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Open Access Methodology article

Transformation of Botrytis cinerea by direct hyphal blasting or by wound-mediated transformation of sclerotia

Shahar Ish - Shalom1, Aviva Gafni2, Amnon Lichter1 and Maggie Levy2*

Author Affiliations

1 Postharvest Science of Fresh Produce, The Volcani Center, ARO, Israel

2 The Department of Plant Pathology and Microbiology, The Robert H. Smith Faculty of Agriculture, Food and Environment, The Hebrew University of Jerusalem, Rehovot, Israel

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BMC Microbiology 2011, 11:266  doi:10.1186/1471-2180-11-266


The electronic version of this article is the complete one and can be found online at: http://www.biomedcentral.com/1471-2180/11/266


Received:21 September 2011
Accepted:21 December 2011
Published:21 December 2011

© 2011 Ish-Shalom et al.; licensee BioMed Central Ltd.

This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Botrytis cinerea is a haploid necrotrophic ascomycete which is responsible for 'grey mold' disease in more than 200 plant species. Broad molecular research has been conducted on this pathogen in recent years, resulting in the sequencing of two strains, which has generated a wealth of information toward developing additional tools for molecular transcriptome, proteome and secretome investigations. Nonetheless, transformation protocols have remained a significant bottleneck for this pathogen, hindering functional analysis research in many labs.

Results

In this study, we tested three different transformation methods for B. cinerea: electroporation, air-pressure-mediated and sclerotium-mediated transformation. We demonstrate successful transformation with three different DNA constructs using both air-pressure- and sclerotium-mediated transformation.

Conclusions

These transformation methods, which are fast, simple and reproducible, can expedite functional gene analysis of B. cinerea.

Keywords:
Botrytis cinerea; sclerotium; Sclerotinia sclerotiorum; transformation; 'Bim-Lab'; electroporation

Background

Botrytis cinerea is a haploid necrotrophic ascomycete which is known as a major pathogen responsible for 'grey mold' disease in more than 200 plant species [1-3]. It attacks aboveground plant organs, and is a major pathogen during post-harvest storage due to its exceptional ability to grow, develop and attack produce at low temperatures. The high impact of diseases caused by B. cinerea has triggered a wide scope of molecular research in recent years, resulting in the sequencing of two B. cinerea strains. This has generated a wealth of information on the genome of this fungus (http://www.broadinstitute.org/annotation/genome/botrytis_cinerea/Home.html; webcitehttp://urgi.versailles.inra.fr/index.php/urgi/Species/Botrytis webcite)[4]. Along with genomic research, the development of additional tools, such as transcriptome, proteome and secretome analysis, has yielded additional information on the mechanisms underlying B. cinerea pathogenicity. These methods have filled in some of the gaps in our knowledge but unlike model organisms such as Neurospora crassa [5], functional analysis remains a significant bottleneck. The first requirement for functional analysis is a robust and high-throughput transformation protocol. However, the existing protoplast-based and Agrobacterium-mediated transformation methods [6-11] are complex and time-consuming; moreover, protoplast preparation is tedious and requires an enzyme cocktail whose consistency between batches is unknown. Here we describe two alternative protocols--direct hyphal transformation by blasting [12] and wounding-mediated transformation of sclerotia--both fast, simple and reproducible methods which might improve functional analysis in B. cinerea and other sclerotium-forming fungi.

Methods

Fungal cultures and growth conditions

B. cinerea isolate BO5.10 was maintained on potato dextrose agar (PDA, 39 g/L, BD Biosciences, Franklin Lakes, NJ, USA) amended with 250 mg/L chloramphenicol (Sigma-Aldrich, St. Louis, MO, USA) at 22-25°C for 7 to 10 days on 90-mm diameter Petri dishes. Conidia were harvested with purified water (resistivity > 18.2.CM; Millipore Milli-Q system) containing 0.001% (w/v) Triton X-100 (Sigma-Aldrich). The number of conidia was counted under a light microscope, at 400× magnification. Selection media consisted of Gamborg B5 pH 5.7 containing 3.16 g/L Gamborg B5 powder with vitamins (Duchefa, Haarlem, The Netherlands), 0.7 g/L of sodium nitrate (Sigma-Aldrich) and 3% (w/v) glucose amended with 50-250 μg/mL hygromycin B (Hyg) (Roche, Basel, Switzerland) and 15 g/L agar or PDA plates, pH 7.1, amended with 20 μg/mL phleomycin (Phleo)(InvivoGen, California, USA).

