Viral preprotoxin signal sequence allows efficient secretion of green fluorescent protein by Candida glabrata, Pichia pastoris, Saccharomyces cerevisiae, and Schizosaccharomyces pombe

Besides its importance as model organism in eukaryotic cell biology, yeast species have also developed into an attractive host for the expression, processing, and secretion of recombinant proteins. Here we investigated foreign protein secretion in four distantly related yeasts (Candida glabrata, Pichia pastoris, Saccharomyces cerevisiae, and Schizosaccharomyces pombe) by using green fluorescent protein (GFP) as a reporter and a viral secretion signal sequence derived from the K28 preprotoxin (pptox), the precursor of the yeast K28 virus toxin. In vivo expression of GFP fused to the N-terminal pptox leader sequence and/or expression of the entire pptox gene was driven either from constitutive (PGK1 and TPI1) or from inducible and/or repressible (GAL1, AOX1, and NMT1) yeast promoters. In each case, GFP entered the secretory pathway of the corresponding host cell; confocal fluorescence microscopy as well as sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western analysis of cell-free culture supernatants confirmed that GFP was efficiently secreted into the culture medium. In addition to the results seen with GFP, the full-length viral pptox was correctly processed in all four yeast genera, leading to the secretion of a biologically active virus toxin. Taken together, our data indicate that the viral K28 pptox signal sequence has the potential for being used as a unique tool in recombinant protein production to ensure efficient protein secretion in yeast.     

Viral Preprotoxin Signal Sequence Allows Efficient Secretion of Green Fluorescent Protein by Candida glabrata, Pichia pastoris, Saccharomyces cerevisiae, and Schizosaccharomyces pombe

Besides its importance as model organism in eukaryotic cell biology, yeast species have also developed into an attractive host for the expression, processing, and secretion of recombinant proteins. Here we investigated foreign protein secretion in four distantly related yeasts (Candida glabrata, Pichia pastoris, Saccharomyces cerevisiae, and Schizosaccharomyces pombe) by using green fluorescent protein (GFP) as a reporter and a viral secretion signal sequence derived from the K28 preprotoxin (pptox), the precursor of the yeast K28 virus toxin. In vivo expression of GFP fused to the N-terminal pptox leader sequence and/or expression of the entire pptox gene was driven either from constitutive (PGK1 and TPI1) or from inducible and/or repressible (GAL1, AOX1, and NMT1) yeast promoters. In each case, GFP entered the secretory pathway of the corresponding host cell; confocal fluorescence microscopy as well as sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western analysis of cell-free culture supernatants confirmed that GFP was efficiently secreted into the culture medium. In addition to the results seen with GFP, the full-length viral pptox was correctly processed in all four yeast genera, leading to the secretion of a biologically active virus toxin. Taken together, our data indicate that the viral K28 pptox signal sequence has the potential for being used as a unique tool in recombinant protein production to ensure efficient protein secretion in yeast.     

The Zygosaccharomyces bailii antifungal virus toxin zygocin: cloning and expression in a heterologous fungal host

Zygocin, a monomeric protein toxin secreted by a virus-infected killer strain of the osmotolerant spoilage yeast Zygosaccharomyces bailii, kills a broad spectrum of human and phytopathogenic yeasts and filamentous fungi by disrupting cytoplasmic membrane function. The toxin is encoded by a double-stranded (ds)RNA killer virus (ZbV-M, for Z. bailii virus M) that stably persists within the yeast cell cytosol. In this study, the protein toxin was purified, its N-terminal amino acid sequence was determined, and a full-length cDNA copy of the 2.1 kb viral dsRNA genome was cloned and successfully expressed in a heterologous fungal system. Sequence analysis as well as zygocin expression in Schizosaccharomyces pombe indicated that the toxin is in vivo expressed as a 238-amino-acid preprotoxin precursor (pptox) consisting of a hydrophobic N-terminal secretion signal, followed by a potentially N-glycosylated pro-region and terminating in a classical Kex2p endopeptidase cleavage site that generates the N-terminus of the mature and biologically active protein toxin in a late Golgi compartment. Matrix-assisted laser desorption mass spectrometry further indicated that the secreted toxin is a monomeric 10.4 kDa protein lacking detectable post-translational modifications. Furthermore, we present additional evidence that in contrast with other viral antifungal toxins, zygocin immunity is not mediated by the toxin precursor itself and, therefore, heterologous pptox expression in a zygocin-sensitive host results in a suicidal phenotype. Final sequence comparisons emphasize the conserved pattern of functional elements present in dsRNA killer viruses that naturally infect phylogenetically distant hosts (Saccharomyces cerevisiae and Z. bailii) and reinforce models for the sequence elements that are in vivo required for viral RNA packaging and replication.     

