One step construction of PCR mutagenized libraries for genetic analysis by recombination cloning

Recombination cloning encompasses a set of technologies that transfer gene sequences between vectors through site-specific recombination. Due in part to the instability of linear DNA in bacteria, both the initial capture and subsequent transfer of gene sequences is often performed using purified recombination enzymes. However, we find linear DNAs flanked by loxP sites recombine efficiently in bacteria expressing Cre recombinase and the lambda Gam protein, suggesting Cre/lox recombination of linear substrates can be performed in vivo. As one approach towards exploiting this capability, we describe a method for constructing large (>1 × 10⁶ recombinants) libraries of gene mutations in a format compatible with recombination cloning. In this method, gene sequences are cloned into recombination entry plasmids and whole-plasmid PCR is used to produce mutagenized plasmid amplicons flanked by loxP. The PCR products are converted back into circular plasmids by transforming Cre/Gam-expressing bacteria, after which the mutant libraries are transferred to expression vectors and screened for phenotypes of interest. We further show that linear DNA fragments flanked by loxP repeats can be efficiently recombined into loxP-containing vectors through this same one-step transformation procedure. Thus, the approach reported here could be adapted as general cloning method.     

Simple and straightforward construction of a mouse gene targeting vector using in vitro transposition reactions

In a gene targeting experiment, the generation of a targeting construct often requires complex DNA manipulations. We developed a set of cassettes and plasmids useful for creating targeting vectors to modify the mammalian genome. A positive selection marker cassette (PGK/EM7p-npt), which included dual prokaryotic and eukaryotic promoters to permit consecutive selection for recombination in Escherichia coli and then in mouse embryonic stem cells, was flanked by two FRT-loxP sequences. The PGK/EM7p-npt cassette was placed between the minimum regions of a Tn7 transposable element for insertion into another DNA by means of Tn7 transposase in vitro. We also constructed a plasmid having a loxP-Zeo-loxP cassette between the modified Tn5 outer elements. These cassettes can be integrated randomly into a given genomic DNA through the in vitro transposition reaction, thus producing a collection of genomic segments flanked by loxP sites (floxed) at various positions without the use of restriction enzymes and DNA ligase. We confirmed that this system remarkably reduced the time and labor for the construction of complex gene targeting vectors.     

Genetic characterization and construction of an auxotrophic strain of Saccharomyces cerevisiae JP1, a Brazilian industrial yeast strain for bioethanol production

Used for millennia to produce beverages and food, Saccharomyces cerevisiae also became a workhorse in the production of biofuels, most notably bioethanol. Yeast strains have acquired distinct characteristics that are the result of evolutionary adaptation to the stresses of industrial ethanol production. JP1 is a dominant industrial S. cerevisiae strain isolated from a sugarcane mill and is becoming increasingly popular for bioethanol production in Brazil. In this work, we carried out the genetic characterization of this strain and developed a set of tools to permit its genetic manipulation. Using flow cytometry, mating type, and sporulation analysis, we verified that JP1 is diploid and homothallic. Vectors with dominant selective markers for G418, hygromycin B, zeocin, and ρ-fluoro-dl-phenylalanine were used to successfully transform JP1 cells. Also, an auxotrophic ura3 mutant strain of JP1 was created by gene disruption using integration cassettes with dominant markers flanked by loxP sites. Marker excision was accomplished by the Cre/loxP system. The resulting auxotrophic strain was successfully transformed with an episomal vector that allowed green fluorescent protein expression.     

Lox-dependent gene expression in transgenic plants obtained via Agrobacterium-mediated transformation

Lox sites of the Cre/lox recombination system from bacteriophage P1 were analyzed for their ability to affect on transgene expression when inserted upstream from a gene coding sequence adjacent to the right border (RB) of T-DNA. Wild and mutated types of lox sites were tested for their effect upon bar gene expression in plants obtained via Agrobacterium-mediated and biolistic transformation methods. Lox-mediated expression of bar gene, recognized by resistance of transgenic plants to PPT, occurred only in plants obtained via Agrobacterium-mediated transformation. RT-PCR analysis confirms that PPT-resistant phenotype of transgenic plants obtained via Agrobacterium-mediated transformation was caused by activation of bar gene. The plasmid with promoterless gus gene together with the lox site adjacent to the RB was constructed and transferred to Nicotiana tabacum as well. Transgenic plants exhibited GUS activity and expression of gus gene was detected in plant leaves. Expression of bar gene from the vectors containing lox site near RB allowed recovery of numerous PPT-resistant transformants of such important crops as Beta vulgaris, Brassica napus, Lactuca sativa and Solanum tuberosum. Our results demonstrate that the lox site sequence adjacent to the RB can be used to control bar gene expression in transgenic plants.     

