Abstract
Secondary metabolites have an important impact on the biocontrol potential of soil-derived microbes. In addition, various microbe-produced chemicals have been suggested to impact the development and phenotypic differentiation of bacteria, including biofilms. The non-ribosomal synthesized lipopeptide of Bacillus subtilis, surfactin, has been described to impact the plant promoting capacity of the bacterium. Here, we investigated the impact of surfactin production on biofilm formation of B. subtilis using the laboratory model systems; pellicle formation at the air-medium interface and architecturally complex colony development, in addition to plant root-associated biofilms. We found that the production of surfactin by B. subtilis is not essential for pellicle biofilm formation neither in the well-studied strain, NCIB 3610, nor in the newly isolated environmental strains, but lack of surfactin reduces colony expansion. Further, plant root colonization was comparable both in the presence or absence of surfactin synthesis. Our results suggest that surfactin-related biocontrol and plant promotion in B. subtilis strains are independent of biofilm formation.
1. Introduction
Several species from the “Bacillus subtilis complex” are well-characterized plant growth-promoting rhizobacteria (PGPRs), providing various beneficial activities for plants and inhibiting fungal and bacterial pathogens [1]. Many strains of Bacillus subtilis, Bacillus amyloliquefaciens and Bacillus velezensis are currently used in organic and traditional agriculture to prevent infection and/or increase yields of various crops [2–4]. These species are of particular interest because they can form stress-resistant endospores, a cell-type ideal for product formulation. Most PGPR Bacillus spp. also produce a wide range of bioactive molecules, such as lipopeptides, which directly influences plant growth and defence [5].
Many of these molecules are synthesized by multienzyme-complexes called non-ribosomal peptide synthetases (NRPS) [6]. B. subtilis NCIB3610 possesses 3 NRPS clusters and one NRPS/polyketide synthetase (PKS) cluster, which is few compared to the bioactive molecule synthesis capacity of B. velezensis strains [1]. Bacillaene, a broad spectrum antibiotic, is synthesized by proteins encoded in 80 kB pksA-S cluster [7]. The ppsA-E encodes for the peptide synthetase responsible for the synthesis of plipastatin (fengycin family), a strong antifungal molecule [5,8], while the siderophore bacillibactin is synthesized by the product of the dhbA-F operon [9]. Finally, SrfAA-AD produces versatile molecules from the surfactin family [10].
Surfactin molecules are composed of a heptapeptide, i.e. two acidic and five nonpolar amino acids, interlinked with a β-hydroxy fatty acid, and condensed in a cyclic lactone right structure [10,11]. The amino acid sequence, the length, and the branching of the fatty acid moiety can vary in surfactin molecules produced by different Bacillus species, strains and/or growth conditions [12]. For example, on tomato roots B. amyloliquefaciens S499 produces surfactin variants with C12, C13, C14 and C15 acyl chains, the last two composing more than 80% of total surfactins produced in these conditions [13]. Surfactin, as its name suggests, is an extremely powerful biosurfactant, and thus helps bacteria moving on solid surface [6,14–18]. These molecules are abundantly produced when B. subtilis colonizes plant roots, and they elicit the induce systemic resistance in plants [19–22].
