Plasmid stability in recombinant Saccharomyces cerevisiae

Because of many advantages, the yeast Saccharomyces cerevisiae is increasingly being employed for expression of recombinant proteins. Usually, hybrid plasmids (shuttle vectors) are employed as carriers to introduce the foreign DNA into the yeast host. Unfortunately, the transformed host often suffers from some kind of instability, tending to lose or alter the foreign plasmid. Construction of stable plasmids, and maintenance of stable expression during extended culture, are some of the major challenges facing commercial production of recombinant proteins. This review examines the factors that affect plasmid stability at the gene, cell, and engineering levels. Strategies for overcoming plasmid loss, and the models for predicting plasmid instability, are discussed. The focus is on S. cerevisiae, but where relevant, examples from the better studied Escherichia coli system are discussed. Compared to free suspension culture, immobilization of cells is particularly effective in improving plasmid retention, hence, immobilized systems are examined in some detail. Immobilized cell systems combine high cell concentrations with enhanced productivity of the recombinant product, thereby offering a potentially attractive production method, particularly when nonselective media are used. Understanding of the stabilizing mechanisms is a prerequisite to any substantial commercial exploitation and improvement of immobilized cell systems.     

CAN1-SUC2 gene fusion studies in Saccharomyces cerevisiae

Summary Various gene fusions between the arginine permease and invertase have been constructed in order to obtain information about whether part of the CAN1 gene product can induce secretion of biologically active invertase missing its own signal sequence. A construction containing 30 N-terminal amino acid residues of the CAN1 gene product fused to invertase was not secreted. When the CAN1 portion was elongated to 477 or 560 amino acid residues, secretion of the fusion proteins was observed. A fusion lacking 59 amino acids at the amino-terminal end of the arginine permease was also secreted. These results indicate that the amino-terminal end of the arginine permease is neither sufficient nor essential for membrane insertion; instead this enzyme should contain an internal targeting sequence facilitating secretion. Some general implications on the biosynthesis and topology of membrane proteins are also discussed as well as the homology with histidine permease.     

Crabtree-negative characteristics of recombinant xylose-utilizing Saccharomyces cerevisiae

For recombinant xylose-utilizing Saccharomyces cerevisiae, ethanol yield and productivity is substantially lower on xylose than on glucose. In contrast to glucose, xylose is a novel substrate for S. cerevisiae and it is not known how this substrate is recognized on a molecular level. Failure to activate appropriate genes during xylose-utilization has the potential to result in sub-optimal metabolism and decreased substrate uptake. Certain differences in fermentative performance between the two substrates have thus been ascribed to variations in regulatory response. In this study differences in substrate utilization of glucose and xylose was analyzed in the recombinant S. cerevisiae strain TMB3400. Continuous cultures were performed with glucose and xylose under carbon- and nitrogen-limited conditions. Whereas biomass yield and substrate uptake rate were similar during carbon-limited conditions, the metabolic profile was highly substrate dependent under nitrogen-limited conditions. While glycerol production occurred in both cases, ethanol production was only observed for glucose cultures. Addition of acetate and 2-deoxyglucose pulses to a xylose-limited culture was able to stimulate transient overflow metabolism and ethanol production. Application of glucose pulses enhanced xylose uptake rate under restricted co-substrate concentrations. Results are discussed in relation to regulation of sugar metabolism in Crabtree-positive and -negative yeast.     

Characterization of the cyrl-2 UGA mutation in Saccharomyces cerevisiae

Summary cyrl-2 is a temperature-sensitive mutation of the yeast adenylate cyclase structural gene, CYR1. The cyrl-2 mutation has been suggested to be a UGA mutation since a UGA suppressor SUP201 has been isolated as a suppressor of the cyrl-2 mutation. Construction of chimeric genes restricted the region containing the cyrl-2 mutation, and the cyrl-2 UGA mutation was identified at codon 1282, which lies upstream of the region coding for the catalytic domain of adenylate cyclase. Alterations in the region upstream of the cyrl-2 mutation site result in null mutations. The complete open reading frame of the cyrl-2 gene expressed under the control of the GAL1 promoter complemented cyrl-dl in a galactose-dependent manner. These results suggest that at the permissive temperature weak readthrough occurs at the cyrl-2 mutation site to produce low levels of active adenylate cyclase. An endogenous suppressor in yeast cells is assumed to be responsible for this readthrough.     

