Figures
Abstract
Brucella ovis is a major cause of reproductive failure in rams and it is one of the few well-described Brucella species that is not zoonotic. Previous work showed that a B. ovis mutant lacking a species-specific ABC transporter (ΔabcBA) was attenuated in mice and was unable to survive in macrophages. The aim of this study was to evaluate the role of this ABC transporter during intracellular survival of B. ovis. In HeLa cells, B. ovis WT was able to survive and replicate at later time point (48 hpi), whereas an ΔabcBA mutant was attenuated at 24 hpi. The reduced survival of the ΔabcBA mutant was associated with a decreased ability to exclude the lysosomal marker LAMP1 from its vacuolar membrane, suggesting a failure to establish a replicative niche. The ΔabcBA mutant showed a reduced abundance of the Type IV secretion system (T4SS) proteins VirB8 and VirB11 in both rich and acid media, when compared to WT B. ovis. However, mRNA levels of virB1, virB8, hutC, and vjbR were similar in both strains. These results support the notion that the ABC transporter encoded by abcEDCBA or its transported substrate acts at a post-transcriptional level to promote the optimal expression of the B. ovis T4SS within infected host cells.
Citation: Silva TMA, Mol JPS, Winter MG, Atluri V, Xavier MN, Pires SF, et al. (2014) The Predicted ABC Transporter AbcEDCBA Is Required for Type IV Secretion System Expression and Lysosomal Evasion by Brucella ovis. PLoS ONE 9(12): e114532. https://doi.org/10.1371/journal.pone.0114532
Editor: Daniel E. Voth, University of Arkansas for Medical Sciences, United States of America
Received: June 24, 2014; Accepted: November 10, 2014; Published: December 4, 2014
Copyright: © 2014 Silva et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper and its Supporting Information files.
Funding: US PHS grants AI050553 and AI090387 to R.M.T. supported this work. T.M.A.S. was supported by a fellowship from CNPq, Brazil. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Brucella ovis is one of the main causes of reproductive failure in sheep [1]. In sexually mature rams, the infection causes chronic epididymitis, orchitis, and infertility, whereas in ewes, it is characterized by uncommon abortion and stillbirth [2], [3]. B. ovis has a worldwide distribution in main sheep-raising areas, resulting in significant economic losses for the sheep industry [1], [4]. This organism is a stably rough Gram-negative coccobacillus that belongs to the alpha-2-Proteobacteria family [2], [5]. Unlike most of the well-described Brucella spp., B. ovis does not cause disease in humans [2].
Similar to other Brucella spp., B. ovis is a facultative intracellular bacterium able to survive and replicate in phagocytic and nonphagocytic cells, and establishing chronic infections in animals [6], [7]. In the absence of classical virulence factors, such as capsule and fimbriae [7], Brucella species require specific virulence factors for their survival, and replication in host cells [8]–[11], including the virB-encoded type IV secretion system (T4SS) and its secreted effector proteins. Previous studies have shown attenuation of virB mutant strains in either pathogenic smooth species (Brucella melitensis, Brucella abortus, and Brucella suis) or rough species (B. ovis) [8], [12]–[16]. Brucella strains lacking a functional T4SS cannot evade degradation in lysosomes and, consequently, do not reach their replicative niche in the rough endoplasmatic reticulum [17] nor establish chronic infection [9], [10], [13].
Genomic analyses of B. ovis resulted in the identification a pathogenicity island (BOPI-1) in chromosome II containing 28 open reading frames (ORFs), which are absent in other classical Brucella species [18]. This island comprises genes that potentially encode pathogenesis-associated proteins, including an ATP-binding cassette (ABC) transporter (BOV_A0504-BOV_A0500, designated abcEDCBA) [18], [19]. ABC transporters are responsible for nutrient uptake and the export of toxins and antibiotics, and they may play an important role in gene expression [20], [21]. In Brucella spp., a polysaccharide ABC transporter is required for B. abortus pathogenesis in the murine model [11], whereas ABC transporter proteins related to iron transport and toxin excretion were not essential for B. abortus chronic infection in mice [21], [22].
In B. ovis, a species-specific ABC transporter located at the BOPI-1 was essential for survival and replication in a mouse model and in macrophages [19]. However, it is not known what the specific role of this transporter is and whether it affects other virulence factors necessary for B. ovis survival in host cells. B. ovis is the classical Brucella species with lowest number of ABC transporters predicted to be functional, due to high numbers of pseudogenes in conserved Brucella spp. regions predicted to encode ABC systems [18], [23]. This may be one of the determinants of the low pathogenicity of B. ovis during animal and human infections. Hence, studying specific features of B. ovis may explain why it is not virulent in humans [18]. Moreover, high numbers of pseudogenes in ABC systems may allow evaluation of the pathogenic role of conserved transporters in B. ovis by one single gene deletion. This is less feasible in classical Brucella species, like B. melitensis and B. abortus, due to the presence of redundant transporters, which may compensate the function of a deleted protein.
The goal of this study was to evaluate the role of a specific ABC transporter during B. ovis in vitro growth, intracellular survival, and trafficking. Our results show here that the specific locus abcEDCBA, encoding a putative peptide importer, promotes intracellular survival by affecting T4SS protein expression at a post-transcriptional level and, consequently, contributing to B. ovis evasion of phagosome/lysosome fusion.
Materials and Methods
Bacterial strains, media and culture condition
Bacterial strains used in this study were the virulent strain B. ovis ATCC 25840 (WT); ΔabcBA mutant strain (TMS2) lacking a putative ABC transporter [19]; B. ovis WT and ΔabcBA isogenic strains expressing mCherry fluorescence (named TMS8 and TMS9, respectively), with the insertion of pKSoriT-bla-kan-PsojA-mCherry plasmid [24] (Table 1). All inocula were cultured on Trypticase Soy Agar (TSA, BD) plates with 5% sheep blood for three days at 37°C in 5% CO2, as previously described [25]. For proteomic analysis, B. ovis WT and ΔabcBA were grown in triplicate on TSA plates with 10% hemoglobin for three days. Kanamycin (Kan, 100 µg/mL) and Ampicillin (Amp, 200 µg/mL) were added to media when necessary. For strains TMS8 and TMS9, selected colonies were Amp resistant and fluorescent, as previously described [24].
Considering that B. ovis does not grow adequately in conventional liquid media [26], a rich Trypticase Soy Broth (TSB, BD) was supplemented with 10% of FBS (Gibco). Strains were cultured overnight at 37°C on rotary shaker. Additionally, B. ovis in vitro growth was measured in TSB media supplemented with different concentrations of FBS (0, 2, 5, or 10%), nickel (NiSO4 at 0.5, 1 or 2 mM) or after chelation of divalent cations by adding EDTA (10, 25, or 50 mM). Strains were cultured up to 48 h at 37°C on rotary shaker.
For cloning, E. coli DH5α and TOP10 (Invitrogen) were grown on LB media or rich SOC media [2% tryptone, 0.5% yeast extract, 10 mM NaCl, 2.5 mM KCl, 10 mM MgCl2, 10 mM MgSO4, 20 mM glucose] and then plated on LB with selective antibiotics (Table 1).
Salmonella enterica serovar Typhimurium LT2 (STm WT) and the mutant STm LT2 opp-250 (del:BC), tppB16:Tn10, dpp-101:Tn5 (TT17573) with non-functional peptide transporters were obtained from Dr. John Roth's strain collection, at UC Davis. Additionally, TT17573 (oppBC tppB dpp) strain expressing B. ovis ABC transporter locus (TMS14) was constructed. STm WT and mutants were grown overnight at 37°C on a rotary shaker in LB media or minimal M9 media [47.7 mM Na2HPO4, 22 mM KH2PO4, 8.6 mM NaCl, 18.6 mM NH4Cl, 2 mM MgSO4, 0.1 mM CaCl2] supplemented with 0.4% glucose and 1 µg/mL thiamine. Kan (100 µg/mL), tetracycline (10 µg/mL) and Amp (100 µg/mL) were added when necessary.
