Kohsai Fukuda

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.

UV hypersensitivity of yeast linear plasmids.

The Kluyveromyces linear plasmids pGKL 1 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 wildtype 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.

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 α 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.

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 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.

Isolation and characterization of a mutant recombinant Saccharomyces cerevisiae strain with high efficiency xylose utilization.

A recombinant xylose-utilizing Saccharomyces cerevisiae strain carrying one copy of heterologous XYL1 and XYL2 from Pichia stipitis and endogenous XKS1 under the control of the TDH3 promoter in the chromosomal DNA was constructed from the industrial haploid yeast strain NAM34-4C, which showed thermotolerance and acid tolerance. The recombinant S. cerevisiae strain SCB7 grew in minimal medium containing xylose as the sole carbon source, and its shortest generation time (G(short)) was 5 h. From this strain, four mutants showing rapid growth (G(short) = 2.5 h) in the minimal medium were isolated. The mutants carried four mutations that were classified into three linkage groups. Three mutations were dominant and one mutation was recessive to the wild type allele. The recessive mutation was in the PHO13 gene encoding para-nitrophenyl phosphatase. The other mutant genes were not linked to TAL1 gene encoding transaldolase. When the mutants and their parental strain were used for the batch fermentation in a complex medium at pH 4.0 containing 30 g/L xylose at 35 °C with shaking (60 rpm) and an initial cell density (Absorbance at 660 nm) of 1.0, all mutants showed efficient ethanol production and xylose consumption from the early stage of the fermentation culture. In two mutants, within 24 h, 4.8 g/L ethanol was produced, and the ethanol yield was 47%, which was 1.4 times higher than that achieved with the parental strain. The xylose concentration in the medium containing the mutant decreased linearly at a rate of 1 g/L/h until 24 h.

Draft Genome Sequence of the Formaldehyde-Resistant Fungus Byssochlamys spectabilis No. 5 (Anamorph Paecilomyces variotii No. 5) (NBRC109023)

ABSTRACT Byssochlamys spectabilis no. 5 (anamorph Paecilomyces variotii no. 5) (NBRC109023) was isolated from a soil sample in 2001 in Kumamoto Prefecture, Japan. This fungus is highly resistant to formaldehyde. Here, we report a draft genome sequence of P. variotii no. 5; this draft was produced with the intent of investigating the mechanism of formaldehyde resistance. This is the first report of the genome sequence of any Paecilomyces species.

Purification and properties of S-hydroxymethylglutathione dehydrogenase of Paecilomyces variotii no. 5, a formaldehyde-degrading fungus

S-hydroxymethylglutathione dehydrogenase from Paecilomyces variotii No. 5 strain (NBRC 109023), isolated as a formaldehyde-degrading fungus, was purified by a procedure that included ammonium sulfate precipitation, DEAE-Sepharose and hydroxyapatite chromatography and isoelectrofocusing. Approximately 122-fold purification was achieved with a yield of 10.5%. The enzyme preparation was homogeneous as judged by sodium dodecyl polyacrylamide gel electrophoresis (SDS-PAGE). The molecular mass of the purified enzyme was estimated to be 49 kDa by SDS-PAGE and gel filtration, suggesting that it is a monomer. Enzyme activity was optimal at pH 8.0 and was stable in the range of pH 7.0–10. The optimum temperature for activity was 40°C and the enzyme was stable up to 40°C. The isoelectric point was pH 5.8. Substrate specificity was very high for formaldehyde. Besides formaldehyde, the only aldehyde or alcohol tested that served as a substrate was pyruvaldehyde. Enzyme activity was enhanced by several divalent cations such as Mn2+ (179%), Ba2+ (132%), and Ca2+ (112%) but was completely inhibited by Ni2+, Fe3+, Hg2+, p-chloromercuribenzoate (PCMB) and cuprizone. Inactivation of the enzyme by sulfhydryl reagents (Hg2+ and PCMB) indicated that the sulfhydryl group of the enzyme is essential for catalytic activity.

Progressive Rearrangement of Telomeric Sequences Added to Both the ITR Ends of the Yeast Linear pGKL Plasmid.

Relocation into the nucleus of the yeast cytoplasmic linear plasmids was studied using a monitor plasmid pCLU1. InSaccharomyces cerevisiae, the nuclearly-relocated pCLU1 replicated in a linear form (termed pTLU-type plasmid) which carried the host telomeric repeats TG1–3 of 300–350 bp at both ends. The telomere sequences mainly consisted of a major motif TGTGTGGGTGTGG which was complementary to part of the RNA template of yeast telomerase and were directly added to the very end of the pCLU1-terminal element ITR (inverted terminal repeat), suggesting that the ITR end played a role as a substrate of telomerase. The telomere sequences varied among isolated pTLU-type plasmids, but the TG1–3 organization was symmetrically identical on both ends of any one plasmid. During cell growth under non-selective condition, the telomeric repeat sequences were progressively rearranged on one side, but not on the opposite side of pTLU plasmid ends. This indicates that the mode of telomeric DNA replication or repair differed between both ends. Clonal analysis showed that the intense rearrangement of telomeric DNA was closely associated with extreme instability of pTLU plasmids.