Preparation of the DNA constructs

The bacterio-Rhodopsin (bR) (BC1G_02456.1) knockout construct (Figure 1a) was based on a modified Gateway vector (Invitrogen, Gaithersburg, MD, USA)[13]. The regions which flank the bR gene (BC1G_02456.1) are present on both sides of the Hygr cassette. The upstream 420-bp fragment (bR 5') was amplified using primers: bR5'F AGATGGGGCGGCTGGGTA and bR5'R AGATC-CCACTATCCTATCA. The downstream 418-bp flanking region (bR 3') was amplified using the primers bR3'F TAGTCGCGAACGATGTGAAG and bR3'R GAACACATCGTCCGTTTCCT. The middle region of the hygromycin resistance cassette (Hygr) (1832 bp) was amplified using the primers bRHF GGGG-ACAACTTTGTATAGAAAAGTTGGCGGCCGCCACAAAGACCTCTCGCCTTT and bRHR GGGGACAACTTTGTATAATAAAGTTGGCGGCCGCCCGACTCCCAACTCG-ACTAC. Fragments were joined together by PCR in three stages as previously described [12].

thumbnailFigure 1. Constructs for transformation of B. cinerea. (a) bR knockout construct is based on the work of Shafran and colleagues [13] and contains two flanking regions of the bR gene (bR 3' and bR 5') and in between the Hygr cassette as selection marker. Homologous recombination with genomic DNA is presented (dashed lines are genomic flanking regions next to bR gene). (b) The bR gene was cloned into the pBC-Phleo plasmid between the EcoRI (upstream) and BamHI (downstream) restriction sites upstream to the Phleor cassette. (c) The HP1 knockout construct is composed of two flanking regions of the gene and in between a Hygr cassette as selection marker. The relative location of primers which were used to verify transformation is marked by arrows and numbers (detailed in Methods, primer sequences are listed in Table 1).

The pBC-bRPhleo construct (Figure 1b) was generated by cloning the bR gene (1068 nt) using primers: bRBF: AGCCTCGTCCTGTACAACTATAGGATCCCATCCCA-CAACATAACTCT and bRER: TTAACTGTACTCCTATCCTATACTTAAGATACTTTTCGGTTAGAGCGGATG into the pDES-Phleo vector [14] between the EcoRI (upstream) and BamHI (downstream) restriction sites.

The third construct, knocked out in hypothetial protein 1 (HP1) (BC1G_14370.1), was generated by fusion of three PCR fragments (Figure 1c) [15]. The upstream fragment of HP1 (524 bp) was amplified by the primers: HP5'F AGTGTTCAACGAGCTCCA; HP5'R AGGTGAGTGTTGCGGCTAGT and the downstream flanking region (83 bp) was amplified using primers: HP3'F GGATAAAGAACAGCTAATCT and HP3'R ACTAGCCGCAACACTCACCT. The Hygr cassette (3728 bp) was amplified from pCT74 [16] using primers HHF: AGGTGAGTGTTGCGGCTAGTGCACTGCTCTGCTGTCTCTGAAGCTGGTCC G, and HHR: ATCAGTTAACGTGGATAAAGAACA. After sequencing, the PCR fragments were joined to the Hygr fragment by PCR with the nested primers (HP5'F and 3'HR TTCAATATCAGTTAACGTCGACCTCGTTCTGGATATGGAGGA and 5'HF CCAGTTGAATTGTCTCCTCCAGTCGACGTTACTGGTTCCCGGT and HP3'R) as described previously [15].

Protoplast preparation

Protoplasts were prepared as previously described by Noda and colleagues [17] with some modifications. Conidia from a well-sporulated plate were harvested and used to inoculate 100 mL of liquid malt medium containing (per L): 5 g glucose, 15 g malt extract (Bacto Malt Extract, BD Biosciences), 1 g casein peptone (Sigma-Aldrich), 1 g yeast extract (BD Biosciences), 1 g casamino acids (Sigma-Aldrich). The culture was shaken overnight at 150 rpm at 18 to 22°C. The developing mycelium was collected on a Nytex membrane and the membrane was washed with 60 mL sterile water followed by two washes with 0.6 M cold KCl buffer (AnalaR, Leicestershire, England) containing 50 mM CaCl2 (Amerco, Reno, NV, USA). The washed mycelium (1.2 to 1.5 g) was transferred into a 50-mL Erlenmeyer flask with 10 mL filter-sterilized protoplast solution containing 0.4 mg/mL lysing enzymes (Sigma-Aldrich, cat no. L-1412-5G) suspended in KCl buffer. The suspension was shaken for 1 to 2 h at 85 rpm and 28°C and generation of protoplasts was monitored by light microscope. The protoplasts were generated from germinating conidia, broken hyphae or both sources together and were separated from the original tissue over a 60-mesh Nytex membrane (Sigma-Aldrich). Protoplasts were further purified by two centrifugations (1485g, 4°C, 10 min) and the pellet was washed by gentle resuspension in 10 mL KCl buffer, centrifuged, resuspended in the residual buffer and transferred into a new pre-cooled tube. The number of protoplasts was adjusted to 108 cells/mL.

