Cre/lox system and PCR-based genome engineering in Bacillus subtilis

We have developed a fast and accurate method to engineer the Bacillus subtilis genome that involves fusing by PCR two flanking homology regions with an antibiotic resistance gene cassette bordered by two mutant lox sites (lox71 and lox66). The resulting PCR products were used directly to transform B. subtilis, and then transient Cre recombinase expression in the transformants was used to recombine lox71 and lox66 into a double-mutant lox72 site, thereby excising the marker gene. The mutation process could also be accomplished in 2 days by using a strain containing a cre isopropyl-beta-d-thiogalactopyranoside (IPTG)-inducible expression cassette in the chromosome as the recipient or using the lox site-flanked cassette containing both the cre IPTG-inducible expression cassette and resistance marker. The in vivo recombination efficiencies of different lox pairs were compared; the lox72 site that remains in the chromosome after Cre recombination had a low affinity for Cre and did not interfere with subsequent rounds of Cre/lox mutagenesis. We used this method to inactivate a specific gene, to delete a long fragment, to realize the in-frame deletion of a target gene, to introduce a gene of interest, and to carry out multiple manipulations in the same background. Furthermore, it should also be applicable to large genome rearrangement.     

New integrative method to generate Bacillus subtilis recombinant strains free of selection markers

The novel method described in this paper combines the use of blaI, which encodes a repressor involved in Bacillus licheniformis BlaP beta-lactamase regulation, an antibiotic resistance gene, and a B. subtilis strain (BS1541) that is conditionally auxotrophic for lysine. We constructed a BlaI cassette containing blaI and the spectinomycin resistance genes and two short direct repeat DNA sequences, one at each extremity of the cassette. The BS1541 strain was obtained by replacing the B. subtilis P(lysA) promoter with that of the P(blaP) beta-lactamase promoter. In the resulting strain, the cloning of the blaI repressor gene confers lysine auxotrophy to BS1541. After integration of the BlaI cassette into the chromosome of a conditionally lys-auxotrophic (BS1541) strain by homologous recombination and positive selection for spectinomycin resistance, the eviction of the BlaI cassette was achieved by single crossover between the two short direct repeat sequences. This strategy was successfully used to inactivate a single gene and to introduce a gene of interest in the Bacillus chromosome. In both cases the resulting strains are free of selection marker. This allows the use of the BlaI cassette to repeatedly further modify the Bacillus chromosome.     

A simple method for multiple modification of the Escherichia coli K-12 chromosome

We developed a simple method of generating markerless deletions in the Escherichia coli chromosome. The method consists of two recombination events stimulated by lambda Red recombinase. The first recombination replaced a target region with a marker cassette and the second then eliminated the marker cassette. The marker cassette included an antibiotic resistant gene and a negative selection marker (Bacillus subtilis sacB). Since sacB makes E. coli sensitive to sucrose, a markerless deletion strain was successfully selected using its sucrose-resistant phenotype. To stimulate these recombination events, 1-kbp homologous sequences adjacent to the target region were connected to both ends of the marker cassette or connected to each other by PCR. The average efficiency of the recombinations was 24% and 93% respectively. Eliminating the marker cassette with a fragment including an additional sequence, insertion was also possible. This markerless deletion method should be useful in creating a highly modified E. coli chromosome.     

Heat-inducible autolytic vector for high-throughput screening

In directed evolution, a high-throughput screening system is often a prerequisite for sampling the enzyme variants. When the target enzyme is expressed intracellularly, for example when Escherichia coli is used as the host, chemical or enzymatic disruption of cell membrane is often required in many cases, which can be tedious, time-consuming, and costly. In this study, a set of heat-inducible autolytic vectors were constructed to solve this problem, in which the SRRz lysis gene cassette from bacteriophage lambda was placed downstream of heat-inducible promoters, lambda cI857/pR promoter and its mutant, c1857/pR(M). The artificial autolytic units were inserted into the backbone of pUC18 (away from the multiple cloning sites). For the wild promoter; cI857/pR, the SRRz lysis cassette was expressed by temperature up-shift from 28 degrees to 38 degrees C, and the lysis efficiency of transformed bacterial cells was found to be consistent and could reach 96.3% as measured by the reporter beta3-galactosidase assay. In order to obtain a higher cell growth rate, the mutant promoter cI857/pR(M) was utilized to allow bacteria growth at 35 degrees C and lysis at 42 degrees C. However; this heat-inducible system showed significant inconsistency in terms of lysis efficiency. Bacillus subtilis 168 lipase A gene was further inserted into the multiple cloning sites of the autolytic vector containing cI857/pR, and 93.7% of the expressed lipase activity was found in the culture medium upon heat induction, demonstrating the utility of the vector for expression and rapid extracellular assay of heterologous enzymes.     

