High-resolution genetic analysis of the requirements for horizontal transmission of the ESBL plasmid from Escherichia coli O104:H4

Horizontal dissemination of the genes encoding extended spectrum beta-lactamases (ESBLs) via conjugative plasmids is facilitating the increasingly widespread resistance of pathogens to beta-lactam antibiotics. However, there is relatively little known about the regulatory factors and mechanisms that govern the spread of these plasmids. Here, we carried out a high-throughput, transposon insertion site sequencing analysis (TnSeq) to identify genes that enable the maintenance and transmission of pESBL, an R64 (IncI1)-related resistance plasmid that was isolated from Escherichia coli O104:H4 linked to a recent large outbreak of gastroenteritis. With a few exceptions, the majority of the genes identified as required for maintenance and transmission of pESBL matched those of their previously defined R64 counterparts. However, our analyses of the high-density transposon insertion library in pESBL also revealed two very short and linked regions that constitute a previously unrecognized regulatory system controlling spread of IncI1 plasmids. In addition, we investigated the function of the pESBL-encoded M.EcoGIX methyltransferase, which is also encoded by many other IncI1 and IncF plasmids. This enzyme proved to protect pESBL from restriction in new hosts, suggesting it aids in expanding the plasmid''s host range. Collectively, our work illustrates the power of the TnSeq approach to enable rapid and comprehensive analyses of plasmid genes and sequences that facilitate the dissemination of determinants of antibiotic resistance.     

The genome of Burkholderia cenocepacia J2315, an epidemic pathogen of cystic fibrosis patients

Bacterial infections of the lungs of cystic fibrosis (CF) patients cause major complications in the treatment of this common genetic disease. Burkholderia cenocepacia infection is particularly problematic since this organism has high levels of antibiotic resistance, making it difficult to eradicate; the resulting chronic infections are associated with severe declines in lung function and increased mortality rates. B. cenocepacia strain J2315 was isolated from a CF patient and is a member of the epidemic ET12 lineage that originated in Canada or the United Kingdom and spread to Europe. The 8.06-Mb genome of this highly transmissible pathogen comprises three circular chromosomes and a plasmid and encodes a broad array of functions typical of this metabolically versatile genus, as well as numerous virulence and drug resistance functions. Although B. cenocepacia strains can be isolated from soil and can be pathogenic to both plants and man, J2315 is representative of a lineage of B. cenocepacia rarely isolated from the environment and which spreads between CF patients. Comparative analysis revealed that ca. 21% of the genome is unique in comparison to other strains of B. cenocepacia, highlighting the genomic plasticity of this species. Pseudogenes in virulence determinants suggest that the pathogenic response of J2315 may have been recently selected to promote persistence in the CF lung. The J2315 genome contains evidence that its unique and highly adapted genetic content has played a significant role in its success as an epidemic CF pathogen.     

Comparative Metabolic Systems Analysis of Pathogenic Burkholderia

Burkholderia cenocepacia and Burkholderia multivorans are opportunistic drug-resistant pathogens that account for the majority of Burkholderia cepacia complex infections in cystic fibrosis patients and also infect other immunocompromised individuals. While they share similar genetic compositions, B. cenocepacia and B. multivorans exhibit important differences in pathogenesis. We have developed reconciled genome-scale metabolic network reconstructions of B. cenocepacia J2315 and B. multivorans ATCC 17616 in parallel (designated iPY1537 and iJB1411, respectively) to compare metabolic abilities and contextualize genetic differences between species. The reconstructions capture the metabolic functions of the two species and give insight into similarities and differences in their virulence and growth capabilities. The two reconstructions have 1,437 reactions in common, and iPY1537 and iJB1411 have 67 and 36 metabolic reactions unique to each, respectively. After curating the extensive reservoir of metabolic genes in Burkholderia, we identified 6 genes essential to growth that are unique to iPY1513 and 13 genes uniquely essential to iJB1411. The reconstructions were refined and validated by comparing in silico growth predictions to in vitro growth capabilities of B. cenocepacia J2315, B. cenocepacia K56-2, and B. multivorans ATCC 17616 on 104 carbon sources. Overall, we identified functional pathways that indicate B. cenocepacia can produce a wider array of virulence factors compared to B. multivorans, which supports the clinical observation that B. cenocepacia is more virulent than B. multivorans. The reconciled reconstructions provide a framework for generating and testing hypotheses on the metabolic and virulence capabilities of these two related emerging pathogens.     

