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Efficient transformation of lactococcus lactis il1403 and generation of knock out mutants by homologous recombination
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Efficient transformation of lactococcus lactis il1403 and generation of knock out mutants by homologous recombination
1.
Journal of Basic
Microbiology 2007, 47, 281–286 281 Technical Note Efficient transformation of Lactococcus lactis IL1403 and generation of knock-out mutants by homologous recombination Simon D. Gerber and Marc Solioz Department of Clinical Pharmacology, University of Berne, Berne, Switzerland Lactococcus lactis IL1403 is a Gram-positive bacterium of great biotechnological interest for food grade applications. Its use is however hampered by the difficulty to efficiently transform this strain. We here describe a detailed, optimized electrotransformation protocol which yields a transformation efficiency of 106 cfu/µg of DNA with the two E. coli Gram-positive shuttle vectors pC3 and pVA838. The utility of the protocol was demonstrated by the generation of single- and double-knock-out mutants by homologous recombination. Keywords: Electroporation / Gram-positive / Transformation efficiency / Single-crossover / Gene disruption Received: November 28, 2006; returned for modification: December 18, 2006; accepted: January 04, 2007 DOI 10.1002/jobm.200610297 Introduction* (McIntyre and Harlander 1989a, 1989b), while trans- formation efficiencies of 106 to 108 cfu/µg were reported Lactococcus lactis IL1403 is a Gram-positive bacterium for L. lactis strain LM0230 (Powell et al. 1988, Holo and which is widely used in the food industry (De Vos Nes 1995). Similarly, L. lactis subsp. cremoris could be 1996), but also as a model organism for molecular stud- transformed with an efficiency of 5.7 × 107 cfu/µg (Holo ies, because its genome has been sequenced recently and Nes 1989b). These latter efficiencies approach those (Bolotin et al. 2001) and its proteome has been exten- which can be obtained with Escherichia coli and open the sively characterized (Guillot et al. 2003). Like many door to most of the available genetic tools. However, Gram-positive organisms, L. lactis is difficult to trans- there exist large differences in transformability, not form because of the rigid peptidoglycan layer which only between species, but also between different strains serves as a physical barrier for the entry of DNA of the same species. In particular, transformation of (Beveridge 1981). With the development of electropora- Lactococcus lactis IL1403 in excess of 104 cfu/µg could not tion, this barrier could be overcome in Gram-positive be obtained in our and several other laboratories work- bacteria with varying efficiency. Electroporation intro- ing with this organism (personal communication, duces temporary holes into the cell wall and membrane Bojovic et al. 1991). This is in contrast to a report by Kim by an electric discharge, thus allowing DNA to enter et al., describing the electrotransformation of L. lactis the cell (Potter 1988, Solioz and Waser 1990, Miller IL1403 at an efficiency of 108 cfu/µg (Kim et al. 1996). It 1994, Drury 1994, Weaver 1995). The efficiency of is not clear why this work could not be reproduced by transformation by electroporation is very strain and us and others. Possibilities are that the IL1403 strain method specific and varies over a range of 102 to 108 used by the Korean group differed from that used in colony forming unit (cfu) per µg of plasmid DNA other laboratories or that the high transformation effi- (Luchansky et al. 1988). For example Lactococcus lactis ciency was a specific property of the single vector, subsp. lactis strains LM0232 and JK301 could reproduci- pGKV21, used in this study. We here describe a repro- bly be transformed at an efficiency of only 103 cfu/µg ducible, efficient electrotransformation protocol for Lactococcus lactis IL1403, yielding 106 cfu/µg of plasmid Correspondence: Marc Solioz, Dept. of Clinical Pharmacology, University of Berne, Murtenstrasse 35, 3010 Berne, Switzerland DNA for two different E. coli-L. lactis shuttle vectors. The E-mail: marc.solioz@ikp.unibe.ch utility of the method was documented by the genera- Phone: +41 31 632 3268 Fax: +41 31 632 4997 tion of gene knock-out and double knock-out mutants © 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim www.jbm-journal.com
2.
