The X. citri subsp. citri used in the study36,37 was the sequenced strain 306.1Escherichia coli strain DH10B (F−mcrA Δ(mrr-hsdRMS-mcrBC) ϕ80lacZΔM15 ΔlacX74 recA1 endA1 araΔ139 Δ(ara, leu)7697 galU galK λ-rpsL (StrR) nupG) was used for cloning. DH10B was cultivated at 37°C in LB38 and Xac at 30°C in NYG (Peptone 5g/L, yeast extract 3g/L and glycerol 20g/L). For the amylase tests, soluble starch was added to NYG-agar at a final concentration of 0.2%. During the cloning procedure, ampicillin (20μg/mL) and kanamycin (10μg/mL) were added to the media to allow for selection of plasmid-carrying colonies.

Basic molecular biology experiments were conducted as per prescribed protocols.38 Electrotransformation of Xac was performed as described previously.39 DNA polymerases and restriction and modifying enzymes were obtained from Fermentas (Thermo Scientific). The construction of pHF5Ca (GenBank FJ562210) has been previously described in the literature40; pHF5Na (GenBank FJ573043) is a variant of pHF5Ca in which the tap1479 has been replaced by the tap176121 (Fig. 1A). The tap1761 cassette was isolated by PCR using pBS1761 as template21 and the primer pair PBS1761F 5′-TGA GGA TCC ATG ATA ACT TCG TAT AGC ATA C and PBS1761R 5′-TCA TTC TAG ACT ATA GGG CGA ATT GGG TAC C. Following PCR, the purified fragment was digested with BamHI/XbaI and ligated to the backbone of pre-digested pHF5Ca. For detecting the presence of pHF5Ca integrated into the Xac genome diagnostic PCR was performed. The primer pair used for this purpose was: pxyl 5′-GTA CTT ACT ATA TGA AAT AAA ATG and 1479R 5′-ATC AAG CTT CAG GTT GAC TTC CCC G.

Fig. 1.

Expression vectors for Tandem Affinity purification in Xac. (A) Schematic representation of pHF5Ca and pHF5Na: the protein expression vectors for TAP-tagging in Xac. Each vector carries a different TAP-coding DNA, tap1479 and tap1761 respectively, which produce TAP fusions to either the C- or N-terminal ends of proteins under study. Both vectors are based on the pCR2.1-TOPO backbone which carries a pUC replication origin and DNA cassettes for ampicillin (Ap) and kanamycin (kan) resistance. (B) DNA sequence of the xylose promoter region common to pHF5Ca and pHF5Na showing the location of the ribosome binding-site (RBS) and the start codon (ATG). (C) The DNA sequences of the 3′-ends of tap1479 and tap1761. Underneath each sequence is the schematic view of the protein fusion that can be produced using the tag. Note that the organization of the modules that compose the TAP-tags (CBP, TEV, and ProtA) differ with respect to TAP1479 and TAP1761 (see text); for the C-terminal fusions, the TAP1479 has ProtA located at the extreme C-terminus of the polypeptide, while ProtA is at the beginning of the protein in the N-terminal fusions. Unique restriction sites for DNA cloning are shown in black; non-unique sites in gray. CBP, calmodulin binding-protein; TEV, Tobacco Etch Virus Protease recognition sequence; ProtA, Protein A from Staphylococcus aureus; and EK, enterokinase recognitions sequence (DDDDK, present only in TAP1761); pxyl, xylose promoter; xylR, the xylose repressor gene; amy, an 800bp fragment of the alpha-amylase gene from Xac.

Strains of E. coli/pHF5Ca and Xac amy::pHF5Ca were activated by the inoculation of 2–3 isolated colonies in 3mL of LB or NYG, respectively, along with the required antibiotics. The inoculums were cultured for 8h at 30°C and 180rpm. At the end of the designated growth period, the cultures were diluted 1:50 (E. coli) or 1:10 (Xac) in Erlenmeyer flasks containing 50mL LB or NYG broth plus antibiotics. Cultures were grown for 14h at 30°C and 180rpm. At the end of the time period, strains were again diluted 1:50 (E. coli) or 1:10 (Xac) in Erlenmeyer flasks containing 50mL LB or NYG broth (for Western blotting) or 500mL LB or NYG (for protein purification). Cultures were incubated at 30°C and 180rpm till an OD600 value of 0.5 was reached. For induction of protein expression, xylose was added to the growth medium to a final concentration of 0.5%; time period for induction was 1h (E. coli) and 4h (Xac) using conditions identical to those employed for culture growth. Subsequent to induction, cells were harvested by centrifugation at 4000×g for 10min followed by washing with cell wash buffer (30mM Tris–HCl, 200mM NaCl); cell pellets were stored at −80°C till use.