Cloning and complementation
To express B. ovis ABC transporter locus in S. Typhimurium TT17573 (oppBC tppB dpp) strain, the entire abcEDCBA locus (5.6 Kb) was amplified by PCR, using genomic DNA from B. ovis ATCC 25840. A histidine tag (6x-his) and a stop codon were engineered into the C-terminal region (Table 2). PCR reactions were prepared with 23 µL of Supermix High Fidelity (Invitrogen), 0.7 mM of each primer abc-his (Table 2) and 2 µL of the genomic DNA. Cycling parameters, as described by [27], were as follows: denaturation at 94°C for 3 min; 35 cycles of denaturation at 94°C for 1 min, annealing at 50°C for 1 min and extension at 60°C for 6 min; and final extension at 60°C for 10 min. The 5.6 Kb product was purified from agarose gel using QIAEXII kit (Qiagen) and, then, inserted into the cloning vector pCR2.1 TOPO, following the manufacturer's instructions (Invitrogen). The insert was excised by double digestion with SpeI and KpnI, and cloned into expression vector pBBR1-MCS4, AmpR (4 Kb). To confirm the sequence and orientation of the insert, the constructed plasmid, named pTSabc, was sequenced using primers M13 (Invitrogen) (Table 2). Then, the plasmid was introduced into S. Typhimurium TT17573 (oppBC tppB dpp) by electroporation, with previous heating of the bacteria for 30 min at 50°C [28]. Colonies resistant to Tet, Kan, and Amp were selected and the ABC transporter expression in TMS14 (TT17573:abcEDCBA) was confirmed by Western blot, using anti-Histidine tag mouse monoclonal antibody conjugated with HRP (Lifetech).
The deletion of oppBC and transposon insertion into dppA and tppB in S. Typhimurium TT17573 were confirmed by PCR as described, using pairs of primers shown in Table 2.
S. Typhimurium lethality assay
Considering that STm has three types of peptide ABC transporters, which mainly transport dipeptides (Dpp), tripeptides (Tpp) or oligopeptides (Opp) [29]–[31], we attempted to use this organism to predict the function of B. ovis transporter by evaluating bacterial resistance to toxic peptides [29], [32].
For the lethality assay, STm WT, STm TT17573 (oppBC tppB dpp), and TMS14 (TT17573:abcEDCBA) mutant expressing the B. ovis abcE-A transporter were grown overnight in M9 liquid media. Each bacterial strain was adjusted to 3×105 CFU/mL in fresh M9 with 0.7% noble agar (BD) and layered over M9 agar plates containing antibiotics. After solidifying, 7 mm-filter paper disks containing 0.5 mg and 1 mg of alafosfalin (L-Alanyl-L-1-aminoethylphosphonic acid, Sigma-Aldrich) or 0.2 mg and 0.4 mg of trilysine (Sigma-Aldrich) were placed onto the plate. After drying the disks, plates were incubated for 16 h at 37°C. The ability of a toxic peptide to inhibit bacterial growth was quantified by determining the diameter (mm) of the inhibitory zone surrounding a filter paper disk with the toxic peptides. Assays were performed three times independently, with triplicate samples.
Proteomic analysis by Differential Gel Electrophoresis (DIGE)
Protein expression of WT and ΔabcBA B. ovis were compared by DIGE during in vitro growth in rich media. For each bacterial strain, triplicates grown independently were used. Protein was extracted with 2 vol of lysis buffer (8 M urea, 2 M thiourea, 4% w/v CHAPS, 40 mM Tris1M, mix of protease inhibitors) (GE Healthcare), followed by 3 h of agitation and cellular lysis by passing through a 26G needle. Lysates were centrifuged at 20,000×g for 30 min at room temperature, and the supernatants were recovered, quantified by 2D Quant Kit (GE Healthcare), and kept at −80°C. A pool of protein extracts obtained from triplicate samples was used.
To identify differentially expressed proteins between B. ovis WT and ΔabcB mutant, the protein mixture (50 µg) of each strain was labeled with 400 pmol of either Cy3 or Cy5 dye (GE Healthcare), according to the manufacturer's instructions. A protein mixture of both strains (50 µg) was labeled with Cy2 dye as internal control. These reactions were carried out on ice for 30 min in the dark and quenched with 1 µL of lysine (10 mM) for 10 min on ice. Four DIGE gels were done and a dye-swap was performed. All labeled proteins (150 µg) were added to 3.4 µL of immobilized pH gradient (IPG) buffer (10 µL/mL), 450 µg of unlabeled protein, and IEF buffer (8 M urea, 2 M thiourea, 4% CHAPS, 0.0025% bromophenol blue, 10 mg/mL dithiothreitol) in a total volume of 340 µL per IPG strip (18 cm, pH 4–7, GE Healthcare). The samples were incubated overnight with the IPG strips, submitted to isoelectric focusing using Ettan IPGphor system (GE Healthcare), followed by incubation in equilibrium solution (50 mM Tris-HCl, pH 8.8, 6 M urea, 30% glycerol, 2% SDS, 0.002% bromophenol blue, and 125 mM DTT) for 15 min and an additional incubation in a new solution containing 13.5 mM iodoacetamide instead of DTT.
Electrophoresis was performed in 12% SDS-PAGE using an Ettan Electrophoresis unit (GE Healthcare) at 10 mA/gel for 1 h, followed by 45 mA/gel until the dye front reached the bottom of the gel. Each gel was scanned using Typhoon FLA 9000 (GE Healthcare) with excitation/emission wavelengths of 488/520, 532/580, and 633/670 nm for Cy2, Cy3, and Cy5 dyes, respectively. Gel images were analyzed using DeCyder 2D software, Version 7.0 (GE Healthcare). Spots with p-value <0.05 and average of volume ratio over 1.5 were selected for mass spectrometry (MS) identification. To extract the spots of interest, all DIGE gels were subsequently stained with colloidal Coomassie Brilliant blue G-250, as previously described [33].
Mass spectrometry (MS) and prediction of protein interactions
Differentially expressed spots between WT and ΔabcBA B. ovis were excised from gel, treated with trypsin, and desalted using Zip-Tips (Millipore Corporation), as described elsewhere [34]. Each sample was mixed with 0.5 vol of saturated matrix solution (10 mg/mL α-cyano-4-hydroxycinnamic acid in 50% acetonitrile/0.1% trifluoroacetic acid). Then, samples were spotted on MTP AnchorChip 600/384 (Bruker Daltonics) and let it dry at room temperature. For protein identification, raw data were acquired on a MALDI-TOF/TOF AutoFlex III instrument (Bruker Daltonics) in the positive/reflector mode controlled by FlexControl software. Instrument calibration was previously done using peptide calibration standard II (Bruker Daltonics) as a reference.
Data from mass spectrometry were aligned against all non-redundant protein sequence database from NCBI (http://www.ncbi.nlm.nih.gov) using the MASCOT software MS/MS ion search tool (http://www.matrixscience.com). The parameters in this search were as follows: no restriction on protein molecular weight, loss of a trypsin cleavage site, variable modifications of methionine (oxidation), cysteine (carbamidomethylation), and pyroglutamate formation at the N-terminal glutamine. The mass tolerance for searched peptides were 0.8 Da for MS spectra and 0.6 Da for MS/MS spectra. Peptides were identified when the scoring value exceeded the identity or extensive homology threshold value calculated by the MASCOT (p<0.05).
Interactions of identified proteins were predicted by using the STRING software (http://string-db.org), as previously described [35]. The evidence mode was set up at an average confidence level 0.4 and the search parameters included: neighborhood, gene fusion, co-occurrence, co-expression, experiments, databases, and text mining.
HeLa cell culture and infection
HeLa cells were cultured in a 75 cm2 flasks with Dulbecco's modified Eagle medium (DMEM, Gibco) supplemented with 10% FBS, at 37°C with 5% of CO2. When reaching 80–90% of confluence, cells were treated with Trypsin-EDTA 0.05% for 10 min, and seeded overnight in a 24-well plate at a density of 1×105 cells per well. The next day, HeLa cells were infected as previously described [36], with some modifications for B. ovis. Briefly, B. ovis WT, ΔabcBA and mCherry-expressing isogenic strains (TMS8 and TMS9) were grown for 3 days, resuspended in DMEM supplemented media, and added 0.5 mL to each well, to infect HeLa cells with the multiplicity of infection (MOI) of 1000. The plates were centrifuged at 400 × g for 5 min at room temperature and incubated for 30 min at 37°C in 5% CO2. The cells were washed three times with Dulbecco phosphate-buffered saline (DPBS) to remove free bacteria, followed by the addition of 0.5 mL of DMEM supplemented media with 50 mg/mL of gentamicin into the wells, to kill the extracellular bacteria. This was considered the zero time point.
In order to determine bacterial survival, the medium was aspirated at 0, 8, 24, and 48 h after infection and HeLa cells were lysed with 0.5 ml of 0.5% Tween 20, followed by rising each well with 0.5 mL of PBS. Viable bacteria were quantified by serial 10-fold dilutions in sterile PBS and plating on TSA with 5% sheep blood. This experiment was performed in triplicate and repeated three times.