Site-specific integration of DNA into wild-type and mutant lox sites placed in the plant genome

The bacteriophage P1 Cre—lox site-specific recombination system has been used to integrate DNA specifically at lox sites previously placed in the tobacco genome. As integrated molecules flanked by wild-type lox sites can readily excise in the presence of Cre recombinase, screening for mutant lox sites that can resist excisional recombination was performed. In gene integration experiments, wild-type and mutant lox sites were used in conjunction with two strategies for abolishing post-integration Cre activity: (i) promoter displacement of a cre-expression construct present in the target genome; and (ii) transient expression of cre. When the promoter displacement strategy was used, integrant plants were recovered after transformation with constructs containing mutant lox sequences, but not with constructs containing wild-type lox sites. When cre was transiently expressed, integrant plants were obtained after transformation with either mutant or wild-type lox sites. DNA rearrangements at the target locus were less frequent when mutant lox sites were used. DNA integration at the genomic lox site was usually without additional insertions in the genome. Thus, the Cre—lox site-specific recombination system is useful for the single-copy integration of DNA into a chromosomal lox site.     

New vector system for induction of gene expression in dicotyledonous plants

A system of two vectors, pEnLox and pCre, was developed. The pEnLox vector is used to induce insertional mutations, while pCre is used to obtain transgenic plants expressing the Cre recombinase gene. The T-DNA enhancer is flanked by the loxP sites in the pEnLox vector. As an Arabidopsis thaliana insertional mutant obtained by transformation with pEnLox is crossed with another transgenic line carrying the cre gene, the enhancer sequence is eliminated. The vector system makes it possible to induce insertional mutations and to determine whether the mutant phenotype is caused by the loss-of-function insertional mutation or by overespression of nearby genes in response to the enhancer contained in the insert.     

Bacteriophage P1 site-specific recombination. III. Strand exchange during recombination at lox sites

When hybrid λ-P1 phages containing either loxP or loxR sites are crossed under conditions where only the P1 lox site-specific recombination system is active, most of the crossovers occur in a region of the DNA that contains the lox sites. The remainder of the lox-mediated crossovers (4% in a P × P cross and 32% in a P × R cross) occur close to, but outside of, either loxP or loxR. These latter crossovers are not detected if one of the partners in the cross carries a deletion of loxP. We explain these results by an exchange of strands at lox sites and a migration of the resulting cross-strand junction outside of lox.     

Site-directed integration of the cre gene mediated by Cre recombinase using a combination of mutant lox sites

The Cre-lox system is an important tool for genetic manipulation. To promote integrative reactions, two strategies using mutant lox sites have been developed. One is the left element/right element (LE/RE)-mutant strategy and the other is the cassette exchange strategy using heterospecific lox sites such as lox511 or lox2272. We compared the recombination efficiencies using these mutant lox sites in embryonic stem (ES) cells, and found that the combination of the LE/RE mutant and lox2272 showed high recombination efficiency and stability of the recombined structure. Taking advantage of this stability, we successfully integrated the cre gene into the mutant lox sites by Cre-mediated recombination. Germ line chimeric mice were produced from the cre-integrated ES cell clones, and Cre-expressing mouse lines were established. The inserted cre gene was stably maintained through the generations. This cre knock-in system using the LE/RE-lox2272 combination should be useful for the production of various cre mice for gene targeting or gene trapping.     

