INTRODUCTION
Enterohemorrhagic
Escherichia coli (EHEC) strains are foodborne pathogens that can cause severe clinical complications, including hemorrhagic colitis (HC) and hemolytic-uremic syndrome (HUS), through the production of Shiga toxin (Stx) and other virulence factors (
1–3). Stx is encoded on a temperate lambdoid bacteriophage and is therefore induced via the bacterial SOS response (
4–6). Certain antibiotics and DNA-damaging agents are known to trigger phage induction and increase the expression of Stx
in vivo and
in vitro (
7,
8). In the intestinal environment, members of the microbiome and their metabolites can modulate the pathogenicity of EHEC strains in multiple ways (
9). Commensal bacteria can reduce the growth and colonization of EHEC, broadly limiting virulence factor expression (
10). Alternatively, strains that are sensitive to the
stx-converting phage can be infected and thus amplify Stx production (
11–13). Finally, small molecules such as bacteriocins that target EHEC can both inhibit growth and promote Stx expression by the induction of the phage lytic cycle (
14,
15).
Bacteriocin activity was first described nearly a century ago (
16) and is widespread in
E. coli, with up to 60% of strains being identified as colicin producers in some surveys (
17–19). Microcins (Mccs), which have a lower molecular weight than colicins (
20), are found less frequently and are not as well characterized (
21). They are generally smaller than 10 kDa in size, are not SOS-induced, and are secreted by intact cells (
22,
23). Foundational studies on microcin B17 (MccB17), MccJ25, and others revealed that microcins are typically expressed in stationary phase when cells are starved for nutrients (
24–26). In particular, iron-limiting conditions often stimulate microcin production (
27–29). Some microcins are posttranslationally modified with the addition of siderophores (
30–32), and many colicins and microcins exploit siderophore receptors for entry into target cells (
33,
34). The expression of bacteriocins in nutrient-poor environments can also confer a fitness advantage to producing strains, allowing them to kill their competitors and better colonize a given niche (
35–37). In mouse models, for example, iron limitation can be advantageous for either pathogens (
38) or probiotic bacteria (
39) that produce bacteriocins.
Previous studies of the human
E. coli isolate 0.1229 revealed that cell-free supernatants from this strain were sufficient to induce the SOS response and increase the Stx expression of EHEC (
15). Microcin B17, which is encoded on a 96.3-kb plasmid in 0.1229, contributed to but was not fully responsible for SOS induction or Stx amplification (
15). An additional factor with Stx-amplifying activity was localized to p0.1229_3, a 12.9-kb plasmid in the strain (
15). This activity was dependent on TolC for efflux from 0.1229 and TonB for import into the target cell (
15). The SOS-inducing, Stx-amplifying agent of p0.1229_3 is presumed to be a new microcin, first described in strain 0.1229 and thus designated Mcc1229. Although the chemical identity of Mcc1229 is not known, it is encoded within a 5.2-kb region of p0.1229_3 whose annotations include hypothetical proteins, an ABC transporter, a cupin superfamily protein, and domain of unknown function (DUF)-containing proteins (
15).
Only a small number of microcins have been purified, and their functions in complex environments like the gut microbiome are not well defined (
21). Some have theorized that the microcins prevalent in phylogroup B2
E. coli strains enhance their ability to dominate the rectal niche and colonize the urinary tract (
40). 0.1229 is a phylogroup B2 isolate of sequence type 73 (ST73). Other members of ST73 are notable urinary pathogens (e.g., CFT073), and the lineage carries many virulence factors that can promote colonization and persistence
in vivo (
41,
42). In 0.1229, MccB17 and Mcc1229 may serve this purpose, as they are lethal to competing
E. coli strains (
15). To elucidate the role of the putative microcin Mcc1229, we have clarified its export, import, immunity, and regulation. We have also probed the effect of 0.1229 and its microcins in a germfree mouse model of EHEC infection.
DISCUSSION
A putative microcin from the human
E. coli isolate 0.1229 was previously shown to induce the SOS response and Stx expression in target strains (
15). Here, we have confirmed the activity of this microcin (Mcc1229), isolated its activity from that of a second microcin encoded by 0.1229 (MccB17), and further characterized its production, regulation, and effects. Like several other colicins and microcins, Mcc1229 uses the CirA siderophore receptor (
Fig. 5) and the TonB complex (
Fig. 6) for entry into a target cell. CirA was first identified as the
colicin
I receptor and is also used by colicin/microcin V (
33,
49). In the producing strain, evidence suggests that Mcc1229 requires the
mctABC operon of plasmid p0.1229_3 for activity (
Fig. 3). Open reading frames similar to
mctA, with cysteine-rich C-terminal regions and cognate ABC transporters, are also consistent with typical microcin operons (
50).