A novel leader peptide which allows efficient secretion of a fragment of human interleukin 1 beta in Saccharomyces cerevisiae.

Killer strains of Kluyveromyces lactis secrete a toxin which presumably is processed during secretion from a larger precursor. Analysis of the sequence of the K. lactis killer toxin gene predicts that the first 16 amino acids at the amino terminus of the protein should represent its leader peptide. We have tested the capability of this leader peptide to direct secretion of a protein fused to it by inserting a synthetic oligonucleotide identical to the sequence of the putative leader peptide into a yeast expression vector. Subsequently, the cDNA coding for the secreted active portion of the human interleukin 1 beta (IL-1 beta) was fused to the leader peptide sequence of the killer toxin. This construction in Saccharomyces cerevisiae is capable of directing synthesis and secretion of correctly processed IL-1 beta into the culture medium.     

A novel yeast secretion signal isolated from 28K killer precursor protein encoded on the linear DNA plasmid pGKL1.

Saccharomyces cerevisiae harboring linear dsDNA plasmids, pGKL1 and pGKL2, secretes a killer toxin consisting of 97, 31 and 28 kilodalton subunits (Nucleic Acids Res., 15, 1031-1046, 1987). We isolated the DNA encoding the N-terminal pre-sequence of the 28K precursor protein and constructed a new secretion vector in S. cerevisiae. Mouse alpha-amylase fused to the 28K signal sequence was secreted into the culture medium with a high efficiency similar to those fused to the mating factor alpha and 97K-31K killer signal sequences. This data clearly indicates that 28K presequence functions as a secretion signal. Glycosylated and nonglycosylated alpha-amylase molecules were detected in the culture medium. The secretion of alpha-amylase was blocked by sec18-1 mutation. The secreted alpha-amylase recovered from the medium was found to migrate faster in SDS-polyacrylamide gel than the precursor form of alpha-amylase synthesized in vitro. These lines of evidence suggest that mouse alpha-amylase fused to 28K killer signal sequence was processed, glycosylated and secreted through the normal secretion pathway of the yeast.     

Viral induced yeast apoptosis

In an analogous system to mammals, induction of an apoptotic cell death programme (PCD) in yeast is not only restricted to various exogenous factors and stimuli, but can also be triggered by viral killer toxins and viral pathogens. In yeast, toxin secreting killer strains are frequently infected with double-stranded (ds)RNA viruses that are responsible for killer phenotype expression and toxin secretion in the infected host. In most cases, the viral toxins are either pore-forming proteins (such as K1, K2, and zygocin) that kill non-infected and sensitive yeast cells by disrupting cytoplasmic membrane function, or protein toxins (such as K28) that act in the nucleus by blocking DNA synthesis and subsequently causing a G1/S cell cycle arrest. Interestingly, while all these virus toxins cause necrotic cell death at high concentration, they trigger caspase- and ROS-mediated apoptosis at low-to-moderate concentration, indicating that even low toxin doses are deadly by triggering PCD in enemy cells. Remarkably, viral toxins are not solely responsible for cell death induction in vivo, as killer viruses themselves were shown to trigger apoptosis in non-infected yeast. Thus, as killer virus-infected and toxin secreting yeasts are effectively protected and immune to their own toxin, killer yeasts bear the intrinsic potential to dominate over time in their natural habitat.     

Secretion of killer toxin encoded on the linear DNA plasmid pGKL1 from Saccharomyces cerevisiae

