Kluyveromyces lactis killer system: analysis of cytoplasmic promoters of the linear plasmids

New Cytoplasmic Virus-Like Elements (VLEs) in the Yeast Debaryomyces hansenii

Yeasts can have additional genetic information in the form of cytoplasmic linear dsDNA molecules called virus-like elements (VLEs). Some of them encode killer toxins. The aim of this work was to investigate the prevalence of such elements in D. hansenii killer yeast deposited in culture collections as well as in strains freshly isolated from blue cheeses. Possible benefits to the host from harboring such VLEs were analyzed. VLEs occurred frequently among fresh D. hansenii isolates (15/60 strains), as opposed to strains obtained from culture collections (0/75 strains). Eight new different systems were identified: four composed of two elements and four of three elements. Full sequences of three new VLE systems obtained by NGS revealed extremely high conservation among the largest molecules in these systems except for one ORF, probably encoding a protein resembling immunity determinant to killer toxins of VLE origin in other yeast species. ORFs that could be potentially involved in killer activity due to similarity to genes encoding proteins with domains of chitin-binding/digesting and deoxyribonuclease NucA/NucB activity, could be distinguished in smaller molecules. However, the discovered VLEs were not involved in the biocontrol of Yarrowia lipolytica and Penicillium roqueforti present in blue cheeses.

Messenger RNAs of Yeast Virus-Like Elements Contain Non-templated 5' Poly(A) Leaders, and Their Expression Is Independent of eIF4E and Pab1

We employed virus-like elements (VLEs) pGKL1,2 from Kluyveromyces lactis as a model to investigate the previously neglected transcriptome of the broader group of yeast cytoplasmic linear dsDNA VLEs. We performed 5′ and 3′ RACE analyses of all pGKL1,2 mRNAs and found them not 3′ polyadenylated and containing frequently uncapped 5′ poly(A) leaders that are not complementary to VLE genomic DNA. The degree of 5′ capping and/or 5′ mRNA polyadenylation is specific to each gene and is controlled by the corresponding promoter region. The expression of pGKL1,2 transcripts is independent of eIF4E and Pab1 and is enhanced in lsm1Δ and pab1Δ strains. We suggest a model of primitive pGKL1,2 gene expression regulation in which the degree of 5′ mRNA capping and 5′ non-template polyadenylation, together with the presence of negative regulators such as Pab1 and Lsm1, play important roles. Our data also support a hypothesis of a close relationship between yeast linear VLEs and poxviruses.

Genetic Compatibility and Extensibility of Orthogonal Replication

We recently developed an orthogonal replication system (OrthoRep) in yeast that allows for the rapid continuous mutagenesis of a special plasmid without mutating the genome. Although OrthoRep has been successfully applied to evolve several proteins and enzymes, the generality of OrthoRep has not yet been systematically studied. Here, we show that OrthoRep is fully compatible with all Saccharomyces cerevisiae strains tested, demonstrate that the orthogonal plasmid can encode genetic material of at least 22 kb, and report a CRISPR/Cas9-based method for expedient genetic manipulations of OrthoRep. It was previously reported that the replication system upon which OrthoRep is based is only stable in respiration-deficient S. cerevisiae strains that have lost their mitochondrial genome (ρ⁰ strains). However, here we trace this biological incompatibility to the activity of the dispensable toxin/antitoxin system encoded on the wild-type orthogonal plasmid. Since the toxin/antitoxin system is replaced by genes of interest in any OrthoRep application, OrthoRep is a generally compatible platform for continuous in vivo evolution in S. cerevisiae.

Tunable Expression Systems for Orthogonal DNA Replication

We recently developed an orthogonal DNA replication (OrthoRep) system capable of driving the rapid continuous evolution of genes in vivo. However, OrthoRep uses a special transcription system, the components of which (e.g., promoters) have previously limited the strength with which OrthoRep-encoded genes can be expressed. Here, we report a collection of synthetic and evolved OrthoRep expression parts that allow OrthoRep-encoded genes to span expression levels matching those of endogenous Saccharomyces cerevisiae genes. Specifically, we found that various promoter mutations as well as a genetically encoded poly(A) tail enable us to tune the expression level of OrthoRep-encoded genes over a large range and up to levels 43-fold higher than were previously attained, reaching at least ∼40% of the strength of the genomic TDH3 promoter. We further show that expression level gains using our new parts are stable over passaging and consistent across multiple genes and OrthoRep systems of different mutation rates. This new set of expression parts further expands OrthoRep's applicability to the continuous in vivo evolution of proteins and pathways.