282
S.D. Gerber and M. Solioz Journal of Basic Microbiology 2007, 47, 281–286 by homologous recombination with non-replicating Table 1. Primers used in this study. E. coli vectors. Primer Sequence* name dm01 CCCAAGCTTGGGCGGTTGCCGTCAATGAAGTG Materials and methods dm02 GCCTAGGGCTTGCTGTCAGCATCCCTGTT fm19 CCACCGGGTAAAGTTCACGGGAG Bacterial strains, plasmids and primers sg4 CTGTCTCTTATACACATCTTACCGCATTAAAGCTTG sg5 CTGTCTCTTATACACATCTCGAGCGCTTAGTGG Lactococcus lactis IL1403 was used for electroporation and sg6 TGCCGTTGCAGAGGCTGGTTATAAAG for single cross-over recombination. E. coli DH5α and sg7 ACATGAATTCTCCTTGGGCTAATAAACC TOP10 (Invitrogen) strains were used in all the cloning sg8 ACATGAATTCTGTGGAGCTTTCAGAAC steps for plasmid construction. The E. coli-Gram-positive sg9 GCGTTGATTGAGACAATCAC sg14 TACGGGATCCTTACCCTTAAGTTATTGGTATGAC shuttle vectors pC3 and pVA838 have been described sg15 GCGGATCCCGACTAAAGCACCCATTAGTTC previously (Solioz and Waser 1990, Macrina et al. 1982) sg18 TCACTATAGGGCGAATTGG and pCR-Blunt II-Topo™ vector was from Invitrogen. * Primer sequences are in the 5′ to 3′ direction. The For electrotransformation, plasmid DNA was purified nucleotides in bold are complementary to the templates and by CsCl density gradient centrifugation as described underlined bases indicate restriction sites engineered into (Humphreys et al. 1975) and resuspended in 10 mM Tris- the 5' extensions of some primers. Cl, 1 mM EDTA, pH 7.5. Vector pCYZA27 containing the entire L. lactis cop operon was constructed by PCR ampli- a 200 Ω (50 W) resistor, wired in series with the elec- fication of a 3.9 kb genomic fragment of Lactococcus lactis troporation cuvette. This arrangement differs from the IL1403, using primers dm01 and dm02 (Table 1), with setup using a Bio-Rad pulse controller which allows to TaKaRa LA Taq™ polymerase (Takara) and blunt-end introduce various resistors in parallel. The cuvette had ligation into the pCR-Blunt II-Topo™ vector (Invitrogen) an electrode gap of 0.1 cm and was home-made as de- as described by the manufacturer. For gene knock-out, scribed previously. Capacitance was set to 25 µF. Plas- the basal vector pSG1, which is unable to replicate in mids pC3 and pVA838 were used for quantitative elec- L. lactis, was constructed by PCR amplification of the troporation into L. lactis IL1403. L. lactis was grown at erythromycin resistance gene of pVA838 with primer sg4 30 °C in SGM17 media, which is M17 media (Terzaghi and sg5 and blunt-end ligation of the 1.8 kb product and Sandine 1975) supplemented with 1 mM MgSO4, with the pCR-Blunt II-Topo vector. For disruption of the 0.5 M sucrose, 2% glycine, 1.5% glucose. SM17MC me- copA gene, a 1 kb internal copA fragment, cut from dia for phenotypic expression was M17 media contain- pCYZA27 with EcoRV and XbaI, was ligated with pSG1, ing 0.5 M sucrose, to which 10 mM MgCl2 and 2 mM cut with the same enzymes, resulting in pSG3. For dis- CaCl2 were added after autoclaving. Cells were plated ruption of the copB gene, an internal 1 kb fragment of either on M17, SR (containing per liter: 10 g tryptone, copB was PCR amplified with primers sg7 and sg8 from 5 g yeast extract, 200 g sucrose, 10 g glucose, 25 g gela- genomic DNA of L. lactis IL1403 and ligated with pCR- tin, 2.5 mM CaCl2, 2.5 mM MgCl2, pH 6.8) or on BHIS Blunt II-Topo. From the resultant plasmid, pSG4, the media (38 g/l Brain Heart Infusion broth (Difco) sup- copB fragment was excised with PstI and ligated with PstI- plemented with 1 mM MgSO4 and 1% glucose after cut pSG1, resulting in pSG7. For double gene knock-out, autoclaving). Highest transformation efficiencies were pSG13 was constructed by PCR amplifying the chloram- obtained by plating on SR media. Erythromycin was phenicol resistance gene of pC3 with primers sg14 and used at 5 µg/ml and chloramphenicol at 15 µg/ml. Elec- sg15, cutting the product with BamHI and ligating the 1 troporation buffer was prepared either with EDTA kb fragment into pSG7, cut with the same enzyme. Clon- (0.5 M sucrose, 10% glycerol, 50 mM Na-EDTA, pH 7.0) ing was performed by standard protocols as described by or without EDTA (0.5 M sucrose, 10% glycerol, pH 7.0) Sambrook et al. (1989). E. coli DH5α was transformed with and was prepared and autoclaved on the day before use. the rubidium chloride method of New England Biolab. The routine isolation of plasmid DNA was performed Gene knock-out and mutant analysis with NucleoBond® Plasmid Purification Kits (Macherey- To generate knock-out strains, L. lactis IL1403 was trans- Nagel) according to the manufacturer’s instructions. formed with 1 to 2 µg of the corresponding plasmid DNA and cells plated on BHIS plates containing the Electroporation of L. lactis IL1403 corresponding antibiotic. For analysis, genomic DNA Electroporation of L. lactis was performed as outlined in was isolated as described (Ausubel et al. 1995) and 0.5 µl Table 2, using a Gene Pulser® from Bio-Rad, fitted with was used for PCR. Knock-outs in ΔcopA were confirmed © 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim www.jbm-journal.com
3.
