Genetic transformation of Saccharomyces cerevisiae with single-stranded circular DNA vectors

We asked if single-stranded vector DNA molecules could be used to reintroduce cloned DNA sequences into a eukaryotic cell and cause genetic transformation typical of that observed using double-stranded DNA vectors. DNA was presented to Saccharomyces cerevisiae following a standard transformation protocol, genetic transformants were isolated, and the physical state of the transforming DNA sequence was determined. We found that single-stranded DNA molecules transformed yeast cells 10- to 30-fold more efficiently than double-stranded molecules of identical sequence. More cells were competent for transformation by the single-stranded molecules. Single-stranded circular (ssc) DNA molecules carrying the yeast 2 μ plasmid-replicator sequence were converted to autonomously replicating double-stranded circular (dsc) molecules, suggesting their efficient utilization as templates for DNA synthesis in the cell. Single-stranded DNA molecules carrying 2 μ plasmid non-replicator sequences recombined with the endogenous multicopy 2 μ plasmid DNA. This recombination yielded either the simple molecular adduct expected from homologous recombination (40% of the transformants examined) or aberrant recombination products carrying incomplete transforming DNA sequences, endogenous 2 μ plasmid DNA sequences, or both (60% of the transformants examined). These aberrant recombination products suggest the frequent use of a recombination pathway that trims one or both of the substrate DNA molecules. Similar aberrant recombination products were detected in 30% of the transformants in cotransformation experiments employing single-stranded and double-stranded DNA molecules, one carrying the 2 μ plasmid replicator sequence and the other the selectable genetic marker. We conclude that single-stranded DNA molecules are useful vectors for the genetic transformation of a eukaryotic cell. They offer the advantage of high transformation efficiency, and yield the same intracellular DNA species obtained upon transformation with double-stranded DNA molecules. In addition, single-stranded DNA molecules can participate in a recombination pathway that trims one or both DNA recombination substrates, a pathway not detected, at least at the same frequency, when transforming with double-stranded DNA molecules     

Ectopic Integration of Transforming DNA Is Rare among Neurospora Transformants Selected for Gene Replacement

In a variety of organisms, DNA-mediated transformation experiments commonly produce transformants with multiple copies of the transforming DNA, including both selected and unselected molecules. Such ``cotransformants' are much more common than expected from the individual transformation frequencies, suggesting that subpopulations of cells, or nuclei, are particularly competent for transformation. We found that Neurospora crassa transformants selected for gene replacement at the am gene had not efficiently incorporated additional DNA, suggesting that nuclei that undergo transformation by homologous recombination are not highly competent at integration of DNA by illegitimate recombination. Spheroplasts were treated with DNA fragments homologous to am and with an Escherichia coli hph plasmid. Transformants were initially selected for hph (hygromycin(R)), allowed to conidiate to generate homokaryons and then selected for either Am(-) (gene replacements) or hph. Surprisingly, most am replacement strains were hygromycin(S) (124/140) and carried no extraneous DNA (116/140). Most transformants selected for hph also had ectopic copies of am DNA and/or multiple copies of hph sequences (32/35), generally at multiple sites, confirming that efficient cotransformation could occur. To test the implication that cotransformation involving gene replacement and ectopic integration is rare, we compared the yields of am replacement strains with or without prior selection for hph. The initial selection did not appreciably help (or hinder) recovery of strains with replacements.     

Directed insertion of a selectable marker into a circular plasmid of Borrelia burgdorferi.

Studies of the biology of Borrelia burgdorferi and the pathogenesis of Lyme disease are severely limited by the current lack of genetic tools. As an initial step toward facile genetic manipulation of this pathogenic spirochete, we have investigated gene inactivation by allelic exchange using a mutated borrelial gyrB gene that confers resistance to the antibiotic coumermycin A1 as a selectable marker. We have transformed B. burgdorferi by electroporation with a linear fragment of DNA in which this selectable marker was flanked by sequences from a native borrelial 26-kb circular plasmid. We have identified coumermycin A1-resistant transformants in which gyrB had interrupted the targeted site on the 26-kb plasmid via homologous recombination with the flanking sequences. Antibiotic resistance conferred by the mutated gyrB gene on the plasmid is dominant, and transformed spirochetes carrying this plasmid do not contain any unaltered copies of the plasmid. Coumermycin A1 resistance can be transferred to naive B. burgdorferi by transformation with borrelial plasmid DNA from the initial transformants. This work represents the first example of a directed mutation in B. burgdorferi whereby a large segment of heterologous DNA (gyrB) has been inserted via homologous recombination with flanking sequences, thus demonstrating the feasibility of specific gene inactivation by allelic exchange.     