Transcription apparatus of the yeast virus-like elements: Architecture, function, and evolutionary origin

Extrachromosomal hereditary elements such as organelles, viruses, and plasmids are important for the cell fitness and survival. Their transcription is dependent on host cellular RNA polymerase (RNAP) or intrinsic RNAP encoded by these elements. The yeast Kluyveromyces lactis contains linear cytoplasmic DNA virus-like elements (VLEs, also known as linear plasmids) that bear genes encoding putative non-canonical two-subunit RNAP. Here, we describe the architecture and identify the evolutionary origin of this transcription machinery. We show that the two RNAP subunits interact in vivo, and this complex interacts with another two VLE-encoded proteins, namely the mRNA capping enzyme and a putative helicase. RNAP, mRNA capping enzyme and the helicase also interact with VLE-specific DNA in vivo. Further, we identify a promoter sequence element that causes 5' mRNA polyadenylation of VLE-specific transcripts via RNAP slippage at the transcription initiation site, and structural elements that precede the termination sites. As a result, we present a first model of the yeast virus-like element transcription initiation and intrinsic termination. Finally, we demonstrate that VLE RNAP and its promoters display high similarity to poxviral RNAP and promoters of early poxviral genes, respectively, thereby pointing to their evolutionary origin.

Refined Pichia pastoris reference genome sequence

Strains of the species Komagataella phaffii are the most frequently used "Pichia pastoris" strains employed for recombinant protein production as well as studies on peroxisome biogenesis, autophagy and secretory pathway analyses. Genome sequencing of several different P. pastoris strains has provided the foundation for understanding these cellular functions in recent genomics, transcriptomics and proteomics experiments. This experimentation has identified mistakes, gaps and incorrectly annotated open reading frames in the previously published draft genome sequences. Here, a refined reference genome is presented, generated with genome and transcriptome sequencing data from multiple P. pastoris strains. Twelve major sequence gaps from 20 to 6000 base pairs were closed and 5111 out of 5256 putative open reading frames were manually curated and confirmed by RNA-seq and published LC-MS/MS data, including the addition of new open reading frames (ORFs) and a reduction in the number of spliced genes from 797 to 571. One chromosomal fragment of 76kbp between two previous gaps on chromosome 1 and another 134kbp fragment at the end of chromosome 4, as well as several shorter fragments needed re-orientation. In total more than 500 positions in the genome have been corrected. This reference genome is presented with new chromosomal numbering, positioning ribosomal repeats at the distal ends of the four chromosomes, and includes predicted chromosomal centromeres as well as the sequence of two linear cytoplasmic plasmids of 13.1 and 9.5kbp found in some strains of P. pastoris.

Autoselection of cytoplasmic yeast virus like elements encoding toxin/antitoxin systems involves a nuclear barrier for immunity gene expression

Cytoplasmic virus like elements (VLEs) from Kluyveromyces lactis (Kl), Pichia acaciae (Pa) and Debaryomyces robertsiae (Dr) are extremely A/T-rich (>75%) and encode toxic anticodon nucleases (ACNases) along with specific immunity proteins. Here we show that nuclear, not cytoplasmic expression of either immunity gene (PaORF4, KlORF3 or DrORF5) results in transcript fragmentation and is insufficient to establish immunity to the cognate ACNase. Since rapid amplification of 3' ends (RACE) as well as linker ligation of immunity transcripts expressed in the nucleus revealed polyadenylation to occur along with fragmentation, ORF-internal poly(A) site cleavage due to the high A/T content is likely to prevent functional expression of the immunity genes. Consistently, lowering the A/T content of PaORF4 to 55% and KlORF3 to 46% by gene synthesis entirely prevented transcript cleavage and permitted functional nuclear expression leading to full immunity against the respective ACNase toxin. Consistent with a specific adaptation of the immunity proteins to the cognate ACNases, cross-immunity to non-cognate ACNases is neither conferred by PaOrf4 nor KlOrf3. Thus, the high A/T content of cytoplasmic VLEs minimizes the potential of functional nuclear recruitment of VLE encoded genes, in particular those involved in autoselection of the VLEs via a toxin/antitoxin principle.