Journal of Basic
Microbiology 2007, 47, 281–286 Transformation of L. lactis IL1403 283 Table 2. Transformation protocol. Step Operation 1 Preparation of cells: Inoculate 5 ml of SGM17 media with L. lactis IL403 from glycerol stock and incubate overnight at 30 °C in a closed tube. 2 Inoculate 50 ml of SGM17 with the 5 ml overnight culture and incubated at 30 °C overnight in a closed bottle. 3 Inoculate 450 ml of freshly prepared SGM17 with the 50 ml overnight culture and incubated at 30 °C in a closed bottle. Grow culture to an OD546 of about 0.4 (mid- to late-log phase) and collect cells by centrifugation for 10 min at 8000 × g at 4 °C. 4 Resuspended the pellets with 400 ml of ice-cold electroporation buffer without EDTA, using a 10 ml pipette, and centrifuge as before. 5 Resuspended the pellets in 200 ml of ice-cold electroporation buffer with EDTA and incubated at 4 °C for 15 min, followed by centrifugation as before. 6 Wash cells a third time with 400 ml of ice-cold electroporation buffer without EDTA. 7 Resuspend the final pellet in 4 ml of electroporation buffer at 4 °C. Flash-freeze aliquots of 120 to 500 µl in liquid nitrogen and store at – 80 °C. These electrocompetent cells are stable for at least four weeks. 8 Electroporation: Thaw the electrocompetent cells on ice. 9 Flame the reusable electrodes with ethanol for sterilization and assemble them. Cool the electrode assembly (or a corresponding disposable cuvette) with liquid nitrogen until it gets frosted. Use the cuvette immediately when the frost thaws (e.g. near zero degrees). 10 The following must be conducted as fast as possible: Pipet 120 µl of electrocompetent cells into an Eppendorf tube on ice and add plasmid DNA. Gently mix by tapping and pipette the cells into the cold electroporation cuvette. Before triggering the discharge, draw 900 µl of ice-cold SM17MC media into an Eppendorf pipet tip. Electroporate at 1.3 kV, 200 Ω serial resistor, 25 µF and immediately wash the cells out of the cuvette into a fresh Eppendorf tube on ice with the 900 ml of cold SM17MC media ready in a pipet (not later than after 1 to 2 s after the pulse). 11 Incubate the electroporated cells on ice for 5 min. 12 Incubate the electroporated cells for 90 min at 30 °C to allow for phenotypic expression. 13 Plate the cells on either M17, SR or BHIS plates supplemented with 5 µg/ml of erythromycin or 15 µ/ml of chloramphenicol and incubate the plates overnight at 30 °C. by PCR with primers fm19 and sg6 and those in ∆copB efficiency was very dependent on the concentration of with primers sg9 and sg18. PCR products were purified glycine in the growth media (Holo and Nes 1989a, and digested with restriction enzymes as described Shepard and Gilmore 1995). It leads to replacement of (Sambrock et al. 1989). Double knock-outs were con- D-alanine in peptidoglycan synthesis and the accumula- firmed with the same primers. Commercial sequencing tion of modified peptidoglycan precursors accumulate. (Microsynth, Balgach, Switzerland) was used to verify Since these are poor substrates in the transpeptidation the PCR products. reaction, a high percentage of muropeptides remains uncross-linked, which “loosens” the cell wall (Hammes et al. 1973). Concentrations of 2 – 3% glycine gave opti- Results mal results, while concentrations above 3% inhibited growth. I was crucial to harvest the cells in the mid-log Optimization of tansformation to late-log phase of growth. The transformation effi- Optimization of the transformation efficiency of L. lactis ciency was also strongly dependent on the handling of IL1403 required the adjustment of many parameters cells. Osmotic stabilization of the cells by adding su- and Table 2 summarizes the transformation protocol crose to the buffers proved instrumental. Mechanical we developed. stress had to be avoided as much as possible and the Most critical was the electrical circuit which was cells had to be kept cold at all times. Finally, transfor- used and the parameters for electroporation. In con- mation efficiency was 20 – 30% higher when the cells trast to previously published methods (e.g. Holo and were plated on SR plates compared to BHIS or M17 Nes 1989c), a 200 Ω resistor was wired in series rather plates. Under the optimized conditions, transformation than in parallel with the electroporation cuvette, which efficiencies of 106 cfu/µg could reproducibly be ob- resulted in longer pulse