A novel yeast secretion vector utilizing secretion signal of killer toxin encoded on the yeast linear DNA plasmid pGKL1

The NH2-terminal signal region comprising of approximately 70% length of the prepro-sequence of the pGKL killer precursor protein was found to direct an efficient secretion of the mouse alpha-amylase into the culture medium of Saccharomyces cerevisiae. The alpha-amylase molecule secreted into the culture medium was identified by both immuno-blotting and assay of the enzyme activity. The amount of alpha-amylase secreted via the killer toxin signal was comparable to that directed by the leader sequence of mating factor alpha. The secretion of alpha-amylase using the killer toxin signal was blocked at 37C but not at 25C in sec18-1 host, indicating that alpha-amylase is exported through the normal secretion pathway of S. cerevisiae.     

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.     

The yeast linear DNA killer plasmids, pGKL1 and pGKL2, possess terminally attached proteins.

The terminal structures of linear DNA killer plasmids from yeast, pGKL1 and pGKL2, were analyzed. Results obtained by exonuclease treatments of these plasmids show that both pGKL plasmids have free hydroxyl 3'-ends and blocked 5'-ends. Electrophoretic analysis of the terminal restriction fragments treated with proteases revealed that pGKL1 and pGKL2 have proteins bound at 5'termini and that the terminal protein of pGKL1 is distinct from that of pGKL2. This is the first linear DNA-terminal protein association found in yeast.     

Incompatibility of linear DNA killer plasmids pGKL1 and pGKL2 from Kluyveromyces lactis with mitochondrial DNA from Saccharomyces cerevisiae.

Two linear killer plasmids (pGKL1 and pGKL2) from Kluyveromyces lactis stably replicated and expressed the killer phenotype in a neutral petite mutant [( rho0]) of Saccharomyces cerevisiae. However, when cytoplasmic components were introduced by cytoduction from a wild-type [( rho+]) strain of S. cerevisiae, the linear plasmids became unstable and were frequently lost from the cytoductant cells during mitosis, giving rise to nonkiller clones. The phenomenon was ascribed to the incompatibility with the introduced S. cerevisiae mitochondrial DNA (mtDNA), because the plasmid stability was restored by [rho0] mutations in the cytoductant cells. Incompatibility with mtDNA was also apparent for the transmission of plasmids into diploid progeny in crosses between killer cells carrying the pGKL plasmids and [rho+] nonkiller cells lacking the plasmids. High-frequency transmission of the plasmids was observed in crosses lacking mtDNA [( rho0] by [rho0] crosses) and in crosses involving mutated mtDNA with large deletions of various regions of mitochondrial genome. In contrast, mutated mtDNA from various mit- mutations also exerted the incompatibility effect on the transmission of plasmids. Double-stranded RNA killer plasmids were stably maintained and transmitted in the presence of wild-type mtDNA and stably coexisted with pGKL killer plasmids in [rho0] cells of S. cerevisiae.     

Palindrome-hairpin linear plasmids possessing only a part of the ORF1 gene of the yeast killer plasmid pGKL1

Summary The yeast Kluyveromyces lactis haboring linear DNA plasmids pGKL1 and pGKL2 exhibits killer and killer-resistant phenotypes. Two new linear plasmids pK192L and pK192S were found in the weak killer mutant KUV192 induced by UV irradiation. pK192S was always accompanied by pK192L in subclones of KUV192. Both plasmids were derived from pGKL1 by deletion of the large right part of it. pK192L was 4.9 kb in size and had a palindromic structure consisting of 2.35 kb inverted terminal repetitions and a 215 base unique sequence. Analysis of denatured and renatured DNA strands suggested that pK192S was a hairpin-like form of pK192L. The pK192 plasmids were maintained only in cells haboring either pGKL1 or pGKL1S in addition to pGKL2 and competed with pGKL1 or pGKL1S for their maintenance. Since no complete ORF1 was conserved in pK192 plasmids, these results lead to the conclusion that the ORF1 gene is necessary for the replication and/or maintenance of pGKL1.     

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.     

A new linear DNA plasmid isolated from the yeast Saccharomyces kluyveri

Summary A new linear DNA plasmid, designated pSKL, was found in the yeast Saccharomyces kluyveri. Restriction maps of the 14.2 kb plasmid were constructed. By the use of CsCl-Hoechst 33258 centrifugation containing guanidine chloride, pSKL was isolated as a DNA-protein complex. The protein was associated with the terminal regions of pSKL. The two terminal EcoRI fragments of pSKL were cloned and their nucleotide sequences were determined. pSKL had inverted terminal repeats of 483 bp with a unique structure in which fairly homologous sequences of 30 bp were repeated eight times.     

Expression and identification of immunity determinants on linear DNA killer plasmids pGKL1 and pGKL2 in Kluyveromyces lactis.