Brucella ovis confocal microscopy
HeLa cells were seeded overnight on a 12-mm glass coverslips in a 24-well plate at a density of 3×104 cells per well. The cells were infected with B. ovis mCherry-expressing WT or ΔabcBA strain with MOI of 1000. At 8, 24, and 48 h post infection, each coverslip was washed three times with PBS, fixed with 3% paraformaldehyde (pH 7.4) at 37°C for 20 min, followed by three washes with PBS and incubation in 50 mm NH4Cl in PBS for at least 10 min, to quench free aldehyde groups. Samples were permeabilized with 10% horse serum and 0.1% saponin in PBS for 30 min at room temperature. After removing the coverslips, each sample was labeled with rabbit anti-human LAMP-1 antibody (Thermo Scientific), by inverting the coverslips onto droplets of primary antibody diluted (1∶1000) in 10% horse serum and 0.1% saponin solution in PBS. After incubating for 1 h at room temperature, each sample was washed with PBS and labeled with diluted (1∶1000) Alexa Fluor 488 anti-rabbit antibody (Lifetech) for 1 h at room temperature. Then, cells were washed twice with 0.1% saponin in PBS, once in PBS, once in distilled H2O and mounted in Mowiol 4–88 mounting medium (Calbiochem). Samples were analyzed on a Carl Zeiss LSM 510 confocal laser scanning microscope for image acquisition. Confocal images of 1024×1024 pixels were acquired as projections of three consecutive slices with a 0.38-μm step and gathered using Adobe Photoshop CS5. To quantify B. ovis infection in cells and LAMP-1+ compartment colocalization, at least 100 bacteria and 100 cells per sample were counted. All experiments were performed independently three times and in triplicate.
Expression of T4SS proteins by Western blot
The expression of VirB proteins, which constitute the T4SS, were evaluated during in vitro growth of B. ovis WT and ΔabcBA strains. Each sample was cultured on TSA plates with 5% of sheep blood for three days and subsequently transferred to TSB with 10% FBS, at a starting OD600 of 0.1. After incubating overnight on a rotary shaker at 37°C, cells from 1 mL of each culture were pelleted by centrifugation and resuspended in SDS-PAGE buffer. VirB expression was also analyzed after growth of B. ovis on TSA plates containing 5% of sheep blood, by scraping an aliquot straight from the plate and resuspending in SDS buffer.
Considering that T4SS expression in classical Brucella species is induced by acidic pH and nutrient-poor conditions [37], expression of VirB proteins under these conditions was assayed. To this end, 109 CFU of each strain was suspended in modified minimal E medium pH 5.0, and incubated for additional 6 h at 37°C on a rotary shaker, as previously described [38]. VirB protein expression is also promoted by urocanic acid, which induces expression of two T4SS regulators (HutC and VjbR) in an acidic environment [39]. Therefore, B. ovis WT and ΔabcBA (109 CFU) were suspended in modified minimal E medium (pH 5.0) supplemented with urocanic acid 5 mM or glutamic acid 5 mM (control), and incubated for additional 4 h at 37°C on a rotary shaker. Assays were performed at least three times independently for each strain.
For Western blot, bacterial proteins were extracted by heating the samples for 10 min in 4% SDS buffer. The total protein (10 to 20 µg) was electrophoresed on a 12% SDS-PAGE gel, and transferred to a nitrocellulose membrane. Membranes were blocked in blocking solution (PBS containing 2% non-fat skim milk powder and 0.05% Tween 20) for 1 h and incubated for 1 h with rabbit anti-VirB8, anti-VirB9 or anti-VirB11 polyclonal antibody diluted in blocking solution (1∶5000). Then, membranes were washed three times with blocking solution and incubated for another 1 h with diluted (1∶5000) goat anti-rabbit IgG antibody (Biorad) conjugated with horseradish peroxidase (HRP). HRP activity was detected with a chemiluminescent substrate (Perkin-Elmer). As a loading control, same sample concentrations used in Western blot were loaded on a separate SDS-PAGE gel and stained with Coomassie Brilliant Blue.
Bacterial RNA extraction and Real Time RT-PCR
To compare gene expression of B. ovis WT and ΔabcBA strains during in vitro growth, RNA was extracted from 1 mL of bacterial samples grown on TSB media with 10% FBS for 24 h at 37°C on rotary shaker. RNA extraction was carried out using TRI reagent (Molecular Research Center, Cincinnati) as previously described [13], followed by RNA purification with RNeasy Minelute cleanup kit (QIAGEN) and DNase treatment (Invitrogen) for 1 h at 37°C. Real-time PCR was performed using TaqMan reverse transcription reagent (Applied Biosystems) with 10 µL of RNA from each sample in a 60((L volume. To assess whether there was genomic DNA contamination in samples, a new 30((L mix volume of TaqMan reagent was performed with 5((L of RNA, without adding reverse transcriptase enzyme. Four (L of cDNA was used as the template for each reverse transcription-PCR (RT-PCR) in a 25 µL volume, with 12.5 µL of SYBR Green (Applied Biosystems) and 0.3 µM of each primer listed in Table 3. Data were analyzed using the comparative Ct method (Applied Biosystems). Transcript levels of virB1, virB8, vjbR, hutC, abcA, and abcC were normalized with mRNA levels of the housekeeping 16S ribosomal gene (Table 3). Ct values of B. ovis WT genes were expressed in relation to B. ovis ΔabcBA strain.
Statistical analyses
All CFU data were logarithmically transformed and submitted to analysis of variance (ANOVA). For confocal microscopy, all percentage data were submitted to angular transformation prior ANOVA. Means of groups were compared with Tukey's test (GraphPad InStat 3) and considered significant when p<0.05. Confocal microscopy and real time data represent geometric mean and standard error of three independent experiments. For real time PCR, Ct values were compared between groups by Student T test, and considered significant when p<0.05.
Results
Prediction of ABC transporter function during in vitro growth
According to genomic analysis of B. ovis [18], [23], the B. ovis abcEDCBA locus was previously predicted to encode a peptide importer [19]. Additional analysis was performed in this study, by aligning the nucleotide sequence to sequences available at the NCBI protein database (BLASTx).
Two proteins encoded by abcA (BOV_A0500) and abcB (BOV_A0501), which were deleted in the abcBA mutant strain, are predicted to be ATPases of ABC systems, with conserved Walker A and B motifs. Therefore, deletion of abcA and abcB would lead to inactivation of the transporter. Both ATPases showed 99% identity only with Brucella pinnipedialis B2/94 and Brucella sp. 63/311, and 91% identity with two phylogenetically related bacteria (Ochrobactrum anthropi and Ochrobactrum intermedium). Proteins encoded by abcE-C (BOV_A0504-502) were identical to a conserved group of ABC systems functioning in uptake of dipeptides, oligopeptides and nickel (Dpp/Opp/Nik). Both abcD and abcC are predicted to be transmembrane proteins, whereas abcE encodes a predicted substrate-binding protein, suggesting a function of the ABC system in substrate uptake.
The role of the B. ovis abcEDCBA transporter was evaluated during in vitro growth, using a liquid medium that allowed for exponential growth of both WT and ΔabcBA strains. Both strains showed limited growth after 24 h in TSB media (Figure S1A), which is a standard laboratory media for Brucella spp. [40]. When TSB was supplemented with different concentrations of FBS (2, 5, or 10%), WT and ΔabcBA showed equally proportional growth, reaching maximal growth with 10% FBS (Figure S1A). For further B. ovis experiments, TSB with 10% FBS was used as the standard liquid media.
Considering the genomic prediction of B. ovis abcEDCBA-encoded proteins as a nickel transporter (Nik), it was evaluated if in vitro growth was impacted by adding or removing nickel from the growth medium. Addition of NiSO4 (0.5, 1, or 2 mM) to TSB with 10% FBS did not increase growth of either B. ovis ΔabcBA mutant, or the WT strain after 48 h (Figure S1B). Also, chelation of divalent cations, including nickel, by adding EDTA at 10, 25 or 50 mM into the media equally limited the growth of both strains. These results show that deletion of the abcEDCBA–encoded ABC transporter did not restrict nickel uptake or in vitro growth of ΔabcBA B. ovis.
