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.     

Novel Method for Genomic Promoter Shuffling by Using Recyclable Cassettes

Genetic elements of interest can be introduced into the Saccharomyces cerevisiae genome via homologous recombination. The current method is to link such an element to a selectable marker gene to be integrated into the target locus. However, the marker gene in this method cannot be reused, which limits repeated manipulation of the yeast genome. An alternative method is to utilize a counterselectable gene, such as URA3, with flanking tandem repeats. After integration, URA3 along with one copy of the repeat can be popped out via internal recombination, leaving behind one copy of the unwanted repeat. Here we describe a novel concept of genetic element shuffling in which the tandem repeats are made of the desired genetic element, so that after integration and popping out, only one copy of the element remains at the desired locus to function. As a proof of principle, we constructed three recyclable cassettes (P_PGK1-URA3-P_PGK1, P_GAL1-URA3-P_GAL1, and P_tetO7-URA3-P_tetO7) and integrated them upstream of an engineered chromosomal P_HIS3-mCherry-Myc locus. After promoter shuffling, the mCherry-Myc gene was regulated precisely as anticipated.     

A Method for Gene Disruption That Allows Repeated Use of USR3 Selection in the Construction of Multiply Disrupted Yeast Strains

In this paper, we describe a 3.8-kb molecular construct that we have used to disrupt yeast genes. The construct consists of a functional yeast URA3 gene flanked by 1.1-kb direct repeats of a bacterial sequence. It is straightforward to insert the 3.8-kb segment into a cloned target gene of interest and then introduce the resulting disruption into the yeast genome by integrative transformation. An appropriate DNA fragment containing the disruption plus flanking homology can be obtained by restriction enzyme digestion. After introducing such fragments into yeast by transformation, stable integrants can be isolated by selection for Ura+. The important feature of this construct that makes it especially useful is that recombination between the flanking direct repeats occurs at a high frequency (10(-4)) in vegetatively grown cultures. After excision, only one copy of the repeat sequence remains behind. Thus in the resulting strain, the Ura+ selection can be used again, either to disrupt a second gene in similar fashion or for another purpose.     

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.     

Isogenic Strain Construction and Gene Mapping in Candida Albicans

Genetic manipulation of Candida albicans is constrained by its diploid genome and asexual life cycle. Recessive mutations are not expressed when heterozygous and undesired mutations introduced in the course of random mutagenesis cannot be removed by genetic back-crossing. To circumvent these problems, we developed a genotypic screen that permitted identification of a heterozygous recessive mutation at the URA3 locus. The mutation was introduced by targeted mutagenesis, homologous integration of transforming DNA, to avoid introduction of extraneous mutations. The ura3 mutation was rendered homozygous by a second round of transformation resulting in a Ura(-) strain otherwise isogenic with the parental clinical isolate. Subsequent mutation of the Ura(-) strain was achieved by targeted mutagenesis using the URA3 gene as a selectable marker. URA3 selection was used repeatedly for the sequential introduction of mutations by flanking the URA3 gene with direct repeats of the Salmonella typhimurium hisG gene. Spontaneous intrachromosomal recombination between the flanking repeats excised the URA3 gene restoring a Ura(-) phenotype. These Ura(-) segregants were selected on 5-fluoroorotic acid-containing medium and used in the next round of mutagenesis. To permit the physical mapping of disrupted genes, the 18-bp recognition sequence of the endonuclease I-SceI was incorporated into the hisG repeats. Site-specific cleavage of the chromosome with I-SceI revealed the position of the integrated sequences.     

A New Method for Repeated “Self-Cloning” Promoter Replacement in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

A method for repeated PCR-mediated promoter replacement in the yeast Saccharomyces cerevisiae is described. It was proposed to use the DNA fragment comprising the marker gene that enables both positive and negative selection (a selectable/counter-selectable marker) surrounded by direct repeats of the desired promoter as a promoter replacement cassette. This fragment is integrated upstream of the target gene because of PCR-added terminal sequences for homologous recombination with the target locus. Subsequent marker excision via homologous recombination between the copies of the two promoters leaves one copy of the desired promoter upstream of the target genes, without any heterologous scar sequence. To test this method, a set of plasmids bearing the S. cerevisiae URA3 gene surrounded by two copies of the ADH1 or PGK1 promoter was constructed. Using these cassettes, the native promoters of the GSH1 and GSH2 genes were replaced in the ura3Δ0 recipient strains. The proposed method is useful for research applications due to simple marker excision, and for construction of “self-cloning” industrial strains, because no heterologous DNA is retained in the genome of the resulting strain after marker excision.     

