-micrometers DNA, plasmid pMB9, and a 1.2-kilobase DNA fragment of S. cerevisiae bearing the LEU2 gene. A chimeric plasmid constructed with pSR1 and YIp1, the larger EcoRI-SalI fragment of pBR322 ligated with a 6.1-kilobase DNA fragment of S. cerevisiae bearing the HIS3 gene, could replicate autonomously in an S. cerevisiae host and produced isomers, presumably by intramolecular recombination at the inverted repeats.

Sensitivity to the Yeast Plasmid 2mu DNA is conferred by the nuclear allele nibl

Two strains of Saccharomyces carlsbergensis that lacked the plasmid 2mu DNA responded differently when the plasmid was introduced into them. In one strain, cells lacking 2mu DNA ("cir0") produced the normal "smooth" colony morphology, but cells bearing 2mu DNA ("cir+") produced heterogeneous "nibbled" colonies. In the second strain, both cir+ and cir0 strains exhibited a smooth colony morphology. Crosses between these strains revealed that a single recessive nuclear gene, called nibl, conferred the nibbled colony morphology in the presence of 2mu DNA. By a series of backcrosses, nibl was introduced into a Saccharomyces cerevisiae background. nibl caused a nibbled colony morphology in this background just as it did in S. carlsbergensis. nibl was mapped to the left arm of chromosome XVI. Twelve independent smooth revertants were isolated from two nibl [cir+] strains. Seven were analyzed, and all were found to be chromosome VII disomes. Chromosome VII disomy and suppression of the nibbled phenotype cosegregated in crosses. Thus, chromosome VII disomy can suppress the nibbled phenotype. The results of other experiments (C. Holm, Cell 29:585-594, 1982) indicate that the nibbled colony morphology is the result of lethal sectoring and that the lethality is caused by a high copy number of 2mu DNA. I suggest, therefore, that the product of the nibl gene may play a role in controlling the copy number of 2mu DNA. Possible models for the suppression of the nibbled phenotype by chromosome VII disomy are discussed.

Genetic properties of chromosomally integrated 2 mu plasmid DNA in yeast

We obtained strains of yeast with large segments of 2 mu plasmid DNA integrated at several chromosomal locations by selecting genetically for recombination between a chromosomal sequence carried on a 2 mu-circle-containing hybrid plasmid and a homologous sequence on the chromosome. In all diploids examined, the presence of 2 mu circle sequences causes a marked instability of the chromosome into which the 2 mu DNA is inserted. Although in some cases the loss of genetic markers is due to physical loss of the entire chromosome, in most cases the loss of markers appears to be due to a mitotic homozygotization of markers: the allelic information from the homologous chromosome replaces the information distal to the integrated 2 mu DNA. The instability caused by integrated 2 mu DNA sequences requires the activity of the specialized site-specific recombination system encoded by the 2 mu plasmid. We propose that the presence of integrated 2 mu DNA allows efficient integration of additional copies of the intact 2 mu plasmid by the action of the plasmid-coded special recombination system. Unequal sister-strand exchanges within the inverted repetition would result in the formation of dicentric chromosomes whose breakage during mitosis might begin a cycle analogous to the breakage-fusion-bridge cycle described many years ago in maize.

Intrachromosomal gene conversion in yeast

We have shown that the yeast Saccharomyces cerevisiae has a mechanism by which information from one gene can be transferred non-reciprocally to a repeated copy of the gene on the same chromosome. This intrachromosomal gene conversion may be important in maintaining sequence homogeneity within families of repeated eukaryotic genes.