地衣芽胞杆菌dif序列的功能鉴定

地衣芽胞杆菌是重要的工业菌株,如何为其建立一种有效的基因删除技术是对该菌株进行遗传改良的基础。枯草芽胞杆菌difB8序列已经被成功用于枯草芽胞杆菌多基因的删除。在分析地衣芽胞杆菌基因组序列并获得与枯草芽胞杆菌difB8以。序列十分相似的一段序列difBLi的基础上,构建了在庆大霉素抗性基因两侧具有difBLi的重组质粒pMD19-difGm和pHY-XI’：：difGm,通过电击转化法将质粒pHY-XI’：：difGm导入B．1icheniformis ATCC14580中,筛选获得了具有庆大霉素抗性的转化子。在转化子的传代过程中,重组质粒的庆大霉素抗性基因在体内Xer／dif／f位点特异性重组系统的介导下通过其侧翼的dif位点进行同源重组而被准确删除。确证了地衣芽胞杆菌中dif序列的功能,为地衣芽胞杆菌基因组中多基因的删除提供了一种新的实验途径。     

The use of phage lambda promotors for expressing genes of secreted proteins in Bacillus subtilis cells

At was shown with the help of promoterless alpha-amylase and staphylokinase genes that lambda PR and lambda PL promoters could be used in Bacillus subtilis. Promoters strength was compared to promoter of alpha-amylase gene, this enabled to order the promoters in a row: PAA greater than lambda PR greater than lambda PL. The lambda PR promoter region was controlled by temperature in E. coli cells only, but not in B. subtilis, therefore, the active lambda C1857 gene product was not produced in B. subtilis cells. The lambda PR promoter is used by B. subtilis at a later growth stage than PAA and the lambda PL promoter at a still later stage than lambda PR. The data enables lambda PR to be considered as quite useful for Bacilli.     

Directional ligation of long-flanking homology regions to selection cassettes for efficient targeted gene-disruption in Candida albicans

PCR-product directed gene disruption with a marker cassette having short homology regions is often used in Candida albicans. However, it is quite inefficient due to the high frequency of non-homologous recombination at non-targeted loci, which necessitates extensive screening to identify the correct disruptants. Thus, many PCR-based methods to introduce long flanking homology regions have been developed to increase the frequency of integration at the targeted loci. However, these methods are not that amenable for use with the widely employed C. albicans marker cassettes having direct repeats, as these repeats tend to recombine during PCR, resulting in shorter amplified products without the selection marker. To circumvent this limitation, we have developed a dinucleotide-sticky-end-ligation strategy to add one flanking homology region to one side of the selection cassette, and the other flanking homology region to the other side of the selection cassette. This method involves release of the selection cassette from the plasmid by digestion with two different restriction enzymes, followed by partial fill-in, to provide a unique two base overhang at each end of the cassette. The flanking homology regions, corresponding to the gene to be disrupted, are individually PCR-amplified, and treated with T4-DNA Polymerase in the presence of appropriate dNTPs to yield two base-5' overhangs. The primers used for the PCR have additional bases at the 5' ends such that after T4 DNA Polymerase treatment, the two flanks will have distinct overhangs compatible with the overhangs of the partially filled-in selection cassette. The selection cassette and the flanks are then ligated together and directly used to transform C. albicans. We have successfully used this method for disruption of several C. albicans genes. We have also used this method to recreate insertion mutations obtained with transposons to reconfirm the mutant phenotypes. This approach can be extended to other organisms like Schizosaccharomyces pombe which also require long flanking regions of homology for targeted gene disruption.     

Construction of an Arxula adeninivorans host-vector system based on trp1 complementation

A host/vector expression system based on an Arxula adeninivorans Delta atrp1 gene disruption mutant has been constructed. For this purpose the ATRP1 gene encoding a phosphoribosyl anthranilate isomerase was isolated from the yeast A. adeninivorans and its genome locus was characterized. The Delta atrp1 mutant was generated applying an amplified DNA fragment containing the ALEU2m gene flanked by ATRP1 gene sequences of some 750 bp. The generated auxotrophic host strain was transformed with the plasmid pAL-ATRP1-amyA, which contains the ATRP1 gene as selection marker and the 25S rDNA for targeting. For expression assessment, the plasmid was equipped with an expression cassette consisting of the Bacillus amyloliquefaciens-derived amyA gene fused to the constitutive A. adeninivorans-derived TEF1 promoter and Saccharomyces cerevisiae-derived PHO5 terminator. Transformants contained a single chromosomal copy of the heterologous DNA and were found to be mitotically stable. In initial fermentation trials on a 200 ml shake flask scale maximal alpha-amylase product levels of ca. 300 nkat ml(-1) were observed after 72 h of cultivation with more than 95% of the recombinant alpha-amylase accumulated in the culture medium.     