Electroporation

The electroporation protocol was adapted from [18], with some modifications, and used on either protoplasts or germinated conidia. Protoplasts were prepared as described above and washed with cold electroporation buffer containing 1 mM N-2-hydroxyethlpiperazine-N'-2-ethanesulfonic acid (HEPES, Sigma-Aldrich), 50 mM mannitol (Sigma-Aldrich), pH 7.5. Conidia were incubated in malt medium for 4 h at 25°C, centrifuged (835g, 4°C) and then washed with cold electroporation buffer and their concentration was adjusted to 108 conidia/mL. Aliquots of protoplasts or germinated conidia (100 μL) were dispensed in cold electroporation cuvettes (Bio-Rad, Hercules, CA, USA) and 2.5 to 10 μg DNA was added. The electroporation was performed with a 'Gene Pulser' (Bio-Rad) operated at 1.4 kV, 800 W and 25 μF. After application of the electrical pulse, the conidia or protoplasts were transferred to regeneration medium containing (per L purified sterile water): 145.7 g mannitol (Sigma-Aldrich), 4 g yeast extract, 1 g soluble starch and 16 g agar (Difco Laboratories, Detroit, MI, USA). After 10 h, an overlay of 10 mL HM medium consisting of: 1% (w/v) malt extract, 4% glucose, 0.4% (w/v) yeast extract, 125 mg Na2HPO4, 320 mg NH4C1, 180 mg MgSO4 7H20, 13 mg CaC12 2H2O, 4 mg FeC13 6H2O, 250 mg Na2SO4, 1100 mg MES, 1300 mg HEPES and 1.5% agar, pH 5.5 with 50 μg/mL of hygromycin B (Hyg), was poured onto the plates. Colonies appeared after 4 to 5 days and were transferred to Gamborg B5 solid medium with 50 μg/mL Hyg or PDA medium supplemented with 20 μg/mL Phleo.

Transformation of sclerotia

For sclerotium transformation, B. cinerea or Sclerotinia sclerotiorum sclerotia were collected from mature colonies grown on PDA plates for 10 days or more at 22°C or 18°C, respectively. Sclerotia were disinfected by three washes with 1% sodium hypochlorite, followed by three washes with sterilized purified water. The sclerotia were dried between washes on sterile Whatman filter paper in a biological hood and were completely dried prior to transformation. The dried sclerotia were wounded by generating a hole in the middle of the sclerotia (without penetrating through) with a sterile needle (21G) followed by four applications at 30-s intervals of 5 μL DNA solution (a total of 0.5 to 2 μg) or sterile purified water, both supplemented with 0.01% (v/v) Silwet L-77 surfactant (Agri-Turf Supplies, Santa Barbara, CA, USA). After 10 to 15 min, the solution was fully absorbed and sclerotia were placed on water-agar plates which were then incubated for 1 to 2 days at 22°C. At this stage, sclerotia were transferred to solid selective media. When vacuum was added to this procedure, the sclerotia were transferred, after wounding, into a 1.5-mL polypropylene tube and covered with DNA solution (0.05 μg/mL) or water as a control, both supplemented with 0.01% Silwet L-77 surfactant. The tubes were placed in a Speedvac (Heto Lab Inc., Laurel, MD, USA) and vacuum was applied for 20 min. The growing hyphae were then transferred onto new plates containing Gamborg B5 solid medium and 50 μg/mL Hyg. Viable colonies were transferred to new plates (55-mm Petri dish) with increasing concentrations of Hyg, up to 250 μg/mL in steps of 50 μg/mL, or PDA medium supplemented with 20 μg/mL Phleo that was increased to 60 μg/mL in 10 μg/mL steps.