Site-Specific Integration of Transgenes in Soybean via Recombinase-Mediated DNA Cassette Exchange

A targeting method to insert genes at a previously characterized genetic locus to make plant transformation and transgene expression predictable is highly desirable for plant biotechnology. We report the successful targeting of transgenes to predefined soybean (Glycine max) genome sites using the yeast FLP-FRT recombination system. First, a target DNA containing a pair of incompatible FRT sites flanking a selection gene was introduced in soybean by standard biolistic transformation. Transgenic events containing a single copy of the target were retransformed with a donor DNA, which contained the same pair of FRT sites flanking a different selection gene, and a FLP expression DNA. Precise DNA cassette exchange was achieved between the target and donor DNA via recombinase-mediated cassette exchange, so that the donor DNA was introduced at the locus previously occupied by the target DNA. The introduced donor genes expressed normally and segregated according to Mendelian laws.Plant transformation has challenges such as random integration, multiple transgene copies, and unpredictable expression. Homologous recombination (Iida and Terada, 2005; Wright et al., 2005) and DNA recombinase-mediated site-specific integration (SSI) are promising technologies to address the challenges for placing a single copy of transgenes into a precharacterized site in a plant genome.Several site-specific DNA recombination systems, such as the bacteriophage Cre-lox and the yeast FLP-FRT and R-RS, have been used in SSI studies (Ow, 2002; Groth and Calos, 2003). A common feature of these systems is that each system consists of a recombinase Cre, FLP, or R and two identical or similar palindromic recognition sites, lox, FRT, or RS. Each recognition site contains a short asymmetric spacer sequence where DNA strand exchange takes place, flanked by inverted repeat sequences where the corresponding recombinase specifically binds. If two recognition sites are located in cis on a DNA molecule, the DNA segment can be excised if flanked by two directionally oriented sites or inverted if flanked by two oppositely oriented sites. If two recognition sites are located in trans on two different DNA molecules, a reciprocal translocation can happen between the two DNA molecules or the two molecules can integrate if at least one of them is a circular DNA (Ow, 2002; Groth and Calos, 2003).Single-site SSI can integrate a circular donor DNA containing one recognition site into a similar site previously placed in a plant genome. The integrated transgene now flanked by two recognition sites is vulnerable to excision. Transient Cre expression and the use of mutant lox sites to create two less compatible sites after integration helped reduce the subsequent excision in tobacco (Nicotiana tabacum; Albert et al., 1995; Day et al., 2000). A similar approach was used to produce SSI events in rice (Oryza sativa), and the transgene was proven stably expressed over generations (Srivastava and Ow, 2001; Srivastava et al., 2004; Chawla et al., 2006). Using a promoter trap to displace a cre gene in the genome with a selection gene from the donor, approximately 2% SSI was achieved in Arabidopsis (Arabidopsis thaliana; Vergunst et al., 1998).When two recognition sites located on a linear DNA molecule are similar enough to be recognized by the same recombinase but different enough to reduce or prevent DNA recombination from happening between them, the DNA segment between the two sites may not be easily excised or inverted. When a circular DNA molecule carrying the same two incompatible sites is introduced, the circular DNA can integrate by the corresponding recombinase at either site on the linear DNA to create a collinear DNA with four recognition sites, two from the original linear DNA and two from the circular DNA. DNA excision can subsequently occur between any pair of compatible sites to restore the two original DNA molecules or to exchange the intervening DNA segments between the two DNA molecules. This process, termed recombinase-mediated cassette exchange (RMCE), can be employed to integrate transgenes directionally into predefined genome sites (Trinh and Morrison, 2000; Baer and Bode, 2001).RMCE using two oppositely oriented identical RS sites, a donor containing the R recombinase gene and a third RS site to limit random integration, resulted in cassette exchange between the donor and a previously placed target in tobacco (Nanto et al., 2005). RMCE using both the Cre-lox and FLP-FRT systems improved RMCE frequency in animal cell cultures (Lauth et al., 2002). RMCE using two directly oriented incompatible FRT sites and transiently expressed FLP recombinase achieved cassette exchange between a target previously placed in the Drosophila genome and a donor introduced as a circular DNA (Horn and Handler, 2005). A gene conversion approach involving Cre-lox- and FLP-FRT-mediated SSI, RMCE, and homologous recombination was explored in maize (Zea mays; Djukanovic et al., 2006). RMCE using two oppositely oriented incompatible lox sites and transiently expressed Cre recombinase produced single-copy RMCE plants in Arabidopsis (Louwerse et al., 2007).To develop FLP-FRT-mediated RMCE in soybean (Glycine max), we created transgenic target lines containing a hygromycin resistance gene flanked by two directly oriented incompatible FRT sites via biolistic transformation. Single-copy target lines were selected and retransformed with a donor DNA containing a chlorsulfuron resistance gene flanked by the same pair of FRT sites. An FLP expression DNA was cobombarded to transiently provide FLP recombinase. RMCE events were obtained from multiple target lines and confirmed by extensive molecular characterization.     