decay times, τ. It was found tained. Fig. 1 shows the dependency of the transforma- that τ-values of 20 to 40 ms were most efficient, requir- tion efficiency on the DNA concentration for the 6.3 kb ing a voltage of 13 kV/cm. Other important factors were E. coli-Gram-positive shuttle vector pC3. From 10 to the growth media, the wash protocol for the cells, 700 ng of plasmid DNA, the transformation efficiency plasmid purity, cell density, expression media, and was essentially constant, but dropped sharply at higher phenotypic expression times. High transformation DNA concentrations. Transformation efficiencies ob- © 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim www.jbm-journal.com
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S.D. Gerber and M. Solioz Journal of Basic Microbiology 2007, 47, 281–286 Gene knock-out by homologous recombination To accomplish gene knock-out, we chose the strategy of Campbell-like plasmid integration by homologous re- 106 combination (Leenhouts et al. 1989, 1991). This results in the integration of the entire plasmid into the chro- Transformation efficiency [cfu/µg] mosome and, if the integration site is designed accord- ingly, inactivation of the desired gene. To this end, the pCR-Blunt II-Topo vector (Invitrogen) was used as a plasmid which cannot replicate in L. lactis. To provide antibiotic resistance markers which are suitable for L. lactis, the erythromycin and the chloramphenicol resistance genes of pC3 were cloned into this plasmid. As model genes, we inactivated the copA and copB genes, which encode putative copper ATPases and are ap- proximately 2 kb long. DNA fragments of 1 kb and corresponding to the central regions of the copA or the copB genes were cloned into the modified pCR-Blunt II- 105 0 .0 0 1 0 .0 1 0 .1 1 10 Topo vectors pSG3 and pSG7, respectively. Following µ P la s m id D N A [µ g ] electroporation with these plasmids, only cells contain- ing a plasmid copy integrated into the chromosome Figure 1. Dependence of transformation efficiency on amount of plasmid DNA. L. lactis IL1403 was transformed by the procedure retained antibiotic resistance. Resistant cells were ob- given in Table 1 with varying amounts of pC3 and plated on SR tained at a frequency of approximately 10 per µg–1 of plates containing 5 µg/ml erythromycin. All experiment were plasmid DNA. Chromosomal integration of the plasmid performed in a triplicates. was tested by PCR amplification of genomic DNA, using a primer directed against the plasmid DNA and one tained with the unrelated 9.2 kb E. coli-Gram-positive directed against genomic DNA near the expected inte- shuttle pVA838 were reduced in proportion to the lar- gration site. The expected PCR products were obtained, ger size of this vector. The highest number of trans- namely a 1.57 kb fragments for ∆copA mutants and formants in absolute terms (> 106) was obtained with 1 1.96 kb fragments for ∆copB mutants, respectively to 2 µg of DNA, which were the conditions used for (Fig. 2). The PCR product of the ∆copA∆copB double gene knock-out by homologous recombination. knock-out strain was of low intensity for unknown reason, but DNA sequencing revealed 98% sequence 1 2 3 4 5 6 7 8 9 identity with the predicted product. Correct integration was further confirmed by restriction digest analysis of the PCR products, which yielded the correct fragmenta- 10 tion pattern in all cases (Fig. 3). The integrations were apparently stable in the presences of antibiotics, as has been noted previously in other organisms (Leloup et al. 1 1997). 0.5 0.2 Discussion We here describe a detailed, optimized electroporation Figure 2. Genomic PCR products from knock-outs strain. Genomic protocol for Lactococcus lactis IL1403 to obtain a trans- DNA was PCR amplified as described under Materials and methods formation efficiency of 106 cfu/µg DNA. This supports and the products resolved on a 2% agarose gel, stained with ethidium bromide. The PCR products of the following DNA-primer genetic engineering of this biotechnologically impor- combinations are shown: lane 1, DNA standard (MassRuler, tant strain by homologous recombination or by using Fermentas); lane 2, ∆copA-fm19/sg6; lane 3, wild-type-fm19/sg6; targeted group II introns (Frazier et al. 2003). As proof- lane 4, ∆copB-sg9/sg18; lane 5, wild-type-sg9/sg18; lane 6, ∆copA- fm19/sg6 of double knock-out; lane 7, wild-type-fm19/sg6; lane 8, of-principle, we used the current transformation proto- ∆copB-sg9/sg18 of double knock-out; lane 9 wild-type-sg9/sg18. col to create single and double knock-out mutants in The sizes of DNA markers are indicated in kb on the ordinate. L. lactis IL1403 in two genes, copA and copB, by homolo- © 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim www.jbm-journal.com