The rather wide-spread and extremely A/T rich yeast virus like elements (VLEs, also termed linear plasmids) which encode toxic anticodon nucleases (ACNases) ensure autoselection in the cytoplasm by preventing functional nuclear capture of the cognate immunity genes, but how? When expressed in the nucleus, the mRNA of the VLE immunity genes is split into fragments to which poly(A) tails are added. Consistently, lowering the A/T content by gene synthesis prevented transcript cleavage and permitted functional nuclear expression providing full immunity against the respective ACNase toxin. Thus, internal poly(A) cleavage is likely to prevent functional nuclear immunity gene expression.

Site-directed mutagenesis of the heterotrimeric killer toxin zymocin identifies residues required for early steps in toxin action

Zymocin is a Kluyveromyces lactis protein toxin composed of αβγ subunits encoded by the cytoplasmic virus-like element k1 and functions by αβ-assisted delivery of the anticodon nuclease (ACNase) γ into target cells. The toxin binds to cells' chitin and exhibits chitinase activity in vitro that might be important during γ import. Saccharomyces cerevisiae strains carrying k1-derived hybrid elements deficient in either αβ (k1ORF2) or γ (k1ORF4) were generated. Loss of either gene abrogates toxicity, and unexpectedly, Orf2 secretion depends on Orf4 cosecretion. Functional zymocin assembly can be restored by nuclear expression of k1ORF2 or k1ORF4, providing an opportunity to conduct site-directed mutagenesis of holozymocin. Complementation required active site residues of α's chitinase domain and the sole cysteine residue of β (Cys250). Since βγ are reportedly disulfide linked, the requirement for the conserved γ C231 was probed. Toxicity of intracellularly expressed γ C231A indicated no major defect in ACNase activity, while complementation of k1ΔORF4 by γ C231A was lost, consistent with a role of β C250 and γ C231 in zymocin assembly. To test the capability of αβ to carry alternative cargos, the heterologous ACNase from Pichia acaciae (P. acaciae Orf2 [PaOrf2]) was expressed, along with its immunity gene, in k1ΔORF4. While efficient secretion of PaOrf2 was detected, suppression of the k1ΔORF4-derived k1Orf2 secretion defect was not observed. Thus, the dependency of k1Orf2 on k1Orf4 cosecretion needs to be overcome prior to studying αβ's capability to deliver other cargo proteins into target cells.

Anticodon nuclease encoding virus-like elements in yeast

A variety of yeast species are known to host systems of cytoplasmic linear dsDNA molecules that establish replication and transcription independent of the nucleus via self-encoded enzymes that are phylogenetically related to those encoded by true infective viruses. Such yeast virus-like elements (VLE) fall into two categories: autonomous VLEs encode all the essential functions for their inheritance, and additional, dependent VLEs, which may encode a toxin-antitoxin system, generally referred to as killer toxin and immunity. In the two cases studied in depth, killer toxin action relies on chitin binding and hydrophobic domains, together allowing a separate toxic subunit to sneak into the target cell. Mechanistically, the latter sabotages codon-anticodon interaction by endonucleolytic cleavage of specific tRNAs 3' of the wobble nucleotide. This primary action provokes a number of downstream effects, including DNA damage accumulation, which contribute to the cell-killing efficiency and highlight the importance of proper transcript decoding capacity for other cellular processes than translation itself. Since wobble uridine modifications are crucial for efficient anticodon nuclease (ACNase) action of yeast killer toxins, the latter are valuable tools for the characterization of a surprisingly complex network regulating the addition of wobble base modifications in tRNA.

Repeated capture of a cytoplasmic linear plasmid by the host nucleus in Debaryomyces hansenii

Debaryomyces hansenii is a halotolerant yeast species that has been shown to carry various nuclear genes of plasmid or viral origin (NUPAVs). However, a recent ancestor of such NUPAVs has not been identified. Here we determined for the first time the molecular structure of an entire cytoplasmic linear plasmid, pDH1A, indigenous to this species. The element is related to non-autonomous killer plasmids from Kluyveromyces lactis and Pichia acaciae and carries a B-type DNA polymerase as well as remnants of a killer toxin system, a secreted chitin-binding protein. Other essential toxin subunits or an immunity function, however, appear to be lost, while two additional small open reading frames are present. Transcripts for all four genes located on pDH1A could be verified by RT-PCR. Interestingly, all genes from pDH1A could be identified as ancestors of NUPAVs located at different chromosomes within the nucleus of D. hansenii, suggesting repeated nuclear capture of fragments originating from pDH1A.