A strong link between biofilm formation and surfactin production was suggested for different Bacillus species. Mutations in the surfactin synthesis operon were reported to cause partial to severe biofilm defect B. velezensis FZB42 and B. amyloliquefaciens UMAF6614 [23,24]. Non-surfactin producer strains of UMAF6614 were also impaired in root colonization [25]. Under specific laboratory growth conditions (i.e. exponentially growing cells inoculated into lysogeny broth medium), surfactin was shown to trigger biofilm formation in B. subtilis via a pore-forming activity, which causes intracellular potassium leakage sensed by KinC that in turns activate the genetic pathway responsible for biofilm formation [26]. This “quorum-sensing like” activity was demonstrated in the model strain NCIB3610. Similarly to reports in B. velezensis and B. amyloliquefaciens, a surfactin deletion mutant of B. subtilis 6051 was shown to be defective for biofilm formation and root colonization [19]. However, a different study showed that biofilms formed by B. subtilis tomato rhizoplane isolates had comparable dry weight among wild-type and surfactin mutants [27]. Finally, deletion of sfp, which is known to be involved in the production of surfactin since it encodes for a 4′ phosphopantetheinyl transferase that activates the peptidyl carrier protein domains from the NRPS machinery, impairs biofilm formation in B. subtilis 3610 [28]. Since sfp mutation is defective for the synthesis of all NRP-derived molecules (surfactin, bacillibactin, plipastatin and bacillaene), this impair in biofilm formation could be due to a defect in other biosynthetic pathways than surfactin [14]. These conflicting reports and recent results in our laboratories lead us to revisit the importance of surfactin for biofilm formation of B. subtilis in vitro and on planta.
2. Material and Methods
2.1 Strains, media, and chemicals
Strains used in the study are listed in Table S1. For routine growth, cells were propagated on lysogeny broth (LB; Luria-Bertani or Lenox broth) medium. When necessary, antibiotics were used at the following concentrations: MLS (1 μg mL−1 erythromycin, 25 μg mL−1 lincomycin); spectinomycin (100 μg mL−1); chloramphenicol (5 μg mL−1) and kanamycin (10 μg mL−1). New B. subtilis isolates were obtained from 5 sampling sites in Germany and Denmark (see Table S1 for coordinates) by selecting for spore formers in the soil. Soil samples were mixed with 0.9% saline solution, vortexed on a rotary shaker for 2 min, incubated at 80°C for 25 min and serially diluted on 2×SG medium solidified with 1.5% agar [29]. Highly structured colonies were targeted and isolation of B. subtilis strains was confirmed using 16S sequencing followed by whole genome [30]. New isolates and their srfAC::spec derivatives (srfAC::spec marker was transferred from DS1122 [31]) were labeled with constitutively expressed gfp from Phyperspank using phyGFP plasmids that integrates into the amyE locus [32].
All solvents used for HRMS and chromatography were VWR Chemicals LC-MS grade, while for metabolites extraction the solvents were HPLC grade (VWR Chemicals). Surfactin standard was purchased from Sigma-Aldrich (Cat. No. S3523).
2.2 Culture conditions
For pellicles assays, cells were pre-grown for 2 hours and diluted 1:100 in 3mL LB 3 times, and at the last incubation cells were grown until they reach an OD600 between 0.3 and 0.6. OD600 was then adjusted at 0.3 with LB, and 13.5 μL were used to inoculate 1mL of medium in a 24-well plates. Media used for these experiments were MSgg [28] and MSNc + Pectin (MSN: 5mM Potassium phosphate buffer pH7, 0.1M Mops pH7, 2mM MgCl2, 0.05mM MnCl2, 1μM ZnCl2, 2 μM thiamine, 700 μM CaCl2, 0.2% NH4Cl; 0,5% cellobiose and 0,5% pectin (Sigma)). Incubation was done at 30°C. For pellicle assays of recent B. subtilis soil isolates and its mutant derivatives, three to four colonies were inoculated in 3 ml LB and incubated at 37°C with shaking at 225 rpm for 4 h. The OD600 was adjusted to 1.5 and 1 % inoculum of the pre-grown culture was used to seed bacterial biofilms in MSgg [28] or MOLP [33] media at 30°C. For colony biofilms, one colony was inoculated in 3 mL LB and rolled for 3h at 37°C. The culture was adjusted to an OD600 of 1, then 2μL were spotted on solidified (1.5% agar) MSgg media.