Multiple Orientation-Dependent, Synergistically Interacting, Similar Domains in the Ribosomal DNA Replication Origin of the Fission Yeast, Schizosaccharomyces pombe

Previous investigations have shown that the fission yeast, Schizosaccharomyces pombe, has DNA replication origins (500 to 1500 bp) that are larger than those in the budding yeast, Saccharomyces cerevisiae (100 to 150 bp). Deletion and linker substitution analyses of two fission yeast origins revealed that they contain multiple important regions with AT-rich asymmetric (abundant A residues in one strand and T residues in the complementary strand) sequence motifs. In this work we present the characterization of a third fission yeast replication origin, ars3001, which is relatively small (~570 bp) and responsible for replication of ribosomal DNA. Like previously studied fission yeast origins, ars3001 contains multiple important regions. The three most important of these regions resemble each other in several ways: each region is essential for origin function and is at least partially orientation dependent, each region contains similar clusters of A+T-rich asymmetric sequences, and the regions can partially substitute for each other. These observations suggest that ars3001 function requires synergistic interactions between domains binding similar proteins. It is likely that this requirement extends to other fission yeast origins, explaining why such origins are larger than those of budding yeast.     

Excess SeqA leads to replication arrest and a cell division defect in Vibrio cholerae

Although most bacteria contain a single circular chromosome, some have complex genomes, and all Vibrio species studied so far contain both a large and a small chromosome. In recent years, the divided genome of Vibrio cholerae has proven to be an interesting model system with both parallels to and novel features compared with the genome of Escherichia coli. While factors influencing the replication and segregation of both chromosomes have begun to be elucidated, much remains to be learned about the maintenance of this genome and of complex bacterial genomes generally. An important aspect of replicating any genome is the correct timing of initiation, without which organisms risk aneuploidy. During DNA replication in E. coli, newly replicated origins cannot immediately reinitiate because they undergo sequestration by the SeqA protein, which binds hemimethylated origin DNA. This DNA is already methylated by Dam on the template strand and later becomes fully methylated; aberrant amounts of Dam or the deletion of seqA leads to asynchronous replication. In our study, hemimethylated DNA was detected at both origins of V. cholerae, suggesting that these origins are also subject to sequestration. The overproduction of SeqA led to a loss of viability, the condensation of DNA, and a filamentous morphology. Cells with abnormal DNA content arose in the population, and replication was inhibited as determined by a reduced ratio of origin to terminus DNA in SeqA-overexpressing cells. Thus, excessive SeqA negatively affects replication in V. cholerae and prevents correct progression to downstream cell cycle events such as segregation and cell division.     

Efficient production of (R)-(−)-mandelic acid in biphasic system by immobilized recombinant E. coli

The recombinant Escherichia coli M15/BCJ2315 which harbored a mandelonitrilase from Burkholderia cenocepacia J2315 was immobilized via catecholic chitosan and functionalized with magnetism by iron oxide nanoparticles. The immobilized cells showed high activity recovery, enhanced stability and good operability in the enantioselective hydrolysis of mandelonitrile to (R)-(−)-mandelic acid. Furthermore, the immobilized cells were reused up to 15 cycles without any activity loss in completely hydrolyzing mandelonitrile (100 mM) within 1 h in aqueous solution. The ethyl acetate–water biphasic system was built and optimized. Under the optimal conditions, as high as 1 M mandelonitrile could be hydrolyzed within 4 h with a final yield and ee value of 99% and 95%, respectively. Moreover, the successive hydrolysis of mandelonitrile was performed by repeated use of the immobilized cells for 6 batches, giving a final productivity (g L⁻¹ h⁻¹) and relative production (g g⁻¹) of 40.9 and 38.9, respectively.     

Regulation of Hfq mRNA and Protein Levels in Escherichia coli and Pseudomonas aeruginosa by the Burkholderia cenocepacia MtvR sRNA

Small non-coding RNAs (sRNAs) are important players of gene expression regulation in bacterial pathogens. MtvR is a 136-nucleotide long sRNA previously identified in the human pathogen Burkholderia cenocepacia J2315 and with homologues restricted to bacteria of the Burkholderia cepacia complex. In this work we have investigated the effects of expressing MtvR in Escherichia coli and Pseudomonas aeruginosa. Results are presented showing that MtvR negatively regulates the hfq mRNA levels in both bacterial species. In the case of E. coli, this negative regulation is shown to involve binding of MtvR to the 5′-UTR region of the hfq_Ec mRNA. Results presented also show that expression of MtvR in E. coli and P. aeruginosa originates multiple phenotypes, including reduced resistance to selected stresses, biofilm formation ability, and increased susceptibility to various antibiotics.     