Pichia acaciae killer system: genetic analysis of toxin immunity

The gene responsible for self-protection in the Pichia acaciae killer plasmid system was identified by heterologous expression in Saccharomyces cerevisiae. Resistance profiling and conditional toxin/immunity coexpression analysis revealed dose-independent protection by pPac1-2 ORF4 and intracellular interference with toxin function, suggesting toxin reinternalization in immune killer cells.

Autonomous cytoplasmic linear plasmid pPac1-1 of Pichia acaciae: molecular structure and expression studies

The genome organization of the linear DNA-element pPac1-1 from Pichia acaciae was determined. It turned out to be the smallest autonomous cytoplasmic yeast plasmid known so far, consisting of only 12 646 bp, carrying the shortest terminal inverted repeats yet found (138 bp). As for other cytoplasmic linear yeast plasmids, it is characterized by a strikingly high A + T content (75.35%). Ten putative genes (open reading frames, ORFs) reside on the element, leaving only 2.9% of the sequence outside a coding region. Highest similarities of the predicted proteins were obtained for proteins encoded by the three hitherto known autonomous cytoplasmic linear yeast plasmids. Amino acid sequences correspond to predicted polypeptides encoded by ORFs 2-11 of the linear plasmids pGKL2 of Kluyveromyces lactis, pSKL of Saccharomyces kluyveri and pPE1B of Pichia etchellsii. As for the latter, ORF1 existing on the two other plasmids is lacking on pPac1-1. Consistent with cytoplasmic localization, a cytoplasmic promoter termed upstream conserved sequence (UCS) is located in front of each reading frame. RT-PCR transcript analyses for ORFs 8, 9 and 11 proved expression of such genes but functions could not be attributed. The genome organization of pPac1-1 and other autonomous linear elements was found to be almost congruent, irrespective of the accompanying smaller elements, which may or may not encode their own element-specific DNA polymerases.

Yeast autonomous linear plasmid pGKL2: ORF9 is an actively transcribed essential gene with multiple transcription start points

A pair of linear plasmids, pGKL1 (8.9 kb) and pGKL2 (13.4 kb), resides in the cytoplasm of Kluyveromyces lactis killer strains. The smaller element, actually conferring the killer phenotype, strictly depends on the larger autonomous pGKL2. Here, we have examined the previously uncharacterized pGKL2 open reading frame (ORF)9 (1.34 kb). Northern analysis of a killer plasmid carrying Saccharomyces cerevisiae strain applying an ORF9-specific probe revealed a single transcript closely matching the size of the ORF9 coding region. Multiple transcriptional start points, determined by primer extension analysis, are located 16 nt downstream of a conserved sequence element regarded as the cytoplasmic promoter. In vivo disruption of pGKL2/ORF9 using the cytoplasmically expressible marker-gene LEU2* resulted in the establishment of a three-plasmid system composed of the native cytoplasmic elements pGKL1/2 and a hybrid of the latter, which only remained stable under selective conditions. The native pGKL2, however, did not segregate during prolonged subcultivations, proving an essential function of ORF9 for plasmid maintenance.

Novel yeast killer toxins provoke S-phase arrest and DNA damage checkpoint activation‡