Development of an efficient genetic manipulation strategy for sequential gene disruption and expression of different heterologous <Emphasis Type="Italic">GFP</Emphasis> genes in <Emphasis Type="Italic">Candida tropicalis</Emphasis>

The diploid yeast Candida tropicalis, which can utilize n-alkane as a carbon and energy source, is an attractive strain for both physiological studies and practical applications. However, it presents some characteristics, such as rare codon usage, difficulty in sequential gene disruption, and inefficiency in foreign gene expression, that hamper strain improvement through genetic engineering. In this work, we present a simple and effective method for sequential gene disruption in C. tropicalis based on the use of an auxotrophic mutant host defective in orotidine monophosphate decarboxylase (URA3). The disruption cassette, which consists of a functional yeast URA3 gene flanked by a 0.3 kb gene disruption auxiliary sequence (gda) direct repeat derived from downstream or upstream of the URA3 gene and of homologous arms of the target gene, was constructed and introduced into the yeast genome by integrative transformation. Stable integrants were isolated by selection for Ura⁺ and identified by PCR and sequencing. The important feature of this construct, which makes it very attractive, is that recombination between the flanking direct gda repeats occurs at a high frequency (10^?8) during mitosis. After excision of the URA3 marker, only one copy of the gda sequence remains at the recombinant locus. Thus, the resulting ura3 strain can be used again to disrupt a second allelic gene in a similar manner. In addition to this effective sequential gene disruption method, a codon-optimized green fluorescent protein-encoding gene (GFP) was functionally expressed in C. tropicalis. Thus, we propose a simple and reliable method to improve C. tropicalis by genetic manipulation.     

mazF as a counter-selectable marker for unmarked genetic modification of Pichia pastoris

In this study, we demonstrate a novel method for unmarked genetic modification of the methylotrophic yeast Pichia pastoris , in which the Escherichia coli toxin gene mazF was used as a counter-selectable marker. mazF was placed under the tightly controlled AOX1 promoter, and the induced expression of MazF in P. pastoris halted cell growth. A modular plasmid was constructed in which mazF and a Zeocin resistance gene acted as counter-selectable and active-selectable markers, respectively, and the MazF-ZeoR cassette was flanked by two direct repeats for marker recycling. Linearized delivery vectors constructed from the modular plasmid were integrated into the P. pastoris genome via homologous recombination, introducing genetic modifications. Upon counter-selection with methanol medium, which induces the AOX1 promoter, the markers were recycled efficiently via homologous recombination between the direct repeats. We used this method successfully to knock-out the ARG1 and MET2 genes, knock-in a green fluorescent protein expression cassette, and perform site-directed mutagenesis on the ARG1 gene, all without introducing unwanted selection markers. The novel method allows repeated use of the selectable marker gene for multiple modifications and will be a useful tool for P. pastoris studies.     

A genetic system for direct selection of gene-positive clones during recombinational cloning in yeast

Transformation-associated recombination (TAR) is a cloning technique that allows specific chromosomal regions or genes to be isolated directly from genomic DNA without prior construction of a genomic library. This technique involves homologous recombination during spheroplast transformation between genomic DNA and a TAR vector that has 5′ and 3′ gene targeting sequences (hooks). Typically, TAR cloning produces positive YAC recombinants at a frequency of ~0.5%; the positive clones are identified by PCR or colony hybridization. This paper describes a novel TAR cloning procedure that selects positive clones by positive and negative genetic selection. This system utilizes a TAR vector with two targeting hooks, HIS3 as a positive selectable marker, URA3 as a negative selectable marker and a gene-specific sequence called a loop sequence. The loop sequence lies distal to a targeting hook sequence in the chromosomal target, but proximal to the targeting hook and URA3 in the TAR vector. When this vector recombines with chromosomal DNA at the gene-specific targeting hook, the recombinant YAC product carries two copies of the loop sequence, therefore, the URA3 negative selectable marker becomes mitotically unstable and is lost at high frequency by direct repeat recombination involving the loop sequence. Positive clones are identified by selecting against URA3. This method produces positive YAC recombinants at a frequency of ~40%. This novel TAR cloning method provides a powerful tool for structural and functional analysis of complex genomes.     

Development of an integrative DNA transformation system for the yeast Candida tropicalis.