The functional contributions of the cupin-like
mctC and DUF-containing
mctD-
mctE ORFs in the Mcc1229 cluster have not yet been elucidated. In our system, the
mctDE region conferred immunity to Mcc1229 killing and Stx amplification (
Fig. 7), and we were unable to generate in-frame deletions of these ORFs. It is possible that previous mutants constructed by one-step recombination (
15) retained wild-type plasmid copies or acquired secondary mutations that masked this effect. Still, it is not clear whether the DUF-containing proteins encoded by
mctD and
mctE directly interact with the microcin. Current Pfam records indicate that the DUF2164 domain present in MctE is found in 804 protein sequences in 715 species, but it is not associated with a clan or superfamily (
51). DUF4440, which is found in MctD, belongs to a family in the nuclear transport factor 2 (NTF2) clan, which includes numerous proteins with enzymatic and nonenzymatic functions (
52). Some proteins with NTF2-like folds are known to provide immunity to bacterial toxins, but their sequences (Pfam PF15655) are diverse and dissimilar to the DUF4440 domain in MctD (
53). Proteins with DUF4440 and/or NTF2-like domains have also been shown to operate in polyketide biosynthesis pathways, where they are involved in catalyzing the formation of natural products (
54,
55). Some proteins with cupin domains have enzymatic activity (
56,
57), so it is possible that the p0.1229_3 MctC is involved in the processing or modification of Mcc1229. Contrary to previous reports, we found that neither MctF nor MctG was essential for microcin activity (see Fig. S1 in the supplemental material). Based on their homology to MbeD and MbeB family mobilization/exclusion proteins, we hypothesize that deletions of the
mctF and
mctG ORFs may have altered plasmid maintenance or copy number.
Beyond its cellular export and import, the observed Fe-Fur regulation of Mcc1229 further supports its classification as a microcin. Mcc1229’s amplification of Stx was increased in the presence of chelating agents, and this effect could be reversed by the addition of iron specifically (
Fig. 2). Moreover, the expression levels of the
mctA,
mctB,
mctC, and
mctD genes were increased in a Δ
fur background (
Fig. 4B). Taken together, these data likely indicate that Mcc1229 is transcriptionally repressed by the canonical Fe-Fur complex (
58). A similar pattern is seen in the regulation of microcin E492 in
Klebsiella pneumoniae (
29). Like the site upstream of
mceX in the MccE492 operon, the putative Fur box upstream of
mctA is 68% (13/19 nucleotides [nt]) identical to the consensus Fur sequence described for
E. coli (
59,
60). Fur-regulated microcins may provide a competitive advantage for
E. coli strains
in vivo where iron availability is restricted (
61,
62).
In our study, the microcin Mcc1229 was produced
in vivo but had no effect on EHEC colonization or disease (
Fig. 8). Nevertheless, we observed a striking example of suppression by
E. coli 0.1229 in which PA2 was rarely if ever recovered from coinfections. Most other
E. coli strains do not suppress EHEC to the same extent, although there is precedent for colonization suppression by the probiotic strain Nissle 1917 (
63,
64). Intriguingly, both Nissle and 0.1229 belong to sequence type 73 (ST73), a lineage frequently isolated from extraintestinal pathogenic
E. coli (ExPEC) infections (
65). ST73 strains carry a broad assortment of virulence factors, including many genes for adherence and iron acquisition, that could provide a selective advantage over competitors (
66). Ongoing studies may determine whether colonization resistance is a trait that is common to ST73.
Interactions with the microbiome can alter the virulence of EHEC in numerous ways. Understanding these effects will help predict the unique pathogenicity and disease outcomes of a given infection. Here, we have expanded upon the attributes of Mcc1229, a new E. coli microcin that induces the SOS response and amplifies Stx2a expression in vitro. When characterizing the interplay of Mcc1229 and EHEC in vivo, however, we found that microcin activity was not a significant contributor to EHEC virulence or colonization efficiency. This discrepancy highlights the need for additional research regarding the dynamics of bacteriocin expression in the intestinal environment. The regulation, stability, and activity spectrum of bacteriocins all influence their physiological role, as do external factors such as inflammation and nutrient availability. Although Mcc1229 can be unified with other microcins based on the cellular factors described in this work, its actual ecological impact was not apparent from our germfree mouse model and awaits further clarification.
MATERIALS AND METHODS
Bacterial strains and culture conditions.