Certain strains of Pichia acaciae and Wingea robertsiae (synonym Debaryomyces robertsiae) harbour extranuclear genetic elements that confer a killer phenotype to their host. Such killer plasmids (pPac1-2 of P. acaciae and pWR1A of W. robertsiae) were sequenced and compared with the zymocin encoding pGKL1 of Kluyveromyces lactis. Both new elements were found to be closely related to each other, but they are only partly similar to pGKL1. As for the latter, they encode functions mediating binding of the toxin to the target cell's chitin and a hydrophobic region potentially involved in uptake of a toxin subunit by target cells. Consistently, mutations affecting the target cell's major chitin synthase (Chs3) protect it from toxin action. Heterologous intracellular expression of respective open reading frames identified cell cycle-arresting toxin subunits deviating structurally from the likewise imported gamma-subunit of the K. lactis zymocin. Accordingly, toxicity of both P. acaciae and Wingea toxins was shown to be independent of RNA polymerase II Elongator, which is indispensable for zymocin action. Thus, P. acaciae and Wingea toxins differ in their mode of action from the G1-arresting zymocin. Fluorescence-activated cell sorting analysis and determination of budding indices have proved that such novel toxins mediate cell cycle arrest post-G1 during the S phase. Concomitantly, the DNA damage checkpoint kinase Rad53 is phosphorylated. As a mutant carrying the checkpoint-deficient allele rad53-11 displays toxin hypersensitivity, damage checkpoint activation apparently contributes to coping with toxin stress, rather than being functionally implemented in toxin action.

Structural and functional analysis of the killer element pPin1-3 from Pichia inositovora

Strains of the yeast Pichia inositovora that carry the linear plasmids pPin1-1 (18 kb) and pPin1-3 (10 kb) display a killer activity towards Saccharomyces cerevisiae. Cloning and sequencing of the smaller plasmid, pPin1-3, revealed that it is 9683 bp long and has 154-bp terminal inverted repeats. Comparison of pPin1-3 with the only other completely sequenced killer plasmid, pGKL1 of Kluyveromyces lactis, revealed differences in genome organization. The Pichia element has four ORFs that account for 95% of the sequence. ORF1 is homologous to the putative immunity gene of the K. lactis system. A viral B-type DNA polymerase is encoded by ORF2. The predicted product of ORF3 displays similarities to the alpha- and beta-subunits of the heterotrimeric K. lactis killer toxin, also known as zymocin. A cysteine-rich chitin-binding site and a chitinase signature, characteristic for the alpha-subunit of zymocin were identified in Orf3p. Chitin affinity chromatography and Western analysis confirmed the plasmid specific expression and secretion of a protein that cross-reacts with an antibody raised against the alpha-subunit of K. lactis zymocin. Disruption of the major chitin synthase-gene ( CHS3) renders S. cerevisiae resistant to the toxin, providing further evidence that chitin is the cellular receptor for the P. inositovora toxin. Orf4p of pPin1-3 displays only weak similarities to the gamma-subunit of zymocin, which causes a G1 cell-cycle arrest in S. cerevisiae. However, disruption of the S. cerevisiae gene ELP3/TOT3, which encodes a histone-acetyltransferase that is essential for zymocin action, resulted in reduced sensitivity to the P. inositovora toxin also. Thus, despite obvious differences in genome organization and protein architecture, both killer systems very probably have similar modes of action.

Linear plasmids pWR1A and pWR1B of the yeast Wingea robertsiae are associated with a killer phenotype

Wingea robertsiae CBS6693 (synonym Debaryomyces robertsiae) was previously reported to harbor two cryptic linear plasmids, designated pWR1A (8.3 kb) and pWR1B (14.6 kb). Reexamination of a putative plasmid encoded killer phenotype involved UV-curing as well as a highly sensitive toxin assay. Killer activities of concentrated culture supernatants prepared from both, a plasmid carrying and a cured plasmid-free strain, were examined in liquid media. Supernatants collected from plasmid carrying strains subjected to cultures of the plasmid-free derivative had clear concentration-dependent inhibitory effects, whereas plasmid harboring cells were not affected. Incubation at 65 degrees C for 10 min totally destroyed the toxin. Since supernatants prepared from the plasmid-free strain did not possess such killer activity and the presence of the plasmids confered resistance, toxin as well as immunity functions appear plasmid encoded. Beyond this, chitin affinity chromatography and Western blot analysis proved plasmid specific expression and secretion of a protein displaying similarities to the alpha-subunit of the Kluyveromyces lactis killer toxin. The assay applied in this study will most probably allow disclosure of other hidden killer phenomena, which may have escaped detection by conventionally applied plate assays.