Application of the resident plasmid integration technique to construct a strain of Streptococcus godronii able to express the Bacillus circulans cycloisomaltooligosaccharide glucanotransferase gene,and secrete its active gene product

A novel transformation technique, resident plasmid integration, for the cloning of foreign DNA in oral streptococci was described recently (T. Shiroza and H. K. Kuramitsu, Plasmid, 1995, 34, 85–95). This technique is based on the integration of linearized foreign genes by recombination-proficient bacteria onto a resident plasmid, if an appropriate selection marker is flanked by the same anchor sites present in the resident plasmid. Since the transforming vehicles for this system included a pUC-derived replication origin, the high level expression in Escherichia coli cells hindered the cloning of certain genes. In the present study, new plasmids were constructed, two resident plasmids, four integration plasmids, and four cloning plasmids, all of which possess the medium-copy number replication origin, p15A ori, isolated from pACYC177. The resident plasmids consisted of the following three components: the p15A ori (0.65-kb BglII fragment), the pVA380-1 basic replicon functional in mutans streptococci (2.5-kb BamHI fragment), and either an erythromycin resistance or a spectinomycin resistance gene (0.9- or 1.1-kb BamHI fragment, respectively). Most of the basic replicon of pVA380-1, except for the 3′-portion of the 0.2-kb region, in the resident plasmid was replaced with a kanamycin resistance gene to construct the four integration plasmids. Therefore, the upstream and downstream anchor sites for the double cross-over event in this new system were 0.65-kb p15A ori and the 0.2-kb portion of the 3′-end of pVA380-1 replicon, respectively. This system was used to clone the gene coding for cycloisomaltooligosaccharide glucanotransferase which produces cycloisomaltooligosaccharide, a potent inhibitor of oral streptococcal glucosyltransferase, isolated from Bacillus circulans chromosome, into Streptococcus gordonii, and its gene product was successfully secreted into the culture media. Plasmids described here should be useful tools for introducing heterologous DNA into resident plasmids following integration in oral streptococci.     

Site-specific Bacterial Chromosome Engineering: ΦC31 Integrase Mediated Cassette Exchange (IMCE)

The bacterial chromosome may be used to stably maintain foreign DNA in the mega-base range¹. Integration into the chromosome circumvents issues such as plasmid replication, plasmid stability, plasmid incompatibility, and plasmid copy number variance. This method uses the site-specific integrase from the Streptomyces phage (Φ) C31^2,3. The ΦC31 integrase catalyzes a direct recombination between two specific DNA sites: attB and attP (34 and 39 bp, respectively)⁴. This recombination is stable and does not revert⁵. A "landing pad" (LP) sequence consisting of a spectinomycin- resistance gene, aadA (SpR), and the E. coli ß-glucuronidase gene (uidA) flanked by attP sites has been integrated into the chromosomes of Sinorhizobium meliloti, Ochrobactrum anthropi, and Agrobacterium tumefaciens in an intergenic region, the ampC locus, and the tetA locus, respectively. S. meliloti is used in this protocol. Mobilizable donor vectors containing attB sites flanking a stuffer red fluorescent protein (rfp) gene and an antibiotic resistance gene have also been constructed. In this example the gentamicin resistant plasmid pJH110 is used. The rfp gene⁶ may be replaced with a desired construct using SphI and PstI. Alternatively a synthetic construct flanked by attB sites may be sub-cloned into a mobilizable vector such as pK19mob⁷. The expression of the ΦC31 integrase gene (cloned from pHS62⁸) is driven by the lac promoter, on a mobilizable broad host range plasmid pRK7813⁹.A tetraparental mating protocol is used to transfer the donor cassette into the LP strain thereby replacing the markers in the LP sequence with the donor cassette. These cells are trans-integrants. Trans-integrants are formed with a typical efficiency of 0.5%. Trans-integrants are typically found within the first 500-1,000 colonies screened by antibiotic sensitivity or blue-white screening using 5-bromo-4-chloro-3-indolyl-beta-D-glucuronic acid (X-gluc). This protocol contains the mating and selection procedures for creating and isolating trans-integrants.     