Col-0 A. thaliana ecotype was used throughout the study. In the Canadian laboratory, seeds were surface-sterilized with 70% ethanol followed by 0.3% sodium hypochlorite (v/v) and germinated on Murashige-Skoog medium (Sigma) 0.7% agar with 0.05% glucose in a growth chamber at 25°C. Root colonization assay were performed using MSNg (MSN supplemented with 0.05% glycerol) as described in [34]. In Denmark, Arabidopsis seeds were surface sterilized using 2% (v/v) sodium hypochlorite with mixing on an orbital shaker for 20 min and then washed five times with sterile distilled water. The seeds were placed on pre-dried Murashige and Skoog (MS) basal salts mixture (2.2 g l−1, Sigma) containing 1% agar in an arrangement of approximately 20 seeds per plate at a minimum distance of 1 cm. After 3 days of incubation at 4°C, plates were placed at an angle of 65° in a plant chamber with a light regime of 16 h light (24°C)/8-h dark (21°C). After 6 days, homogenous seedlings ranging 0.8-1.2 cm in length were selected for root colonization assay. Seedlings were transferred into 48-well plates containing 270 μl of MSNg medium [34] per well. The wells were supplemented with 30 μl of exponentially growing bacterial culture diluted to OD600 = 0.2. The sealed plates were incubated at a rotary shaker (90 rpm) at 30°C for 18 h. After the incubation, plants were washed three times with MSNg to remove non-attaching cells and then transferred to a glass slide for imaging using CLSM.
2.3 Beta-galactosidase assays
From pellicle biofilm assays, spent medium was cautiously removed from the wells. The pellicle was then collected in 1mL of Z-buffer (40 mM NaHPO4; 60 mM Na2HPO4; 1 mM MgSO4; 10 mM KCl) and transferred in a 1.5mL tube. The suspensions were sonicated with 1 second pulses (30% power) for 10 seconds total to break the biofilms, and OD600 was measured. Then, 2-mercaptoethanol (final concentration of 38 mM) and freshly prepared lysozyme in Z-buffer (final concentration of 20 µg mL−1) were added. Suspensions were incubated for 30 min at 30°C, diluted and 100µL of an ONPG solution (4 mg mL−1 in Z-buffer with 38mM of 2-mercaptoethanol) were added. 250µL of Na2CO3 1M were added when solutions started turning yellow, and the reaction time was recorded. The A420nm and OD550nm were measured for each solution, and the Miller Units were calculated using: Miller Units = 1000 × [(A420nm − 1.75 × OD550nm)] / (Tmin × Vml × OD600)
2.4 Microscopy
To visualize bacteria on root surfaces in the Canadian laboratory, seedlings were examined with a Zeiss Axio Observer Z1 microscope equipped with a 20X/0.8 Plan-Apochromat objective, and whole root pictures were taken with a Zeiss Axiocam 506 mono. Figure 3A presents representative images of the various mutant and time of colonization. The fluorescence signal was detected using a YFP filter (ex: 500/20, em: 535/30) and a CFP filter for autofluorescence of the root (ex: 436/20, em: 480/40). All images were taken at the same exposure time, processed identically for compared image sets, and prepared for presentation using Zeiss Zen 2.0 software. Each image is representative of at least 12 root colonization assays performed in three independent experiments. Quantification was performed using CellProfiler 3.0 (cellprofiler.org) [35].
In Denmark, the washed plant roots were transferred to microscope slides and gently sealed with cover slips. Plant root colonization was analysed with a confocal laser scanning microscope (TCS SP8 (Leica) equipped with an argon laser and a Plan-Apochromat 63x/1.4 Oil objective). Fluorescent reporter excitation was performed at 488 nm for green fluorescence, while the emitted fluorescence was recorded at 520/23 nm. Single-layer images were acquired and processed with the software ImageJ (National Institutes of Health). Each image is representative of 2 root colonization assays performed in two independent experiments.