Nonreciprocal exchanges of information between DNA duplexes coinjected into mammalian cell nuclei.

We have examined the mechanism of homologous recombination between plasmid molecules coinjected into cultured mammalian cells. Cell lines containing recombinant DNA molecules were obtained by selecting for the reconstruction of a functional Neor gene from two plasmids that bear different amber mutations in the Neor gene. In addition, these plasmids contain restriction-length polymorphisms within and near the Neor gene. These polymorphisms did not confer a selectable phenotype but were used to identify and categorize selected and nonselected recombinant DNA molecules. The striking conclusion from this analysis is that the predominant mechanism for the exchange of information between coinjected plasmid molecules over short distances (i.e., less than 1 kilobase) proceeds via nonreciprocal homologous recombination. The frequency of homologous recombination between coinjected plasmid molecules in cultured mammalian cells is extremely high, approaching unity. We demonstrate that this high frequency requires neither a high input of plasmid molecules per cell nor a localized high concentration of plasmid DNA within the nucleus. Thus, it appears that plasmid molecules, once introduced into the nucleus, have no difficulty seeking each other out and participating in homologous recombination even in the presence of a vast excess of host DNA sequences. Finally, we show that most of the homologous recombination events occur within a 1-h interval after the introduction of plasmid DNA into the cell nucleus.     

Notes High-efficiency transformation system for the biocontrol agents, Trichoderma spp.

We have developed an efficient transformation system based on the use of polyethylene glycol and CaCl2 for the biocontrol agents, Trichoderma spp. Transformation was obtained with the plasmid pAN7-1, carrying a bacterial hygromycin-resistance gene as a selectable marker, under the control of Aspergillus nidulans heterologous expression signals. The system described here yielded 200-800 transformants per microgram of DNA. Transformants contained several copies of the plasmid integrated into their genome, apparently at the same site in the different transformants analysed. Stability of the transformants was achieved by inserting a 2.4kb homologous DNA fragment into pAN7-1. Southern blot analysis indicated that integration in the stable transformants occurs through non-homologous recombination.     

Homologous Recombination as the Main Mechanism for DNA Integration and Cause of Rearrangements in the Filamentous Ascomycete Ashbya Gossypii

A slow and a fast growth phenotype were observed after transformation of the phytopathogenic fungus Ashbya gossypii using a plasmid carrying homologous DNA and as selectable marker the Tn903 aminoglycoside resistance gene expressed from a strong A. gossypii promoter. Transformations with circular plasmids yielded slowly and irregularly growing geneticin-resistant mycelia in which 1% of nuclei contained plasmid sequences. Occasionally, fast growing sectors appeared which were shown to be initiated by homologous integration of the transforming DNA. Transformants obtained with plasmids linearized within the homology region immediately exhibited fast radial growth. In all 28 transformants analyzed plasmid DNA was integrated homologously. Such apparent lack of nonhomologous recombination has so far not been observed in filamentous ascomycetes. In 14 transformants two to four tandemly integrated plasmid copies were found. They underwent several types of genetic changes, mainly in the older mycelium: excision of whole plasmid copies and rearrangements within the integrated DNA (inversions and deletions). These internal rearrangements involved 360-bp inverted repeats, remnants of IS-elements flanking the resistance gene, and 156-bp direct repeats, originating from the strong A. gossypii promoter. Improved vectors lacking sequence repetitions were constructed and used for stable one-step gene replacement in A. gossypii.     

Persistence of freely replicating SV40 recombinant molecules carrying a selectable marker in permissive simian cells

We have demonstrated that a SV40-pBR322 recombinant vector (pSV2-gpt) carrying a bacterial gene of selectable phenotype (Eco-gpt) may persist extrachromosomally in COS1 cells, a simian cell line that endogenously produces SV40 large T antigen. The amount of circular (supercoiled) recombinant DNA was estimated to be between 5 and 2000 copies per cell among several pSV2-transformed COS1 clonal lines examined. Complete pSV2 molecules were found in the majority of the transformants, although some of the pSV2 DNAs recovered were shown to have deletions in the pBR322 region. Our results indicate that removal of the pBR322 "inhibitory sequence" in pSV2 is not necessary for stable maintenance of these recombinant molecules in COS1 cells. In addition, large amounts of pSV2-related high molecular weight DNAs, probably concatemers of pSV2, were detected in the transformed lines.     

Electric field-mediated gene transfer: characterization of DNA transfer and patterns of integration in lymphoid cells.