B. ovis abcEDCBA does not complement a peptide transport-deficient strain of S. Typhimurium
To assess the predicted function of B. ovis ABC transporter as a peptide importer, this protein was constitutively expressed in S. Tm TT17573, which carries spontaneous mutations in the genes oppBC tppB dpp, resulting in non-functional peptide transporters for oligopeptides (Opp), tripeptides (Tpp) and dipeptides (Dpp). Previous studies have characterized peptides that are toxic for STm when taken up by a specific type of transporter [29], [32]. Due to easy growth of STm in protein-restricted media, sensitivity of STm WT, STm TT17573 (oppBC tppB dpp), and TT17573 strain complemented with abcEDCBA (TMS14) were evaluated against trilysine and alafosfalin, which are imported by Tpp and Opp transporters, respectively (Figure S2). For detection of abcEDCBA expression in S. Typhimurium, a 6x-His tag was engineered into the C-terminus of AbcA.
STm WT and TT17573 (oppBC tppB dpp) demonstrated similar growth and metabolic activity by tetrazolium reduction in minimal M9 media (Figure S2). STm WT was susceptible to trilysine and alasfosfalin at two different concentrations (Figure S3A-B). However, STm TT17573 (oppBC tppB dpp) and TMS14 (TT17573:abcEDCBA) were resistant to toxic peptides (Figure S3A), suggesting that these strains have non-functional Tpp and Opp transporters. Introduction of B. ovis abcEDCBA into STm TT17573 did not confer peptide uptake, although expression of abcA was confirmed by Western blot (Figure S3C). These results suggested that B. ovis abcEDCBA does not function in STm as an oligopeptide or tripeptide importer.
Inactivation of Brucella ovis abcEDCBA affects the abundance of metabolic and virulence-associated proteins during in vitro growth
To gain insight into the role of abcEDCBA in the biology of B. ovis, differential expression of proteins between WT and ΔabcBA B. ovis strains was evaluated by 2D-DIGE. A representative image of the protein profile for each strain is shown in Figure 1. By DeCyder 2D image analysis software (GE Healthcare). Considering a volume ratio higher than 1.5; 100 spots had differential expression between the strains (Figure S4), whereas 78 spots were visualized in the gel and extracted for mass spectrometry (MS) identification (Figure 1A). Among these, 55 spots were successfully identified by MS/MS, whereas 40 spots (72,7%) had lower expression (Tables 4 and S1) and 15 spots had higher expression (Tables 5 and S2) in ΔabcBA B. ovis. Tables S1 and S2 show MS data for each spot, including peptide sequence, score, percentage of coverage, predicted and experimental values of isoelectric point (pI) and molecular weight (MW).
(A) Enumerated spots were differently expressed (p<0.05) between ΔabcBA and WT strains and selected for mass spectrometry. Spots with lower expression were excised from B. ovis WT gel (left panel), whereas spots with higher expression were excised from B. ovis ΔabcBA gel (right panel). (B) Topographic 3D images of the signal intensity correspond to a lowly expressed (left) and a highly expressed (right) spot.
A total of 22 proteins had lower expression in B. ovis ΔabcBA, which included the following functional groups: outer membrane protein (Omp31); predicted amino acid and sugar ABC transporter binding proteins (ribose, glycerol, xylose, oligopeptide, and glycine binding proteins); protein folding (chaperonin GroES, acid stress chaperone HdeA); stress proteins (DNA starvation protein HdeA, superoxide dismutase Cu/Zn and Fe-Mn); metabolic enzymes (nucleoside diphosphate kinase); and protein and vitamin biosynthesis (Table 4).
Four proteins, which corresponded to nine spots, were not identified in B. ovis protein database from NCBI. However, the peptide sequences were identified as periplasmic proteins of sugar and aminoacid ABC transporters in other classical Brucella spp. species. Therefore, for these spots, the B. melitensis 16M database was used to predict protein function and interaction. Interestingly, by aligning the nucleotide sequence of protein-encoded genes in B. melitensis with B. ovis database (BLASTn), all four genes were identified as pseudogenes in B. ovis. These findings reveal the expression of four distinct ABC systems in B. ovis during in vitro growth, which were previously annotated incorrectly as pseudogenes.
Nine proteins had higher expression levels in ΔabcBA B. ovis, including: ABC transporters (nickel NikA and amino acid binding proteins); sugar metabolism (succinyl-CoA synthetase and malate dehydrogenase); protein metabolism (zinc protease); and transcriptional regulation (dehydrogenase quinone) (Table 5).
Additionally, to detect virulence and metabolic differences between WT and ΔabcBA strains, interaction network predictions were performed among identified proteins with lower and higher expression in ΔabcBA B. ovis (Figures S5 and S6). Downregulated proteins interacted mainly with two protein groups related to metabolic stress response and ABC transporters (Figures S5), whereas upregulated proteins interacted with a major protein group related to carbohydrate metabolism (Figures S6). Taken together, these results show that B. ovis specific ABC peptide transporter plays an important role in metabolism and expression of virulence proteins of B. ovis.
B. ovis ΔabcBA is not able to survive intracellularly in HeLa cells
A previous study showed that B. ovis ΔabcBA did not survive intracellularly in murine macrophages and was attenuated early during infection in a mouse model [19]. However, we were interested in determining whether the inability of the ΔabcBA mutant to survive intracellularly reflected increased susceptibility to macrophage-specific bactericidal effects [36], [41], or whether it had a general defect in intracellular survival. Since epithelial cell lines can allow the characterization of infection and trafficking of extremely attenuated Brucella spp. strains [36], [41], HeLa cells were infected with B. ovis WT or ΔabcBA strain at MOI 1∶1000 and infection was evaluated at 0, 8, 24, and 48 hours post infection (hpi).
B. ovis WT and ΔabcBA strains demonstrated similar internalization at zero time point and kinetics of infection up to 8 µhpi in HeLa cells. At 24 µhpi, intracellular CFU numbers of the ΔabcBA mutant strain decreased significantly compared to the WT strain (p<0.001). B. ovis ΔabcBA infection was controlled until 48 µhpi, whereas WT B. ovis was able to survive and replicate in HeLa cells (Figure 2). Overall, the predicted ABC importer is required for B. ovis intracellular survival in human epithelial cell line and, consequently, for establishing persistent in vitro infection. Conversely, the results suggest that this transporter is not necessary for B. ovis internalization or early infection, although it may have a crucial role for the bacteria to reach the replicative niche at later time points.
HeLa cells infected with MOI 1:1000 of WT or ΔabcBA of B. ovis and intracellular infection measured at 0, 8, 24, and 48 hours post infection (hpi). Data represent geometric mean and standard error of three independent experiments (***p<0.001).
Moreover, the kinetics of infection of B. ovis WT and ΔabcBA isogenic strains constitutively expressing mCherry (named TMS8 and TMS9) were evaluated in HeLa cells, to confirm that the fluorescent protein expression did not interfere with their phenotype. Both WT-mCherry and ΔabcBA-mCherry strains exhibited identical infection as shown in Figure 2, which allowed us to study B. ovis intracellular trafficking by confocal microscopy.
ABC transporter enables Brucella ovis to evade the phagolysosome fusion
To understand the role of abcEDCBA in intracellular survival of B. ovis, WT B. ovis intracellular trafficking was characterized in HeLa cells by confocal microscopy and compared to the ΔabcBA strain at 8, 24, and 48 µhpi. As illustrated in Figure 3, WT-mCherry and ΔabcBA-mCherry strains had similar patterns of colocalization with LAMP-1 in HeLa cells at 8 and 24 µhpi, when most of Brucella-containing vacuole (BCV) colocalized with LAMP-1+ compartment, as shown in green. At 48 µhpi, higher numbers of mCherry-B. ovis were seen in HeLa cells infected with WT, of which approximately 80% were able to exclude LAMP-1 from their BCV (Figure 3A-C). Conversely, significantly lower numbers of ΔabcBA-mCherry were seen in HeLa cells at 48 µhpi and more than 90% of the bacteria colocalized with LAMP-1 (Figure 3B-C). These results reveal that WT B. ovis is able to avoid phagosome/lysosome fusion and to replicate, whereas the ΔabcBA mutant remained within lysosomes, explaining its inability to survive in a human epithelial cell line. Therefore, the ABC transporter is necessary for B. ovis intracellular survival and replication at later stages of infection, potentially by promoting exclusion of lysosomal markers.
(A) Intracellular trafficking of WT B. ovis (upper panel) and ΔabcBA mutant (lower panel) expressing mCherry (red) during HeLa cell infection. LAMP-1+ compartment is labeled in green. (B) Average percent of colocalized Brucella containing vacuole (BCV) and LAMP-1+ during WT B. ovis (black column) and ΔabcBA (red column) infection. (C) Average number of bacteria per cell during the course of infection. Data represent mean and standard deviation of at least 100 cells from three independent experiments (**p<0.01; ***p<0.001).
