High-efficiency gene inactivation and replacement system for gram-positive bacteria.

A system for high-efficiency single- and double-crossover homologous integration in gram-positive bacteria has been developed, with Lactococcus lactis as a model system. The system is based on a thermosensitive broad-host-range rolling-circle plasmid, pG+host5, which contains a pBR322 replicon for propagation in Escherichia coli at 37 degrees C. A nested set of L. lactis chromosomal fragments cloned onto pG+host5 were used to show that the single-crossover integration frequency was logarithmically proportional to the length of homology for DNA fragments between 0.35 and 2.5 kb. Using random chromosomal 1-kb fragments, we showed that homologous integration can occur along the entire chromosome. We made use of the reported stimulatory effect of rolling-circle replication on intramolecular recombination to develop a protocol for gene replacement. Cultures were first maintained at 37 degrees C to select for a bacterial population enriched for plasmid integrants; activation of the integrated rolling-circle plasmid by a temperature shift to 28 degrees C resulted in efficient plasmid excision by homologous recombination and replacement of a chromosomal gene by the plasmid-carried modified copy. More than 50% of cells underwent replacement recombination when selection was applied for the replacing gene. Between 1 and 40% of cells underwent replacement recombination when no selection was applied. Chromosomal insertions and deletions were obtained in this way. These results show that gene replacement can be obtained at an extremely high efficiency by making use of the thermosensitive rolling-circle nature of the delivery vector. This procedure is applicable to numerous gram-positive bacteria.     

Development of a lactococcal integration vector by using IS981 and a temperature-sensitive lactococcal replication region.

A vector (pKMP10) capable of Campbell-like integration into the Lactococcus lactis subsp. lactis LM0230 chromosome via homologous recombination with chromosomal IS981 sequences was constructed from the replication region of lactococcal plasmid pSK11L, an internal fragment of IS981, and the erythromycin resistance gene and Escherichia coli replication origin of pVA891. The pSK11L replication region is temperature sensitive for maintenance in L. lactis subsp. lactis LM0230, resulting in loss of unintegrated pKMP10 during growth at greater than 37 degrees C. pKMP10 integrants made up 8 to 75% of LM0230(pKMP10) erythromycin-resistant cells following successive growth at 25 degrees C with selection, 39 degrees C without selection, and 39 degrees C with selection. pKMP10 integrants were also isolated from L. lactis subsp. lactis MG1363(pKMP10) but at a 10-fold-lower frequency (4%). No integrants were isolated form L. lactis subsp. lactis MMS368(pKMP10) (a Rec-deficient strain) or LM0230(pKMP1-E) (the corresponding plasmid lacking the IS981 fragment). Examination of 17 LM0230 integrants by Southern hybridization revealed pKMP10 integration into five different chromosomal sites. Four of the integration sites appeared to be chromosomal IS981 sequences, while one was an uncharacterized chromosomal sequence. The four IS981 integrants seemed to have pKMP10 integrated in a tandem repeat structure of undetermined length. Integrated pKMP10 was more stable (0 to 2% plasmid loss) than unintegrated pKMP10 (100% plasmid loss) when grown for 100 generations at 32 degrees C without selection.     

Development of a lactococcal integration vector by using IS981 and a temperature-sensitive lactococcal replication region.

A vector (pKMP10) capable of Campbell-like integration into the Lactococcus lactis subsp. lactis LM0230 chromosome via homologous recombination with chromosomal IS981 sequences was constructed from the replication region of lactococcal plasmid pSK11L, an internal fragment of IS981, and the erythromycin resistance gene and Escherichia coli replication origin of pVA891. The pSK11L replication region is temperature sensitive for maintenance in L. lactis subsp. lactis LM0230, resulting in loss of unintegrated pKMP10 during growth at greater than 37 degrees C. pKMP10 integrants made up 8 to 75% of LM0230(pKMP10) erythromycin-resistant cells following successive growth at 25 degrees C with selection, 39 degrees C without selection, and 39 degrees C with selection. pKMP10 integrants were also isolated from L. lactis subsp. lactis MG1363(pKMP10) but at a 10-fold-lower frequency (4%). No integrants were isolated form L. lactis subsp. lactis MMS368(pKMP10) (a Rec-deficient strain) or LM0230(pKMP1-E) (the corresponding plasmid lacking the IS981 fragment). Examination of 17 LM0230 integrants by Southern hybridization revealed pKMP10 integration into five different chromosomal sites. Four of the integration sites appeared to be chromosomal IS981 sequences, while one was an uncharacterized chromosomal sequence. The four IS981 integrants seemed to have pKMP10 integrated in a tandem repeat structure of undetermined length. Integrated pKMP10 was more stable (0 to 2% plasmid loss) than unintegrated pKMP10 (100% plasmid loss) when grown for 100 generations at 32 degrees C without selection.     