Cre/<Emphasis Type="Italic">lox</Emphasis>-mediated marker gene excision in transgenic maize (Zea mays L.) plants

After the initial transformation and tissue culture process is complete, selectable marker genes, which are used in virtually all transformation approaches, are not required for the expression of the gene of interest in the transgenic plants. There are several advantages to removing the selectable marker gene after it is no longer needed, such as enabling the reuse of selectable markers and simplifying transgene arrays. We have tested the Cre/lox system from bacteriophage P1 for its ability to precisely excise stably integrated marker genes from chromosomes in transgenic maize plants. Two strategies, crossing and autoexcision, have been tested and demonstrated. In the crossing strategy, plants expressing the Cre recombinase are crossed with plants bearing a transgene construct in which the selectable marker gene is flanked by directly repeated lox sites. Unlike previous reports in which incomplete somatic and germline excision were common, in our experiments complete somatic and germline marker gene excision occurred in the F₁ plants from most crosses with multiple independent Cre and lox lines. In the autoexcision strategy, the cre gene, under the control of a heat shock-inducible promoter, is excised along with the nptII marker gene. Our results show that a transient heat shock treatment of primary transgenic callus is sufficient for inducing cre and excising the cre and nptII genes. Genetic segregation and molecular analysis confirmed that marker gene removal is precise, complete and stable. The autoexcision strategy provides a way of removing the selectable marker gene from callus or other tissues such as embryos and kernels.Communicated by D. Hoisington     

Cre/ lox site-specific recombination controls the excision of a transgene from the rice genome

The Cre/lox site-specific recombination controls the excision of a target DNA segment by recombination between two lox sites flanking it, mediated by the Cre recombinase. We have studied the functional expression of the Cre/lox system to excise a transgene from the rice genome. We developed transgenic plants carrying the target gene, hygromycin phosphotransferase (hpt) flanked by two lox sites and transgenic plants harboring the Cre gene. Each lox plant was crossed with each Cre plant reciprocally. In the Cre/lox hybrid plants, the Cre recombinase mediates recombination between two lox sites, resulting in excision of the hpt gene. The recombination event could be detected because it places the CaMV 35S promoter of the hpt gene adjacent to a promoterless gusA gene; as a result the gusA gene is activated and its expression could be visualized. In 73 Cre/lox hybrid plants from various crosses of T0 transgenic plants, 19 expressed GUS, and in 132 Cre/lox hybrid plants from crosses of T2 transgenic plants, 77 showed GUS expression. Molecular data proved the excision event occurred in all the GUS⁺ plants. Recombination occurred with high efficiency at the early germinal stage, or randomly during somatic development stages. Received. 2 April 2001 / Accepted: 29 June 2001     

Site-specific integration of transgene targeting an endogenous <Emphasis Type="Italic">lox-</Emphasis>like site in early mouse embryos

Functional lox-like sequences have been identified within the yeast and mammalian genome. These hetero-specific lox sites also allow Cre recombinase to specifically target efficient integration of exogenous DNA into the endogenous pseudo-lox (ψlox) sequences that occur naturally in the host genome using a Cre/loxP integrative recombination system. We investigated whether the Cre/ψlox system is useful for site-specific integration of transgenes and for improving the production efficiency of transgenic animals. This is the first report on Cre-mediated integrative recombination targeting an endogenous lox-like sequence termed pseudo-loxm5 (ψloxm5) in early mouse embryos. We characterized the Cre/ψloxm5 system in embryonic environment. Cre-expressing plasmid and a transgene (CMV/LacZ gene) flanked by ψloxm5 and ψloxcorem5 sites were co-microinjected into the pronucleus of fertilized mouse oocytes. The injected eggs were transferred into foster mothers, and the recombination products were investigated. The results show that the ψloxm5 site is an active substrate for Cre-mediated recombination in the mouse embryonic environment. The transgenesis efficiency was up to 27% (6/22). The site-specific integration of the transgene into the endogenous ψloxm5 site was found in 50 % of the transgenic pups. Our findings demonstrated that the Cre/ψloxm5 integrative recombination system is an efficient and simple strategy for targeting an endogenous lox-like site in mammalian embryos.     