Replication of a linear mini-chromosome with terminal inverted repeats from the Kluyveromyces lactis linear DNA plasmid k2 in the cytoplasm of Saccharomyces cerevisiae

The k1 and k2 linear DNA plasmids of Kluveromyces lactis replicate in the cytoplasm under the control of plasmid-encoded genes. These plasmids can also replicate autonomously in the cytoplasm of mitochondrial DNA-deficient strains of Saccharomyces cerevisiae. Essential for replication are plasmid-specific terminal inverted repeats (TIRs) to which a terminal protein (TP) is attached at the 5' ends. A plasmid was constructed with k2 TIRs in opposite orientations and with a selectable marker (URA3) under the control of k1UCS2 (upstream conserved sequence 2, the promoter of k1 open reading frame 2) in between the TIRs. Transformation of k1- and k2-containing S. cerevisiae with a fragment generated by releasing the TIR-flanked fragment from the plasmid by restriction digestion was very efficient, despite the absence of a TP. Transformation was also achieved with a fragment generated by PCR. Southern blotting demonstrated that transformants contained multiple copies of DNA fragments with the same size as the transforming DNA, supporting the hypothesis that these were replicating linear mini-chromosomes. The high frequency of transformation strongly suggests that these mini-chromosomes readily replicate supported by k2. Derivatives with a heterologous gene, firefly luciferase (LUC), expressed luciferase at high levels provided the gene was adjacent to a cytoplasmic plasmid promoter (k2UCS5).

Genome organization of the linear Pichia etchellsii plasmid pPE1A: evidence for expression of an extracellular chitin-binding protein homologous to the alpha-subunit of the Kluyveromyces lactis killer toxin

Pichia etchellsii CBS2011 (synonym Debaryomyces etchellsii) is a non-killer yeast harbouring two cryptic linear cytoplasmic DNA-elements, pPE1A (6.7 kb) and pPE1B (12.8 kb). Cloning and complete sequencing of pPE1A revealed a 6749-bp element with a remarkably high A+T content of 77.6%. The termini of pPE1A were found to consist of inversely orientated identical nucleotide repetitions of 178bp, to which proteins are linked at the 5'-ends. It is only the second small, non-autonomous cytoplasmic yeast linear plasmid for which the complete nucleotide sequence is known. Five open reading frames (ORFs) were identified preceded by upstream conserved sequence motifs (UCS) characteristic for cytoplasmic promoters and perfectly matching the UCS consensus (ATNTGA). As none of the putative genes encodes a DNA-polymerase, pPE1A is the first yeast linear plasmid known that does not possess its own element-specific replication machinery. No function could be attributed to ORF1, 3, 4, and 5; the predicted ORF2 gene product is similar to chitin-binding proteins and chitinases, highest homologies were found to the precursor of the alpha- and beta-subunits of the secreted Kluyveromyces lactis zymocin. Consistently, the Orf2p could be isolated from the culture fluid by chitin-Sepharose affinity chromatography and characterized by immuno-probing with an antibody specific for the K. lactis killer toxin alpha-subunit. Production of the protein was found to be plasmid-dependent. The sequence of pPE1A has been submitted to the EMBL data library, Accession No. AJ409097.

Genome organization of the linear cytoplasmic element pPE1B from Pichia etchellsii

The linear cytoplasmic element pPE1B from Pichia etchellsii CBS2011 (synonym Debaryomyces etchellsii) was totally sequenced. It consists of 12835 bp and has a remarkable high A+T content of 77.3%. The termini of pPE1B were found to consist of inversely orientated identical nucleotide repetitions 161 base pairs long, to which proteins are probably covalently linked at the 5' ends. Ten putative genes (open reading frames, ORFs) were identified, covering 96.5% of the total sequence. The predicted polypeptides correspond to proteins encoded by ORFs 2-11 of the linear plasmids pGKL2 of Kluyveromyces lactis and pSKL of Saccharomyces kluyveri. ORF1, existing on both latter elements, is lacking on pPE1B. An upstream conserved sequence motif (UCS) is located at the expected distance from the start codon of each of the 10 ORFs. As the arbitrarily chosen UCS6 was able to drive expression of a reporter gene in the heterologous pGKL-encoded killer system of K. lactis, extranuclear promoter function is probable. The almost congruent genome organization of pPE1B and other autonomous linear yeast plasmids sequenced so far, i.e. pGKL2 and pSKL, suggests a common, presumably viral, ancestor.