Replication of bacteriophage M13: XIII. Structure and replication of cloned M13 miniphage

Restriction analysis of the duplex replicative forms of four cloned M13 miniphage indicates that all species examined contain a single copy of the intergenic space between genes II and IV plus one or more copies of a portion of the genome extending from within gene IV to a site in the HaeIII G fragment within the intergenic space. Both the viral and the complementary strand origins of replication have been localized previously within the 160 base-pair HaeIII G fragment. Since reiteration of a portion of the HaeIII G fragment could possibly lead to phages having multiple copies of the origin of replication, we have determined the location of the viral strand origin-terminus in M13 miniphage by mapping the position of the discontinuity(ies) in mini-RFII³ molecules isolated during asymmetric viral strand synthesis. Limited repair of late life-cycle mini-RFII molecules with DNA polymerase I in the presence of labeled deoxynucleoside triphosphates followed by restriction analysis demonstrates that the discontinuity in the RFII is contained at a unique site within the single HaeIII G fragment. The absence of a discontinuity in the reiterated DNA sequence containing only a portion of the HaeIII G fragment indicates that the reiterations of the origin region do not include the entire sequence specifying the viral strand origin-terminus.     

Biochemical and Functional Studies on the Burkholderia cepacia Complex bceN Gene,Encoding a GDP-D-Mannose 4,6-Dehydratase

This work reports the biochemical and functional analysis of the Burkholderia cenocepacia J2315 bceN gene, encoding a protein with GDP-D-mannose 4,6-dehydratase enzyme activity (E.C.4.2.1.47). Data presented indicate that the protein is active when in the tetrameric form, catalyzing the conversion of GDP-D-mannose into GDP-4-keto-6-deoxy-D-mannose. This sugar nucleotide is the intermediary necessary for the biosynthesis of GDP-D-rhamnose, one of the sugar residues of cepacian, the major exopolysaccharide produced by environmental and human, animal and plant pathogenic isolates of the Burkholderia cepacia complex species. V_max and K_m values of 1.5±0.2 µmol.min⁻¹.mg⁻¹ and 1024±123 µM, respectively, were obtained from the kinetic characterization of the B. cenocepacia J2315 BceN protein by NMR spectroscopy, at 25°C and in the presence of 1 mol MgCl₂ per mol of protein. The enzyme activity was strongly inhibited by the substrate, with an estimated K_i of 2913±350 µM. The lack of a functional bceN gene in a mutant derived from B. cepacia IST408 slightly reduced cepacian production. However, in the B. multivorans ATCC17616 with bceN as the single gene in its genome with predicted GMD activity, a bceN mutant did not produce cepacian, indicating that this gene product is required for cepacian biosynthesis.     

Improved Electrotransformation and Decreased Antibiotic Resistance of the Cystic Fibrosis Pathogen Burkholderia cenocepacia Strain J2315