The linear dsDNA plasmids, pGKL1 (8.9 kb) and pGKL2 (13.4 kb) discovered in Kluyveromyces lactis, confer killer and immunity characteristics upon various yeast strains. We have devised an immunity assay and have been able to show the expression of an immunity phenotype in the K. lactis transformants harbouring conventional circular plasmids which contain DNA fragments of pGKL1. Using this expression system, the immunity determinant on pGKL1 was identified as ORF5. In addition, the presence of pGKL2 was proved to be essential for the expression of the immunity phenotype. This is the first demonstration of this new pGKL2 function, as distinct from its known functions for the replication and maintenance of pGKL1 in yeast cells.     

Characterization of a novel killer toxin encoded by a double-stranded linear DNA plasmid of Kluyveromyces lactis

A novel killer toxin, encoded by a double-stranded linear DNA plasmid pGK l-1 (5.4 MDa) in Kluyveromyces lactis IFO 1267 was purified 320 000-fold from the culture broth of yeast. The toxin was obtained in an electrophoretically homogeneous state with a yield of 24% by hydroxyapatite column chromatography, chromatofocusing and polyacrylamide gel electrophoresis. The purified toxin was dissociated into two subunits with molecular masses of 27 kDa and above 80 kDa, as estimated by Laemmli's sodium dodecylsulfate gel electrophoresis; the exact composition ratio of the two subunits remains unestablished. The isoelectric point was between 4.4 and 4.8. As compared with the reported narrow pH range of action and instability of k1 killer toxin encoded by a double-stranded RNA plasmid of Saccharomyces cerevisiae, the K. Lactis toxin was effective with sensitive strains of S. cerevisiae in a relatively wider pH range between 4 and 8; it was stable for several months at pH 6.0 when stored below -20 degrees C. In contrast to the simple protein nature of the k1 killer toxin with a molecular mass of 11.47 kDa, the K. lactis toxin maintained a mannoprotein nature, as it was absorbed by a ConA-Sepharose column and eluted by methyl alpha-D-mannoside. The growth inhibitory activity of K. lactis toxin was enhanced 2-35-fold by the presence of 4-60% glycerol.     

Structure of yeast pGKL 128-kDa killer-toxin secretion signal sequence. Processing of the 128-kDa killer-toxin-secretion-signal-alpha-amylase fusion protein.

The linear double-stranded DNA plasmid pGKL1 in yeast encodes a killer toxin consisting of 97-kDa, 31-kDa and 28-kDa subunits. A 128-kDa protein precursor of the 97-kDa and 31-kDa subunits, was first synthesized with a 29-amino-acid extension at its NH2-terminus as a secretion signal sequence. In the present study, the property of this signal sequence was studied by the analysis of a fusion protein with mouse alpha-amylase. Using the secretion signal sequence of the killer protein, the mouse alpha-amylase was successfully secreted into the culture medium. An intracellular precursor form of alpha-amylase was identified and purified. Analysis of the NH2-terminal sequence of this precursor molecule indicated that it corresponded to the secretory intermediate (pro form) of alpha-amylase with the removal of the hydrophobic segment (Met1-Gly16) of the secretion signal. Both the secretion of alpha-amylase into the culture medium and the detection of the pro-alpha-amylase species in the cells were prohibited by a sec 11 mutation, or by the conversion of Gly to Val at the 16th position of the secretion signal. These results strongly suggest that the cleavage occurs between Gly16 and Leu17 by a signal peptidase, and that this cleavage is required for the secretion of alpha-amylase into the medium. Based on the data from the NH2-terminal amino acid sequences of secreted alpha-amylases, we conclude that the 29-amino-acid secretion signal present in the 128-kDa killer toxin precursor protein is a prepro structure.     

A palindromic mutation of the linear killer plasmid k2 of yeast.

Production of the killer toxin in Kluyveromyces lactis is dependent on the presence of two linear DNA plasmids, k1 and k2. We isolated a non-killer mutant, VM5, with a modified plasmid composition. It had lost k1, but conserved k2, and acquired, in addition, three new DNA species. The new species were found to be rearranged derivatives of the k2 plasmid. One of them, pVM5-1, was made of the left terminal 4720 bp sequence of k2, including the inverted terminal repeat, and was organized as a large palindromic dimer molecule. The second, pVM5-2, was made of one strand of the pVM5-1 palindrome, folded into a hairpin structure. Like normal k2, pVM5-1 and 2 were present in a high copy number. The third species, pVM5-x, of variable size, was also a deletion product of k2, but not palindromic, and did not contain the terminal repeat. Genetic analysis showed that the presence of the palindromic derivatives appeared to destabilize the normal k2 genome, leading to gradual accumulation of plasmid-less cells.     