2.5 Chemical extraction of secondary metabolites from bacterial cultures
Bacterial strains were cultured on MSgg agar plates for 3 days at 30 °C. An agar plug (6 mm diameter) of each bacterial cultures was transferred to a vial and extracted with 1 mL of isopropanol:ethyl acetate (1:3, v/v) with 1% formic acid. The vials were placed in an ultrasonic bath at full effect for 60 min. Extracts were then transferred to new vials, evaporated to dryness under N2, and re-dissolved in 300 µL of methanol for further sonication over 15 min. After centrifugation at 13400 rpm for 3 min, the supernatants were transferred to new vials and subjected to ultrahigh-performance liquid chromatography-high resolution mass spectrometry (UHPLC-HRMS) analysis.
2.6 UHPLC-HRMS analysis
UHPLC-HRMS was performed on an Agilent Infinity 1290 UHPLC system equipped with a diode array detector. UV–visible spectra were recorded from 190 to 640 nm. Liquid chromatography of 1 µL extract was performed using an Agilent Poroshell 120 phenyl-hexyl column (2.1 × 150 mm, 2.7 μm) at 60 °C with acetonitrile and H2O, both buffered with 20 mM formic acid, as mobile phases. Initially, a linear gradient of 10% acetonitrile in H2O to 100% acetonitrile over 15 min was employed, followed by isocratic elution of 100% acetonitrile for 2 min. The gradient was returned to 10% acetonitrile in H2O in 0.1 min, and finally isocratic condition of 10% acetonitrile in H2O for 2.9 min, all at a flow rate of 0.35 mL/min. MS detection was performed in positive ionization on an Agilent 6545 QTOF MS equipped with an Agilent Dual Jet Stream electrospray ion source with a drying gas temperature of 250 °C, drying gas flow of 8 L/min, sheath gas temperature of 300 °C, and sheath gasflow of 12 L/min. Capillary voltage was set to 4000 V and nozzle voltage to 500 V. MS data processing and analysis were performed using Agilent MassHunter Qualitative Analysis B.07.00.
2.7 Genome re-sequencing
Genomic DNA of 3610, SSB46 and MT529 were isolated using Bacterial and Yeast Genomic DNA kit (EURx). Re-sequencing was performed on an Illumina NextSeq instrument using V2 sequencing chemistry (2×150 nt). Base-calling was carried out with “bcl2fastq” software (v.2.17.1.14, Illumina). Paired-end reads were further analyzed in CLC Genomics Workbench Tool 9.5.1. Reads were quality-trimmed using an error probability of 0.05 (Q13) as the threshold. Reads that displayed ≥80% similarity to the reference over ≥80% of their read lengths were used in mapping. Quality-based SNP and small In/Del variant calling was carried out requiring ≥10× read coverage with ≥25% variant frequency. Only variants supported by good quality bases (Q ≥ 30) on both strands were considered.
3. Results
3.1 Absence of surfactin has no effect on pellicle formation of NCIB 3610
To assess the importance of surfactin production for biofilm development, pellicle formation, a biofilm on the air-medium interface was first examine in liquid biofilm-inducing medium, i.e. MSgg and MSNc + pectin. MSgg induces biofilm formation via iron availability and glutamate, while pectin, a plant-derived polysaccharide, is the main environmental cue inducing biofilm formation in MSNc + pectin [34]. Since both media present different cues for the bacterial cells, and that pectin was shown to strongly induce surfactin production [36], importance of this molecule for biofilm formation could vary according to the medium used. As shown in Fig. 1A, deletion of srfAA, and consequently absence of surfactin, does not visibly affect pellicle formation in either liquid media. Similarly, a strain deleted for sfp, which is defective for synthesis of all NRP-derived molecules, is also able to form pellicle in both media.