By the kar1-mediated cytoduction, linear double-stranded DNA plasmids pGKL1 and pGKL2, encoding killer toxin complex, have been successfully transferred to the recipient strains with about 30% frequency. The killer toxin was found to be secreted through the normal yeast secretory pathway by introducing pGKL plasmids into the several Saccharomyces cerevisiae sec mutants and examining the secretion of killer toxin. S. cerevisiae cells, harboring newly isolated deletion plasmid pGKL1D, expressed only the 28K protein among three killer subunits, and secreted the 28K subunit at a level of zero to 20% efficiency of the cells containing intact pGKL1 plasmid. These data indicated that subunit interaction (cosecretion) of killer proteins is required for the efficient secretion of 28K subunit. The 28K precursor protein was found to translocate across the canine pancreatic endoplasmic reticulum membrane under the direction of its own signal peptide in vitro without any other subunits. From kex2 mutant cells harboring pGKL1 plasmid, the 97K subunit, and its precursor 128K protein were not secreted, however, the 28K subunit was secreted in the same amount as that secreted from KEX2 cells. These lines of evidence suggest that the final assembly of killer toxin complex after KEX2 site of Golgi apparatus is not essential for the secretion of 28K subunit, and therefore, that putative interaction between 128K protein and 28K subunit for the transport between endoplasmic reticulum and Golgi apparatus may be required for the efficient secretion of 28K subunit.     

Phenotypic expression of Kluyveromyces lactis killer toxin against Saccharomyces spp.

The secretion of killer toxins by some strains of yeasts is a phenomenon of significant industrial importance. The activity of a recently discovered Kluyveromyces lactis killer strain against a sensitive Saccharomyces cerevisiae strain was determined on peptone-yeast extract-nutrient agar plates containing as the carbon source glucose, fructose, galactose, maltose, or glycerol at pH 4.5 or 6.5. Enhanced activity (50 to 90% increase) was found at pH 6.5, particularly on the plates containing galactose, maltose, or glycerol, although production of the toxin in liquid medium was not significantly different with either glucose or galactose as the carbon source. Results indicated that the action of the K. lactis toxin was not mediated by catabolite repression in the sensitive strain. Sensitivities of different haploid and polyploid Saccharomyces yeasts to the two different killer yeasts S. cerevisiae (RNA-plasmid-coded toxin) and K. lactis (DNA-plasmid-coded toxin) were tested. Three industrial polyploid yeasts sensitive to the S. cerevisiae killer yeast were resistant to the K. lactis killer yeast. The S. cerevisiae killer strain itself, however, was sensitive to the K. lactis killer yeast.     

Phenotypic expression of Kluyveromyces lactis killer toxin against Saccharomyces spp

The secretion of killer toxins by some strains of yeasts is a phenomenon of significant industrial importance. The activity of a recently discovered Kluyveromyces lactis killer strain against a sensitive Saccharomyces cerevisiae strain was determined on peptone-yeast extract-nutrient agar plates containing as the carbon source glucose, fructose, galactose, maltose, or glycerol at pH 4.5 or 6.5. Enhanced activity (50 to 90% increase) was found at pH 6.5, particularly on the plates containing galactose, maltose, or glycerol, although production of the toxin in liquid medium was not significantly different with either glucose or galactose as the carbon source. Results indicated that the action of the K. lactis toxin was not mediated by catabolite repression in the sensitive strain. Sensitivities of different haploid and polyploid Saccharomyces yeasts to the two different killer yeasts S. cerevisiae (RNA-plasmid-coded toxin) and K. lactis (DNA-plasmid-coded toxin) were tested. Three industrial polyploid yeasts sensitive to the S. cerevisiae killer yeast were resistant to the K. lactis killer yeast. The S. cerevisiae killer strain itself, however, was sensitive to the K. lactis killer yeast.     

Repair of UV damage in the fission yeast Schizosaccharomyces pombe

This review is concerned with repair and tolerance of UV damage in the fission yeast, Schizosaccharomyces pombe and with the differences between Sch. pombe and budding yeast, Saccharomyces cerevisiae in their response to UV irradiation. Sch. pombe is not as sensitive to ultra-violet radiation as Sac. cerevisiae nor are any of its mutants as sensitive as the most sensitive Sac. cerevisiae mutants. This can be explained in part by the fact that Sch. pombe, unlike budding yeast or mammalian cells, has an extra pathway (UVER) for excision of UV photoproducts in addition to nucleotide excision repair (NER). However, even in mutants lacking this additional pathway, there are significant differences between the two yeasts. Sch. pombe mutants that lack the alternative pathway are still more UV-resistant than wild-type Sac. cerevisiae; recombination mutants are significantly UV sensitive (unlike their Sac. cerevisiae equivalents); mutants lacking the second pathway are sensitized to UV by caffeine; and checkpoint mutants are relatively more sensitive than the budding yeast equivalents. In addition, Sch. pombe has no photolyase. Thus, the response to UV in the two yeasts has a number of significant differences, which are not accounted for entirely by the existence of two alternative excision repair pathways. The long G2 in Sch. pombe, its well-developed recombination pathways and efficient cell cycle checkpoints are all significant components in survival of UV damage.     