Effect of aspirin on mitochondrial mutagens in Saccharomyces cerevisiae

Summary The mitochondrial mutation petite was induced in yeast cells by ethidium bromide (EB), Adriamycin (ADR) and 4-nitroquinoline-N-oxide (NQO). In the presence of aspirin in concentrations ranging from 0.1 to 1.0 mg/ml, the mutagenicity of EB and ADR was reversed but petite induction by NQO was unaffected. At these concentrations, aspirin also reversed mitochondrial inhibition by oligomycin, a non-mutagenic inhibitor of the organellar ATPase complex.Cells grown in the presence of aspirin alone showed a significantly higher rate of oxygen uptake than untreated control cultures when the drug concentration ranged from 0.05 to 1.0 mg/ml. At concentrations of 2 mg/ml and above, aspirin inhibited mitochondrial respiration.     

A dominant interfering mutation in RAS1 of Saccharomyces cerevisiae

A mutant allele of RAS1 that dominantly interferes with the wild-type Ras function in the yeast Saccharomyces cerevisiae was discovered during screening of mutants that suppress an ira2 disruption mutation. A single amino acid substitution, serine for glycine at position 22, was found to cause the mutant phenotype. The inhibitory effect of the RAS1 ^Ser22 gene could be overcome either by overexpression of CDC25 or by the ira2 disruption mutation. These results suggest that the RAS1^Ser22 gene product interferes with the normal interaction of Ras with Cdc25 by forming a dead-end complex between Ras1^Ser22 and Cdc25 proteins.     

Early vegetative segregation of mitochondrial genes in Saccharomyces cerevisiae

The vegetative segregation of seven mitochondrial gene loci was studied in yeast. At various times after mating antibiotic resistant and sensitive strains, samples of the diploid progeny were examined to determine the segregation rates of the alleles at each locus in three- and four-factor crosses. The rate of segregation was approximately the same for the cap1, ery1, oli1, oli2, and par1 loci, which are scattered over about two-thirds of the mitochondrial DNA molecule. Differences in segregation rates were found but showed no consistent relationship to the map positions of the loci. This is in contrast to the segregation of chloroplast genes in Chlamydomonas, where loci segregate at rates proportional to their distance from an “attachment point” which appears to govern the partitioning of chloroplast DNA molecules between daughter chloroplasts when the chloroplast divides. Our data are compatible with a model in which the mitochondrial DNA molecules in a cell occur in a small number of groups corresponding to individual nucleoids or mitochondria. Most or all of the molecules in a group carry the same allele at any given locus. These genetically homogeneous groups of molecules may thus be the units of segregation, and may be partitioned randomly between mother cell and bud at each division.     

Identification of the mitochondrial receptor complex in Saccharomyces cerevisiae

Mitochondrial protein import involves the recognition of preproteins by receptors and their subsequent translocation across the outer membrane. In Neurospora crassa, the two import receptors, MOM19 and MOM72, were found in a complex with the general insertion protein, GIP (formed by MOM7, MOM8, MOM30 and MOM38) and MOM22. We isolated a complex out of S. cerevisiae mitochondria consisting of MOM38/ISP42, the receptor MOM72, and five new yeast proteins, the putative equivalents of N. crassa MOM7, MOM8, MOM19, MOM22 and MOM30. A receptor complex isolated out of yeast cells transformed with N. crassa MOM19 contained the N. crassa master receptor in addition to the yeast proteins. This demonstrates that the yeast complex is functional, and provides strong evidence that we also have identified the yeast MOM19.     

TFS1: A suppressor of cdc25 mutations in Saccharomyces cerevisiae

Summary The TFS1 gene of Saccharomyces cerevisiae is a dosage-dependent suppressor of cdc25 mutations. Overexpression of TFS1 does not alleviate defects of temperature-sensitive adenylyl cyclase (cdc35) or ras2 disruption mutations. The ability of TFS1 to suppress cdc25 is allele specific: the temperature-sensitive cdc25-1 mutation is suppressed efficiently but the cdc25-5 mutation and two disruption mutations are only partially suppressed. TFS1 maps to a previously undefined locus on chromosome XII between RDN1 and CDC42. The DNA sequence of TFS1 contains a single long open reading frame encoding a 219 amino acid polypeptide that is similar in sequence to two mammalian brain proteins. Insertion and deletion mutations in TFS1 are haploviable, indicating that TFS1 is not essential for growth.     