Molecular cloning and the biochemical characterization of two novel phytases from B. subtilis 168 and B. licheniformis

A novel phytase gene ( phyL) was cloned from Bacillus licheniformis by multiple steps of degenerate and inverse PCR. The coding region of the phyL gene was 1,146 bp in size and a promoter region of approximately 300 bp was identified at the upstream sequence. This gene, together with a phytase gene ( 168phyA) identified in the B. subtilis strain 168 genome by a homology search, was cloned and over-expressed in B. subtilis using a phi105MU331 prophage vector system. Up to 35 units of phytase/ml were secreted into the culture media; and mature enzymes of around 44-47 kDa were purified for characterization. Both phytases exhibited broad temperature and pH optima and showed high thermostability. Of the two, the phytase encoded by phyL exhibited higher thermostability, even at a lower calcium concentration, as it was able to recover 80% of its original activity after denaturation at 95 degrees C for 10 min. With their neutral pH optima and good temperature stabilities, these Bacillus phytases are good candidates for animal feed applications and transgenic studies.     

The gene amyE(TV1) codes for a nonglucogenic alpha-amylase from Thermoactinomyces vulgaris 94-2A in Bacillus subtilis.

We isolated the gene amyE(TV1) from Thermoactinomyces vulgaris 94-2A encoding a nonglucogenic alpha-amylase (AmyTV1). A chromosomal DNA fragment of 2,247 bp contained an open reading frame of 483 codons, which was expressed in Escherichia coli and Bacillus subtilis. The deduced amino acid sequence of the AmyTV1 protein was confirmed by sequencing of several peptides derived from the enzyme isolated from a T. vulgaris 94-2A culture. The amino acid sequence was aligned with several known alpha-amylase sequences. We found 83% homology with the 48-kDa alpha-amylase part of the Bacillus polymyxa beta-alpha-amylase polyprotein and 50% homology with Taka amylase A of Aspergillus oryzae but only 45% homology with another T. vulgaris amylase (neopullulanase, TVA II) recently cloned from strain R-47. The putative promoter region was characterized with primer extension and deletion experiments and by expression studies with B. subtilis. Multiple promoter sites (P3, P2, and P1) were found; P1 alone drives about 1/10 of the AmyTV1 expression directed by the native tandem configuration P3P2P1. The expression levels in B. subtilis could be enhanced by fusion of the amyE(TV1) coding region to the promoter of the Bacillus amyloliquefaciens alpha-amylase gene.     

Expression and secretion of carboxymethyl cellulase in Bacillus subtilis by Lactobacillus casei lactate dehydrogenase gene promoter

The secretion ability of the signal peptide of carboxymethyl cellulase (CMCase) was combined with the high expression ability of the Lactobacillus casei lactate dehydrogenase gene (ldh) promoter sequence (P) in Bacillus subtilis RM125. The CMCase was successfully secreted to the culture medium and the enzyme activity by P (11.2 U/ml) was approximately 4 fold higher than by its own promoter (2.7 U/ml).     

Sequential gene disruption in Candida albicans by FLP-mediated site-specific recombination

The genetic manipulation of the human fungal pathogen Candida albicans is difficult because of its diploid genome, the lack of a known sexual phase and its unusual codon usage. We devised a new method for sequential gene disruption in C. albicans that is based on the repeated use of the URA3 marker for selection of transformants and its subsequent deletion by FLP-mediated, site-specific recombination. A cassette was constructed that, in addition to the URA3 selection marker, contained an inducible SAP2P-FLP fusion and was flanked by direct repeats of the minimal FLP recognition site (FRT). This URA3 flipper cassette was used to generate homozygous C. albicans mutants disrupted for both alleles of either the CDR4 gene, encoding an ABC transporter, or the MDR1 gene, encoding a membrane transport protein of the major facilitator superfamily. After insertion of the URA3 flipper into the first copy of the target gene, the whole cassette could be efficiently excised by induced FLP-mediated recombination, leaving one FRT site in the disrupted allele of the target gene. The URA3 flipper was then used for another round of mutagenesis to disrupt the second allele. Deletion of the cassette from primary and secondary transformants occurred exclusively by intrachromosomal recombination of the FRT sites flanking the URA3 flipper, whereas interchromosomal recombination between FRT sites on the homologous chromosomes was never observed. This new gene disruption strategy facilitates the generation of specific, homozygous C. albicans mutants as it eliminates the need for a negative selection scheme for marker deletion and minimizes the risk of mitotic recombination in sequential disruption experiments.     