Identification of a novel gene, H34, in wheat using recombinant inbred lines and single nucleotide polymorphism markers

Hessian fly (HF), Mayetiola destructor, is an important pest of wheat (Triticum aestivum L.) worldwide. Because it has multiple biotypes that are virulent to different wheat HF resistance genes, pyramiding multiple resistance genes in a cultivar can improve resistance durability, and finding DNA markers tightly linked to these genes is essential to this process. This study identified quantitative trait loci (QTLs) for Hessian fly resistance (HFR) in the wheat cultivar ‘Clark’ and tightly linked DNA markers for the QTLs. A linkage map was constructed with single nucleotide polymorphism and simple sequence repeat markers using a population of recombinant inbred lines (RILs) derived from the cross ‘Ning7840’ × ‘Clark’ by single-seed descent. Two QTLs associated with resistance to fly biotype GP were identified on chromosomes 6B and 1A, with the resistance alleles contributed from ‘Clark’. The QTL on 6B flanked by loci Xsnp921 and Xsnp2745 explained about 37.2 % of the phenotypic variation, and the QTL on 1A was flanked by Xgwm33 and Xsnp5150 and accounted for 13.3 % of phenotypic variation for HFR. The QTL on 6B has not been reported before and represents a novel wheat gene with resistance to HF, thus, it is designated H34. A significant positive epistasis was detected between the two QTLs that accounted for about 9.5 % of the mean phenotypic variation and increased HFR by 0.16. Our results indicated that different QTLs may contribute different degrees of resistance in a cultivar and that epistasis may play an important role in HFR.     

Molecular epidemiology of clinical and carrier strains of methicillin resistant Staphylococcus aureus (MRSA) in the hospital settings of north India

Background

The study was conducted between 2000 and 2003 on 750 human subjects, yielding 850 strains of staphylococci from clinical specimens (575), nasal cultures of hospitalized patients (100) and eye & nasal sources of hospital workers (50 & 125 respectively) in order to determine their epidemiology, acquisition and dissemination of resistance genes.

Methods

Organisms from clinical samples were isolated, cultured and identified as per the standard routine procedures. Susceptibility was measured by the agar diffusion method, as recommended by the Nat ional Committee for Clinical Laboratory Standards (NCCLS). The modified method of Birnboin and Takahashi was used for isolation of plasmids from staphylococci. Pulsed-field gel electrophoresis (PFGE) typing of clinical and carrier Methicillin resistant Staphylococcus aureus (MRSA) strains isolated during our study was performed as described previously.

Results

It was shown that 35.1% of Staphylococcus aureus and 22.5% of coagulase-negative staphylococcal isolates were resistant to methicillin. Highest percentage of MRSA (35.5%) was found in pus specimens (n = 151). The multiple drug resistance of all MRSA (n = 180) and Methicillin resistant Coagulase-negative Staphylococcus aureus (MRCNS) (n = 76) isolates was detected. In case of both methicillin-resistant as well as methicillin-sensitive Saphylococcal isolates zero resistance was found to vancomycin where as highest resistance was found to penicillin G followed by ampicillin. It was shown that the major reservoir of methicillin resistant staphylococci in hospitals are colonized/infected inpatients and colonized hospital workers, with carriers at risk for developing endogenous infection or transmitting infection to health care workers and patients. The results were confirmed by molecular typing using PFGE by SmaI-digestion. It was shown that the resistant markers G and T got transferred from clinical S. aureus (JS-105) to carrier S. aureus (JN-49) and the ciprofloxacin (Cf) and erythromycin (E) resistance seemed to be chromosomal mediated. In one of the experiments, plasmid pJMR1O from Staphylococcus aureus coding for ampicillin (A), gentamicin (G) and amikacin (Ak) resistance was transformed into Escherichia coli. The minimal inhibitory concentrations (MICs) for A and G were lower in E. coli than in S. aureus. However, the MIC for Ak was higher in E. coli transformants than in S. aureus.

Conclusion

There is a progressive increase in MRSA prevalence and multi-drug resistance in staphylococci. Vancomycin is still the drug of choice for MRSA infections. The major reservoir of methicillin resistant staphylococci in hospitals is colonized/infected inpatients and colonized hospital workers. Resistance transfer from staphylococci to E. coli as well as from clinical to carrier staphylococci due to antibiotic stress seemed to be an alarming threat to antimicrobial chemotherapy.     