Inverted repeated sequences in yeast nuclear DNA

The inverted repeated sequences (foldback DNA) of yeast nuclear DNA have been examined by electron microscopy and hydroxyapatite chromatography. Of the inverted repeat structures seen in the electron microscope, 34% were hairpins and 66% had a single stranded loop at the end of a duplex stem. The number average length of the repeat was 0.3 kb and the single stranded loop was 1.6 kb. It is estimated that there are approximately 250 inverted repeats per haploid genome. A statistical analysis of the frequency of molecules containing multiple inverted repeats showed that these sequences are non-randomly distributed. The distribution of inverted repeats was also examined by measuring the fraction of total DNA in the foldback fraction that bound to hydroxyapatite as a function of single strand fragment size. This analysis also indicated that the inverted repeats are clustered. Renaturation kinetic analysis of isolated foldback and inverted repeat stem sequence DNA showed that these sequences are enriched for repetitive DNA.

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

By examining both the transformation efficiency of yeast of various plasmids containing defined regions of the 2 mu circle genome and the characteristics of the resultant transformants, we have identified several regions of the 2 mu circle genome which are involved in 2 mu 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 2 mu circle genome or a fragment of 2 mu circle encompassing the origin of replication, we have determined that efficient use of the 2 mu 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 2 mu circle molecule to undergo intramolecular recombination in yeast, we have identified a 2 mu circle gene which codes for a product required for this process.

Nucleotide sequence of the yeast plasmid

The nucleotide sequence of the yeast DNA plasmid (2 mu circle) from Saccharomyces cerevisiae strain A364A D5 has been determined. The plasmid contains 6,318 base pairs, including two identical inverted repeats of 599 base pairs. Possible functions are suggested, and attributes of an improved vector for cloning foreign DNAs in yeast are discussed.

Saccharomyces cerevisiae plasmid, Scp or 2 mum: intracellular distribution, stability and nucleosomal-like packaging

Cell fractions from yeast strains known to harbor the plasmic 2 mum or Scp were treated with nucleases used to probe eukaryotic chromosome structure. Scp and subfragments were identified by hybridization to natural or cloned Scp probes according to Southern (34). Specificity was confirmed with non-Scp probes. Copy/haploid nuclear genome(n) was estimated from reconstructions at a resolution of 0.5/n. About 43-67% of the total cellular copy exists as nucleoprotein complexes which separate from other debris on isokinetic sucrose gradients with s-values of 67-110. These complexes are totally degraded by DNAase I. Digestion with micrococcal nuclease produced integral-sized fragments; they are not generated by direct mixing of pure Scp with nuclear chromatin from a[cir] strain. Initial digests gave a repeat of 168 +/- 3 base pairs (bp) for both Scp and nuclear nucleoprotein; advanced digests reduced the nuclear repeat relative to Scp by 8 bp. Of a potential 37 repeat units/plasmid, 31-32 were directly measured. A strain difference in Scp autodegradation was found. A partial nuclease resistant form was also demonstrated whose abundance was cell strain and growth stage dependent. Both Scp isomers exist in these complexes which are structurally similar to simian viral 40 minichromosomes.

A bacterial cell that synthesizes a protein containing the antigenic determinants of rat prolactin

Bacterial minicells containing three different recombinant plasmids with rat prolactin cDNA sequences inserted at the Pst I site of pBR322 via the poly(dG):poly(dC) joining technique were examined for the expression of rat prolactin antigenic determinants. The three prolactin coding sequences were in the same orientation as the coding sequence of the ampicillin-resistance gene of pBR322. The presence of each of the three recombinant plasmids induced some prolactin synthesis by the bacteria as measured by immunoprecipitation with anti-prolactin antisera. About 10% of the protein synthesized from one of the plasmids, prl 3, precipitated with the antisera. These prolactin antigenic determinants were part of a larger fused protein.

Hybridizable sequences between cytoplasmic ribosomal RNAs and 3 micron circular DNAs of Saccharomyces cerevisiae and Torulopsis glabrata

We have shown that 2.8 and 3.1 micron circular DNA molecules, previously reported to be present in Saccharomyces cerevisiae and Torulopsis glabrata respectively, contain sequences hybridizing to cytoplasmic ribosomal RNAs. In S. cerevisiae the 2.8 micron circular DNA appears to be identical to the rDNA repeating unit from nuclear DNA, both in length (approximately 9000 base pairs) and in the location of the 25, 18 and 5.8S rRNA sequences on the large HindIII fragment (6500 bp) and the presence of the 5S rRNA sequence on the small HindIII fragment. The 3.1 micron molecule from T. glabrata is approximately 2000 base pairs longer than the S. cerevisiae molecule and in addition, one of the HindIII sites lies within the region hybridizing to 25, 18 and 5.8S rRNAs. In S. cerevisiae the 4-5 copies of the 2.8 micron circular DNA molecules per cell, which have an extra-nuclear location, do not appear to be essential for cell viability as in one strain they were undetectable.