Removal of heterologous sequences from Plasmodium falciparum mutants using FLPe-recombinase

Genetically-modified mutants are now indispensable Plasmodium gene-function reagents, which are also being pursued as genetically attenuated parasite vaccines. Currently, the generation of transgenic malaria-parasites requires the use of drug-resistance markers. Here we present the development of an FRT/FLP-recombinase system that enables the generation of transgenic parasites free of resistance genes. We demonstrate in the human malaria parasite, P. falciparum, the complete and efficient removal of the introduced resistance gene. We targeted two neighbouring genes, p52 and p36, using a construct that has a selectable marker cassette flanked by FRT-sequences. This permitted the subsequent removal of the selectable marker cassette by transient transfection of a plasmid that expressed a 37°C thermostable and enhanced FLP-recombinase. This method of removing heterologous DNA sequences from the genome opens up new possibilities in Plasmodium research to sequentially target multiple genes and for using genetically-modified parasites as live, attenuated malaria vaccines.     

Scarless and sequential gene modification in <Emphasis Type="Italic">Pseudomonas</Emphasis> using PCR product flanked by short homology regions

Background  

The lambda Red recombination system has been used to inactivate chromosomal genes in various bacteria and fungi. The procedure consists of electroporating a polymerase chain reaction (PCR) fragment containing antibiotic cassette flanked by homology regions to the target locus into a strain that can express the lambda Red proteins (Gam, Bet, Exo).     

Overproduction and purification of Bacillus subtilis DNA polymerase III.

The objectives of this work were to engineer the cloned polC gene encoding Bacillus subtilis DNA polymerase III for controlled overexpression in Escherichia coli and to devise a facile purification scheme permitting the large-scale production of pure recombinant polymerase. The translational signals of polC were restructured by expression cassette PCR (MacFerrin et al., 1990, Proc. Natl. Acad. Sci. USA 87, 1937-1941), and the modified gene was inserted into the expression plasmid, pKC30 (Rosenberg et al., 1983, in "Methods in Enzymology," Vol. 101, pp. 123-138, Academic Press, San Diego), under the strict control of the coliphage lambda pL promoter and its repressor, cI. When the system was derepressed at 32 degrees C, soluble DNA polymerase III accumulated at levels approximating 2% of total cellular protein. The recombinant protein was purified to greater than 99% purity by utilizing a tandem combination of Cibacron blue agarose, phenyl-Sepharose, and MonoQ FPLC chromatography. The properties of the purified recombinant protein were indistinguishable from those of native B. subtilis DNA polymerase III.     

PCR- and ligation-mediated synthesis of split-marker cassettes with long flanking homology regions for gene disruption in Candida albicans

Because Candida albicans is a diploid organism, two consecutive steps of gene disruption are required to generate a gene knock-out. The same marker (URA3) is often used for disruption of both copies of the gene. This is possible because, after the first round of disruption, homologous recombination between direct repeats flanking the URA3 marker and the subsequent counterselection allow for the efficient recovery of Ura- revertants. Unfortunately, the URA-blaster disruption cassette cannot be used in a PCR-based disruption approach. The hisG repeats flanking the URA3 gene in the disruption cassette anneal to one another during PCR and thereby prevent amplification of the complete cassette. We explored the use of transformation based on split-marker recombination to circumvent this problem. To avoid any cloning steps and to retain the advantage of long flanking regions for disruption, we combined this with a PCR- and ligation-mediated approach for generating marker cassettes. We used this approach to disrupt the C. albicans FAL1 (ATP-dependent RNA helicase) gene. Long 5' and 3' FAL1-specific regions were amplified by PCR and individually ligated to a URA-blaster cassette. The resulting ligation reactions were used separately as templates to generate two FAL1 disruption cassettes with overlapping URA3 marker regions. Simultaneous transformation with both overlapping disruption cassettes yielded efficient disruption of one FAL1 allele.