Progressive alteration of telomeric sequences at one end of a yeast linear plasmid and its possible association with reduced plasmid stability.

After selection for migration into the nucleus, a cytoplasmic yeast linear plasmid bearing an inverted terminal repeat (ITRs) at each end replicates in Saccharomyces cerevisiae in a linear form, called pTLU, which carries host telomeric repeats (TG(1-3))(n) of about 300-350 bp added to the ITR ends. We previously showed that the nucleotide composition of the added telomeric sequences varied among individual pTLU isolates, while those on the two ends of any given pTLU were always identical. The telomeric sequences of pTLU remained unchanged over numbers of cell generations when cells were selected for expression of the plasmid-borne nuclear marker. We report here that progressive alterations in telomeric sequences can be detected in cells which are grown under non-selective conditions. Surprisingly, in any given molecule, the telomeric alterations occur exclusively on one side, either the left or the right end, while the sequence at the opposite end remained identical to the original, suggesting a difference in the mode of DNA replication between the plasmid ends. These alterations occur over a broad area extending from the termini of telomeres to nucleotides near the junction between the telomeric sequences and the pTLU-ITR, implying that the plasmid ends undergo successive rounds of extension and contraction. Clonal analysis under non-selective conditions indicated that the alterations in telomeric sequences are generally associated with extreme instability of the pTLU plasmid.

Use of lycorine and DAPI staining in Saccharomyces cerevisiae to differentiate between rho0 and rho- cells in a cce1/delta cce1 nuclear background.

In the yeast Saccharomyces cerevisiae, mutants are viable with large deletions (rho-), or even complete loss of the mitochondrial genome (rho0). One class of rho- mutants, which is called hypersuppressive, is characterised by a high transmission of the mutated mitochondrial genome to the diploid progeny when mated to a wild-type (rho+) haploid. The nuclear gene CCE1 encodes a cruciform cutting endonuclease, which is located in the mitochondrion and is responsible for the highly biased transmission of the hypersuppressive rho- genome. CCE1 is a Holliday junction specific endonuclease that resolves recombination intermediates in mitochondrial DNA. The cleavage activity shows a strong preference for cutting after a 5'-CT dinucleotide. In the absence of the CCE1 gene product, the mitochondrial genomes remain interconnected and have difficulty segregating to the daughter cells. As a consequence, there is an increase in the fraction of daughter cells that are rho0. In this paper we demonstrate the usefulness of lycorine, together with staining by 4',6-diamidino-2-phenylindole (DAPI), to assay for the mitotic stability of a variety of mitochondrial genomes. We have found that rho+ and rho- strains that contain CT sequences produce a large fraction of rho0 progeny in the absence of CCE1 activity. Only those rho- mitochondrial genomes lacking the CT recognition sequence are unaffected by the cce1 allele.

Analysis of deletion mutations of the rpsL gene in the yeast Saccharomyces cerevisiae detected after long-term flight on the Russian space station Mir.

Using the yeast Saccharomyces cerevisiae on board the Russian space station Mir, we studied the effects of long-term space flight on mutation of the bacterial ribosomal protein L gene (rpsL) cloned in a yeast-Escherichia coli shuttle vector. The mutation frequencies of the cloned rpsL gene on the Mir and the ground (control) yeast samples were estimated by transformation of E. coli with the plasmid DNAs recovered from yeast and by assessment of the conversion of the rpsL wild-type phenotype (Sm(S)) to its mutant phenotype (Sm(R)). After a 40-day space flight, some part of space samples gave mutation frequencies two to three times higher than those of the ground samples. Nucleotide sequence analysis showed no apparent difference in point mutation rates between the space and the ground mutant samples. However, the greater part of the Mir mutant samples were found to have a total or large deletion in the rpsL sequence, suggesting that space radiation containing high-linear energy transfer (LET) might have caused deletion-type mutations.