New method for generating deletions and gene replacements in Escherichia coli.

We describe a method for generating gene replacements and deletions in Escherichia coli. The technique is simple and rapid and can be applied to most genes, even those that are essential. What makes this method unique and particularly effective is the use of a temperature-sensitive pSC101 replicon to facilitate the gene replacement. The method proceeds by homologous recombination between a gene on the chromosome and homologous sequences carried on a plasmid temperature sensitive for DNA replication. Thus, after transformation of the plasmid into an appropriate host, it is possible to select for integration of the plasmid into the chromosome at 44 degrees C. Subsequent growth of these cointegrates at 30 degrees C leads to a second recombination event, resulting in their resolution. Depending on where the second recombination event takes place, the chromosome will either have undergone a gene replacement or retain the original copy of the gene. The procedure can also be used to effect the transfer of an allele from a plasmid to the chromosome or to rescue a chromosomal allele onto a plasmid. Since the resolved plasmid can be maintained by selection, this technique can be used to generate deletions of essential genes.     

Efficient Targeted Integration at Leu1-32 and Ura4-294 in Schizosaccharomyces Pombe

Homologous integration into the fission yeast Schizosaccharomyces pombe has not been well characterized. In this study, we have examined integration of plasmids carrying the leu1(+) and ura4(+) genes into their chromosomal loci. Genomic DNA blot analysis demonstrated that the majority of transformants have one or more copies of the plasmid vector integrated via homologous recombination with a much smaller fraction of gene conversion to leu1(+) or ura4(+). Non-homologous recombination events were not observed for either gene. We describe the construction of generally useful leu1(+) and ura4(+) plasmids for targeted integration at the leu1-32 and ura4-294 loci of S. pombe.     

Strategy for chromosomal gene targeting in RecA-deficient Escherichia coli strains

Reengineering DNA by homologous recombination in Escherichia coli often depends on helper functions provided on a temporarily introduced replicon that is subsequently cured from the cells. The suicide vector pKSS offers a new curing strategy. pKSS specifies a variant of phenylalanyl-transfer RNA (tRNA) synthetase conferring relaxed substrate specificity towards phenylalanine analogs that results in their lethal incorporation into cellular proteins. Consequently, the presence of p-chlorophenylalanine selects for strains that have lost pKSS. This principle, in conjunction with a plasmid-borne recA gene, was exploited for targeted chromosomal mutagenesis by double homologous recombination in RecA-negative E. coli strains. Gene replacement with a kanamycin-resistance cassette was possible in a single step by plating on kanamycin and p-chlorophenylalanine agar plates and incubating at 37 degrees C. The presence of the correct chromosomal mutation and the absence of the plasmid were established by several control experiments. A simple screen confirmed the desired resistance phenotype in 44% of the initially selected clones, and 75% of these had the correct genotype.     

A strategy to construct vector-free amylolytic strains through nondisruptive homologous recombination: application to Enterococcus faecalis.

In order to direct chromosomal integration of the alpha-amylase-encoding gene from Bacillus licheniformis (amyL) under the control of expression and secretion signals from Enterococcus faecalis, the chromosomal fragment (named AB) from the pGIP3124 plasmid [Hols et al., Gene 118 (1992) 21-30] was chosen and split into two fragments (A and B). A translation fusion between the A fragment and 'amyL, deleted of its expression and secretion signals, was made and this fusion was flanked with the AB fragment at its right end. The A::'amyL:AB integration module was cloned into a thermosensitive pE194 replicon (chloramphenicol resistant; CmR) and electro-transformed into E. faecalis OG1X. After an overnight culture in selective liquid medium, the offspring from the amylolytic transformants obtained was shown to yield CmR colonies with two distinct halo sizes on iodine-stained starch plates. Southern analysis clearly showed that the smaller halos corresponded to descendants in which the plasmid had integrated into the chromosome through homologous recombination. One such Amy+ integrant in the AB site was further cultured under nonselective conditions at 42 degrees C for about 20 generations, and the offspring was screened for Amy+/CmS clones. Such revertants were indeed found, and Southern analysis clearly showed that the vector matrix had been excised through homologous recombination between the redundant A sites, leaving the integrated amy gene intact.     