Total protein extracts were prepared by resuspending 20mg of each cell pellet in 100μL of SDS-sample buffer. Sample processing, SDS-PAGE, and transfer to PVDF membrane was conducted using standard methodology.38 For detection of the immobilized TAP-tag, the PVDF membrane was washed with PBS-Tween-20 (0.2%) containing 5% skimmed milk and incubated with a secondary antibody coupled to HRP (rabbit Anti-Horse IgG; SIGMA A6917) in a dilution of 1:3000. The principle underlying this methodology is that Protein A, which is part of the TAP-tag, is known to bind IgG isotypes directly. Following incubation with the antibody, the western blot was developed by immersing the membrane in ECL detection reagents (Amersham ECL Western Blotting System kit-GE). The chemiluminescence produced was captured on X-ray film (Hyperfilm, GE) for further analysis.

Cell pellets obtained from 500mL cultures were dissolved in pre-chilled 10mL TST (50mM Tris–HCl pH 8.0, 150mM NaCl, and 0.05% Tween 20) containing a one-fourth of a tablet of EDTA-free protease inhibitors (Roche 1.873.580). Cells were lysed by sonication using a Vibra-Cell VCX 130 (Sonics) (10 pulses of 10s each with intervals of 1min) and the sonicated samples were then centrifuged at 48,000×g for 30min at 4°C. Batch binding of proteins to the affinity resin was done by incubating the clarified suspensions with 500μL of IgG-Sepharose (previously equilibrated in TST; GE 17-0969-01) on an ice bath with gentle agitation through a rotary shaker (120rpm). After a 2h incubation, resin was transferred to a 10mL disposable column (Poly-prep BioRad 731-1550) and washed 3–4 times with 20 column-volumes of TST using gravity flow. Samples of 100μL were collected throughout the process for SDS-PAGE analysis. The TAP-tag was released from the resin by acid elution using 0.5M acetic acid (pH 3.4; adjusted with 10M ammonium acetate). Eluate fractions of 1mL each were precipitated using TCA (3% final) and centrifuged for 10min using a microcentrifuge at maximum speed; protein pellets were washed once with absolute ethanol and then dissolved in 100μL of SDS sample buffer for SDS-PAGE.

The plant host used for this study was the sweet orange cultivar ‘Bahia’ (Citrus sinensis L. Osbeck). Orange trees were cultivated under green-house conditions. Cells to be tested were cultivated in the appropriate medium until OD600 reached ∼0.6 (∼108CFU/mL). Subsequent to growth, cell suspensions or dilutions were used to inoculate leaves on the abaxial surface with the help of hypodermic syringes (1mL) fitted with needles. Symptoms were observed in the course of three weeks from the day of inoculation.

In this study, the two TAP expression vectors used for Xac, pHF5Ca and pHF5Na, carry the xylose promoter (pxyl), the xylose repressor (xylR), and the TAP encoding sequences tap1479 or tap1761 (Fig. 1A). These components are separated by a short stretch of DNA containing a Ribosome Binding Site (RBS) whose sequence is a consensus for both Bacillus subtilis as well as E. coli41 (Fig. 1B). The xylose promoter used has been previously evaluated by our group in Xac and found to function satisfactorily.17,40 The two TAP sequences, tap1479 and tap1761, encode for tags used in Tandem Affinity Purification of protein complexes and are composed of three components (Fig. 1C): (a) Two domains of Protein A (ProtA; Staphylococcus aureus) that is known to have a strong affinity for IgG; (b) A peptide that binds calmodulin (CBP); (c) A short peptide stretch containing the recognition sequence for the protease TEV (Tobacco Etch Virus) separating the above mentioned components.21,22 The expression vectors pHF5Ca and pHF5Na differ only in the TAP-tags that they encode; pHF5Ca carries the tap1479 and is used for the expression of protein fusions containing the peptide TAP1479 at the C-termini whereas the pHF5Na carries the tap1761 and is used to produce fusions of TAP1761 to the N-termini of proteins of interest. Additionally, both the vectors used are integrative as they carry the amy106-914 fragment of Xac which drives their integration into the amy locus of the bacterium via a single crossover event. Upon integration, the amy gene of Xac is disrupted and the bacterium becomes incapable of degrading starch.