Relocation of a cytoplasmic yeast linear plasmid to the nucleus is associated with circularization via nonhomologous recombination involving inverted terminal repeats.

The linear plasmid pCLU1 from the yeast Kluyveromyces lactis normally replicates in the cytoplasm, with the aid of the helper linear plasmid pGKL2, using terminal protein (TP) as a primer. However, it relocates to the nucleus when selection is applied for the expression of a plasmid-borne nuclear marker. Migration to the nucleus occurred in K. lactis at a frequency of about 10(-3)/cell ten or more times higher than the rate observed in Saccharomyces cerevisiae. The nuclear plasmids existed only in a circularized form in K. lactis, while in S. cerevisiae a telomere-associated linear form is also found. Sequence analysis showed that circularization in K. lactis was caused by non-homologous recombination between the inverted terminal repeat (ITR) at the ends of the linear form and non-specific internal target sites in pCLU1. No sequence similarity existed among the junction sites, indicating that the free ITR end plays a crucial role in circularization. In S. cerevisiae, circular plasmids were generated not only by nonhomologous recombination, but also by homologous recombination between short direct repeats within pCLU1. Circularization via the ITR end was observed independently of RAD52 activity. Sequences highly homologous to ARS core elements, 5'-ATTTATTGTTTT-3' for K. lactis and 5'-(A/T)TTTAT(T/G)TTT(A/T)-3' for S. cerevisiae, were detected at multiple sites in the nuclear forms of the plasmids.

Telomere sequences attached to nuclearly migrated yeast linear plasmid.

The yeast linear plasmid pCLU1, derived from pGKL1, has terminal proteins (TPs) covalently attached at the 5' ends of inverted terminal repeats (ITRs) and replicates in the cytoplasm, presumably using the TP as a primer for DNA synthesis. In Saccharomyces cerevisiae, under certain conditions, pCLU1 migrated into the nucleus and replicated in either linear or circular form. The linear-form plasmid lacked TPs; instead it carried host-telomere repeats at the ITR ends. The present study showed that (1) the added telomere was primarily composed of the repeated tracts of TGTGTGGGTGTGG, which was complementary to the RNA template of yeast telomerase, (2) the telomeric addition occurred at the very end of the ITRs, and (3) the sequence composition of the added telomeres was diverse among individual plasmids, but symmetrically identical at both ends of each plasmid. A similar mode of telomere addition was also observed in cells defective in the RAD52 gene.

Kluyveromyces lactis killer plasmid pGKL2: evidence for a viral-like capping enzyme encoded by ORF3.

ORF3 of the cytoplasmic linear plasmid pGKL2 was disrupted in vivo by integration of a selectable marker. Long-term cultivation of transformants carrying hybrid plasmids with a disrupted ORF3 under selective pressure did not deprive strains of the native counterpart, thereby proving its essentiality for pGKL2 replication and maintenance. The predicted ORF3 polypeptide was found to contain conserved motifs acquainted with mRNA-capping enzymes in the required order, just as in cytoplasmic viruses; new conserved motifs were also identified.

The linear plasmid pDHL1 from Debaryomyces hansenii encodes a protein highly homologous to the pGKL1-plasmid DNA polymerase.

Both the linear plasmids, pDHL1 (8.4 kb) and pDHL2 (9.2 kb), of Debaryomyces hansenii TK require the presence of a third linear plasmid pDHL3 (15.0 kb) in the same host cell for their replication. A 3.5 kb Bam HI-PstI fragment of pDHL1 strongly hybridized by Southern analysis to the 3.5 kb NcoI-AccI fragment of pDHL2, suggesting the importance of this conserved region in the replication of the two smaller pDHL plasmids. The 4.2 kb pDHL1 fragment containing the above hybridized region was cloned and sequenced. The results showed that the cloned pDHL1 fragment encodes a protein of 1000 amino acid residues, having a strong similarity to the DNA polymerase coded for by ORF1 of the killer plasmid pGKL1 from Kluyveromyces lactis. The catalytic and proof-reading exonuclease domains as well as terminal protein motif were well conserved as in DNA polymerases of pGKL1 and other yeast linear plasmids. Analysis of the cloned fragment further showed that pDHL1 encodes a protein partly similar to the alpha subunit of the K. lactis killer toxin, although killer activity was not known in the DHL system. Analysis of the 5' non-coding region of the two above pDHL1-ORFs reveal the presence of the upstream conserved sequence similar to that found upstream of pGKL1-ORFs. The possible hairpin loop structure was also found just in front of the ATG start codon of the pDHL1-ORFs like pGKL1-ORFs. Thus the cytoplasmic pDHL plasmids were suggested to possess a gene expression system comparable to that of K. lactis plasmids.