Isolation of a circular derivative of yeast chromosome III: implications for the mechanism of mating type interconversion

We describe genetic and physical characterization of rearrangements of chromosome III which result in changes of cell type in S. cerevisiae. Two types of rearrangements were obtained as rare events which caused a change at the locus controlling cell type, MAT, associated with a recessive lethal mutation, in one case from MATalpha to MATa-lethal, and in the other case from MATa to MATalpha-lethal. The MATa-lethal mutation is a deletion on the right arm of chromosome III, which we demonstrate extends to (or near) HMalpha. We suggest this deletion removes MATalpha and activates cryptic MATa information stored in HMalpha as proposed in the cassette model of mating type interconversion. The MATalpha-lethal mutation is the result of the formation of a circular chromosome III, which we interpret to remove MATa and activate the cryptic MATalpha information stored at HMa. Strains carrying the MATalpha-lethal chromosome contain a circular chromosome of length 62.6 plus or minus 5.7 mum, which is absent in related strains. This chromosome was confirmed to be chromosome III by hybridization of specific yeast DNA fragments to supercoiled DNA obtained from MATalpha-lethal strains. The isolation of a large circular derivative of chromosome III allows correlation of genetic and physical distance based on large distances-1 centimorgan corresponds to approximately 2700 base pairs.

Expression of the yeast galactokinase gene in Escherichia coli

In Saccharomyces cerevisiae the genes for three of the enzymes involved in galactose metabolism are tightly linked near the centromere of chromosome II (Douglas and Hawthorne, 1964). However, the molecular mechanisms which control the expression of these genes are not well understood. A DNA fragment containing at least one of these yeast genes, the galactokinase gene (gal1), has been joined to the bacterial plasmid pBR322 and maintained in an Escherichia coli strain that carries a deletion in its own galactokinase gene, galK. The presence of the yeast gene was demonstrated by (i) complementation of the E. coli galactokinase deletion, (ii) by hybridization of the cloned DNA fragment to restriction enzyme digests of total yeast DNA and (iii) by assaying for yeast galactokinase activity in bacterial cell extracts. The yeast DNA fragment is 4700 base pairs long, and enables the host E. coli K-12 strain to grow in minimal medium containing galactose as the sole carbon source with a generation time of 14.3 h. The yeast galactokinase activity in the bacterial extracts is 0.7% of the bacterial galactokinase activity found in wild-type E. coli fully induced with fucose.

2 micrometer covalently closed non-mitochondrial circular DNA in the petite-negative yeast Schizosaccharomyces pombe

A population of small covalently closed non-mitochondrial circular DNA molecules was isolated from the petite-negative yeast Schizosaccharomyces pombe. The mean length of these molecules, possessing the same density as nuclear DNA (1.695 g/cm3) is 1.95 +/- 0.18 micrometer. The presence of these minicircles in crude mitochondrial preparations indicates their tight association with mitochondrial particles. Their disappearance after DNase treatment of mitochondria demonstrates their extramitochondrial location.