Expression of pGKL killer 28K subunit in Saccharomyces cerevisiae: identification of 28K subunit as a killer protein.

Saccharomyces cerevisiae and other yeast cells harboring the linear double stranded (ds) DNA plasmids pGKL1 and pGKL2 secrete a killer toxin consisting of 97K, 31K and 28K subunits into the culture medium (EMBO J. 5, 1995-2002 (1986), Nucleic Acids Res., 15, 1031-1046 (1987]. The 28K subunit of the killer toxin was successfully expressed in S. cerevisiae when it was cloned on a circular plasmid with its putative promoter region replaced with that of S. cerevisiae chromosomal genes. The expression of the 28K subunit of the killer toxin in killer-sensitive cells resulted in the death of the host cells. This killing activity by the 28K subunit was prevented by the expression of the killer immunity, indicating that the killing activity of the killer toxin complex was carried out by the 28K subunit. Although the 28K subunit was synthesized as a intact precursor protein with its own signal sequence, it was not secreted into the culture medium but remained in the host cells. This indicated that 28K subunit killed host cells from inside of the cells rather than from outside. We further suggested that 28K killer subunit without 97K and 31K subunits did not kill the killer-sensitive cells from outside.     

Immunity to K1 killer toxin: internal TOK1 blockade

K1 killer strains of Saccharomyces cerevisiae harbor RNA viruses that mediate secretion of K1, a protein toxin that kills virus-free cells. Recently, external K1 toxin was shown to directly activate TOK1 channels in the plasma membranes of sensitive yeast cells, leading to excess potassium flux and cell death. Here, a mechanism by which killer cells resist their own toxin is shown: internal toxin inhibits TOK1 channels and suppresses activation by external toxin.     

Schizosaccharomyces pombe possesses two plasma membrane alkali metal cation/H antiporters differing in their substrate specificity

The Schizosaccharomyces pombe plasma membrane Na(+)/H(+) antiporter, SpSod2p, has been shown to belong to the subfamily of yeast Na(+)/H(+) antiporters that only recognize Na(+) and Li(+) as substrates. Nevertheless, most of the studied plasma membrane alkali metal cation/H(+) antiporters from other yeasts have broader substrate specificities, exporting K(+) and Rb(+) as well. Such antiporters probably play two roles in the physiology of cells: the elimination of surplus toxic cations, and the regulation of stable intracellular K(+) content, pH and cell volume. The systematic sequencing of the Sch. pombe genome revealed the presence of an as-yet uncharacterized homolog of the Spsod2 gene (designated Spsod22). Spsod22 and Spsod2 were expressed in Saccharomyces cerevisiae cells lacking their own alkali metal cation efflux systems, and the transport properties of both Sch. pombe antiporters were compared to those of the Sac. cerevisiae Nha1 antiporter expressed under the same conditions. Here we show that SpSod22p has broad substrate specificity upon heterologous expression in Sac. cerevisiae cells and contributes to cell tolerance to high external levels of K(+). Thus, the Sch. pombe genome encodes two plasma membrane alkali metal cation/H(+) antiporters that play different roles in the physiology of the yeast.     

The expression of cDNA clones of yeast M1 double-stranded RNA in yeast confers both killer and immunity phenotypes.

Two cDNA clones of the segment of Saccharomyces cerevisiae M1 double-stranded RNA, which codes for the yeast killer toxin, have been expressed in yeast using the expression vector pYT760. Toxin expression and secretion depended upon the presence of a yeast promoter. Transformants not only contain an authentic preprotoxin precursor, as determined by precipitation of intracellular proteins with antitoxin antisera, but also display an immunity phenotype. The evidence is that the immunity protein is part of the preprotoxin and may act by masking toxin binding sites. Neither cDNA clone had a complete 5' terminus and the preprotoxin translational start was missing. The promoter and the initiator ATG were supplied by the expression vector. One clone with a full-length preprotoxin but altered N-terminal amino acids gave a normal glycosylated intracellular precursor. A clone with an N-terminal nine amino acid deletion gave a precursor which was not glycosylated but toxin was still secreted.     