Transposition of pGh9:ISS1 is random and efficient in Streptococcus thermophilus CNRZ368

Streptococcus thermophilus bacteria are used as a starter in the fermentation of yogurts and many cheeses. To construct mutants of S. thermophilus CNRZ368, the use of the plasmid pGh9:ISS1 was considered. This plasmid is known to be a good tool for insertional mutagenesis in gram-positive bacteria, owing to its ability to integrate in the genome by a mechanism of replicative transposition. However, the presence of three endogenous ISS1 copies in the genome of S. thermophilus CNRZ368 and the possible occurrence of homologous recombination could reduce the efficiency of pGh9:ISS1 as a tool for generating mutants. To address this question, the ability of pGh9:ISS1 to transpose randomly in the genome of strain CNRZ368 was investigated. The results of our experiments indicated that: (i) the frequency of transposition of ISS1 was high, approximately 2 x 10(-2), in S. thermophilus CNRZ368; (ii) the integration of multiple tandem copies of the plasmid was frequent; (iii) homologous recombination events between ISS1 were not predominant; and (iv) plasmid pGh9:ISS1 transposed randomly around the S. thermophilus CNRZ368 chromosome. In addition, we describe the strategy used to localize the pGh9:ISS1 insertion locus on the physical map of strain CNRZ368 and the method used to clone the regions flanking this insertion site, especially when multiple copies of the plasmid were integrated in tandem.     

Target frequency and integration pattern for insertion and replacement vectors in embryonic stem cells.

Gene targeting has been used to direct mutations into specific chromosomal loci in murine embryonic stem (ES) cells. The altered locus can be studied in vivo with chimeras and, if the mutated cells contribute to the germ line, in their offspring. Although homologous recombination is the basis for the widely used gene targeting techniques, to date, the mechanism of homologous recombination between a vector and the chromosomal target in mammalian cells is essentially unknown. Here we look at the nature of gene targeting in ES cells by comparing an insertion vector with replacement vectors that target hprt. We found that the insertion vector targeted up to ninefold more frequently than a replacement vector with the same length of homologous sequence. We also observed that the majority of clones targeted with replacement vectors did not recombine as predicted. Analysis of the recombinant structures showed that the external heterologous sequences were often incorporated into the target locus. This observation can be explained by either single reciprocal recombination (vector insertion) of a recircularized vector or double reciprocal recombination/gene conversion (gene replacement) of a vector concatemer. Thus, single reciprocal recombination of an insertion vector occurs 92-fold more frequently than double reciprocal recombination of a replacement vector with crossover junctions on both the long and short arms.     

Replacement recombination in Lactococcus lactis.

In the pUC18-derived integration plasmid pML336 there is a 5.3-kb chromosomal DNA fragment that carries the X-prolyl dipeptidyl aminopeptidase gene (pepXP). The gene was inactivated by the insertion of an erythromycin resistance determinant into its coding sequence. Covalently closed circular DNA of pML336 was used for the electrotransformation of Lactococcus lactis. In 2% of the erythromycin-resistant transformants the pepXP gene was inactivated by a double-crossover event (replacement recombination) between pML336 and the L. lactis chromosome. The other transformants in which the pepXP gene had not been inactivated carried a Campbell-type integrated copy of the plasmid. Loss of part of the Campbell-type integrated plasmid via recombination between 1.6-kb nontandem repeats occurred with low frequencies that varied between less than 2.8 x 10(-6) and 8.5 x 10(-6), producing cells with a chromosomal structure like that of cells in which replacement recombination had taken place.     

The construction of a cloning vector designed for gene replacement in Bordetella pertussis

We report here the construction of a plasmid cloning vector, pRTP1, designed to facilitate exchange of cloned and chromosomal alleles of the human bacterial pathogen Bordetella pertussis. pRTP1 provides the ability to successively select two homologous recombination events within the cloned sequences. The first is by selection for maintenance of the ampicillin-resistance gene on the plasmid which is unable to replicate autonomously after transfer via conjugation. The second selection, via streptomycin (Sm) selection, is against the maintenance of vector sequences which contain a gene encoding the Sm-sensitive allele of the gene for ribosomal protein S12 thus rendering an otherwise Sm-resistant strain Sm-sensitive. We demonstrate the use of this vector to introduce an unmarked mutation, constructed in vitro, into the chromosomal locus encoding pertussis toxin.     