E. coli strains were routinely grown in lysogeny broth (LB) (10 g/L tryptone, 5 g/L yeast extract, 10 g/L NaCl) at 37°C and maintained in 20% glycerol at −80°C. Minimal medium (M9) was formulated with 12.8 g/L Na2HPO4·7H2O, 3 g/L KH2PO4, 0.5 g/L NaCl, 1 g/L NH4Cl, 2 mM MgSO4, and 0.1 mM CaCl2. M9 medium was supplemented with 0.1% Casamino Acids, 0.005% thiamine, and 0.4% of the desired carbon source. Mueller-Hinton (MH) agar was prepared according to the manufacturer’s instructions. EDTA, 2,2′-bipyridyl, FeCl3, CaCl2, MgCl2, and MnCl2 were added to media at 0.2 mM. The following antibiotics were used: ampicillin at 50 μg/mL, chloramphenicol at 12.5 μg/mL, kanamycin at 25 μg/mL, and tetracycline at 10 μg/mL. All medium components were purchased from BD Difco (Franklin Lakes, NJ), and all enzymes were purchased from New England BioLabs (NEB) (Ipswich, MA), unless otherwise noted.
One-step recombination.
E. coli knockouts were constructed according to the protocol of Datsenko and Wanner (
67). Primers incorporating 40 bp immediately upstream and downstream of the gene of interest were used to amplify the
cat cassette from pKD3 or the
kan cassette from pKD4 (
Tables 1 and
2). The target strain was first transformed with pKD46, grown to mid-log phase, and then induced with 0.02 M
l-arabinose for 1 h. Cells were washed with cold water and 10% glycerol and electroporated with the
cat or
kan PCR product using a GenePulser II instrument (2.5 kV, 0.2-cm-gap cuvettes; Bio-Rad, Hercules, CA). Transformants were verified by colony PCR with primers approximately 200 bp up- and downstream of the gene of interest, and the site of the insertion was confirmed by Sanger sequencing (
Tables 1 and
2). Mutants were complemented with a plasmid copy of the gene of interest and cloned into the medium-copy-number vector pBR322 by Gibson assembly (
68). Assembly primers were designed using NEBuilder (NEB) (
Table 2). Amplicons were purified with the QIAquick cleanup kit (Qiagen, Germantown, MD) and assembled with the Gibson assembly cloning kit according to the manufacturers’ instructions. Assembly junctions were likewise confirmed by colony PCR and Sanger sequencing (
Tables 1 and
2).
Because multiple efforts to inactivate tonB in PA2 by one-step recombination were unsuccessful, we generated a ΔtonB::cat mutant in the EDL933 background. This mutant was complemented by pKP315, kindly provided by Kathleen Postle, which carries an arabinose-inducible copy of tonB on a pBAD24 backbone. l-Arabinose was added to EDL933 cultures at 0.3%.
lacZ fusions.
Transcriptional activity was measured by fusing selected p0.1229_3 fragments to a promoterless
lacZ gene in the pRS551 vector (
69). Fragments were amplified from p0.1229_3 using the indicated primers (
Tables 1 and
2) and digested with EcoRI-HF and BamHI-HF enzymes. The products were cleaned up using the QIAquick kit and ligated into an EcoRI-BamHI digest of pRS551. Ligation mixtures were transformed into chemically competent DH5α cells (New England BioLabs) and verified by miniprep and restriction digests. The constructs were then electroporated into
E. coli 0.1229ΔB17. Reporter strains were cultured in LB, with shaking at 37°C, and grown to mid-logarithmic phase. Cells were then harvested and suspended in Z buffer (0.06 M Na
2HPO
4·7H
2O, 0.04 M NaH
2PO
4·H
2O, 0.01 M KCl, 0.001 M MgSO
4·7H
2O, 0.05 M β-mercaptoethanol [pH 7]). LacZ activity was measured by the hydrolysis of
o‐nitrophenyl‐β‐
d‐galactoside according to the method of Miller (
70).
qPCR.