Importantly, the 3610 srfAA deletion strain used here was newly created (harbouring a kanamycin resistant gene) and did not match the pellicle formation phenotype of the originally published laboratory stock, 3610 srfAA::erm (SSB46; [28]), the latter showing an important delay in pellicle formation (Fig. S1). When the srfAA::erm marker was re-introduced into 3610 by SPP1 phage transduction, the newly obtained srfAA::erm strain (MT529) displayed comparable pellicle development to 3610 and srfAA::kan strains. Consequently, the genomes of 3610, SSB46, and the newly created MT529 strains were re-sequenced. In addition to the srfAA::erm mutation, SSB46 strain contained six point mutations that did not exist the ancestral 3610 or the re-created MT529 strain (see Table S2). However, deletion mutants of the SNP harbouring genes combined with srfAA::kan did not recapitulate the important defect observed with SSB46 strain (Fig. S1), suggesting that the mutation causing the defect is not a loss-of-function or that certain combination of SNPs are responsible for the observed phenotype of SSB46 strain.
Importance of surfactin and sfp for activation of the two main operons involved in biosynthesis of the extracellular matrix, i.e. tapA-sipW-tasA and epsA-O, was further examined using transcriptional lacZ fusions. As shown in Fig. 1B and D, absence of surfactin or deletion of sfp have little to no effect on tapA transcription, and slightly decreases epsA-O transcription in MSgg. In MSNc pectin, absence of surfactin actually increases tapA and epsA-O transcription (Fig. 1C), which also correlates with the more vigorous aspect of pellicles (see Fig.1A). In the same medium, absence of sfp impairs transcription of both biofilm operons. In summary, in liquid media srfAA or sfp deletion has only mild impacts on pellicle biofilm formation in B. subtilis 3610.
3.2 Deletion of sfp and srfAA alters colony structure
Biofilm strength can also be evaluated using the complex architecture of colony biofilms growing on solid biofilm-inducing media. Since surfactin is a biosurfactant [17,37], its absence might have more severe effect on solid media as observed for sliding, a matrix dependent colony expansion [17]. Indeed, as shown in Fig. 2A, colonies of srfAA show less spreading on solid MSgg and MSNc pectin, but are still very wrinkly. These wrinkles are likely composed mostly of proteinaceous (TasA) fibres, since expression of Peps is drastically reduced by absence of surfactin, while PtapA is not affected (Fig. 2B). Interestingly, the sfp mutant produces small, flat colonies in both media. This strain also has significantly reduced LacZ activity for both biofilm reporters (PtapA and Peps) and media, which correspond to the flat phenotype of the colonies. While calculation of the miller units includes normalization for cell number (OD600), this lack of biofilm gene expression could also be attributable to lack of cell growth and incapacity to reach the cell density required for biofilm formation.
Colony morphology results on solid media clearly show that srfAA and sfp deletion lead to phenotypes, indicating that in the latter absence of other molecule(s) synthesized via NRP machinery also impacts biofilm formation. Thus, we examined deletion mutants for bacillibactin (dhbA-F), plipastatin (ppsB) and bacillaene (pksL) (Fig. S2). The mutant defective for B. subtilis siderophore bacillibactin showed small, almost featureless colonies on both media, suggesting an important role for iron-acquisition molecules in this process. The double srfAA dhbA-F deletion recapitulated the sfp phenotype, suggesting that on solid media, both molecules are required for robust biofilm formation.
3.3 Surfactin is not required for root colonization by B. subtilis
In a natural environment, surfactin production is triggered by contact with plant roots few hours before biofilm formation [36]. Thus, we evaluated the importance of surfactin for root colonization of A. thaliana seedlings, using the system described in [34]. B. subtilis root colonization was monitored using a PtapA-yfp reporter, allowing us to identify cells actively forming a biofilm on roots. Since absence of surfactin might only delay, instead of inhibit, root colonization, different time points after inoculation were examined. As shown in Fig. 3A, there was no apparent difference in the root colonization patterns and capacities of WT and srfAA cells. We validated these observations by imaging whole roots and determining the ratio of YFP expression/root area, which gives us a quantitative measurement of colonization. Indeed, while colonization somewhat varied from one seedling to another, overall there was no significant difference between WT and srfAA root colonization at any time points.