Southern analysis of individual transfectants generated by electroporation demonstrated a strong preference for the integration of DNA in low copy number even when electroporation was performed in the presence of increasing DNA concentrations. Although transfer of multiple DNA copies was detected at higher DNA concentrations (16 pmoles/ml or greater), the average gene copy number even at 36 pmoles DNA per ml, was only 13. Multiple gene copies were integrated at either a few chromosomal sites, or at a single site within individual transfectants. Restriction endonuclease cleavage data were consistent with a random orientation of molecules within a concatemer, suggesting that the concatemer may have risen via end-to-end ligation of linear molecules, rather than by homologous recombination. Integration of exogenous DNA into the host chromosome occurred preferentially at the ends of the linear molecule. Although the linearization site was lost upon integration, endonuclease sites as close as 18 bp from the linearization site were retained. These data, as well as direct restriction mapping of the transferred genes, indicate that DNA transfer and integration occur without DNA rearrangement. Taken together, these results suggest that electroporation may offer some unique advantages for the transfer of eukaryotic genes.     

Application of a ribosomal DNA integration vector in the construction of a brewer's yeast having alpha-acetolactate decarboxylase activity

An integration plasmid, pIARL28, containing the ribosomal DNA gene as a homologous recombination sequence was constructed for introduction of the alpha-acetolactate decarboxylase gene into brewer's yeast. The transformation efficiency of pIARL28 was 20- to 50-fold higher than those of the other YIp vectors, as yeast cells had approximately 140 copies of the ribosomal DNA gene. All transformants showed very high alpha-acetolactate decarboxylase activity due to the multiple integrated copies of the plasmid. The transformants were grown in nonselective conditions, and segregants which had maintained the alpha-acetolactate decarboxylase expression cassette but no other vector sequences were isolated. Southern analysis showed that these marker-excised segregants contained more than 20 copies of the alpha-acetolactate decarboxylase gene and were stably maintained under nonselective conditions. Fermentation tests confirmed that the diacetyl concentration was considerably reduced in wort fermented by these marker-excised segregants. The degree of reduction was related to the copy number of the alpha-acetolactate decarboxylase gene.     

Application of a ribosomal DNA integration vector in the construction of a brewer's yeast having alpha-acetolactate decarboxylase activity.

An integration plasmid, pIARL28, containing the ribosomal DNA gene as a homologous recombination sequence was constructed for introduction of the alpha-acetolactate decarboxylase gene into brewer's yeast. The transformation efficiency of pIARL28 was 20- to 50-fold higher than those of the other YIp vectors, as yeast cells had approximately 140 copies of the ribosomal DNA gene. All transformants showed very high alpha-acetolactate decarboxylase activity due to the multiple integrated copies of the plasmid. The transformants were grown in nonselective conditions, and segregants which had maintained the alpha-acetolactate decarboxylase expression cassette but no other vector sequences were isolated. Southern analysis showed that these marker-excised segregants contained more than 20 copies of the alpha-acetolactate decarboxylase gene and were stably maintained under nonselective conditions. Fermentation tests confirmed that the diacetyl concentration was considerably reduced in wort fermented by these marker-excised segregants. The degree of reduction was related to the copy number of the alpha-acetolactate decarboxylase gene.     

A model for integration of DNA into the genome during transformation of Fusarium graminearum

Transformants of Fusarium graminearum were derived using linearized DNA of plasmids designed to replace the trichodiene synthase gene, a cutinase gene or a xylanase gene with a hygromycin-resistance marker cassette by homologous recombination between 1-kbp segments of flanking DNA. Most transformants did not exhibit the DNA structure expected of integration by classical double recombination. Instead, they contained linearized plasmid joined end-to-end and variably incorporated into the genome. Transformant types included ectopic integrations and integrations at the target site with or without removal of the targeted gene. We have analyzed a large number of transformants using cloning, PCR and DNA sequencing to determine the structures of their integrated DNA, and describe a model to explain their derivations. The data indicate that 1-3 copies of input DNA are first joined end-to-end to produce either linear or circular structures, probably mediated by the non-homologous end-joining (NHEJ) system. The end-joins typically have 1-5 nucleotides in common and are near or within the original cleavage site of the plasmid. Ectopic integrations occur by attaching linear DNA to two ends of genomic DNA via the same joining mechanism. Integration at the target site is consistent with replication around circularized input DNA, beginning and ending within the flanking homologous DNA, resulting in the integration of multiple copies of the entire structure. This results in deletion or duplication of the target site, or leaves one copy at either end of the integrated multimer. Reiterated DNA in the more complex structures is unstable due to homologous recombination, such that conversion to simpler forms is detected.     