Integration of heterologous plasmid DNA into multiple sites on the genome of Campylobacter coli following natural transformation.

The efficiency of homologous recombination in Campylobacter coli following the introduction of DNA by natural transformation was determined by using a series of nonreplicating integrative vectors containing DNA fragments derived from the C. coli catalase gene. Homologous recombination occurred with as little as 286 homologous bp present and was not detected when 270 bases of homology was provided. Instead, when plasmids with little or no homology to the chromosome were introduced by natural transformation, the vector DNA became chromosomally integrated at random sites scattered throughout the C. coli genome. Southern analysis and nucleotide sequencing revealed that recombination had occurred between nonhomologous sequences and can therefore be described as illegitimate. There were at least five different recombination sites on plasmid pSP105. The ability of C. coli to acquire heterologous plasmids by natural transformation, and maintain them by chromosomal integration following illegitimate recombination, has fascinating implications for the genomic diversity and evolution of this species.     

Homologous recombination and double-strand break repair in the transformation of Rhizopus oryzae

Genetic transformation of the Mucorales fungi has been problematic, since DNA transformed into the host rarely integrates and usually is mitotically unstable in the absence of selective pressure. In this study, transformation of Rhizopus oryzae was investigated to determine if the fate of introduced DNA could be predicted based on double-strand break repair and recombination mechanisms found in other fungi. A transformation system was developed with uracil auxotrophs of Rhizopus oryzae that could be complemented with the pyrG gene isolated in this work. DNA transformed as circular plasmids was maintained extrachromosomally in high-molecular-weight (>23 kb) concatenated arrangement. Type-I crossover integration into the pyrG locus and type-III pyrG gene replacement events occurred in approximately 1-5% of transformants. Linearization of the plasmid pPyr225 with a single restriction enzyme that cleaves within the vector sequence almost always resulted in isolates with replicating concatenated plasmids that had been repaired by end-joining recombination that restored the restriction site. The addition of a 40-bp direct repeat on either side of this cleavage site led to repair by homologous recombination between the repeated sequences on the plasmid, resulting in loss of the restriction site. When plasmid pPyr225 was digested with two different enzymes that cleave within the vector sequence to release the pyrG containing fragment, only pyrG gene replacement recombination occurred in transformants. Linearization of plasmid pPyr225 within the pyrG gene itself gave the highest percentage (20%) of type-I integration at the pyrG locus. However, end-joining repair and gene replacement events were still the predominant types of recombination found in transformations with this plasmid topology.     

Gene disruption and replacement as a feasible approach for mutagenesis of Campylobacter jejuni.

Campylobacter jejuni and Campylobacter coli are important causes of human enteric infections. Several determinants of pathogenicity have been proposed based on the clinical features of diarrheal disease and on the phenotypic properties of Campylobacter strains. To facilitate an understanding of the genetic determinants of Campylobacter virulence, we have developed a method for constructing C. jejuni mutants by shuttle mutagenesis. In the example described here, a kanamycin resistance gene was inserted into Campylobacter DNA fragments encoding 16S rRNA cloned in Escherichia coli. These disrupted, modified sequences were returned to C. jejuni via conjugation. Through the apparent process of homologous recombination, the kanamycin resistance-encoding sequences were rescued by chromosomal integration, resulting in the simultaneous gene replacement of one of the 16S sequences of C. jejuni and the loss of the vector. We propose that Campylobacter isogenic mutants could be developed by using this system of shuttle mutagenesis.     

Genomic integration system based on pBR322 sequences for the cyanobacterium Synechococcus sp. PCC7942: transfer of genes encoding plastocyanin and ferredoxin.

Synechococcus sp. PCC7942 recipient strains were constructed for the chromosomal integration of DNA fragments cloned in any pBR322-derived vector, which carries the ampicillin resistance (ApR) marker. The construction was based on the incorporation of specific recombination targets, the so-called 'integration platforms', into the chromosomal metF gene. These platforms consist of an incomplete bla gene (ApS) and the pBR322 ori separated from each other by a gene encoding an antibiotic (streptomycin or kanamycin) resistance (SmR or KmR). Recombination between a pBR322-derived donor plasmid and such a chromosomal platform results with high frequency in restoration of the bla gene and replacement of the chromosomal marker (SmR or KmR) by the insert of the donor plasmid. The integration into the platform depends on recombination between pBR322 ori and bla sequences only and is therefore independent of the DNA insert to be transferred. The desired recombinants are found by selection for a functional bla gene (ApR) and subsequent screening for absence of the chromosomal antibiotic marker. Gene transfer with this integration system was found to occur efficiently and reliably. Furthermore, the presence of the pBR322 ori in the platform allowed for 'plasmid rescue' of integrated sequences. The system was applied successfully for the transfer of the gene encoding plastocyanin (petE1) from Anabaena sp. PCC7937 and for the integration of an extra copy of the gene encoding ferredoxin I (petF1) from Synechococcus sp. PCC7942 itself.     