In a previous study, we demonstrated that Xac mutant strains carrying the GFP expression vectors pPM2a or pPM7g integrated into the amy locus were capable of inducing disease symptoms in citrus plants.17 Herein, in continuation of the previous study, we wanted to evaluate if the presence of the TAP coding DNA altered or affected the virulence/pathogenicity associated with Xac. To test this hypothesis, pHF5Ca was electroporated into Xac; and kanR transformants (candidates potentially carrying the vector pHF5Ca) were selected for further characterization. To certify that the TAP expression vector had integrated into amy locus, a set of putative mutants were tested for their ability to degrade starch on a test plate.17 The results clearly demonstrated that the candidate mutants were deficient in starch degradation hence proving that pHF5Ca was stably integrated into the amy locus of Xac such that these mutants were unable to produce alpha-amylase (data not shown). Alongside the starch degradation test, we also carried out diagnostic PCRs on a selection of six kanR mutants so as to certify the presence of pHF5Ca (Fig. 2). The diagnostic PCRs detected a DNA fragment of ∼640bp corresponding to the tap1479 in all the mutants analyzed (compare lanes 2–7 with the positive control in lane 8 wherein pHF5Ca was used as DNA template). No bands were detected in the negative control (lane 1, wild type Xac).

Fig. 2.

Colony PCR to detect the presence of pHF5Ca integrated into the chromosomal DNA of Xac. Subsequent to electrotransformation of Xac with the expression vector pHF5Ca, six kanR mutants were selected and subjected to colony PCR using the primers PBS1479F/R specific for the amplification of the tap1479 (approximately 640bp). The PCR amplicons were visualized after migration through a 0.7% agarose gel. Lane: 1, WT Xac (negative control); 2–7, the six selected mutants; 8, PCR using pHF5Ca as the DNA template (positive control); and 9, DNA molecular weight marker (1kb DNA ladder, NEB).

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In order to verify if Xac amy::pHF5Ca was capable of causing disease symptoms in a susceptible host, two independently selected mutants were inoculated into leaves of sweet orange (Fig. 3A–C). Seven days post-inoculation, the borders of the area inoculated with Xac clearly exhibited the typical water-soaking symptom associated with the disease (Fig. 3D–F). These areas developed brownish canker-like lesions during the course of the next three weeks (data not shown). A point to note is that the mutant strains displayed the same distinct lesion pattern as the wild type. In contrast, the area inoculated with NYG-medium (negative control) showed only a mild chlorosis. In summary, the results obtained in this study clearly demonstrated that the ability to cause disease remained unaffected following integration of the Xac amy::pHF5Ca mutants.

Fig. 3.

The integration of the TAP expression system into the chromosome of Xac does not alter its pathogenicity. Two independently selected mutants of Xac amy::pHF5Ca (1 and 2) were inoculated into leaves of sweet orange Bahia alongside the wild type strain (Xac wt) and a sample of NYG-medium (negative control). A map of the inoculation is shown on the right-hand side of the figure. Pictures were taken immediately after inoculation (A–C) and also 7 days post-inoculation (D–F). The test was conducted in triplicate (A–C).

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The production of a TAP-tag can be detected in Western blotting assays by exploiting the ability of ProtA to bind to the IgG antibody.42 A strain of E. coli carrying pHF5Ca (multicopy) vector and two Xac amy::pHF5Ca mutant strains (harboring a single copy of the expression cassette integrated into the amy locus of Xac) were cultivated and induced with xylose. Total protein extracts were separated by SDS-PAGE (Fig. 4A) and transferred onto a PVDF membrane so as to facilitate detection of TAP1479 using antibody reactions. The bands of the size expected for the TAP1479 (∼21kDa) were detected for both the mutant strains of Xac as well as for E. coli transformed with pHF5Ca (Fig. 4B, lanes 1–2, and 5–8). The results also showed that the production of TAP1479 was responsive to induction by xylose (lanes 1 and 2, 5 and 6, 7 and 8). For the negative control, wild type Xac, no signal corresponding to the band size of TAP1479 was detected (lanes 3 and 4). It was observed that E. coli produced more of the tag than the Xac mutants, a result that is consistent with the multicopy condition of pHF5Ca in E. coli. The results obtained clearly show that the expression system is functional in both bacteria and also that an intact and active ProtA moiety was produced in Xac.