We developed the alkane and fatty-acid utilizing yeast Candida tropicalis as a host for DNA transformations. The system is based on an auxotrophic mutant host of C. tropicalis which is defective in orotidine monophosphate decarboxylase (ura3). The ura3 host was isolated by mutagenesis and a double-selection procedure that combined nystatin enrichment selection and 5-fluoro-orotic acid resistance selection. As a selectable marker, we isolated and characterized the C. tropicalis URA3 gene. Plasmid vectors that contained the C. tropicalis URA3 gene transformed the C. tropicalis mutant host at a frequency of 10(3) to 10(4) transformants per micrograms of plasmid DNA. Vectors that contained the Saccharomyces cerevisiae URA3 gene could not transform C. tropicalis. DNA transfer was accomplished by modified versions of either spheroplast generation (CaCl2-polyethylene glycol)-fusion or cation (LiCl) procedures developed for S. cerevisiae. Plasmid vectors that had been cut within the C. tropicalis URA3 fragment integrated by homologous recombination at the URA3 locus.     

Isolation of metabolic genes and demonstration of gene disruption in the phytopathogenic fungus Ustilago maydis

A cDNA library was constructed in the yeast expression vector pYcDE8 using mRNA from the phytopathogenic fungus Ustilago maydis and cDNAs capable of complementing mutations in three yeast genes, URA3, LEU2 and TPI1, were identified. Nucleotide sequence analysis indicated that the cDNA clone, which complemented the yeast ura3 mutation, carries the pyr6 gene encoding orotidine-5'-phosphate decarboxylase. The genomic copy of the pyr6 gene was isolated by hybridization with the cDNA and used to complement a pyr- mutant of U. maydis. One-step gene disruption was demonstrated by transforming U. maydis with a copy of the pyr6 gene interrupted in the coding region by a selectable marker for resistance to hygromycin B.     

Generation of a selectable marker free,highly expressed single copy locus as landing pad for transgene stacking in sugarcane

Key message

A selectable marker free, highly expressed single copy locus flanked by insulators was created as landing pad for transgene stacking in sugarcane. These events displayed superior transgene expression compared to single-copy transgenic lines lacking insulators. Excision of the selectable marker gene from transgenic sugarcane lines was supported by FLPe/FRT site-specific recombination.

Abstract

Sugarcane, a tropical C4 grass in the genus Saccharum (Poaceae), accounts for nearly 80% of sugar produced worldwide and is also an important feedstock for biofuel production. Generating transgenic sugarcane with predictable and stable transgene expression is critical for crop improvement. In this study, we generated a highly expressed single copy locus as landing pad for transgene stacking. Transgenic sugarcane lines with stable integration of a single copy nptII expression cassette flanked by insulators supported higher transgene expression along with reduced line to line variation when compared to single copy events without insulators by NPTII ELISA analysis. Subsequently, the nptII selectable marker gene was efficiently excised from the sugarcane genome by the FLPe/FRT site-specific recombination system to create selectable marker free plants. This study provides valuable resources for future gene stacking using site-specific recombination or genome editing tools.

     

Transformation system for an asporogenous methylotrophic yeast, Candida boidinii: cloning of the orotidine-5''-phosphate decarboxylase gene (URA3), isolation of uracil auxotrophic mutants, and use of the mutants for integrative transformation.

An integrative transformation system was established for an asporogenous methylotrophic yeast, Candida boidinii. This system uses a uracil auxotrophic mutant of C. boidinii as the host strain in combination with its URA3 gene as the selectable marker. First, the C. boidinii URA3 gene coding for orotidine-5'-phosphate decarboxylase (ODCase) was cloned by using complementation of the pyrF mutation of Escherichia coli. Next, the host ODCase-negative mutant strains (ura3 strains) were isolated by mutagenesis and selection for 5-fluro-orotic acid (5-FOA) resistance. Five ura3 host strains that exhibited both a low reversion rate and good methylotrophic growth were obtained. All of these strains could be transformed to Ura+ phenotype with a C. boidinii URA3-harboring plasmid linearized within the Candida DNA. The transformants had a stable Ura+ phenotype after nonselective growth for 10 generations. These results and extensive Southern analysis indicated that the linearized plasmid was integrated into the host chromosomal DNA by homologous recombination at the URA3 locus in C. boidinii.     

Fluorescence based assay of GAL system in yeast Saccharomyces cerevisiae

The GAL1 promoter is one of the strongest inducible promoters in the yeast Saccharomyces cerevisiae. In order to improve recombinant protein production we have developed a fluorescence based method for screening and evaluating the contribution of various gene deletions to protein expression from the GAL1 promoter. The level of protein synthesis was determined in 28 selected mutant strains simultaneously, by direct measurement of fluorescence in living cells using a microplate reader. The highest, 2.4-fold increase in GFP production was observed in a gal1 mutant strain. Deletion of GAL80 caused a 1.3-fold increase in fluorescence relative to the isogenic strain. GAL3, GAL4 and MTH1 gene deletion completely abrogated GFP synthesis. Growth of gal7, gal10 and gal3 also exhibited reduced fitness in galactose medium. Other genetic perturbations affected the GFP expression level only moderately. The fluorescence based method proved to be useful for screening genes involved in GAL1 promoter regulation and provides insight into more efficient manipulation of the GAL system.     