Engineering large fragment insertions into the chromosome of Escherichia coli

An effective DNA replacement system has been established for engineering large fragment insertions into the chromosome of Escherichia coli. The DNA replacement plasmid, pHybrid I, was first constructed based on the bacterial artificial chromosome (BAC) vector. Two fragments of the E. coli genome, 5.5 and 6.5 kb in length, were introduced into the vector for homologous recombination. In addition to the chloramphenicol gene, a second gene neo was introduced for double marker screening for recombinant clones. By shot-gun cloning and homologous recombination techniques, using our new recombinant vector (pHybrid I), a 20-kb fragment from Lactococcus lactis genomic DNA has been successfully integrated into the chromosome of the E. coli strain J93-140. Plating tests and PCR amplification indicated that the integration remained stable after many generations in cell culture. This system will be especially useful for the chromosome engineering of large heterologous fragment insertions, which is necessary for pathway engineering.     

Development of a cloning system in Mycoplasma pulmonis

A system suitable for recombinant DNA manipulation in mycoplasmas was developed using the cloned antibiotic-resistance genes of Tn4001 and Tn916. An integrative plasmid containing one of the resistance markers was inserted into the genome of Mycoplasma pulmonis to form a recipient strain. This was accomplished by transformation and homologous recombination between chromosomal DNA sequences cloned onto the integrative plasmid. A second vector, the cloning vector, containing the same plasmid replicon and alternate resistance marker, carried cloned foreign DNA. When transformed into mycoplasmal recipients, homologous recombination between plasmid sequences resulted in integration of the cloning vector and foreign DNA. A Brucella abortus gene coding for a 31-kDa protein and the P1 structural gene and operon from Mycoplasma pneumoniae were introduced to examine the feasibility of developing mycoplasma as cloning hosts. Recombinant plasmids as large as 20 kb were inserted into M. pulmonis, and the integrated foreign DNA was stably maintained. The maximum size of clonable DNA was not determined, but plasmids larger than 22 kb have not been transformed into mycoplasmas using polyethylene glycol. Also the size of genome (800-1200 kb) may affect the stability of larger inserts of foreign DNA. This system is applicable to any mycoplasma capable of transformation, homologous recombination and expression of these resistance markers. Because of their lack of a cell wall, mycoplasmas may be useful cloning hosts for membrane or excreted protein genes from other sources.     

Gene replacement techniques for <Emphasis Type="Italic">Escherichia coli</Emphasis> genome modification

The subject of this review covers modern experimental procedures for chromosomal gene replacement in Escherichia coli and related bacteria, which enable the specific substitution of targeted genome sequences with copies of those carrying defined mutations. Two principal methods for gene replacement were established. The first “in–out” method is based on integration of plasmid into bacterial chromosome and subsequent resolving of the cointegrate. The “linear fragment” method (recombineering) is based on homologous recombination mediated by short homology arms at the ends of linear DNA molecule. Many new protocols and improvements in targeted gene replacement were introduced during the last 10 years. These methods are well suited for high-throughput functional gene studies and for many biotechnological applications.     

An efficient method of selectable marker gene excision by Xer recombination for gene replacement in bacterial chromosomes

A simple, effective method of unlabeled, stable gene insertion into bacterial chromosomes has been developed. This utilizes an insertion cassette consisting of an antibiotic resistance gene flanked by dif sites and regions homologous to the chromosomal target locus. dif is the recognition sequence for the native Xer site-specific recombinases responsible for chromosome and plasmid dimer resolution: XerC/XerD in Escherichia coli and RipX/CodV in Bacillus subtilis. Following integration of the insertion cassette into the chromosomal target locus by homologous recombination, these recombinases act to resolve the two directly repeated dif sites to a single site, thus excising the antibiotic resistance gene. Previous approaches have required the inclusion of exogenous site-specific recombinases or transposases in trans; our strategy demonstrates that this is unnecessary, since an effective recombination system is already present in bacteria. The high recombination frequency makes the inclusion of a counter-selectable marker gene unnecessary.