Synapsis-Mediated Fusion of Free DNA Ends Forms Inverted Dimer Plasmids in Yeast

When yeast (Saccharomyces cerevisiae) is transformed with linearized plasmid DNA and the ends of the plasmid do not share homology with the yeast genome, circular inverted (head-to-head) dimer plasmids are the principal product of repair. By measurements of the DNA concentration dependence of transformation with a linearized plasmid, and by transformation with mixtures of genetically marked plasmids, we show that two plasmid molecules are required to form an inverted dimer plasmid. Several observations suggest that homologous pairing accounts for the head-to-head joining of the two plasmid molecules. First, an enhanced frequency of homologous recombination is detected when genetically marked plasmids undergo end-to-end fusion. Second, when a plasmid is linearized within an inverted repeat, such that its ends could undergo head-to-tail homologous pairing, it is repaired by intramolecular head-to-tail joining. Last, in the joining of homologous linearized plasmids of different length, a shorter molecule can acquire a longer plasmid end by homologous recombination. The formation of inverted dimer plasmids may be related to some forms of chromosomal rearrangement. These might include the fusion of broken sister chromatids in the bridge-breakage-fusion cycle and the head-to-head duplication of genomic DNA at the sites of gene amplifications.     

DNA recombination-initiation plays a role in the extremely biased inheritance of yeast [rho-] mitochondrial DNA that contains the replication origin ori5

Hypersuppressiveness, as observed in Saccharomyces cerevisiae, is an extremely biased inheritance of a small mitochondrial DNA (mtDNA) fragment that contains a replication origin (HS [rho(-)] mtDNA). Our previous studies showed that concatemers (linear head-to-tail multimers) are obligatory intermediates for mtDNA partitioning and are primarily formed by rolling-circle replication mediated by Mhr1, a protein required for homologous mtDNA recombination. In this study, we found that Mhr1 is required for the hypersuppressiveness of HS [ori5] [rho(-)] mtDNA harboring ori5, one of the replication origins of normal ([rho(+)]) mtDNA. In addition, we detected an Ntg1-stimulated double-strand break at the ori5 locus. Purified Ntg1, a base excision repair enzyme, introduced a double-stranded break by itself into HS [ori5] [rho(-)] mtDNA at ori5 isolated from yeast cells. Both hypersuppressiveness and concatemer formation of HS [ori5] [rho(-)] mtDNA are simultaneously suppressed by the ntg1 null mutation. These results support a model in which, like homologous recombination, rolling-circle HS [ori5] [rho(-)] mtDNA replication is initiated by double-stranded breakage in ori5, followed by Mhr1-mediated homologous pairing of the processed nascent DNA ends with circular mtDNA. The hypersuppressiveness of HS [ori5] [rho(-)] mtDNA depends on a replication advantage furnished by the higher density of ori5 sequences and on a segregation advantage furnished by the higher genome copy number on transmitted concatemers.     

Chromosomal targeting of replicating plasmids in the yeast Hansenula polymorpha.

Using an optimized transformation protocol we have studied the possible interactions between transforming plasmid DNA and the Hansenula polymorpha genome. Plasmids consisting only of a pBR322 replicon, an antibiotic resistance marker for Escherichia coli and the Saccharomyces cerevisiae LEU2 gene were shown to replicate autonomously in the yeast at an approximate copy number of 6 (copies per genome equivalent). This autonomous behaviour is probably due to an H. polymorpha replicon-like sequence present on the S. cerevisiae LEU2 gene fragment. Plasmids replicated as multimers consisting of monomers connected in a head-to-tail configuration. Two out of nine transformants analysed appeared to contain plasmid multimers in which one of the monomers contained a deletion. Plasmids containing internal or flanking regions of the genomic alcohol oxidase gene were shown to integrate by homologous single or double cross-over recombination. Both single- and multi-copy (two or three) tandem integrations were observed. Targeted integration occurred in 1-22% of the cases and was only observed with plasmids linearized within the genomic sequences, indicating that homologous linear ends are recombinogenic in H. polymorpha. In the cases in which no targeted integration occurred, double-strand breaks were efficiently repaired in a homology-independent way. Repair of double-strand breaks was precise in 50-68% of the cases. Linearization within homologous as well as nonhomologous plasmid regions stimulated transformation frequencies up to 15-fold.     

Pathways of Transformation in Ustilago Maydis Determined by DNA Conformation

Ustilago maydis was transformed by plasmids bearing a cloned, selectable gene but lacking an autonomously replicating sequence. Transformation was primarily through integration at nonhomologous loci when the plasmid DNA was circular. When the DNA was made linear by cleavage within the cloned gene, the spectrum of integration events shifted from random to targeted recombination at the resident chromosomal allele. In a large fraction of the transformants obtained using linear DNA, the plasmid DNA was not integrated but was maintained in an extrachromosomal state composed of a concatameric array of plasmid units joined end-to-end. The results suggest the operation of several pathways for transformation in U. maydis, and that DNA conformation at the time of transformation governs choice of pathways.     