Amplification of drug resistance genes flanked by inversely repeated IS1 elements: involvement of IS1-promoted DNA rearrangements before amplification.

Tn2653 contains one copy of the tet gene and two copies of the cat gene derived from plasmid pBR325 and is flanked by inverted repeats of IS1. Transposed onto the P1-15 prophage, it confers a chloramphenicol resistance phenotype to the Escherichia coli host. Because the prophage is perpetuated as a plasmid at about one copy per host chromosome, the host cell is still tetracycline sensitive even though P1-15 is carrying one copy of the tet gene. We isolated P1-15::Tn2653 mutants conferring a tetracycline resistance phenotype, in which the whole transposon and variable flanking P1-15 DNA segments were amplified. Amplification was most probably preceded by IS1-mediated DNA rearrangements which led to long direct repeats containing Tn2653 sequences and P1-15 DNA. Subsequent recombination events between these direct repeats led to amplification of a segment containing the tetracycline resistance gene in tandem arrays.     

Cre-loxP重组系统删除内源性选择标记基因的效能评价

选择标记的使用和残留可引起消费者对转基因生物环境安全和产品安全的担忧,建立消除选择标记的有效对策甚为必要.本研究的目标是评价Cre-LoxP重组系统删除内源性选择标记基因的效能,为猪安全转基因研究提供实验依据和技术支撑.本文所用的打靶载体ΔMSTN含有LoxP位点锚定的选择标记表达框(LoxP-CMV-NeoR-IRES-EGFP-LoxP). 经电穿孔将该打靶载体导入猪肾PK15细胞,经G418筛选,获得稳定整合该载体、EGFP表达均一的单克隆细胞系. 将Cre重组酶表达载体pTurbo-Cre导入该细胞系,借助流式分选（FACS）、终点PCR、荧光定量PCR、TA克隆与测序等手段,证明Cre-LoxP重组系统可在猪细胞内高效介导内源性选择标记基因的删除反应,EGFP水平的删除效率达到46.1 %,DNA水平的删除效率则达到97 %.本文的研究结果为消除选择标记的安全隐患提供了可靠的解决方案,为建立猪安全转基因技术提供了重要的科学依据.     

Meiotic recombination within the centromere of a yeast chromosome

In order to examine the frequency of nonreciprocal recombination (gene conversion) within the centromere of the yeast chromosome, we constructed strains that contained heterozygous restriction sites in the conserved centromere sequences of chromosome III in addition to heterozygous markers flanking the centromere. One of these markers was the selectable URA3 gene, which was inserted less than one kb from the centromere. We found that meiotic conversion of the URA3 gene occurred at normal frequency (about 2% of unselected tetrads) and that more than one-third of these convertants coconverted the markers within the centromere. In addition, we observed tetrads in which conversion events extended through the centromere to include a marker on the opposite side from URA3. We conclude that meiotic conversion events occur within the centromere at rates similar to other genomic sequences.     

Adaptation of the yeast URA3 selection system to gram-negative bacteria and generation of a {delta}betCDE Pseudomonas putida strain

A general procedure for efficient generation of gene knockouts in gram-negative bacteria by the adaptation of the Saccharomyces cerevisiae URA3 selection system is described. A Pseudomonas putida strain lacking the URA3 homolog pyrF (encoding orotidine-5'-phosphate decarboxylase) was constructed, allowing the use of a plasmid-borne copy of the gene as the target of selection. The delivery vector pTEC contains the pyrF gene and promoter, a conditional origin of replication (oriR6K), an origin of transfer (mobRK2), and an antibiotic selection marker flanked by multiple sites for cloning appropriate DNA segments. The versatility of pyrF as a selection system, allowing both positive and negative selection of the marker, and the robustness of the selection, where pyrF is associated with uracil prototrophy and fluoroorotic acid sensitivity, make this setup a powerful tool for efficient homologous gene replacement in gram-negative bacteria. The system has been instrumental for complete deletion of the P. putida choline-O-sulfate utilization operon betCDE, a mutant which could not be produced by any of the other genetic strategies available.