Transformation by hyphal blasting

The hyphal-blasting procedure was adopted from Levy and colleagues [12] with some modifications. PDA plates were inoculated in the center with 20 μL of spore suspension (107 spores) and then incubated at 22°C for 24 to 48 h until the colony diameter was in the range of 2 to 2.5 cm. Before use, blast cassettes were cleaned by immersion in soap and water, followed by five washes with sterile purified water, disinfection with 70% ethanol and drying in a biological cabin. For the blasting procedure, a 'Bim-Lab' instrument (Bio-Oz, Yad Mordehai, Israel) was used. The instrument was adjusted to the manual setting at a pressure of 2 bars, and the 'gun' was set at a height of 15 cm above the Petri dish. Cassettes were loaded with 0.5 to 3 μg of the DNA solution or sterile purified water diluted with 0.01% Silwet L-77 surfactant. The cassette containing the DNA was connected to the gun and the DNA was blasted over the edge of the colony mycelium four to five times at 10-s intervals until drops were fully dispersed over the plate. Plates were then incubated for 20 to 24 h and 10 plugs from the perimeter of the colony were transferred to Gamborg B5 solid medium plates supplemented with 50 μg/mL Hyg.

Analysis of transformants

The stability of the strains in all of the above methods was verified by five transfers of the colony edges onto new solid Gamborg B5 medium with increasing concentrations of Hyg (from 50 to 250 μg/mL) or PDA medium supplemented with 20 μg/mL Phleo that was increased up to 60 μg/mL in 10 μg/mL steps and then five subsequent transfers onto PDA plates without the selection.

For DNA extraction, B. cinerea mycelium was grown in 20 mL Gamborg B5 liquid medium for 3 days and harvested by filtration over three layers of sterile 3 MM paper discs. Freshly harvested (100 to 200 mg) or lyophilized (10 to 20 mg) mycelia were added to 2-mL tubes with a volume of glass beads (Sigma-Aldrich, 200-300 μm) equivalent to 100-200 μL, 700 μL breaking buffer (2% Triton X-100, 1% w/v SDS, 100 mM NaCl, 10 mM Tris-HCl pH 8.0, 1 mM EDTA, all from Sigma-Aldrich) and 500 μL chloroform:isoamyl alcohol (24:1, v/v). Tubes were sealed and vortexed for 7 to 10 min, at a speed of 7-8 in a Genie 2 vortex (Scientific Industries, Inc., New York, NY, USA) and then centrifuged for 10 min at maximum speed (Eppendorf 5415 D). The supernatant (500 μL) was amended with 50 μL of 3 M sodium acetate pH 5.2 and 1 mL of 96% ethanol. Tubes were then incubated for 45 min at -20°C and DNA was precipitated by centrifugation (10 min, maximum speed). The DNA was washed with 70% ethanol and centrifuged for 5 min at 10,500g. The pellet was dried for 1 h in a biological hood and suspended in 100 μL TE (10 mM Tris HCl pH 8.0, 0.1 mM EDTA) or sterile ultra-purified water. DNA extraction from S. sclerotiorum was performed by fast extraction from mycelial plugs using NaOH as described by Levy and colleagues [12].

To verify transformation, we performed PCR analyses on DNA extracted from putative transformants using Hygr (Hyg F and Hyg R) and Phleor (Phleo F and Phleo R) cassette primers (Table 1). For verification of knockout by homologous recombination, a 480-bp fragment was amplified with primer bR-gen 5'F, which is located in the 5' upstream genomic region of the bR gene and is not present in the 5' fragment of the bR construct, and primer bR-Hyg 5'R from the Hyg cassette; a 590-bp fragment was amplified by primer bR-gen 3'F which is located in the 3' downstream genomic region of the bR gene and is not present in the 3' fragment of the bR construct, and primer bR-Hyg 3'R which is located at the 3' end of the Hyg cassette.

Table 1. Primer details for the PCR analysis of transformants

All PCR analyses were performed in 0.2-mL tubes containing PCR reagent (ReddyMix®, Thermo Fisher Scientific Inc., Surrey, UK) with 5 pmol of primers, 12.5 to 25 ng template DNA and sterile purified water to a final volume of 20 μL. PCR was carried out on a T-gradient PCR instrument (Biometra, Goettingen, Germany). Activation of the enzyme was carried out at 95°C for 5 min followed by denaturation for 45 s at 94°C, annealing at 62°C for 45 s, elongation at 70°C for 45 s for 30 to 40 cycles, and 10 min of elongation at 70°C. PCR products were analyzed on a 1 to 2% agarose gel according to their size and stained with 'Safeview' (G108 SafeView™ Nucleic Acid Stain, Applied Biological Materials Inc., Richmond, Canada).