Production of fluorescent and cytotoxic K28 killer toxin variants through high cell density fermentation of recombinant <Emphasis Type="Italic">Pichia pastoris</Emphasis>

Background

Virus infected killer strains of the baker’s yeast Saccharomyces cerevisiae secrete protein toxins such as K28, K1, K2 and Klus which are lethal to sensitive yeast strains of the same or related species. K28 is somewhat unique as it represents an α/β heterodimeric protein of the A/B toxin family which, after having bound to the surface of sensitive target cells, is taken up by receptor-mediated endocytosis and transported through the secretory pathway in a retrograde manner. While the current knowledge on yeast killer toxins is largely based on genetic screens for yeast mutants with altered toxin sensitivity, in vivo imaging of cell surface binding and intracellular toxin transport is still largely hampered by a lack of fluorescently labelled and biologically active killer toxin variants.

Results

In this study, we succeeded for the first time in the heterologous K28 preprotoxin expression and production of fluorescent K28 variants in Pichia pastoris. Recombinant P. pastoris GS115 cells were shown to successfully process and secrete K28 variants fused to mCherry or mTFP by high cell density fermentation. The fluorescent K28 derivatives were obtained in high yield and possessed in vivo toxicity and specificity against sensitive yeast cells. In cell binding studies the resulting K28 variants caused strong fluorescence signals at the cell periphery due to toxin binding to primary K28 receptors within the yeast cell wall. Thereby, the β-subunit of K28 was confirmed to be the sole component required and sufficient for K28 cell wall binding.

Conclusion

Successful production of fluorescent killer toxin variants of S. cerevisiae by high cell density fermentation of recombinant, K28 expressing strains of P. pastoris now opens the possibility to study and monitor killer toxin cell surface binding, in particular in toxin resistant yeast mutants in which toxin resistance is caused by defects in toxin binding due to alterations in cell wall structure and composition. This novel approach might be easily transferable to other killer toxins from different yeast species and genera. Furthermore, the fluorescent toxin variants described here might likewise represent a powerful tool in future studies to visualize intracellular A/B toxin trafficking with the help of high resolution single molecule imaging techniques.

     

A molecular target for viral killer toxin: TOK1 potassium channels.

Killer strains of S. cerevisiae harbor double-stranded RNA viruses and secrete protein toxins that kill virus-free cells. The K1 killer toxin acts on sensitive yeast cells to perturb potassium homeostasis and cause cell death. Here, the toxin is shown to activate the plasma membrane potassium channel of S. cerevisiae, TOK1. Genetic deletion of TOK1 confers toxin resistance; overexpression increases susceptibility. Cells expressing TOK1 exhibit toxin-induced potassium flux; those without the gene do not. K1 toxin acts in the absence of other viral or yeast products: toxin synthesized from a cDNA increases open probability of single TOK1 channels (via reversible destabilization of closed states) whether channels are studied in yeast cells or X. laevis oocytes.     

Recombinational repair in Schizosaccharomyces pombe: role in maintaining genomic integrity

Recombinational repair was first detected in budding yeast Saccharomyces cerevisiae and was also studied in fission yeast Schizosaccharomyces pombe over the recent decade. The discovery of Sch. pombe homologs of the S. cerevisiae RAD52 genes made it possible not only to identify and to clone their vertebrate counterparts, but also to study in detail the role of DNA recombination in certain cell processes. For instance, recombinational repair was shown to play a greater role in maintaining genome integrity in fission yeast and in vertebrates compared with S. cerevisiae. The present state of the problem of recombinational double-strand break repair in fission yeast is considered with a focus on comparisons between Sch. pombe and higher eukaryotes. The role of double-strand break repair in maintaining genome stability is discussed.     

K+ fluxes in Schizosaccharomyces pombe

All living cells accumulate high concentrations of K+ in order to keep themselves alive. To this end they have developed a great diversity of transporters. The internal level of K+ is the result of the net balance between the activities of the K+ influx and the K+ efflux transporters. Potassium fluxes have been extensively studied and characterized in Saccharomyces cerevisiae. However, this is not the case in the fission yeast and, in addition, the information available indicates that both yeasts present substantial and interesting differences. In this paper we have reviewed and summarized the information on K+ fluxes in Schizosaccharomyces pombe. We have included some unpublished results recently obtained in our laboratory and, in particular, we have highlighted the significant differences found between the well-known yeast S. cerevisiae and the fission yeast Sch. pombe.