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Microbiology 2007, 47, 281–286 Transformation of L. lactis IL1403 285 A 1 2 3 4 5 6 7 B 1 2 3 4 5 6 7 10 10 1 1 0.5 0.5 0.2 0.2 Figure 3. Restriction enzyme analysis of PCR products. (A) The PCR product ∆copA-fm19/sg6 (cf. Figure 2) was digested with restriction enzymes and resolved on a 2% agarose gel stained with ethidium bromide. Lane 1, DNA standard, lane 2, undigested, lane 3, EcoRV; lane 4, XbaI; lane 5, EcoRV and XbaI; lane 6, Nsi I; lane 7, ClaI. (B) The PCR product ∆copB-sg9/sg18 (cf. Fig. 2) was digested with restriction enzymes and resolved on a 2% agarose gel stained with ethidium bromide. Lane 1, DNA standard, lane 2, undigested, lane 3, HpaI; lane 4, SphI; lane 5, BstEII; lane 6, Van911; lane 7, XbaI. The sizes of DNA markers are indicated in kb on the ordinate. gous Campbell-like recombination with an E. coli plas- suggesting that this strain has an intrinsically lower mid unable to replicate in L. lactis. Use of this method recombination frequency compared to other Gram- has been wide-spread (Simon and Chopin 1988, Leen- positive bacteria. Indeed, we were unable to effect inte- houts et al. 1990, Biswas et al. 1993), but has, to our gration into the ytjD gene with a 274 bp fragment, but knowledge, never been applied to strain IL1403. The could do so with a 379 bp fragment (Mourlane and low transformation efficiency of IL1403 was previously Solioz, personal communication). Some of the critical overcome for genetic engineering experiments by the parameters in transformation identified in this work, use of special thermolabile plasmids. These could carry- such as low temperature, osmotic stabilization, rapid ing either an insertion sequence for unspecific integra- transfers, and ohmically controlled discharge may be tion (Maguin et al. 1996, Uguen and Uguen 2002), or a applicable to other hard-to-transform Gram-positive defined sequence for homologous recombination (Le bacteria. Bourgeois et al. 1992, Sperandio et al. 2005). The high The efficient electrotransformation procedure de- transformation efficiency to 106 cfu/µg of plasmid DNA scribed here features a 200 Ω serial resistor as a critical reported here allows direct genetic engineering of element. The protocol lends itself to genetic engineer- IL1403 by homologous recombination using any E. coli ing of Lactococcus lactis IL1403 and possibly other Gram- plasmid carrying homologous L. lactis DNA. We ob- positive bacteria refractory to efficient electroporation. tained on average ten knock-out mutants per experi- It allows gene knock-out with standard E. coli vectors by ment, corresponding to an integration frequency of Campbell like recombination, without the need for approximately 10–5. This low integration frequency may thermosensitive replicons. The two E. coli-Gram-positive be a specific characteristic of IL1403, as much higher shuttle vectors employed here, pC3 and pVA838, have integrations frequencies had been reported for other not previously been used in L. lactis and appear well Gram-positive bacteria. A critical parameter for the suited for genetic work in L. lactis. integration frequency is the length of the homologous genomic DNA insert in the plasmid. Leloup et al. care- fully studied the integration frequency as a function of Acknowledgements insert size (Leloup et al. 1997). They found that the inte- gration frequency in Lactobacillus sakei increased linearly We thank Francis Macrina for providing plasmid with the insert size up to 10–3 at 1 kb of DNA. Larger pVA838 and Emmanuelle Maguin for Lactococcus lactis inserts did not appear to significantly increase the inte- IL1403. This work was supported by grant 3100A0- gration frequency. We observe an integration fre- 109703 from the Swiss National Foundation and by a quency of only 10–5 with 1 kb inserts in L. lactis IL1403, grant from the International Copper Association. © 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim www.jbm-journal.com
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