Kluyveromyces lactis cytoplasmic plasmid pGKL2: heterologous expression of Orf3p and proof of guanylyltransferase and mRNA-triphosphatase activities

The predicted ORF3 polypeptide (Orf3p) of the linear genetic element pGKL2 from Kluyveromyces lactis was expressed in Bacillus megaterium as a fusion protein with a His(6X)-tag at the C-terminus for isolation by Ni-affinity chromatography. This is the first time that a yeast cytoplasmic gene product has been expressed heterologously as a functional protein in a bacterial system. The purified protein was found to display both RNA 5'-triphosphatase and guanylyltransferase activities. When the lysine residue present at position 177 of the protein within the sequence motif (KXDG), highly conserved in capping enzymes and other nucleotidyl transferases, was substituted by alanine, the guanylyltransferase activity was lost, thereby proving an important role for the transfer of GMP from GTP to the 5'-diphosphate end of the mRNA. Our in vitro data provides the first direct evidence that the polypeptide encoded by ORF3 of the cytoplasmic yeast plasmid pGKL2 functions as a plasmid-specific capping enzyme. Since genes equivalent to ORF3 of pGKL2 have been identified in all autonomous cytoplasmic yeast DNA elements investigated so far, our findings are of general significance for these widely distributed yeast extranuclear genetic elements.

Genetics and molecular physiology of the yeast Kluyveromyces lactis

With the recent development of powerful molecular genetic tools, Kluyveromyces lactis has become an excellent alternative yeast model organism for studying the relationships between genetics and physiology. In particular, comparative yeast research has been providing insights into the strikingly different physiological strategies that are reflected by dominance of respiration over fermentation in K. lactis versus Saccharomyces cerevisiae. Other than S. cerevisiae, whose physiology is exceptionally affected by the so-called glucose effect, K. lactis is adapted to aerobiosis and its respiratory system does not underlie glucose repression. As a consequence, K. lactis has been successfully established in biomass-directed industrial applications and large-scale expression of biotechnically relevant gene products. In addition, K. lactis maintains species-specific phenomena such as the "DNA-killer system, " analyses of which are promising to extend our knowledge about microbial competition and the fundamentals of plasmid biology.

Use of gene shuffles to study the cytoplasmic transcription system operating on Kluyveromyces lactis linear DNA plasmids

A modified double selection approach for manipulation of the cytoplasmic plasmids k1 and k2 from dairy yeast Kluyveromyces lactis has been exploited to investigate promoter and gene function. Using TRP1-mediated integration of a LEU2 gene fusion, we have shown that expression of the selection marker is strictly dependent on the k2 promoter UCS5. Also, k2ORF6, the gene encoding the RNA polymerase specific for UCS recognition, is functional when shuffled between the plasmids. Once transplaced onto k1 by means of gene shuffling, the hybrid ORF6 complemented an orf6 deletion created on plasmid k2 eventually yielding yeast strains that contained only two recombinant plasmids: a k2 derivative (rk2/6) with a k2orf6::TRP1 gene deletion, and a k1 derivative (rk1/6) carrying the transplaced ORF6 allele along with the LEU2 marker. This interchangeability of both UCS promoter activity and gene function between k2 and k1 supports the concept of an autonomous transcription system that operates on these nonconventional yeast plasmids.

Genetic manipulation of Kluyveromyces lactis linear DNA plasmids: gene targeting and plasmid shuffles

Genetic manipulation of yeast linear DNA plasmids, particularly of k1 and k2 from the non-conventional dairy yeast Kluyveromyces lactis, has been advanced by the recent establishment of DNA transformation-mediated one-step gene disruption and allele replacement techniques. These methods provide the basis for a strategy for the functional analysis of plasmid genes and DNA elements. By use of double selection regimens, these single-gene procedures have been extended to effect disruption of individual genes on plasmid k2 and transplacement of a functional copy onto plasmid k1, resulting in the production of yeast strains with an altered plasmid composition. This cytoplasmic gene shuffle system facilitates the introduction of specifically modified alleles into k1 or k2 in order to study the function, expression (from UCS promoters) and regulation of cytoplasmic linear plasmid genes. Additionally, identification, characterization and localization of plasmid gene products of interest are made possible by shuffling GFP-, epitope- or affinity purification-tagged alleles between k2 and k1. The gene shuffle approach can also be used for vector development and heterologous protein expression in order to exploit the biotechnical potential of the K. lactis k1/k2 system in yeast cell factory research.

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.