Fig. 4.

Western blotting analysis to detect expression of TAP1479 by Xac amy::pHF5Ca mutants. The functionality of the TAP expression system was verified by the ability of an E. coli DH10B strain, with pHF5Ca and Xac kanR mutants, carrying the vector integrated into the chromosome, to produce the TAP1479 (approximately 21kDa) (details of the induction procedure have been described in “Materials and methods” section). (A) Coomassie blue-stained 10% SDS-PAGE showing the separation of proteins from cell extracts of E. coli and Xac; lanes: 1, E. coli/pHF5Ca; 2, E. coli/pHF5Ca+0.5% xylose; 3, Xac (WT); 4, Xac WT+0.5% xylose; 5, Xac amy::pHF5Ca mutant 1; 6, Xac amy::pHF5Ca mutant 1+0.5% xylose; 7, Xac amy::pHF5Ca mutant 2, 8; Xac amy::pHF5Ca mutant 2+0.5% xylose; and 9, protein molecular weight marker. (B) X-ray film displaying bands detected by the Western blotting analysis. Proteins in a replica of the gel shown in A were transferred to a PVDF membrane and exposed to a secondary antibody coupled to HRP. Lanes are the same as in (A). The position of the TAP1479 is marked with a black arrow on the right hand side of the film.

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The TAP-tag detected in the previous section appeared to be a resilient polypeptide capable of retaining the property of IgG-binding even after treatment with SDS and boiling as is mandatory for sample preparation in SDS-PAGE electrophoresis. However, results obtained by western blotting do not guarantee function, as the positive outcome can easily be explained as a byproduct of residual IgG binding activity of ProtA. Additionally, for the protein complexes produced in Xac to be useful, it is essential to check if the TAP1479 could be produced in larger amounts and in a soluble form. In order to evaluate this, an attempt was made to purify TAP1479 by affinity separation. An E. coli strain carrying pHF5Ca and a Xac amy::pHF5Ca mutant were cultivated and induced with xylose. Following expression of the TAP-tag, cells were lysed by sonication and clarified cell extracts were subjected to affinity chromatography using IgG-immobilized resin. TAP1479 was successfully purified from the soluble phase of both extracts (Fig. 5; see arrows). As observed in the Western blotting experiments, E. coli produced a relatively higher amount of the tag (a tag concentration of ∼1.4mg/mL was estimated for the sample in lane 8) as compared to the yield from Xac (∼0.2mg/mL, lane 7). However, the amount of tag produced by Xac, though less, should suffice for mass spectrometry identification. The contaminant bands above the TAP1479 represent denatured human IgG which was stripped out from the matrix by the acid elution together with other bacterial proteins that might be interacting with the resin. These results corroborate the use of the expression vectors pHF5Ca and pHF5Na as integration/protein expression systems for TAP-tagging in Xac.

Fig. 5.

Purification of TAP1479 from E. coli/pHF5Ca and Xac amy::pHF5Ca. E. coli DH10B carrying pHF5Ca and a kanR mutant of Xac harboring pHF5Ca integrated into its chromosome were induced for the production of the TAP1479. Following expression, cells were lysed and protein extracts subjected to affinity chromatography through IgG-sepharose. (A) E. coli/pHF5Ca; and (B) Xac amy::pHF5Ca, Coomassie blue-stained 10% SDS-PAGE showing the separation of proteins from the fractions collect throughout the process. (A) lane: 1, clarified lysate; 2, flow through; 3–6, washes (20 column-volumes each); 7, protein molecular weight marker; 8–14, elution fractions. (B) Lane: 1, clarified lysate; 2, flow through; 3–5, washes; 6, protein molecular weight marker; 7–14, elution fractions. The position of the TAP1479 is marked with black arrows in both gels.

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