Lack of the Brucella ovis abcBACDE-encoded transporter reduces the levels of VirB proteins
The T4SS is one of the main virulence mechanisms for Brucella spp., and it is required for intracellular survival and replication by promoting exclusion of lysosomal proteins from the BCV [17], [41]. Taking into account that ΔabcBA mutant lost the ability to exclude LAMP1, we analyzed expression of T4SS components by B. ovis WT and ΔabcBA during in vitro growth in rich and nutrient-limited media, using Western blotting (Figure 4).
Western blot analysis of WT and ΔabcBA B. ovis strains for VirB8, VirB9, and VirB11 expression in different growth conditions. (A) Bacterial strains grown in liquid rich media (middle column) or transferred to minimal media (MM) at pH 5.0 (right column). (B) Samples taken from TSA plate with 5% sheep blood at 3-day growth (right column). Left columns show equal protein concentration of lysate. (C) WT and ΔabcBA strains grown for additional 4 h on MM pH 5.0 supplemented with 5 mM of urocanic acid or glutamic acid (upper panel). Lower panel shows equal protein concentration of lysate. Figures are representative of three independent experiments.
Both strains were grown on rich liquid media (TSB with 10% FBS) and, then, transferred to modified minimal E media (MM) at pH 5.0, which promotes in vitro expression of the T4SS in Brucella spp. [37], [42]. Interestingly, unlike what was described for other Brucella spp., WT B. ovis expressed VirB8 (26 kDa) and VirB11 (40 kDa) in both neutral and acidic media. Conversely, the ΔabcBA mutant had weak expression of VirB proteins, including in the minimal acid media, when compared to WT B. ovis (Figure 4A). Expression of VirB8 and VirB9 (32 kDa) were also evaluated after standard 3-day growth on TSA plate with 5% sheep blood; however, only WT B. ovis was able to express VirB proteins in this condition (Figure 4B). Since virB expression in Brucella spp. has been shown to be induced poor nutritional environment with low pH [38], [39], [43], [44], we evaluated virB expression by B. ovis and B. abortus cultured in vitro in rich neutral medium. Indeed, B. ovis expressed both VirB8 and VirB11 under these conditions, whereas B. abortus did not express these two proteins encoded by the virB operon (Figures S7).
Previous studies have shown that adding urocanic acid into minimal acid media induces in vitro transcription of T4SS in Brucella sp., by increasing the expression of two virB-regulatory proteins, HutC and VjbR [39], [43]. To determine whether expression of virB genes was affected upstream of HutC and VjbR, VirB8 expression was analyzed after transferring WT and ΔabcBA B. ovis into MM media pH 5.0 supplemented with 5 mM of urocanic acid or 5 mM of glutamic acid (control). As illustrated in Figure 4C, even in the presence of urocanic acid, ΔabcBA B. ovis was not able to express VirB8, whereas WT B. ovis maintained the expression of T4SS proteins. For consistent Western blot analyses, protein concentrations were confirmed by staining SDS-PAGE gel of the sample lysate with Comassie brilliant blue (Figure 4A-C).
These findings showed that the expression of T4SS-encoded proteins is independent of low pH in B. ovis, but is dependent on the putative ABC transporter. In close agreement with the bacteriology and confocal microscopy results, these data suggested that ΔabcBA B. ovis did not survive intracellularly due to a lack of T4SS expression.
The AbcEDCBA transporter regulates the Brucella ovis T4SS at a post transcriptional level
To determine if weak expression of T4SS-encoded proteins in B. ovis ΔabcBA was due to an effect on virB transcription, mRNA levels of virB1, virB8 and two T4SS regulators (hutC and vjbR) were measured in B. ovis. Both WT and mutant strains were grown overnight in rich media (TSB with 10% FBS), under the same conditions as used for Western blot analysis, and Ct values of WT were compared to those obtained for the ΔabcBA mutant. Interestingly, real time RT-PCR showed that WT and ΔabcBA B. ovis strains had similar abundance of transcripts for virB genes as well as hutC and vjbR (Figure 5). This result suggests that the predicted ABC transporter does not have an impact on T4SS expression at the level of transcription or mRNA stability, but may rather act at a post-transcriptional level.
Real time RT-PCR of transcriptional levels of virB1, virB8, and regulators vjbR and hutC in WT B. ovis compared to ΔabcBA strain. A conserved gene (abcC) and a deleted gene in ΔabcBA (abcA) were used as controls. Data represent geometric mean of B. ovis WT fold change compared to ΔabcBA in three independent experiments. ***p = 3.5×10−5.
As controls, mRNA levels of a deleted gene (abcA) and a conserved gene upstream of the deleted region (abcC) were also measured. As shown in Figure 5, no significant difference on abcC transcription was observed between the strains, inducating that deletion of ΔabcBA did not affect the transcription of the abcEDCBA operon. As expected, WT B. ovis showed significantly higher Ct values of abcA when compared to ΔabcBA, which confirms the effective deletion of the transporter gene in the mutant strain.
Discussion
Considering previous data [18], [23] and the genomic analysis, B. ovis ABC transporter AbcEDCBA encoded by BOPI-1 was predicted to be a peptide importer of the Opp/Tpp/Nik family. Initially, nickel uptake was evaluated during in vitro growth of both WT and ΔabcBA B. ovis strains. As shown in Figures S1, although B. ovis ΔabcBA showed limited growth in different nickel conditions, it was similar to WT B. ovis growth, suggesting that nickel was taken up equally by both strains. In Brucella spp., three main nickel importers are demonstrated: an ABC transporter nikA-E and two Energy Coupling Factor (ECF-type) transporters, nikK-O and ure2 [45], [46]. Previous genomic study revealed that two genes from ure2 (BOV_1316 and BOV_1319) and nikD (BOV_A0751) are pseudogenes in B. ovis [18], which may compromise the function of two nickel importers. However, ECF nikK-O is conserved and potentially may compensate nickel uptake in ΔabcBA B. ovis mutant. Therefore, we could not exclude the role of ABC transporter as nickel importer.
Additionally, ABC transporter function as peptide importer was analyzed in Salmonella Typhimurium by expressing B. ovis abcA-E locus and evaluating its sensitivity to known toxic peptides [29], [32], [47]. The complemented strain STm-comp was not able to take up the peptides tri-lysine and alafosfalin, which are expected to be imported by Tpp and Opp transporters, respectively (Figures S2). These findings imply that B. ovis ABC transporter probably did not work as tripeptide or as oligopeptide importer in the Salmonella assay, or that its specificity may be different from that of the corresponding Salmonella transporters. Moreover, WT and ΔabcBA B. ovis strains were not susceptible to the highest dose of toxic peptides in nutrient-limited media. B. ovis resistance against tri-lysine might result from a protective effect of outer membrane proteins, as rough strains are highly resistant to antimicrobial cationic peptides [48]. With these findings, it was not possible to conclude which specific substrate AbcEDCBA transports, so additional metabolic and proteomic comparative assays will be necessary to identify its function.
An additional effort in this study to understand the role of the B. ovis-specific ABC transporter was based on the comparison of the proteomic profiles between the WT and ΔabcBA. Interestingly, proteomic data resulted in the identification of five ABC transporter binding proteins which were considered pseudogenes according to the currently available B. ovis genomic data. This finding clearly indicates that computational annotation of B. ovis genome needs revision, given that predicted pseudogenes are expressed and potentially functional. Another proteomic study also demonstrated annotation errors in B. abortus database, after identifying four proteins encoded by pseudogenes [49].
Surprisingly, the ΔabcBA B. ovis strain had lower expression of 10 distinct ABC system binding proteins, including glycine betaine/L-proline (ProX), oligopeptides, D-ribose (RbsB), D-xylose (XylF), and glicerol (UgpB) importers (Table 4). This suggests that the ATPase deletion of a predicted peptide importer compromises other ABC systems and, consequently, restricts nutritional uptake in the ΔabcBA strain. Additionally, the ΔabcBA B. ovis strain had decreased expression of membrane protein Omp31 (BOV_1156), and Cu-Zn Sod (SodC, BOV_A0659) and Fe-Mn Sod (SodB, BOV_0567) antioxidants, which are well characterized virulence factors in Brucella spp. [50], [51], [52], [53]. Previous studies have shown that Omp31 is not required for B. ovis intracellular survival [54], [55], but it is immunogenic in rough Brucella spp. species [50]. Other proteomic studies demonstrated reduced Omp31 expression in a B. melitensis virB mutant strain [56], [57].