The bacterium Burkholderia cenocepacia is pathogenic for sufferers from cystic fibrosis (CF) and certain immunocompromised conditions. The B. cenocepacia strain most frequently isolated from CF patients, and which serves as the reference for CF epidemiology, is J2315. The J2315 genome is split into three chromosomes and one plasmid. The strain was sequenced several years ago, and its annotation has been released recently. This information should allow genetic experimentation with J2315, but two major impediments appear: the poor potential of J2315 to act as a recipient in transformation and conjugation and the high level of resistance it mounts to nearly all antibiotics. Here, we describe modifications to the standard electroporation procedure that allow routine transformation of J2315 by DNA. In addition, we show that deletion of an efflux pump gene and addition of spermine to the medium enhance the sensitivity of J2315 to certain commonly used antibiotics and so allow a wider range of antibiotic resistance genes to be used for selection.Burkholderia cenocepacia is part of the Burkholderia cepacia complex (Bcc), a group of closely related bacteria of soil, water, and roots (41) recently updated to at least 15 related species (42). Bcc displays many interesting features (see reference 27 for a review). Originally discovered as responsible for soft onion rot (3), Bcc species also interact beneficently with plants (see reference 34 for a review) and may degrade pollutants such as phthalate or the herbicide 2,4,5-trichlorophenoxyacetic acid (2,4,5,-T) (25, 33). But it is the emergence of Bcc as an opportunistic pathogen of people suffering from cystic fibrosis (CF) (19) and immunocompromizing conditions that has drawn most attention to these bacteria. Among Bcc species, Burkholderia multivorans and B. cenocepacia are the most prevalent in the epidemiology of CF. In particular, strains of the ET12 lineage of B. cenocepacia were responsible for a major transcontinental epidemic among CF patients in the 1990s (20), an outbreak aggravated by the high levels of resistance to nearly all antibiotics that characterizes Bcc. Species of the Bcc have large genomes (7 to 9 Mb) composed of two or three chromosomes and one or more plasmids, an unusual genomic organization among bacteria. The first Bcc genome to be sequenced was that of B. cenocepacia J2315 (also known as LMG16656), the type strain of the ET12 lineage and the reference strain for CF epidemiology; the sequence was completed and made available by the Wellcome Trust Sanger Institute in 2003. It revealed three chromosomes of 3.9, 3.2, and 0.9 Mb and a plasmid of 93 kb. The annotation of this genome was released recently (15).The pathogenicity and multipartite genome of B. cenocepacia make it an important subject for both practical and fundamental study. Genetic modification is essential to the success of many such investigations. Unfortunately, J2315 throws up major barriers to genetic manipulation. Standard electrotransformation techniques are ineffective with this strain, as also found elsewhere (26). Conjugal introduction of DNA has proved unreliable despite adaptations (7) that have enabled occasional successes with B. cenocepacia species (9, 40) including J2315 (39) (see also Results below). Besides, the natural resistance of J2315 to antibiotics, high even on the scale of the generally extensive resistance of B. cenocepacia species (31), severely restricts the use of antibiotic resistance in genetic selections. Circumventing these problems by resorting to a proxy strain, B. cenocepacia K56-2, that has not been sequenced and is more permissive to gene transfer (26, 17, 32, 9) runs the risk that results will be of uncertain relevance to J2315.In the context of our general aim to decipher the role of the four replicon-specific ParABS systems of J2315 (6), we have sought to overcome these obstacles. We report here the reproducible electrotransformation of J2315, and we analyze factors that improve its efficiency. We report also our isolation of a J2315 derivative with reduced antibiotic resistance and the broadened selection possibilities this offers. Detailed protocols are provided which should facilitate studies of this pathogen.     

Genetic studies with heteroduplex DNA of bacteriophage f1. Asymmetric segregation,base correction and implications for the mechanism of genetic recombination

Heteroduplex DNA of bacteriophage f1 constructed in vitro was used to transfect Escherichia coli. The progeny phage produced were analyzed by genetic means. A strongly asymmetric transfer of information was observed. This result shows that one strand—usually the minus strand—determines in large part the genotypes of progeny phage. These results are discussed in the light of the available information on DNA duplication. Evidence for an activity that corrects mismatched bases will be presented and discussed. Heteroduplex molecules which were heterozygous at the sites that govern sensitivity to B restriction and modification were constructed and analyzed in restricting and non-restricting hosts. Results of these studies give support to a model for f1 genetic recombination that envisages asymmetric heteroduplex formation as an intermediate. These results are discussed in relation to earlier data.     

Lambda Red Mediated Gap Repair Utilizes a Novel Replicative Intermediate in Escherichia coli

The lambda phage Red recombination system can mediate efficient homologous recombination in Escherichia coli, which is the basis of the DNA engineering technique termed recombineering. Red mediated insertion of DNA requires DNA replication, involves a single-stranded DNA intermediate and is more efficient on the lagging strand of the replication fork. Lagging strand recombination has also been postulated to explain the Red mediated repair of gapped plasmids by an Okazaki fragment gap filling model. Here, we demonstrate that gap repair involves a different strand independent mechanism. Gap repair assays examining the strand asymmetry of recombination did not show a lagging strand bias. Directly testing an ssDNA plasmid showed lagging strand recombination is possible but dsDNA plasmids did not employ this mechanism. Insertional recombination combined with gap repair also did not demonstrate preferential lagging strand bias, supporting a different gap repair mechanism. The predominant recombination route involved concerted insertion and subcloning though other routes also operated at lower frequencies. Simultaneous insertion of DNA resulted in modification of both strands and was unaffected by mutations to DNA polymerase I, responsible for Okazaki fragment maturation. The lower efficiency of an alternate Red mediated ends-in recombination pathway and the apparent lack of a Holliday junction intermediate suggested that gap repair does not involve a different Red recombination pathway. Our results may be explained by a novel replicative intermediate in gap repair that does not involve a replication fork. We exploited these observations by developing a new recombineering application based on concerted insertion and gap repair, termed SPI (subcloning plus insertion). SPI selected against empty vector background and selected for correct gap repair recombinants. We used SPI to simultaneously insert up to four different gene cassettes in a single recombineering reaction. Consequently, our findings have important implications for the understanding of E. coli replication and Red recombination.     