Extranuclear expression of the bacterial xylose isomerase (xylA) and the UDP-glucose dehydrogenase (hasB) genes in yeast with Kluyveromyces lactis linear killer plasmids as vectors.

On the basis of the linear killer plasmid pGKL1 from Kluyveromyces lactis, two new linear hybrid plasmids were constructed. One of these, pRSC126, carried the xylA gene from Streptomyces rubiginosus encoding the xylose isomerase. The other linear hybrid molecule, pRSC128, carried the hasB gene of Streptococcus pyogenes encoding the UDP glucose dehydrogenase. Construction was performed in a way that the putative cytoplasmic promoter element of ORF5 of pGKL2 was fused to the coding region of the heterologous genes. After transformation, in vivo recombination led to the establishment of linear hybrid vectors. Though efficiency of expression was low when compared with bacterial systems, cytoplasmic expression of both genes was clearly demonstrated.

A YAC contig of the human CC chemokine genes clustered on chromosome 17q11.2.

CC chemokines are cytokines that attract and activate leukocytes. The human genes for the CC chemokines are clustered on chromosome 17. To elucidate the genomic organization of the CC chemokine genes, we constructed a YAC contig comprising 34 clones. The contig was shown to contain all 10 CC chemokine genes reported so far, except for one gene whose nucleotide sequence is not available. The contig also contains 4 CC chemokine-like genes, which were deposited in GenBank as ESTs and are here referred to as NCC-1, NCC-2, NCC-3, and NCC-4. Within the contig, the CC chemokine genes were localized in two regions. In addition, the CC chemokine genes were more precisely mapped on chromosome 17q11.2 using a somatic cell hybrid cell DNA panel containing various portions of human chromosome 17. Interestingly, a reciprocal translocation t(Y;17) breakpoint, contained in the hybrid cell line Y1741, lay between the two chromosome 17 chemokine gene regions covered by our YAC contig. From these results, the order and the orientation of CC chemokine genes on chromosome 17 were determined as follows: centromere-neurofibromatosis 1-(MCP-3, MCP-1, NCC-1, I-309)-Y1741 breakpoint-RANTES-(LD78gamma, AT744.2, LD78beta)-(NCC-3, NCC-2, AT744.1, LD78alpha)-NCC-4-retinoic acid receptor alpha- telomere.

The terminal protein of the linear DNA plasmid pGKL2 shares an N-terminal domain of the plasmid-encoded DNA polymerase.

The 36K protein attached at the 5' end of the linear DNA plasmid pGKL2 from the yeast Kluyveromyces lactis was first purified and characterized. The terminal protein was purified from cells (1 kg wet weight) by ammonium sulphate precipitation and two rounds of centrifugation to equilibrium in CsCl gradients. The pGKL2 was present only in the post-microsomal supernatant. Approximately 10 mg of the purified pGKL2 was recovered and digested with DNase I. The terminal protein (final ca. 0 center dot 8 mg) was homogeneous by electrophoresis and we determined the N-terminal amino acid sequence up to ten residues, showing that it existed in the cryptic N-terminal domain of pGKL2-ORF2 (DNA polymerase) sequence.