Identification and mapping of the transcriptional and translational products of the yeast plasmid, 2mu circle

We have identified two major and approximately ten minor poly(A)-containing RNA species in S. cerevisiae which arise from in vivo transcription of the yeast plasmid, known as 2mu circle. The two major species, which are 1325 and 1275 bases in length, are transcribed from the two unique halves of the plasmid and extend into the inverted repeat sequences which separate the unique regions. The map positions of the minor transcripts, which range in length from 350 to 2600 bases, indicate that except for a small region of the genome in which no transcription is observed, both strands of the entire 2mu circle genome are transcribed. We also present evidence demonstrating that RNA transcribed from 2mu circular DNA is used to program the synthesis of specific proteins in yeast: that is, yeast RNA complementary to 2mu circle DNA can be translated in vitro to produce specific polypeptides of substantial size. Finally, the pattern of transcription of 2mu circle suggests the possibility that messenger RNA species are derived by cleavage of larger transcripts, and in addition, that the intramolecular recombination of 2mu circle which occurs in yeast functions as a genetic switch to allow separate expression of two sets of genes on the 2mu circle genome.

A cloned Drosophila DNA fragment which codes for a 4 S RNA species

A collection of random Drosophila melanogaster DNA fragments cloned individually in Escherichia coli was screened for the presence of sequences complementary to the 4 S, 5 S and 5.8 S RNA species produced in the D. melanogaster Kc tissue culture line. Four D. melanogaster DNA fragments were found which possessed sequences complementary to the 4 S RNA species but not complementary to the 5 S or 5.8 S RNA. One such cloned fragment (6.81 kilobase in length) was characterized further. It hybridizes in situ to region 22A-C of the left arm of chromosome 2 and does not contain repetitive sequences detectable by renaturation (cot) analysis. This same region was reported earlier by Steffensen and Wimber (Genetics (1971) 69, 163--178) to hybridize in situ to bulk tRNA extracted from D. melanogaster.

Regulation of gene expression by site-specific inversion

A site-specific inversion event is responsible for phase transition in Salmonella, as indicated by heteroduplex analysis of recombinant molecules carrying the gene coding for H2 flagellin in Salmonella. The inversion region corresponds to approximately 800 base pairs in length, and the inversion process does not appear to be dependent upon the E. coli RecA recombination pathway. Specific deletion derivatives of the cloned fragments no longer produce H2-specific flagella, effectively mapping the H2 gene within about 300 bp of the inversion region. Recombinant products of the hybrid molecules arose spontaneously, and they were used in the mapping of restriction sites within the inversion region. The restriction maps further demonstrate the extent and nature of the inversion.

Mapping of regions on cloned Saccharomyces cerevisiae 2-mum DNA coding for polypeptides synthesized in Escherichia coli minicells

Saccharomyces cerevisiae 2-mum DNA and some of its restriction fragments were integrated in vector pCR1 ,pBR313 or pBR322 and their expression in Escherichia coli P678-54 minicells was analyzed. 2mum DNA inserted at the EcoRI site of pCR1 or pBR313 and at the PstI site of pBR322 promoted the synthesis of polypeptides of 48,000, 37,000, 35,000 and 19,000 daltons. The DNA regions coding for these polypeptides were mapped on the 2-mum DNA molecule by insertion of single EcoRI or HindIII restriction fragments and comparison of the polypeptides produced. For the synthesis of the 37,000 dalton polypeptide, intact sites RIB and H3 were required. The disappearance of the 37,000 dalton polypeptide on interruption of one of these sites by insertion of the vector, was correlated with the appearance of a polypeptide of 22,000 or 23,500 daltons respectively. The DNA sequence coding for the 37,000 daltons polypeptide, therefore, has to be located in the S-loop region close to or overlapping with the site RIB and H3. Assuming that the 22,000 and the 23,500 dalton polypeptides are truncated forms of the 37,000 dalton polypeptide, the last polypeptide can be exactly mapped. The polypeptide of 48,000 daltons was mapped to that half of the L-loop segment containing the sites H1 and H2. If, however, HindIII fragment H1-H2 was expressed, the 48,000 dalton polypeptide was lost and concomitantly a 43,000 dalton polypeptide appeared. We assume that this polypeptide results from early termination of the polypeptide of 48,000 daltons. The 35,000 and 9,000 dalton polypeptides were mapped to the S-loop region. The integrated inverted repeat sequence of yeast 2-mum Dna did not induce any detectable insert-specific polypeptide synthesis.