Low-Molecular-Weight DNA Replication Intermediates in Escherichia coli: Mechanism of Formation and Strand Specificity

Chromosomal DNA replication intermediates, revealed in ligase-deficient conditions in vivo, are of low molecular weight (LMW) independently of the organism, suggesting discontinuous replication of both the leading and the lagging DNA strands. Yet, in vitro experiments with purified enzymes replicating sigma-structured substrates show continuous synthesis of the leading DNA strand in complete absence of ligase, supporting the textbook model of semi-discontinuous DNA replication. The discrepancy between the in vivo and in vitro results is rationalized by proposing that various excision repair events nick continuously synthesized leading strands after synthesis, producing the observed LMW intermediates. Here, we show that, in an Escherichia coli ligase-deficient strain with all known excision repair pathways inactivated, new DNA is still synthesized discontinuously. Furthermore, hybridization to strand-specific targets demonstrates that the LMW replication intermediates come from both the lagging and the leading strands. These results support the model of discontinuous leading strand synthesis in E. coli.     

Replication of bacteriophage M13. 8. Differential effects of rifampicin and nalidixic acid on the synthesis of the two strands of M13 duplex DNA

Replication of bacteriophage M13 replicative forms is inhibited by rifampicin, an antibiotic that specifically inhibits the Escherichia coli RNA polymerase, and by nalidixic acid, an inhibitor of phage and bacterial DNA replication. Synthesis of the M13 complementary strand during RF³ replication was at least tenfold more sensitive to inhibition by rifampicin and by nalidixic acid than was that of the viral strand. Since M13 complementary strand synthesis is relatively insensitive to chloramphenicol, an inhibitor of protein synthesis, its inhibition by rifampicin suggests that complementary strands are initiated during RF replication by an RNA priming mechanism similar to that involved in parental RF formation. The nalidixic acid-sensitivity of complementary strand synthesis during RF replication clearly distinguishes this process from the nalidixic acid-resistant formation of the parental complementary strand in the conversion of the infecting single strand to RF.Production of progeny viral strands is indirectly affected by rifampiein in two ways. It prevents the conversion of supercoiled RF (RFI) to the open form (RFII), an essential step both in RF replication and in single-strand synthesis. In addition, rifampiein interferes with the expression of gene 5, an M13 gene function required for the accumulation of progeny viral strands.     

Escherichia coli O104 in Feedlot Cattle Feces: Prevalence,Isolation and Characterization