Migration of the yeast linear DNA plasmid from the cytoplasm into the nucleus in Saccharomyces cerevisiae.

The Kluyveromyces linear plasmids, pGKL1 and pGKL2, carrying terminal protein (TP), are located in the cytoplasm and have a unique gene expression system with the plasmid-specific promoter element termed UCS, which functions only in the cytoplasm. In this study we have developed an in vivo assay system in Saccharomyces cerevisiae which enables the detection of a rare migration of the yeast cytoplasmic plasmid to the nucleus, using a pGKL1-derived cytoplasmic linear plasmid pCLU1. pCLU1 had both the UCS-fused LEU2 gene (a cytoplasmic marker) and the native URA3 gene (a nuclear marker) and therefore its cytoplasmic-nucleo localized could be determined by the phenotypic analysis of the marker. The nuclearly migrated plasmids were often detected as linear plasmids having the telomere sequence of the host yeast at both ends, although circular plasmids were also found. The circular form was produced by the the terminal fusion of pCLU1. Insertion of a Ty element into a nuclearly migrated plasmid was observed, allowing the ROAM-regulated expression of the adjacent nuclearly silent UCS-fused LEU2 gene. The nuclearly located plasmids, whether linear or circular, were less sensitive to UV-mediated curing than pGKL and pCLU1.

ATP1 and ATP2, the F1F0-ATPase alpha and beta subunit genes of Saccharomyces cerevisiae, are respectively located on chromosomes II and X.

Southern blot analysis showed that ATP1 and ATP2 map on chromosomes II and X, respectively. Physical mapping of ATP1 and ATP2 by chromosome fragmentation showed that ATP1 is at the left end of chromosome II and ATP2 is at the right end of chromosome X. Both are located close to telomere sequences of each chromosome; ATP1 and ATP2 being approximately 30 kb and 85 kb from the respective telomeres.

UV hypersensitivity of yeast linear plasmids.

The Kluyveromyces linear plasmids pGKL1 and pGKL2, encoding killer activity, were efficiently cured by UV irradiation. This event was investigated in more detail by the use of the terminal protein (TP)-associated cytoplasmic linear plasmids, pJKL1 and pRKL2, with a selectable marker LEU2. This observation was compared with the UV effect on the nuclear plasmids pLS1 (telomere-associated linear form) and YCp121 (centromere-integrated circular form), indicating that the UV hypersensitivity was specific to the cytoplasmic plasmids. Using rad4 and wild-type strains of S. cerevisiae, both pJKL1 and the nuclear plasmids were found to respond not only to photoreactivation repair but also to excision repair of UV-induced DNA damage. Thus these DNA repair systems were functional for both the nuclear and cytoplasmic plasmids in yeast, and it was suggested that the UV hypersensitivity of cytoplasmic plasmids might have been caused by a defect in other repair systems or in the TP-primed replication. Possibly TP-associated Debaryomyces linear plasmids were also UV hypersensitive.

Osmophilic linear plasmids from the salt-tolerant yeast Debaryomyces hansenii.

Three novel linear plasmids, pDHL1 (8.4 kb), pDHL2 (9.2 kb) and pDHL3 (15.0 kb), were discovered in the halophilic (salt-tolerant) yeast Debaryomyces hansenii. Exonuclease treatment indicated that all three plasmids were blocked at their 5' ends, presumably, by analogy with most other eukaryotic linear plasmids which involved protein attachment. The Debaryomyces plasmids were entirely cured simply by growing cells in normal culture medium, but were stably maintained in culture medium containing salts, sorbitol or glycerol at suitable concentrations. This suggested that the pDHL plasmids required an osmotic pressure for stable replication and maintenance. The Debaryomyces yeast secreted a killer toxin against various yeasts species. Toxin activity was demonstrated only in the presence of salts such as NaCl or KCl, but this killer phenotype was not associated with the pDHL plasmids. Analysis of the plasmid-curing pattern suggested that pDHL3 may play a key role in the replication of the Debaryomyces plasmids. Southern hybridization showed that an extensive homology exists between specific regions of pDHL1 and pDHL2, whereas pDHL3 is unique.