Map of the IncP1β Plasmid pTSA Encoding the Widespread Genes (tsa) for p-Toluenesulfonate Degradation in Comamonas testosteroni T-2

The catabolic IncP1β plasmid pTSA from Comamonas testosteroni T-2 was mapped by subtractive analysis of restriction digests, by sequencing outwards from the tsa operon (toluenesulfonate degradation), and by generating overlapping, long-distance-PCR amplification products. The plasmid was estimated to comprise 72 ± 4 kb. The tsa region was found to be a composite transposon flanked by two IS1071 elements. A cryptic tsa operon was also present in the tsa transposon. Those backbone genes and regions which we sequenced were in the same order as the corresponding genes in resistance plasmid R751, and identities of about 99% were observed. Enrichment cultures with samples from four continents were done to obtain organisms able to utilize p-toluenesulfonate as the sole source of carbon and energy for aerobic growth. Most (15) of the 16 cultures (13 of them isolates) were obtained from contaminated sites and were attributed to three metabolic groups, depending on their metabolism of p-toluenesulfonate. The largest group contained the tsa transposon, usually (six of seven isolates) with negligible differences in sequence from strain T-2.     

Nucleotide sequence of Pseudomonas aeruginosa conjugative plasmid pUM505 containing virulence and heavy-metal resistance genes

We determined the complete nucleotide sequence of conjugative plasmid pUM505 isolated from a clinical strain of Pseudomonas aeruginosa. The plasmid had a length of 123,322 bp and contained 138 complete coding regions, including 46% open reading frames encoding hypothetical proteins. pUM505 can be considered a hybrid plasmid because it presents two well-defined regions. The first region corresponded to a larger DNA segment with homology to a pathogenicity island from virulent Pseudomonas strains; this island in pUM505 was comprised of genes probably involved in virulence and genes encoding proteins implicated in replication, maintenance and plasmid transfer. Sequence analysis identified pil genes encoding a type IV secretion system, establishing pUM505 as a member of the family of IncI1 plasmids. Plasmid pUM505 also contained virB4/virD4 homologues, which are linked to virulence in other plasmids. The second region, smaller in length, contains inorganic mercury and chromate resistance gene clusters both flanked by putative mobile elements. Although no genes for antibiotic resistance were identified, when pUM505 was transferred to a recipient strain of P. aeruginosa it conferred resistance to the fluoroquinolone ciprofloxacin. pUM505 also conferred resistance to the superoxide radical generator paraquat. pUM505 could provide Pseudomonas strains with a wide variety of adaptive traits such as virulence, heavy-metal and antibiotic resistance and oxidative stress tolerance which can be selective factors for the distribution and prevalence of this plasmid in diverse environments, including hospitals and heavy metal contaminated soils.     

Towards a Cre-based recombination system for generating integrated DNA repertoires site-specifically in yeast

A Cre-lox double recombination system is shown to work reasonably well in Saccharomyces cerevisiae. The system comprises an antibiotic resistance marker (the kanMX4 module) integrated at the chromosomal location to be targeted (leu2) of yeast strain FY10 and plasmid pRS315 carrying a foreign gene, human odorant receptor gene OR17-228, for targeting to that locus. Both OR17-228 and kanMX4 are flanked by loxP and loxP 511 sites. Cre recombinase expression was induced from plasmid pBS39. PCR analysis shows that a single copy of OR17-228 can be targeted to the leu2 locus in 22% of yeast cells after 24 h induction. DNA sequences of 5 successfully targeted loci show that OR17-228 is integrated in the intended orientation, and Southern blotting shows that there are no ectopic copies of OR17-228 present in these cases.     

New Multiple-Deletion Method for the Corynebacterium glutamicum Genome, Using a Mutant lox Sequence

Due to the difficulty of multiple deletions using the Cre/loxP system, a simple, markerless multiple-deletion method based on a Cre/mutant lox system combining a right-element (RE) mutant lox site with a left-element (LE) mutant lox site was employed for large-scale genome rearrangements in Corynebacterium glutamicum. Eight distinct genomic regions that had been identified previously by comparative analysis of C. glutamicum R and C. glutamicum 13032 genomes were targeted for deletion. By homologous recombination, LE and RE mutant lox sites were integrated at each end of a target region. Highly efficient and accurate deletions between the two chromosomal mutant lox sites in the presence of Cre recombinase were realized. A deletion mutant lacking 190 kb of chromosomal regions, encoding a total of 188 open reading frames (ORFs), was obtained. These deletions represent the largest genomic excisions in C. glutamicum reported to date. Despite the loss of numerous predicted ORFs, the mutant exhibited normal growth under standard laboratory conditions. The Cre/loxP system using a pair of mutant lox sites provides a new, efficient genome rearrangement technique for C. glutamicum. It should facilitate the understanding of genome functions of microorganisms.