Both SodC and SodB are conserved in the Brucella genus and essential for intracellular survival by evading the respiratory burst within phagocytes [51]. In B. abortus, a mutant lacking SodC is attenuated in macrophages and in mouse model [52]. Therefore, decreased Sod expression in the ΔabcBA B. ovis strain may be, at least partially, responsible for the attenuation of this strain [19], [58].
B. ovis AbcEDCBA was previously shown to play a role in pathogenesis of B. ovis, as ΔabcBA B. ovis strain was attenuated in a mouse model as early as one day post infection and in mouse peritoneal macrophages at 12 µhpi [19]. A recent study also characterized the kinetics of ΔabcBA infection in sexually mature rams. The mutant lacking ABC transporter was not excreted in semen and urine of infected rams, although it induced a similar lymphocytic proliferative response when compared to WT B. ovis [58]. Considering that ΔabcBA was attenuated in both murine model and in the natural host, bacterial infection and trafficking were characterized in HeLa cells, to understand how ABC transporter contributes to B. ovis intracellular survival and replication. Epithelial cell lines differ from phagocytic cells due to lack of bactericidal activity against Brucella sp. [36], [41], which allows for the study of infection and trafficking of severely attenuated mutants, including ΔabcBA B. ovis.
Even though B. ovis is a naturally rough and non zoonotic species [2], it was able to establish infection and successfully replicate in HeLa cells. Interestingly, the ΔabcBA mutant strain showed lower colonization in HeLa cells at 24 µhpi and the infection was controlled until 48 hours, although both strains demonstrated similar internalization (Figure 2). The kinetics of ΔabcBA infection was similar to that previously described in RAW macrophage cell line [19], which supports the notion that predicted ABC importer is crucial for B. ovis intracellular survival, even in the absence of macrophage bactericidal mechanisms.
Trafficking of classical pathogenic species of Brucella spp. is well described in both phagocytic and nonphagocytic cells [17], [36], [38], [41], [59]–[61]. However, few studies have characterized the replication and intracellular trafficking of naturally rough Brucella spp. [62], [63]. This is the first work illustrating B. ovis trafficking in HeLa cells by confocal microscopy, which demonstrate bacterial escape from LAMP-1+ compartment and intracellular replication at later time points. As shown in Figure 3, B. ovis intracellular trafficking was very similar to classical smooth Brucella spp. [17], [41], with early interaction of BCV with lysosome (LAMP1+), followed by exclusion of LAMP1 and bacterial replication. Notably, B. ovis showed a later evasion of lysosome fusion only seen at 48 µhpi (Figure 4B), and not as early as 24 hours, as described for B. abortus [41].
Compared to WT B. ovis, the ΔabcBA mutant strain remained within a LAMP-1+ compartment at all time points and, consequently, was not able to survive in HeLa cells (Figure 4). The trafficking defect observed for ΔabcBA B. ovis was identical to that previously described for Brucella spp. mutants with a non-functional T4SS, as they lose the capacity of excluding LAMP-1 after the initial fusion with the phagolysosomal compartment [7], [17], [41]. Exclusively in B. ovis, T4SS seems to have a critical role not only for persistent infection, but also for establishing early infection in mice and in peritoneal macrophages [16]. In smooth B. abortus, however, lack of T4SS does not interfere with early infection in the mouse, showing phenotype similar as the WT strain until five days post infection [9], [10], [13], [16]. In agreement with our findings, previous studies demonstrated that B. ovis ΔabcBA and ΔvirB2 mutants have identical phenotypes in both mouse model and macrophages [16], [19]. Interestingly, this study shows that the B. ovis ΔabcBA mutant was unable to express VirB proteins in either rich media or acid minimal media that mimics the early BCV environment (Figure 4). Therefore, it is likely that inactivation of AbcEDCBA results in decreased expression of T4SS and, consequently, impairment of B. ovis trafficking and replication within cells.
Early lysosome interaction during Brucella sp. intracellular trafficking is necessary for acidification and maturation of BCV, which is essential for bacterial survival, by inducing T4SS expression [17], [38], [64]. The expression of virB-encoded proteins in classical Brucella sp. is induced by low pH and poor nutritional conditions, which are observed during the initial phase of intracellular trafficking (approximately 5 hours) [38], [42], [44], [65]. Conversely, WT B. ovis differed from all other Brucella species, due to in vitro expression of VirB proteins in both acid and rich neutral media (Figure 4). This showed an exclusive mechanism for T4SS regulation in B. ovis, which was independent of an acidic environment.
Previous studies identified protein regulators of T4SS in Brucella spp., including histidine pathway HutC and a quorum sensing VjbR. Both regulators have an important role by directly binding the virB promoter and actively inducing virB transcription in a nutrient-poor environment, with low pH, and in presence of urocanic acid [38], [39], [43], [44]. Considering that B. ovis also expressed T4SS in rich neutral media and that lack of VirB expression in ΔabcBA B. ovis was observed at any in vitro condition (Figure 4), we analyzed whether the transcription of the these two regulators or of the virB genes was affected in the ΔabcBA mutant. However, the reduced abundance of VirB proteins was not explained by defects in transcription or mRNA stability, since ΔabcBA and WT B. ovis showed similar mRNA levels of hutC, vjbR, virB1, and virB8 genes (Figure 5). Post transcriptional regulation of T4SS proteins have been previously described in B. abortus [36]. In this species, the expression of VjbR and VirB7 were induced in vitro by low pH and solely in the presence of urocanic acid, although similar promoter activities of virB and vjbR were noticed in different growth conditions [39]. Taken together, our data supports the notion that T4SS expression in B. ovis is regulated by AbcEDCBA at a post transcriptional level. One possible mechanism by which this might occur is uptake of a substrate that acts directly to affect translation of virB mRNA, however alternatively, uptake of the ABC transporter substrate could have an indirect effect on VirB protein levels via indirect effects on other metabolic or regulatory pathways. Further experiments will be necessary to distinguish between these possibilities and to identify the substrate of the ABC transporter.
In conclusion, the result of this work revealed that the predicted peptide ABC importer AbcEDCBA was required for B. ovis in vitro expression of other ABC systems and virulence proteins (including Omp31 and Sod), as well as its intracellular survival and evasion from phagosome/lysosome fusion, by interfering with the expression of T4SS-encoded proteins through a post transcriptional mechanism.
Supporting Information
Figure S1.
In vitro growth of Brucella ovis wild-type and ΔabcBA strains. (A) Trypticase soy broth (TSB) supplemented with fetal bovine serum (FBS) at 0, 2, 5, or 10% of and bacterial growth measured after 24 hours. (B) B. ovis WT and ΔabcBA growth after 48 h in standard media (TSB with 10% FBS) after adding NiSO4 (0.5, 1 or 2 mM) or chelating nickel and other divalent cations with EDTA (10, 25 or 50 mM). Data represent average and standard error of three independent experiments.
https://doi.org/10.1371/journal.pone.0114532.s001
(TIF)
Figure S2.
In vitro growth and metabolic activity of Salmonella Typhimurium mutant lacking peptide transporters. S. Typhimurium LT2 wild type (STm WT) and TT17573 mutant with non-functional peptide transporters (oppBC tppB dpp) growth in minimal media and tetrazolium (TTC) reduction. Data represent mean and standard deviation of triplicates in one experiment.
https://doi.org/10.1371/journal.pone.0114532.s002
(TIF)
Figure S3.
Peptide uptake in Salmonella Typhimurium expressing Brucella ovis ABC transporter. (A) Lethality assay of S. Typhimurium LT2 (STm WT), STm TT17573 mutant with afunctional peptide transporters (oppBC tppB dpp), and STm TT17573 complemented with B. ovis locus abcEDCBA (TMS14). Samples grown on minimal media plate containing 0.2 and 0.4 mg of trilysine (left column) or 0.5 and 1 mg of alafosfalin (right column). (B) Diameter (mm) of inhibitory growth zone of STm WT around filter disks containing trilysine or alafosfalin. (C) Expression of B. ovis ABC transporter in TMS14 during in vitro growth confirmed by anti-histidine (α-his) Western blot. Figure is representative of three independent experiments.
https://doi.org/10.1371/journal.pone.0114532.s003
(TIF)
Figure S4.
Heat map and principal component analysis of differently expressed protein spots in DIGE profile. (A) Heat map of 100 spots (lines) differently expressed between ΔabcBA (left column) and WT (right column) B. ovis strains. Expression values are shown on a log scale ranging from −1.5 (down-regulated, green) to +1.5 (up-regulated, red). (B) Principal component analysis shows distribution of highly expressed (right area) and lowly expressed (left area) spots in the score plot. Spots within circle correspond to 95% of confidence interval.
https://doi.org/10.1371/journal.pone.0114532.s004
(TIF)
Figure S5.