Results

Protoplast-mediated transformation by electroporation

Three different DNA constructs were used for transformation of B. cinerea (Figure 1). The bR knockout construct (Figure 1a) was based on a modified Gateway vector according to Shafran and colleagues [13] (see Methods). This construct was used with all transformation methods. Protoplasts generated from germinating conidia or broken hyphae were used for electroporation experiments: the few colonies that slowly recovered from electroporation did not survive the Hyg selection.

Sclerotium-mediated transformation

Both B. cinerea and S. sclerotiorum are known to produce sclerotia--melanized and condensed hyphal structures which are able to survive harsh environmental conditions in nature. Sclerotia can be readily collected from mature (over 10 days old on a Petri dish) cultures and preserved dry under ambient conditions. The possibility of transforming sclerotia is therefore very appealing. Sclerotia were collected from mature culture (> 10 days old), disinfected, wounded with a needle, and DNA supplemented with surfactant Silwet L-77 was introduced by pipetting directly onto the wound. Silwet L-77 was chosen because it reduces surface tension more than most surfactants and has been found to greatly enhance bacterial entry into relatively inaccessible plant tissues in plant transformation [19,20]. In an experiment with the bR knockout construct, 45 sclerotia yielded 21 (46%) Hyg-resistant and PCR-positive transformants (Table 2, Figure 2a), and 13 (62%) of these strains were identified as knockout strains by PCR of the Hyg cassette with the flanking region of bR genomic DNA (Figures 1a and 2a). These results demonstrated the feasibility of sclerotium-mediated transformation.

Table 2. Transformation with the bR knockout construct

thumbnailFigure 2. PCR analyses of transformants of B. cinerea. and S. sclerotiorum. (a) A fragment of the Hygr cassette (550 bp) was amplified by primers 1 and 2 from five different bR knockout strains (1-5). A 480-bp fragment was amplified by primer 3 which is located in the 5' upstream genomic region of the bR gene and by primer 4 in the Hyg cassette (5'), and a 590-bp fragment was amplified by primer 5 which is located in the 3' downstream genomic region of the bR gene and primer 6 which is located at the 3' end of the Hyg cassette (3'); P is the positive control of the bR knockout construct (plasmid DNA). (b) A fragment of the Phleor cassette (1020 bp) was amplified by primers 3 and 4 from four different bR complementation strains (1-4). C is the negative control of the WT strain. (c) A fragment of the Hygr cassette (550 bp) was amplified by primers 1 and 2 from the HP1 transformants (1-7). C is the negative control of the WT strain. (d) A fragment of the Hygr cassette (550 bp) was amplified by primers 1 and 2 from four transformants of S. sclerotiorum (1-4). P is the positive control of the Hygr cassette (plasmid DNA) and C is the negative control of the WT strain (primers sequences are listed in Table 1).

To further verify the reproducibility of this method, we introduced the pBC-bRPhleo complementation cassette, which contains the bR gene and the Phleo selection marker (Phleor) on pBC-Phleo [14], into the B. cinerea bR knockout strain (Figure 1b). The vector was introduced into sclerotia in its native circular structure. The experiment included 120 sclerotia resulting in recovery of 65 Phleo-resistant and PCR-positive isolates (54%) (Table 3). A third construct for knockout of HP1 was generated by fusion PCR [15] (see Methods) (Figure 1c). It was introduced into 20 sclerotia, resulting in three transformants (15%) (Figure 2c, Table 4).

Table 3. Transformation with the pBC-bRPhleo construct

Table 4. Transformation with the HP1 knockout construct

To test whether sclerotium-mediated transformation can be extended to other sclerotium-producing fungi, a linear plasmid containing a Hygr cassette [12] was introduced into sclerotia of S. sclerotiorum, resulting in 5 to 10% transformation efficiency as verified by PCR analysis (Figure 2d) and application of vacuum resulted in a higher number of transformants (data not shown). Other knockout constructs were also successfully introduced into S. sclerotiorum with high efficiency (unpublished data). These results suggest that transformation of sclerotia is a viable approach, while it remains to be determined if the efficiency of transformation is construct-dependent [21].