Intramolecular homologous recombination in cells infected with temperature-sensitive mutants of vaccinia virus.

I have used a plasmid containing two copies of the Saccharmyces cerevisiae his3 gene to study intramolecular homologous recombination in vaccina virus-infected cells. Recombination of the plasmid was monitored by restriction enzyme digestion and Southern blot hybridization in cells infected with representatives from each of 32 complementation groups of temperature-sensitive mutants ts42 and ts17 did not replicate nor detectably recombine the input plasmid. All except one of the mutants that synthesized normal amounts of viral DNA and protein replicated and recombined the plasmid in a manner indistinguishable from wild-type virus. The remaining mutant, ts13, only poorly replicated and recombined the input plasmid. Thus, the processes of replication and recombination could not be separated by using this battery of mutants. Viral mutants defective in late protein synthesis were unable to resolve the vaccinia virus concatemer junction in plasmids but carried out intramolecular homologous recombination with plasmids as efficiently as did wild-type virus at the conditionally lethal temperature. This result distinguishes homologous recombination, which requires early gene products, from resolution of concatemer junctions, which requires additional late gene products.     

Transformation of Dictyostelium discoideum with plasmid DNA

DNA-mediated transformation is one of the most widely used techniques to study gene function. The eukaryote Dictyostelium discoideum is amenable to numerous genetic manipulations that require insertion of foreign DNA into cells. Here we describe two commonly used methods to transform Dictyostelium cells: calcium phosphate precipitation, resulting in high copy number transformants; and electroporation, an effective technique for producing single integration events into genomic DNA. Single integrations are required for gene disruption by homologous recombination. We also discuss how different selection markers affect vector copy number in transformants and explain why blasticidin has become the preferred selectable marker for making gene knockouts. Both procedures can be accomplished in less than 2 h of hands-on time; however, the calcium phosphate precipitation method contains several incubations, including one of at least 4 h, so the total time required for the transformation is approximately 8 h.     

Bacteriophage T7 DNA packaging. I. Plasmids containing a T7 replication origin and the T7 concatemer junction are packaged into transducing particles during phage infection

Bacteriophage T7 DNA is a linear duplex molecule with a 160 base-pair direct repeat (terminal redundancy) at its ends. During replication, large DNA concatemers are formed, which are multimers of the T7 genome linked head to tail through recombination at the terminal redundancy. We define the sequence that results from this recombination, a mature right end joined to the left end of T7 DNA, as the concatemer junction. To study the processing and packaging of T7 concatemers into phage particles, we have cloned the T7 concatemer junction into a plasmid vector. This plasmid is efficiently (at least 15 particles/infected cell) packaged into transducing particles during a T7 infection. These transducing particles can be separated from T7 phage by sedimentation to equilibrium in CsCl. The packaged plasmid DNA is a linear concatemer of about 40 x 10(3) base-pairs with ends at the expected T7 DNA sequences. Thus, the T7 concatemer junction sequence on the plasmid is recognized for processing and packaging by the phage system. We have identified a T7 DNA replication origin near the right end of the T7 genome that is necessary for efficient plasmid packaging. The origin, which is associated with a T7 RNA polymerase promoter, causes amplification of the plasmid DNA during T7 infection. The amplified plasmid DNA sediments very rapidly and contains large concatemers, which are expected to be good substrates for the packaging reaction. When cloned in pBR322, a sequence containing only the mature right end of T7 DNA is sufficient for efficient packaging. Since this sequence does not contain DNA to the right of the site where a mature T7 right end is formed, it was expected that right ends would not form on this DNA. In fact, with this plasmid the right end does not form at the normal T7 sequence but is instead formed within the vector. Apparently, the T7 packaging system can also recognize a site in pBR322 DNA to produce an end for packaging. This site is not recognized solely by a "headful" mechanism, since there can be considerable variation in the amount of DNA packaged (32 x 10(3) to 42 x 10(3) base-pairs). Furthermore, deletion of this region from the vector DNA prevents packaging of the plasmid. The end that is formed in vector DNA is somewhat heterogeneous. About one-third of the ends are at a unique site (nucleotide 1712 of pBR322), which is followed by the sequence 5'-ATCTGT-3'. This sequence is also found adjacent to the cut made in a T7 DNA concatemer to produce a normal T7 right end.