Reduced but accurate translation from a mutant AUA initiation codon in the mitochondrial COX2 mRNA of Saccharomyces cerevisiae

The gene encoding the XorII methyltransferase (M · XorII) was cloned from Xanthomonas oryzae pv. oryzae and characterized in Escherichia coli. The M · XorII activity was localized to a 3.1 kb BamHI-BstXI fragment, which contained two open reading frames (ORFs) of 1272 nucleotides (424 amino acids) and 408 nucleotides (136 amino acids). Ten polypeptide domains conserved in other M⁵ cytosine methyltransferases (MTases) were identified in the deduced amino acid sequence of the 1272 ORF. E. coli Mrr⁺ strains were transformed poorly by plasmids containing the XorII MTase gene, indicating the presence of at least one ^MCG in the recognition sequence for M · XorII (CGATCG). The 408 nucleotide ORF was 36% identical at the amino acid level to sequences of the E. coli dcm-vsr gene, which is required for very short patch repair. X. oryzae pv. oryzae genomic DNA that is resistant to digestion by Pvul and XorII hybridizes with a 7.0 kb fragment containing the XorII MTase gene and vsr homolog, whereas DNA from strains that lack M · XorII activity do not hybridize with the fragment.The sequence presented in this paper has been submitted to NCBI; the accession number is U06424     

NCL1, a novel gene for a non-essential nuclear protein in Saccharomyces cerevisiae

The nucleolar protein Nop2p is an essential gene product that is required for pre-rRNA processing and ribosome biogenesis in Saccharomyces cerevisiae (Hong, B. et al., 1997, Mol. Cell. Biol., 17, 378–388). A search for proteins similar to Nop2p identified a novel yeast gene product that also shares significant homology with the human proliferation associated nucleolar protein p120. The gene encoding this 78 kDa protein was termed NCL1 (for nuclear protein 1; corresponding to YBL024w). Ncl1p and Nop2p contain an evolutionarily conserved motif that has been termed the ‘NOL1/NOP2/fmu family signature' (NOL1 encodes p120). Epitope tagged Ncl1p was found to be localized to the nucleus, including the nucleolus, and was concentrated at the nuclear periphery. NCL1 is not essential. Strains containing a disruption of NCL1, or strains overexpressing NCL1, grow essentially identically to wildtype NCL1 strains on a number of different media and at different temperatures. Disruption of NCL1 does not affect steady-state levels of large and small ribosome subunits, monoribosomes, and polyribosomes. However, disruption of NCL1 leads to increased sensitivity to the antibiotic paromomycin.     

The biogenesis of mitochondrial membranes in the yeast Saccharomyces cerevisiae

Membrane lipids of yeast mitochondria have been enriched by growing yeast cells in minimal medium supplemented with specific unsaturated fatty acids as the sole lipid supplement. Using the activity of marker enzymes for the outer (kynurenine hydroxylase) and inner (cytochrome c oxidase and oligomycin-sensitive ATPase) mitochondrial membranes, Arrhenius plots have been constructed using both pro-mitochondria and mitochondria obtained from O₂-adapting cells in the presence of a second unsaturated fatty acid (i.e. linoleate (N₂) to elaidic (O₂)). Transition temperatures which reflect the unsaturated fatty acid enrichment of the new membranes reveal interesting features involved in the mechanism of the assembly of these two mitochondrial membranes. This approach was further enforced with both lipid depletion and mitochondrial protein inhibition studies. Kynurenine hydroxylase which does not require fatty acid for its continued synthesis during aerobiosis seems to be incorporated into the preformed linoleate-anaerobic outer membrane. The newly synthesized activities of inner mitochondrial membrane enzymes on the other hand, appear to integrate their activity into newly formed aerobic-elaidic-rich inner membrane. These latter enzymes show a distinct dependence on fatty acid supplement for their continued synthesis during their aerobic phase. This suggests that O₂-dependent proteo-lipid precursors are formed before these enzymes are integrated into their membrane mosaic. Two separate models are proposed to explain these results, one for the lipid-rich outer mitochondrial membrane and another for the protein-rich inner mitochondrial membrane.     