RNA was extracted from 16-h-grown LB cultures of 0.1229 and 0.1229Δ
fur::
cat using the Qiagen RNeasy minikit according to the manufacturer’s instructions. Genomic DNA was removed by digestion with RQ1 RNase-free DNase (Promega, Madison, WI), and RNA was converted to cDNA using the SuperScript IV kit (Thermo Fisher). The expression of the
mctA,
mctB,
mctC, and
mctD genes was quantified in 25-μL reaction mixtures using PerfeCTa SYBR green FastMix (Quantabio, Beverly, MA) and 200 nM quantitative PCR (qPCR) primers (
Table 2) on a QuantStudio3 instrument (Thermo Fisher, Waltham, MA). To validate the efficiency (>95%) of each primer pair, its target was amplified from genomic DNA and purified using a spin column cleanup kit (Dot Scientific Inc., Burton, MI). The concentration of this product was measured by spectrophotometry (NanoDrop 1000; Thermo Fisher), and 10-fold dilutions ranging from 10
−2 to 10
−7 ng/μL were used as the templates in qPCR. A standard curve was constructed from the resulting threshold cycle (
CT) values. Differences in gene expression between the wild-type and Δ
fur::
cat strains were determined by the ΔΔ
CT method, using the 16S rRNA
rrsH gene as an internal control (
71).
cDNA and primers prepared for qPCR (
Table 2) were also used to determine the operon structure of the
mct gene cluster. Ten microliters of cDNA was used as the template in a 50-μL
Taq ThermoPol reaction mixture. Touchdown PCR was performed by annealing for two cycles at 64.5°C, two cycles at 59.5°C, and 15 cycles at 54.5°C. Five microliters of this reaction mixture was then used as the template in a second 50-μl PCR mixture with identical primers. The touchdown steps were eliminated in the second PCR, and annealing occurred at 54.5°C for 30 cycles. All reactions were also performed on p0.1229_3 plasmid DNA as proof of successful amplification and on a cDNA control prepared without reverse transcriptase to verify that the cDNA input was not contaminated with genomic DNA.
In-frame deletions.
Previous work demonstrated that a fragment of the p0.1229_3 plasmid encompassing nucleotides 2850 through 7950 was sufficient to amplify Stx when cloned into pBR322 (
15). In-frame deletions of individual ORFs in this vector, pBR322::mcc1229, were generated with NEB’s Q5 site-directed mutagenesis kit. Primers facing outward from the chosen ORF were designed with the NEBaseChanger tool and used with Q5 polymerase to amplify a linear fragment from pBR322::mcc1229 (
Tables 1 and
2). This product was treated with the KLD (kinase, ligase, DpnI) enzyme cocktail to digest template DNA and recircularize the plasmid according to the manufacturer’s instructions. Constructs were verified by PCR of DH5α transformant colonies using VF/VR primers (
Tables 1 and
2). Mutations were then confirmed by Sanger sequencing, and plasmids were electroporated into C600 as described above to ensure that no wild-type copies remained. Complementation of the in-frame deletion mutants was accomplished by fusing the promoter region directly upstream of
mctA to the desired ORF. This fragment was cloned into pACYC184, replacing the vector’s tetracycline resistance gene. Primers for Gibson assembly are given in
Table 2. Clones were verified by restriction digestion and by PCR and Sanger sequencing using the pACYC184 VF/VR primers (
Table 2).
Inhibition assays.
Microcin production was evaluated by measuring the inhibition of a target strain in agar overlays (
72). The microcin-producing strain was spot-inoculated onto MH agar and incubated at 37°C for approximately 24 h. Plates were inverted over filter paper discs impregnated with 300 μL chloroform for 30 min to kill producing cells. Cultures of the target strains were then suspended to 0.05 optical density at 600 nm (OD
600) units per mL in soft (0.7%) nutrient agar, poured on top of the plates, and allowed to solidify. After incubation overnight at 37°C, inhibition was noted by the presence of halos surrounding a microcin-producing colony. Zones of inhibition (ZOIs) were quantified by subtracting the diameter of the producing colony from the diameter of the clear zone surrounding it. Spontaneous mutants growing within the zones of inhibition were restreaked to purify and retested in agar overlays to confirm microcin resistance. Known microcin and colicin producers and their corresponding indicator strains were obtained from the NCTC reference set, kindly provided by Robert F. Roberts (
44).
For inhibition assays using supernatants, plates were inoculated with the test strain in soft agar as described above. Fecal samples from mice colonized with 0.1229 or its derivatives were collected 1 day after inoculation with PA2, suspended in 100 to 200 μL LB, and centrifuged. Ten microliters of the supernatant was spotted on top of the test strain and allowed to dry before incubation overnight at 37°C.
Whole-genome sequencing and bioinformatics.
Genomic DNA was extracted from cultures grown overnight using the DNeasy blood and tissue kit (Qiagen). Libraries were prepared using the Nextera XT kit (Illumina, San Diego, CA) and sequenced on the MiSeq platform, generating 2- by 250-bp reads. Reads were assembled in the Galaxy workspace with the SPAdes tool (
73), and single nucleotide polymorphisms were identified using Snippy (
74), in comparison to the reference genome assembly GCA_000335355.2. Putative Fur binding sites and promoter motifs were identified by analysis of the p0.1229_3 sequence with RSAT (
75) and BPROM (
76), respectively.