Direct hyphal transformation

Another transformation approach which was extensively tested was direct hyphal transformation using a high-pressure air pulse obtained from a 'Bim-Lab' instrument to bombard and transform mycelia [12]. Unlike conventional bombardment, this method employs a DNA solution that contains a surfactant rather than solid particles such as tungsten or gold. The mixture of DNA construct and surfactant is blasted over the periphery of the growing colony onto the hyphal tips during the early stages of growth. Blasting conidia or germinating conidia with the bR knockout construct did not yield any transformants. However, when blasting was performed on a young colony (24-48 h post-inoculation), we obtained 66% putative transformants, while older colonies (72-96 h post-inoculation) produced only 25% putative transformants. In terms of efficiency, five experiments with the bR knockout construct resulted in 50 colonies yielding 39% transformants (Table 2), and 21 (54%) of them were identified as knockout strains by PCR of the Hyg cassette with the flanking region of bR genomic DNA (Figures 1a and 2a). Therefore, we used young colonies for further experiments with the pBC-bRPhleo vector and HP1 construct. Transformation with pBC-bRPhleo resulted in 60 Phleo-resistant colonies, 34% of which were PCR-positive strains (Table 3), while transformation with the HP1 construct yielded an average of 3 transformants from 10 colonies (30%) (Table 4).

Discussion

Since protoplast-based and Agrobacterium-mediated transformation methods are complex and time-consuming, we set out to develop new and simple transformation methods for B. cinerea. We tested different transformation methods, two of which were based on published transformation protocols (electroporation and blasting) and one which is a newly developed method and is based on wounding-mediated transformation of sclerotia.

Electroporation did not yield any results despite repeated attempts under various conditions. In addition, there is no published protocol for B. cinerea and other labs that have tried this method have not reported positive results. Of the other two methods described, transformation of sclerotia was efficient (15-50%), easy to perform, required no dedicated instruments or reagents, and colonies appeared after a relatively short time. A significant advantage of this method is the possibility of storing sclerotia for long periods but obviously, it can only be used on strains and species which form sclerotia. The second method, bombardment of DNA with high-pressure air blasted directly onto the growing hyphal tips, also demonstrated good efficiency (30-40%) and took only a short time, as has also been shown for S. sclerotiorum [12]. Unlike conventional bombardment, this method employs a DNA solution that contains a surfactant, which may assist in DNA penetration into the cells [17,18], rather than solid particles such as tungsten or gold [22]. However, it should be noted that this method requires a specialized instrument. Both methods required small amounts of DNA construct, which can be a significant advantage in terms of cost and throughput, and both methods demonstrated facilitated, high efficiency gene targeting (50-60%).

One possible explanation for the positive results with the sclerotium and blast methods is the fact that they impose minimal stress on the cells. In contrast, the electroporation method requires diversion of metabolism to cell-wall regeneration and membrane recovery, and both of these processes may result in a significant stress response. We believe that these reproducible and reliable transformation procedures will increase the efficiency of transformation, will simplify and improve our ability to resolve gene function in this important phytopathogen, and can be easily calibrated for additional fungi.

Conclusions

In this study we describe two alternative protocols--direct hyphal transformation by blasting and wounding-mediated transformation of sclerotia, which are fast, simple and reproducible and might improve functional analysis in B. cinerea and other sclerotium-forming fungi. Future studies will show if these transformation methods have wide applicability for improved gene-targeting efficiency and if they can replace current methodologies.

Abbreviations

PDA: potato dextrose agar; bR: bacterio-Rhodopsin; HP1: hypothetical protein 1; Hyg: hygromycin B; Phleo: phleomycin/Zeocin.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

ML and AL designed the experiments. SIS and AG performed the experiments. ML, AL and SIS wrote the manuscript. All authors read and approved the final manuscript.

Author information

1Postharvest Science of Fresh Produce, The Volcani Center, ARO, Israel; 2 The Department of Plant Pathology and Microbiology, The Robert H. Smith Faculty of Agriculture, Food and Environment, The Hebrew University of Jerusalem, Israel

Acknowledgements

This paper is contribution no. 616-11 from the Agricultural Research Organization, the Volcani Center, Bet Dagan, Israel. The study was funded by research grant no. VWZN2556 from the Niedersachsen-Israel Fund to M. L. and by research grant nos. IS-3947-06 to A.L. and IS-4210-09 to M. L. from BARD, the United States-Israel Binational Agricultural Research and Development Fund. We thank Prof. Oded Yarden for hosting part of the work in his laboratory which was funded by United States-Israel Binational Agricultural Research and Development Fund No. US-4414-11C. We want to thank Dr. Herve Huet and Dr. Aviv Dombrovsky for their approval and help in operating the Bim-Lab instrument.

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