Interaction network of proteins with lower expression in ΔabcBA Brucella ovis. The red boxes indicate lowly expressed proteins excised from gels and identified by mass spectrometry. Numbers represent the corresponding spot identification. Asterisk indicates identified protein annotated as pseudogene in the B. ovis genome.
https://doi.org/10.1371/journal.pone.0114532.s005
(TIF)
Figure S6.
Interaction network of proteins with higher expression in ΔabcBA Brucella ovis. The red boxes indicate highly expressed proteins excised from gels and identified by mass spectrometry. Numbers represent the corresponding spot identification.
https://doi.org/10.1371/journal.pone.0114532.s006
(TIF)
Figure S7.
Expression of VirB8 and VirB11 by Brucella ovis and Brucella abortus grown under rich and neutral media. B. ovis and B. abortus were cultured in blood agar plates (B) or TSA with 10% hemoglobin (H), and expression of VirB8 and VirB11 was evaluated by Western blot.
https://doi.org/10.1371/journal.pone.0114532.s007
(TIF)
Table S1.
Proteins with lower expression in Brucella ovis ΔabcBA identified by mass spectrometry.
https://doi.org/10.1371/journal.pone.0114532.s008
(DOC)
Table S2.
Proteins with greater expression in Brucella ovis ΔabcBA identified by mass spectrometry.
https://doi.org/10.1371/journal.pone.0114532.s009
(DOC)
Acknowledgments
We thank Maarten de Jong and Sebastian Winter for experimental advice, Xavier DeBolle for kindly providing the mCherry plasmid, Christian Baron for anti-VirB8 antibody, and John Roth for providing the STm and mutant strains.
Author Contributions
Conceived and designed the experiments: TMAS TAP RLS RMT HMA. Performed the experiments: TMAS VA MNX JPSM MGW SFP. Analyzed the data: TMAS TAP RLS RMT JPSM HMA. Wrote the paper: TMAS RLS RMT.
References
- 1. Burgess GW (1982) Ovine contagious epididymitis: a review. Vet Microbiol 7:551–575.
- 2.
Blasco JM (1990) Brucella ovis. In: Nielsen K, Duncan JReds. Animal Brucellosis. Boca Raton: CRC Press. pp 351–378.
- 3. Ficapal A, Jordana J, Blasco J, Moriyon I (1998) Diagnosis and epidemiology of Brucella ovis infection in rams. Small Rumin Res 29:13–19.
- 4. Carpenter TE, Berry SL, Glenn JS (1987) Economics of Brucella ovis control in sheep: epidemiologic simulation model. J Am Vet Med Assoc 190:977–982.
- 5. Godfroid J, Cloeckaert A, Liautard JP, Kohler S, Fretin D, et al. (2005) From the discovery of the Malta fever's agent to the discovery of a marine mammal reservoir, brucellosis has continuously been a re-emerging zoonosis. Vet Res 36:313–326.
- 6.
Thoen CO, Enright F, Cheville NF (1993) Brucella. In: Gyles CL, Thoen COeds. Pathogenesis of bacterial infections in animals. Ames: Iowa State University Press. pp. 236–247.
- 7. Gorvel JP, Moreno E (2002) Brucella intracellular life: from invasion to intracellular replication. Vet Microbiol 90:281–297.
- 8. O'Callaghan D, Cazevieille C, Allardet-Servent A, Boschiroli ML, Bourg G, et al. (1999) A homologue of the Agrobacterium tumefaciens VirB and Bordetella pertussis Ptl type IV secretion systems is essential for intracellular survival of Brucella suis. Mol Microbiol 33:1210–1220.
- 9. Hong PC, Tsolis RM, Ficht TA (2000) Identification of genes required for chronic persistence of Brucella abortus in mice. Infect Immun 68:4102–4107.
- 10. Sieira R, Comerci DJ, Sanchez DO, Ugalde RA (2000) A homologue of an operon required for DNA transfer in Agrobacterium is required in Brucella abortus for virulence and intracellular multiplication. J Bacteriol 182:849–855.
- 11. Rosinha GMS, Freitas DA, Miyoshi A, Azevedo V, Campos E, et al. (2002) Identification and characterization of a Brucella abortus ATP-binding cassette transporter homolog to Rhizobium meliloti ExsA and its role in virulence and protection in mice. Infect Immun 70:5036–5044.
- 12. den Hartigh AB, Sun YH, Sondervan D, Marjolein N, Reinders O, et al. (2004) Differential requirements for VirB1 and VirB2 during Brucella abortus infection. Infect Immun 72:143–149.
- 13. Rolan HG, Tsolis RM (2007) Mice lacking components of adaptive immunity show increased Brucella abortus virB mutant colonization. Infect Immun 75:2965–2973.
- 14. Paixão TA, Roux CM, den Hartigh AB, Sankaran-Walters S, Dandekar S, et al. (2009) Establishment of systemic Brucella melitensis infection through the digestive tract requires urease, the type IV secretion system, and lipopolysaccharide O antigen. Infect Immun 77:4197–4208.
- 15. Zhong Z, Wang Y, Qiao F, Wang Z, Du X, et al. (2009) Cytotoxicity of Brucella smooth strains for macrophages is mediated by increased secretion of the type IV secretion system. Microbiol 155:3392–3402.
- 16. Sá JC, Silva TMA, Costa EA, Silva APC, Tsolis RM, et al. (2012) The virB encode type IV secretion system is critical for establishment of infection and persistence of Brucella ovis infection in mice. PloS ONE 159:130–140.
- 17. Celli J, de Chastellier C, Franchini D-M, Pizarro-Cerda J, Moreno E, et al. (2003) Brucella evades macrophage killing via VirB-dependent sustained interactions with the endoplasmic reticulum. J Exp Med 198:545–556.
- 18. Tsolis RM, Seshadri R, Santos RL, Sangari FJ, Lobo JMG, et al. (2009) Genome degradation in Brucella ovis corresponds with narrowing of its host range and tissue tropism. PloS ONE 4:e5519.
- 19. Silva TMA, Paixão TA, Costa EA, Xavier MN, Sá JC, et al. (2011) Putative ATP-binding cassette transporter is essential for Brucella ovis pathogenesis in mice. Infect Immun 79:1706–1717.
- 20. Tam R, Saier MH (1993) Structural, functional, and evolutionary relationships among extracellular solute-binding receptors of bacteria. Microbiol Rev 57:320–346.
- 21. Ko J, Splitter GA (2000) Brucella abortus tandem repeated ATP-binding proteins, BapA and BapB, homologs of Haemophilus influenzae LktB, are not necessary for intracellular survival. Microb Pathog 29:245–253.
- 22. Danese I, Haine V, Delrue R, Lestrate P, Stevaux O, et al. (2004) The Ton system, an ABC transporter, and a universally conserved GTPase are involved in iron utilization by Brucella melitensis 16M. Infect Immun 72:5783–5790.
- 23. Jenner DC, Dassa E, Whatmore AM, Atkins HS (2009) ATP-Binding cassette systems of Brucella. Comp Funct Genomics 2009:354649.
- 24. Copin R, Vitry M-A, Hanot Mambres D, Machelart A, De Trez C, et al. (2012) In situ microscopy analysis reveals local innate immune response developed around Brucella infected cells in resistant and susceptible mice. PLoS Pathogens 8:e1002575.
- 25.
Alton GG, Jones LM, Angus RD, Verger JM (1988) Techniques for the brucellosis laboratory. Paris: Institut National de la Recherche Agronomique. 190p.
- 26. Plommet M (1991) Minimal requirements for growth of Brucella suis and other Brucella species. Zentralbl Bakteriol 275:436–450.
- 27. Garza E, Finan C, Inverson A, Zhou S (2011) Extension temperature of 60oC required for PCR amplification of large DNA fragments (>5kb) from a low GC bacterium Clostridium acetobutylicum. Wolrd J Microbiol Biotechnol 27:449–451.
- 28. Gonzalez P, Zigler Jr JS, Epstein DL, Borrás T (1999) Increasing DNA transfer efficiency by temporary inactivation of host restriction. Biotechniques 26:892–900.
- 29. Gibson MM, Price M, Higgins CF (1984) Genetic characterization and molecular cloning of the tripeptide permease (tpp) genes of Salmonella typhimurium.. J Bacteriol 160:122–130.