K1 killer toxin, a pore-forming protein from yeast

K1 killer toxin is a secreted, pore-forming protein that kills sensitive yeast cells. The heterodimeric toxin is processed from a precursor in the Golgi, and has allowed identification of the KEX2- and KEX1-encoded proteases. The toxin binds to a glucan receptor on the cell wall of target yeast, and mutational analysis implicates both the alpha- and beta-toxin subunits in receptor binding. Toxin-resistant mutants with altered cell-wall glucans have helped to outline a pathway of assembly of these polysaccharides. Patch-clamp technology has demonstrated the nature of the lethal channel in toxin-treated plasma membranes. The hydrophobic alpha-subunit-encoding region is the site of all mutations affecting channel formation. Immunity to the toxin is conferred by the toxin precursor, and immunity mutations map to the region encoding the alpha subunit. The precursor probably competes with the toxin to prevent channel formation in toxin-producing cells, but the basis of this remains unknown. This toxin/immunity system has a domain structure that differs from that of other characterized toxins and has no known homologues.     

Cloning and nucleotide sequences of the linear DNA killer plasmids from yeast.

The linear DNA killer plasmids (pGKL1 and pGKL2) isolated from a Kluyveromyces lactis killer strain are also maintained and expressed its killer character in Saccharomyces cerevisiae. After these killer plasmid DNAs isolated from S. cerevisiae were treated with alkali, four terminal fragments from each plasmid DNAs were cloned separately. Using these and other cloned DNA fragments, the terminal nucleotide sequences of pGKL2 and the complete nucleotide sequence of pGKL1 were determined. The inverted terminal repetitions of 202 bp and 182 bp were found in pGKL1 and pGKL2, respectively. The pGKL1 sequence showed an extremely high A + T content of 73.2% and it contained five large open reading frames. The largest of these open reading frame was suggested to code for a membrane-bound precursor of glycoprotein subunit of the killer toxin.     

The yeast protein encoded by PUB1 binds T-rich single stranded DNA.

We have characterized binding activities in yeast which recognise the T-rich strand of the yeast ARS consensus element and have purified two of these to homogeneity. One (ACBP-60) is detectable in both nuclear and whole cell extracts, while the other (ACBP-67) is apparent only after fractionation of extracts by heparin-sepharose chromatography. The major binding activity detected in nuclear extracts was purified on a sequence-specific DNA affinity column as a single polypeptide with apparent mobility of 60kDa (ACBP-60). This protein co-fractionates with nuclei, is present at several thousand copies per cell and has a Kd for the T-rich single strand of the ARS consensus between 10(-9) and 10(-10) M. Competition studies with simple nucleic acid polymers show that ACBP-60 has marginally higher affinity for poly dT30 than for a 30 nt oligomer containing the T-rich strand of ARS 307, and approximately 10 fold higher affinity for poly rU. Internal sequence information of purified p60 reveals identity with the open reading frames of genes PUB1 and RNP1 which encode polyuridylate binding protein(s). The second binding activity, ACBP-67, also binds specifically to the T-rich single strand of the ARS consensus, but with considerably lower affinity than ACBP-60. Peptide sequence reveals that the 67kDa protein is identical to the major polyA binding protein in yeast, PAB1.     

A DNA endonuclease isolated from yeast nuclear extract.

We have isolated and partially purified a DNA endonuclease from nuclei of the yeast Saccharomyces cerevisiae. Although purified on the basis of its ability to degrade denatured DNA, the enzyme can also attack native DNA. Denatured oligonucleotide products of the enzyme are sensitive to venom phosphodiesterase (EC3.1.4.1.) but not to bovine spleen phosphodiesterase (EC3.1.4.18). The enzyme has an estimated molecular weight of 6.6--7.5 X 10(4), more than twice as large as the endonucleases involved in DNA repair in Escherichia coli. When analyzed on glycerol gradients, the endonuclease sedimented as a single activity against both denatured DNA and closed circular DNA duplexes. The enzyme showed a 10-fold preference for denatured over native T7 DNA substrate, and appears to produce random nicks in a supercoiled replicative form of phiX174 DNA (RFI) with no discernable preference for the unpaired bases in the supercoiled duplex. The endonuclease appears to be distinct from the yeast endonucleases previously described.     

Analysis of linear plasmids isolated from Streptomyces: association of protein with the ends of the plasmid DNA

Linear DNA plasmids, designated pSLA1 and pSLA2, which were isolated from two strains of Streptomyces sp. producing lankacidin group antibiotics, were analyzed by using restriction endonucleases. Cleavage patterns of these plasmids were very similar, indicating that they are closely related. Cleavage maps of pSLA2 were constructed with BamHI, SalI, BglII, and EcoRI. A protein was associated with the restriction fragments of both ends of pSLA2 and this was not removed by sodium dodecyl sulfate-phenol treatment. pSLA2 was senstive to a 3′-exonuclease, exonuclease III, but was resistant to the 5′-exonuclease, λ-exonuclease. These results suggest that the protein is associated with the 5′ termini of pSLA2. The same terminal structure was also found on pSLA1. The approximate copy number of the plasmid was estimated by a brief method using agarose gel electrophoresis.