Kluyveromyces lactis killer system: ORF1 of pGKL2 has no function in immunity expression and is dispensable for killer plasmid replication and maintenance.

To functionally characterize the genes encoded by the larger killer plasmid pGKL2 from Kluyveromyces lactis a previously developed in-vivo recombination system was exploited. An in-vitro modified version of the cytoplasmically expressible LEU2 gene cartridge (LEU2*) flanked by appropriate pGKL2 segments was used to replace the central part of the ORF1 region of pGKL2. Transformation of a Leu- killer strain resulted in the expected disruption of ORF1 in the resident pGKL2. The Leu+ transformants obtained can be assigned to three classes. Class I carries both killer plasmids, pGKL1/2, and the recombinant pGKL2 derivative termed pRKL2. Class II and III additionally harbor palindrome and hairpin-like plasmids, respectively. Upon subculturing of class I transformants under selective pressure, segregation of the native pGKL2 and the recombinant pRKL2 eventually occurs resulting in total loss of pGKL2. No differences concerning killer and immunity phenotype between a pRKL2-harboring strain and the native pGKL2-carrying recipient could be detected. Thus pGKL2 ORF1 is dispensable for both expression of killer/immunity phenotypes and for the replication and maintenance of the K. lactis killer plasmids.

Heterologous gene expression on the linear DNA killer plasmid from Kluyveromyces lactis.

Linear hybrid plasmids based on the killer plasmid pGKL1 from Kluyveromyces lactis were obtained by in vivo recombination in Saccharomyces cerevisiae. Like pGKL1, the hybrids are located in the cytoplasm, have terminal inverted repeats (TIR) and possess covalently linked proteins at their 5' ends. The construction of cytoplasmic hybrid plasmids is based on the use of a pGKL1 promoter to control the marker gene used for recombination. Nuclear promoters are not recognised in the cytoplasm.

Mating type locus-dependent stability of the Kluyveromyces linear pGKL plasmids in Saccharomyces cerevisiae.

The linear killer plasmids, pGKL1 and pGKL2, from Kluyveromyces lactis stably replicated in mitochondrial DNA-deficient (rho 0) MATa or MAT alpha haploids of Saccharomyces cerevisiae, but were unstable and frequently lost in rho 0 MATa/MAT alpha diploids, suggesting that the replication of pGKL plasmids was under the control of the MAT locus. In MATa/MAT alpha cells of S. cerevisiae, the MAT alpha gene product (alpha 2) is combined with the MATa gene product (a1) and the resultant protein, a1-alpha 2, acts to repress the expression of haploid specific genes. Experiments showed that the K. lactis linear plasmids were stably maintained in rho 0 mata1/MAT alpha diploids, indicating that the a1-alpha 2 repressor interfered with the stability of pGKL2. It was revealed by computer analysis that the consensus sequence homologous to the a1-alpha 2 repressor binding site occurred within the coding regions of pGKL2 genes which were presumed to be essential for the plasmid replication. Since the plasmids were stably maintained in diploids of K. lactis, the mating type control must not be working there.

In vivo construction of linear vectors based on killer plasmids from Kluyveromyces lactis: selection of a nuclear gene results in attachment of telomeres.

Linear vectors based on plasmids pGKL1 and pGKL2 from Kluyveromyces lactis were obtained by in vivo recombination in Saccharomyces cerevisiae and selected for integration of the nuclear LEU2 gene. The linear hybrid molecules obtained had no proteins attached to their 5' ends, as is found for native pGKL plasmids. However, telomere-specific sequences were added to the ends of pGKL1. In contrast to the cytoplasmically localized pGKL plasmids, the newly obtained linear hybrid vectors probably replicate within the nucleus and provide evidence that the nuclear LEU2 gene cannot be expressed in the cytoplasm.