Supernatant experiments.
The supernatants of
E. coli 0.1229 and its derivatives were harvested after 16 h of shaking at 37°C and passed through 0.2-μm cellulose acetate filters (VWR Life Sciences, Radnor, PA). Assays to quantify Stx amplification were performed as previously described (
15). Briefly, the test strain of
E. coli was suspended in 1 mL of the spent supernatant to an OD
600 of 0.05 and inoculated on top of solid LB agar in a 6-well plate (BD Biosciences Inc., Franklin Lakes, NJ).
For Stx assays, the test strains were
E. coli O157:H7 isolates. PA2 (
77) was used routinely as it demonstrated the greatest Stx amplification in previous experiments (
13). EDL933 (
46) was used in the event that a PA2 mutant could not be obtained. Strains were diluted to an OD
600 of 0.05 in either broth or the filtered supernatant and inoculated on top of solid LB agar in 6-well plates. Cultures were then incubated statically at 37°C for 8 h. Aliquots of each culture were removed to measure the OD
620, and the remaining volume was treated with 6 mg/mL polymyxin B for 5 min at 37°C to release intracellular Stx. Samples were then centrifuged for 5 min to pellet cell debris, and supernatants were collected and stored at −80°C until use in a receptor-based enzyme-linked immunosorbent assay (R-ELISA).
R-ELISA.
Shiga toxin was detected in a receptor-based ELISA as previously described (
14). A microtiter plate was first coated with 25 μg/mL ceramide trihexosides (Matreya Biosciences, Pleasant Gap, PA) in methanol. The methanol was evaporated, and the plate was subsequently blocked overnight with 4% bovine serum albumin in phosphate-buffered saline (PBS) containing 0.05% Tween 20 (PBST). Supernatant samples were diluted in PBS as necessary and added to the wells for 1 h, with gentle shaking at room temperature. Monoclonal anti-Stx2 antibody was purchased from Santa Cruz Biotech (Santa Cruz, CA) and added to the wells at 1 μg/mL for 1 h. Anti-mouse secondary antibody conjugated to horseradish peroxidase was purchased from MilliporeSigma (Burlington, MA) and also added at 1 μg/mL for 1 h. Between each of the preceding steps, the plate was washed five times with PBST. One-step Ultra TMB (3,3′,5,5′-tetramethylbenzidine; Thermo Fisher) was then used for detection. The plate was incubated for approximately 5 min before the reaction was stopped with the addition of 2 M H
2SO
4, and the
A450 was measured (Multiskan FC; Thermo Fisher). A standard curve was established using serial dilutions of the lysate from PA11, a high-Stx2a producer (
77). The concentration of Stx2a in
E. coli O157:H7 samples was determined by comparison to this curve and is reported in micrograms per milliliter, normalized to the OD
620 of each
E. coli O157:H7 culture.
Animal experiments.
Male and female Swiss Webster mice aged 3 to 5 weeks were raised in the University of Michigan germfree colony. They were housed in soft-sided bubble isolators or sterile Isocages and fed autoclaved water and laboratory chow ad libitum. Throughout the experiment, the mice received sterile food, water, and bedding to maintain germfree conditions, except for the infecting E. coli strains. All animal experiments were conducted with the approval of the University of Michigan Animal Care and Use Committee.
Mice were infected orally with ∼106 CFU of each E. coli inoculum. In coinfection experiments, 0.1229 and its derivatives were inoculated first, followed by PA2 1 week later. Mice were weighed prior to each inoculation and just prior to euthanasia. They were evaluated daily for evidence of illness (dehydration, ruffled coat, or reluctance to move) and were euthanized 1 or 7 days after PA2 infection or when they became moribund. Prior to euthanasia, evidence of illness was recorded, and at necropsy, samples were collected for bacterial culture, Stx2 ELISAs, and histological examination.
For bacterial cultures, samples of the cecal contents were weighed, serially diluted in sterile LB, and cultured on sorbitol-MacConkey (SMaC) agar. PA2 is non-sorbitol fermenting and appears as white colonies on SMaC plates. Cultures from cocolonized mice were quantified based on the number of pink or white colonies. For the quantification of Stx2, the cecal contents were stored at −20°C until evaluation with a Premier EHEC ELISA kit (Meridian Biosciences Inc., Cincinnati, OH). The concentration of Stx2a was determined by comparison to the PA11 standard curve discussed above (
77).