3.4 Surfactin is dispensable for pellicle and plant-associated biofilm formation in recent soil B. subtilis isolates
To address the generality of lack of surfactin production on pellicle formation ability, we tested pellicle biofilm development of 6 newly isolated B. subtilis strains recovered from soil samples. As the essentiality of surfactin production for pellicle development has been demonstrated on MOLP medium for B. amyloliquefaciens (previously identified as B. subtilis) UMAF6614 [24], pellicle formation was followed both on MSgg and MOLP liquid media that revealed no observable difference between wild-type and their surfactin mutant derivatives (Fig. 4). Additionally, plant colonization was indistinguishable between the wild-type and srfAC::spec strains (Fig. 4). Finally, to demonstrate the surfactin production ability of these new B. subtilis strains, the isolates were inoculated to MSgg medium and UHPLC-HRMS analysis was performed on isopropanol:ethyl acetate extracts of the agar medium below the colonies. Chemical analysis of the extract along with a standard demonstrated that each and every isolates produced surfactin, but not their srfAC::spec derivatives (Fig. S3).
4. Discussion
The promiscuous role of secondary metabolites to function as info chemicals has been previously proposed [38–40]. The B. subtilis produced surfactin has been reported to lead to induction of biofilm development under non-biofilm inducing conditions [26]. Our results highlight that under biofilm inducing conditions, on liquid or solid biofilm-promoting MSgg and MSNg media, biofilm development of B. subtilis 3610 and other newly isolated strains does not require surfactin. Production of both matrix components actually appeared more efficient in MSNc pectin in absence of surfactin, which could be due to the metabolic burden of producing an important NRPs [41,42]. In solid media, srfAA and sfp mutants display strikingly different phenotypes than WT. In both cases, colony diameter is smaller, stressing the need for surfactin to disperse on a surface [17,18]. Intriguingly, absence of surfactin had a stronger impact on eps than on tapA transcription, suggesting that surfactin and/or colony spreading might be involved in regulating exopolysaccharides production on solid surface. This regulation would be independent from SinR and AbrB, which act identically on both operons [43].
Similarly to pellicle biofilm formation in liquid media, various srfA mutants colonize plant roots with an efficacy identical to WT cells. Surfactin production is stimulated by plant polysaccharides such as pectin, as is biofilm formation [34,36]. Thus, our observations suggest that while surfactin production precedes biofilm formation upon contact between cells and roots, both processes are somewhat independent. They also would have independent roles, biofilms favouring root attachment and surfactin production, triggering the induced systemic resistance.
Our results show that for B. subtilis, surfactin production is not required for robust biofilm formation, which is in contradiction with many reports for surfactin requirement in various Bacilli [23,24,44]. In many of these reports however, the species or the strain examined also produce an iturin, bacillomycin, which is not the case for B. subtilis 3610 or the newly isolated B. subtilis strains [30]. Of note, Luo et al. showed that a srf mutant of Bacillus spp. 916 produces weaker pellicles in liquid medium, and flat colonies on solid MSgg. However, in this case deletion of srf also strongly impairs production of bacillomycin L, which is also required for strong biofilm establishment and rice leaves colonization by Bacillus spp. 916 [44]. Thus, requirement of surfactin for biofilm formation and plant colonization is likely species- or strain-specific in Bacillus, and might depend on the presence of iturin production in these strains. Nevertheless, the importance of surfactin production by PGPR strains of Bacilli is primarily for the anti-microbial potential and systemic resistance induction by this multi-functional secondary metabolite.
Acknowledgement
This project was supported by the Danish National Research Foundation (DNRF137) for the Center for Microbial Secondary Metabolites (to H.T.K, M.W., and Á.T.K.), and by a Discovery Grant and Early Career Researcher Supplement from the Natural Sciences and Engineering Council of Canada (NSERC RGPIN-2014-04628 to P.B.B.).
Footnotes
↵# Co-first authors