- 30. Hiles ID, Gallagher MP, Jamieson DJ, Higgins CF (1987) Molecular characterization of the oligopeptide permease of Salmonella typhimurium. J Mol Biol 195:125–142.
- 31. Abouhamad WN, Manson M, Gibson MM, Higgins CF (1991) Peptide transport and chemotaxis in Escherichia coli and Salmonella typhimurium: characterization of the dipeptide permease (Dpp) and the dipeptide-binding protein. Mol Microbiol 5:1035–2047.
- 32. Andrews JC, Short SA (1985) Genetic analysis of Escherichia coli oligopeptide transport mutants. J Bacteriol 161:484–492.
- 33. Neuhoff V, Arold N, Taube D, Ehrhardt W (1988) Improved staining of proteins in polyacrylamide gels including isoelectric focusing gels with clear background at nanogram sensitivity using Coomassie Brilliant Blue G-250 and R-250. Electrophoresis 9:255–262.
- 34. Vieira HGS, Grynberg P, Bitar M, Pires SF, Hilario HO, et al. (2014) Proteomic analysis of Trypanosoma cruzi response to ionizing radiation stress. PloS One 9:e97526.
- 35. Franceschini A, Szklarczyk D, Frankild S, Kuhn M, Simonovic M, et al. (2013) STRING v9.1: protein-protein interaction networks, with increased coverage and integration. Nucleic Acids Res 41:808–815.
- 36. Pizarro-Cerdá J, Méresse S, Parton RG, van der Goot G, Sola-Landa A, et al. (1998) Brucella abortus transits through the autophagic pathway and replicates in the endoplasmic reticulum of nonprofessional phagocytes. Infect Immun 66:5711–5724.
- 37. Kulakov YK, Guigue-Talet PG, Ramuz MR, O’Callaghan D (1997) Response of Brucella suis 1330 and B. canis RM6/66 to growth at acid pH and induction of an adaptive acid tolerance response. Res Microbiol 148:145–151.
- 38. de Jong MF, Sun Y-H, den Hartigh AB, van Dijl JM, Tsolis RM (2008) Identification of VceA and VceC, two members of the VjbR regulon that are translocated into macrophages by the Brucella type IV secretion system. Mol Microbiol 70:1378–1396.
- 39. Arocena GM, Zorreguieta A, Sieira R (2012) Expression of VjbR under nutrient limitation conditions is regulated at the post-transcriptional level by specific acidic pH values and urocanic acid. PLoS ONE 7:e35394.
- 40.
Moreno E, Moriyón I (2006) The genus Brucella. In: Dworkin M, Falkow S, Rosenberg E, Schleifer K-H, Stackebrandt Eeds. Prokaryotes. New York: Springer New York. pp. 315–456.
- 41. Starr T, Ng TW, Wehrly TD, Knodler LA, Celli J (2008) Brucella intracellular replication requires trafficking through the late endosomal/lysosomal compartment. Traffic 9:678–694.
- 42. Rouot B, Alvarez-Martinez M-T, Marius C, Menanteau P, Guilloteau L, et al. (2003) Production of the Type IV Secretion System differs among Brucella species as revealed with VirB5- and VirB8-specific antisera. Infect Immun 71:1075–1082.
- 43. Sieira R, Arocena GM, Bukata L, Comerci DJ, Ugalde RA (2010) Metabolic control of virulence genes in Brucella abortus: HutC coordinates virB expression and the histidine utilization pathway by direct binding to both promoters. J Bacteriol 192:217–224.
- 44. Sieira R (2013) Regulation of virulence in Brucella: an eclectic repertoire of transcription factors defines the complex architecture of the virB promoter. Future Microbiol 8:1193–1208.
- 45. Jubier-Maurin V, Rodrigue A, Ouahrani-Bettache S, Layssac M, Köhler S, et al. (2001) Identification of the nik gene cluster of Brucella suis: regulation and contribution to urease activity. J Bacteriol 183:426–434.
- 46. Sangari FJ, Cayón AM, Seoane A, García-lobo JM (2010) Brucella abortus ure2 contains an acid-activated urea transporter and a nickel transport system. BMC Microbiol 10:1–12.
- 47. Naider F, Becker JM (1975) Multiplicity of oligopeptide transport systems in Escherichia coli. J Bacteriol 122:1208–1215.
- 48. Martín-Martín AI, Sancho P, Tejedor C, Fernandez-Lago L, Vizcaíno N (2011) Differences in the outer membrane- related properties of the six classical Brucella species. Vet. J. 189:103–105.
- 49. Lamontagne J, Béland M, Forest A, Côté-Martin A, Nassif N, et al. (2010) Proteomics-based confirmation of protein expression and correction of annotation errors in the Brucella abortus genome. BMC Genomics 11:1–10.
- 50. Cloeckaert A, Vizcaino N, Paquet JY, Bowden RA, Elzer PH (2002) Major outer membrane proteins of Brucella spp.: past, present and future. Vet Microbiol 90:229–247.
- 51. Ko J, Splitter GA (2003) Molecular host-pathogen interaction in brucellosis: current understanding and future approaches to vaccine development for mice and humans. Clin Microbiol Rev 16:65–78.
- 52. Gee JM, Valderas MW, Kovach ME (2005) The Brucella abortus Cu,Zn superoxide dismutase is required for optimal resistance to oxidative killing by murine macrophages and wild-type virulence in experimentally infected mice. Infect Immun 73:2873–2880.
- 53. Rossetti CA, Galindo CL, Lawhon SD, Garner HR, Adams LG (2009) Brucella melitensis global gene expression study provides novel information on growth phase-specific gene regulation with potential insights for understanding Brucella: host initial interactions. BMC Microbiol 9:81.
- 54. Caro-Hernández P, Fernández-Lago L, de Miguel M-J, Martín-Martín AI, Cloeckaert A, et al. (2007) Role of the Omp25/Omp31 family in outer membrane properties and virulence of Brucella ovis. Infect Immun 75:4050–4061.
- 55. Martín-Martín AI, Caro-Hernández P, Orduña A, Vizcaíno N, Fernández-Lago L (2008) Importance of the Omp25/Omp31 family in the internalization and intracellular replication of virulent B. ovis in murine macrophages and HeLa cells. Microbes Infect 10:706–710.
- 56. Wang Y, Chen Z, Qiao F, Zhong Z, Xu J, et al. (2010) The type IV secretion system affects the expression of Omp25/Omp31 and the outer membrane properties of Brucella melitensis. FEMS Microbiol Lett 303:92–100.
- 57. Wang Y, Chen Z, Qiao F, Ying T, Yuan J, et al. (2009) Comparative proteomics analyses reveal the virB of B. melitensis affects expression of intracellular survival related proteins. PLoS One 4:e5368.
- 58. Silva APC, Macêdo AA, Costa LF, Turchetti AP, Bull V, et al. (2013) Brucella ovis lacking a species-specific putative ATP-binding cassette transporter is attenuated but immunogenic in rams. Vet Microbiol 167:546–553.
- 59. Pizarro-Cerdá J, Moreno E, Gorvel JP (2000) Invasion and intracellular trafficking of Brucella abortus in nonphagocytic cells. Microbes Infect 2:829–835.
- 60. Celli J (2006) Surviving inside a macrophage: the many ways of Brucella. Res Microbiol 157:93–98.
- 61. Starr T, Child R, Wehrly TD, Hansen B, Hwang S, et al. (2012) Selective subversion of autophagy complexes facilitates completion of the Brucella intracellular cycle. Cell Host Microbe 11:33–45.
- 62. Rittig MG, Kaufmann A, Robins A, Shaw B, Sprenger H, et al. (2003) Smooth and rough lipopolysaccharide phenotypes of Brucella induce different intracellular trafficking and cytokine/chemokine release in human monocytes. J Leukoc Biol 74:1045–1055.
- 63. Covert J, Mathison AJ, Eskra L, Banai M, Splitter G (2010) Brucella melitensis, B. neotomae and B. ovis elicit common and distinctive macrophage defense transcriptional responses. Exp Biol Med 234:1450–1467.
- 64. Porte F, Liautard JP, Köhler S (1999) Early acidification of phagosomes containing Brucella suis is essential for intracellular survival in murine macrophages. Infect Immun 67:4041–4047.
- 65. Boschiroli ML, Ouahrani-Bettache S, Foulongne V, Michaux-Charachon S, Bourg G, et al. (2002) The Brucella suis virB operon is induced intracellularly in macrophages. Proc Natl Acad Sci USA 99:1544–1549.