Timing of mitochondrial DNA synthesis during meiosis in Saccharomyces cerevisiae

Mitochondrial DNA (mtDNA) synthesis was examined during meiosis in Saccharomyces cerevisiae using an aneuploid strain disomic (n + 1) for chromosome III. The aneuploid has the advantage over true diploid strains in that it completes early meiotic events, including premeiotic chromosome replication, but does not form mature ascospores. Thus, differential extraction problems, resulting from the simultaneous presence of both unsporulated cells and spores in the population, are eliminated. The kinetic of mtDNA synthesis was monitored by determining the actual mtDNA content of cells following analytical CsCl centrifugation of cell extracts. MtDNA synthesis started soon after the cells were placed in sporulation medium and continued at an approximately constant rate until 24 h, resulting in slightly more than a doubling of the mitochondrial DNA content per cell. [¹⁴C]uracil was incorporated into mtDNA during the entire developmental period. Extensive preferential labeling of mtDNA occurred between 24 and 50 h, when no net DNA synthesis was observed.     

Two adjacent nuclear genes, ISF1 and NAM7/UPF1, cooperatively participate in mitochondrial functions in Saccharomyces cerevisiae

We previously isolated a nuclear 5.7 kb genomic fragment carrying the NAM7/UPF1 gene, which is able to suppress mitochondrial splicing deficiency when present in multiple copies. We show here that an immediately adjacent gene ISF1 (Increasing Suppression Factor) increases the efficiency of the NAM7/UPF1 suppressor activity. The ISF1 gene has been independently isolated as the MBR3 gene and comparison of the ISF1 predicted protein sequence with data libraries revealed a significant similarity with the MBRI yeast protein. The ISF1 and NAM7 genes are transcribed in the same direction, and RNase mapping allowed the precise location of their termini within the intergenic region to be determined. The ISF1 gene is not essential for cell viability or respiratory growth. However as for many mitochondrial genes, ISF1 expression is sensitive to fermentative repression; in contrast expression of the NAM7 gene is unaffected by glucose. We propose that ISF1 could influence the NAM7/UPF1 function, possibly at the level of mRNA turnover, thus modulating the expression of nuclear genes involved in mitochondrial biogenesis.     

Calcium and Saccharomyces cerevisiae

The claim that Ca may be a dispensable element for yeast Saccharomyces cerevisiae has been reexamined. The cells of S. cerevisiae could grow in media which contained no added Ca and were deprived of contaminating Ca²⁺ by filtration through a Chelex 100 column. Also, the cells were able to grow in the presence of fairly high concentrations of EGTA. The apparent intracellular concentrations of Ca, assessed from the content of radioactive ⁴⁵Ca in cells preloaded with ⁴⁵CaCl₂, could vary within the range of approx. 2 nM to 2.8 mM, without adversively affecting growth or morphology of the cells. An extremely low affinity for Ca²⁺ of the system taking up Ca into the cells was corroborated. However, even the Chelex 100-treated media were found in contain 1–5 μM Ca when maintained in glass culture vessels. Also, the ability of the cells to take up Ca from a medium containing surplus of EGTA or EDTA was demonstrated. su14CEDTA, alone or in the presence of Ca, could also be transported into the cells. It has been inferred that Ca must be as essential for yeast as it is for other eucaryotic organisms. The omnipresence of contaminating Ca and peculiarities of the Ca transporting system, combined with an intricate intracellular compartmentation of Ca, would account for the impossibility to prove the importance of Ca for yeast by direct growth studies.     

The complete sequence of the mitochondrial genome of Saccharomyces cerevisiae

The currently available yeast mitochondrial DNA (mtDNA) sequence is incomplete, contains many errors and is derived from several polymorphic strains. Here, we report that the mtDNA sequence of the strain used for nuclear genome sequencing assembles into a circular map of 85 779 bp which includes 10 kb of new sequence. We give a list of seven small hypothetical open reading frames (ORFs). Hot spots of point mutations are found in exons near the insertion sites of optional mobile group I intron-related sequences. Our data suggest that shuffling of mobile elements plays an important role in the remodelling of the yeast mitochondrial genome.