Escherichia coli O104:H4, an hybrid pathotype of Shiga toxigenic and enteroaggregative E. coli, involved in a major foodborne outbreak in Germany in 2011, has not been detected in cattle feces. Serogroup O104 with H type other than H4 has been reported to cause human illnesses, but their prevalence and characteristics in cattle have not been reported. Our objectives were to determine the prevalence of E. coli O104 in feces of feedlot cattle, by culture and PCR detection methods, and characterize the isolated strains. Rectal fecal samples from a total of 757 cattle originating from 29 feedlots were collected at a Midwest commercial slaughter plant. Fecal samples, enriched in E. coli broth, were subjected to culture and PCR methods of detection. The culture method involved immunomagnetic separation with O104-specific beads and plating on a selective chromogenic medium, followed by serogroup confirmation of pooled colonies by PCR. If pooled colonies were positive for the wzx_O104 gene, then colonies were tested individually to identify wzx_O104-positive serogroup and associated genes of the hybrid strains. Extracted DNA from feces were also tested by a multiplex PCR to detect wzx_O104-positive serogroup and associated major genes of the O104 hybrid pathotype. Because wzx_O104 has been shown to be present in E. coli O8/O9/O9a, wzx_O104-positive isolates and extracted DNA from fecal samples were also tested by a PCR targeting wbdD_O8/O9/O9a, a gene specific for E. coli O8/O9/O9a serogroups. Model-adjusted prevalence estimates of E. coli O104 (positive for wzx_O104 and negative for wbdD_O8/O9/O9a) at the feedlot level were 5.7% and 21.2%, and at the sample level were 0.5% and 25.9% by culture and PCR, respectively. The McNemar’s test indicated that there was a significant difference (P < 0.01) between the proportions of samples that tested positive for wzx_O104 and samples that were positive for wzx_O104, but negative for wbdD_O8/O9/O9a by PCR and culture methods. A total of 143 isolates, positive for the wzx_O104, were obtained in pure culture from 146 positive fecal samples. Ninety-two of the 143 isolates (64.3%) also tested positive for the wbdD_O8/O9/O9a, indicating that only 51 (35.7%) isolates truly belonged to the O104 serogroup (positive for wzx_O104 and negative for wbdD_O8/O9/O9a). All 51 isolates tested negative for eae, and 16 tested positive for stx1 gene of the subtype 1c. Thirteen of the 16 stx1-positive O104 isolates were from one feedlot. The predominant serotype was O104:H7. Pulsed-field gel electrophoresis analysis indicated that stx1-positive O104:H7 isolates had 62.4% homology to the German outbreak strain and 67.9% to 77.5% homology to human diarrheagenic O104:H7 strains. The 13 isolates obtained from the same feedlot were of the same PFGE subtype with 100% Dice similarity. Although cattle do not harbor the O104:H4 pathotype, they do harbor and shed Shiga toxigenic O104 in the feces and the predominant serotype was O104:H7.     

Evolution of the methyl directed mismatch repair system in Escherichia coli

DNA mismatch repair (MMR) repairs mispaired bases in DNA generated by replication errors. MutS or MutS homologs recognize mispairs and coordinate with MutL or MutL homologs to direct excision of the newly synthesized DNA strand. In most organisms, the signal that discriminates between the newly synthesized and template DNA strands has not been definitively identified. In contrast, Escherichia coli and some related gammaproteobacteria use a highly elaborated methyl-directed MMR system that recognizes Dam methyltransferase modification sites that are transiently unmethylated on the newly synthesized strand after DNA replication. Evolution of methyl-directed MMR is characterized by the acquisition of Dam and the MutH nuclease and by the loss of the MutL endonuclease activity. Methyl-directed MMR is present in a subset of Gammaproteobacteria belonging to the orders Enterobacteriales, Pasteurellales, Vibrionales, Aeromonadales, and a subset of the Alteromonadales (the EPVAA group) as well as in gammaproteobacteria that have obtained these genes by horizontal gene transfer, including the medically relevant bacteria Fluoribacter, Legionella, and Tatlockia and the marine bacteria Methylophaga and Nitrosococcus.     

Ultra-Low Background DNA Cloning System

Yeast-based in vivo cloning is useful for cloning DNA fragments into plasmid vectors and is based on the ability of yeast to recombine the DNA fragments by homologous recombination. Although this method is efficient, it produces some by-products. We have developed an “ultra-low background DNA cloning system” on the basis of yeast-based in vivo cloning, by almost completely eliminating the generation of by-products and applying the method to commonly used Escherichia coli vectors, particularly those lacking yeast replication origins and carrying an ampicillin resistance gene (Amp^r). First, we constructed a conversion cassette containing the DNA sequences in the following order: an Amp^r 5′ UTR (untranslated region) and coding region, an autonomous replication sequence and a centromere sequence from yeast, a TRP1 yeast selectable marker, and an Amp^r 3′ UTR. This cassette allowed conversion of the Amp^r-containing vector into the yeast/E. coli shuttle vector through use of the Amp^r sequence by homologous recombination. Furthermore, simultaneous transformation of the desired DNA fragment into yeast allowed cloning of this DNA fragment into the same vector. We rescued the plasmid vectors from all yeast transformants, and by-products containing the E. coli replication origin disappeared. Next, the rescued vectors were transformed into E. coli and the by-products containing the yeast replication origin disappeared. Thus, our method used yeast- and E. coli-specific “origins of replication” to eliminate the generation of by-products. Finally, we successfully cloned the DNA fragment into the vector with almost 100% efficiency.