To investigate how Campylobacter jejuni causes the clinical symptoms of diarrhoeal disease in humans, use of a relevant animal model is essential. Such a model should mimic the human disease closely in terms of host physiology, incubation period before onset of disease, clinical signs and a comparable outcome of disease. In this study, we used a gnotobiotic piglet model to study determinants of pathogenicity of C. jejuni. In this model, C. jejuni successfully established infection and piglets developed an increased temperature with watery diarrhoea, which was caused by a leaky epithelium and reduced bile re-absorption in the intestines. Further, we assessed the C. jejuni genes required for infection of the porcine gastrointestinal tract utilising a transposon (Tn) mutant library screen. A total of 123 genes of which Tn mutants showed attenuated piglet infection were identified. Our screen highlighted a crucial role for motility and chemotaxis, as well as central metabolism. In addition, Tn mutants of 14 genes displayed enhanced piglet infection. This study gives a unique insight into the mechanisms of C. jejuni disease in terms of host physiology and contributing bacterial factors.
Campylobacter spp. are recognised as the most common cause of acute food-borne bacterial diarrhoeal disease in humans, both in developed and developing countries1,2 with Campylobacter jejuni being responsible for ~85% of the human infections and Campylobacter coli accounting for ~15%. A spectrum of disease is seen in humans with clinical presentation ranging from watery to severe dysentery-like inflammatory diarrhoea3,4. In developed countries, diarrhoeal disease is manifested by a dysenteric-type illness that reflects the process of inflammation occurring within the gastrointestinal tract, findings that were reproduced in human volunteer studies using clinical isolates of C. jejuni5.
Our understanding of the bacterial components/mechanisms responsible for infection of the human gastrointestinal tract is far from complete. A significant obstacle to elucidating the pathophysiology of Campylobacter infection is the lack of a robust animal model that accurately reproduces the characteristics of gastroenteritis seen in human infection6,7,8.
C. jejuni and C. coli are able to colonise specific pathogen free pigs, however, they are limited in their ability to cause clinical signs of disease9. However, earlier work in the 1980s and 1990s demonstrated the potential of the gnotobiotic piglet model of C. jejuni infection to study the pathogenesis of diarrhoeal disease10,11,12. Gnotobiotic piglets are derived via hysterectomy and are deprived of colostrum, and consequently they lack maternal antibodies and a competing microflora. In the model reported by Vitovec et al.10, one-day old gnotobiotic piglets were orally infected with C. jejuni. Clinical manifestation of enteric disease was observed at day 4–5 post-infection, with signs of disease confined to the large intestine, these included inflammation, oedema and influx of neutrophils10. Transmission electron microscopy showed disruption of the intestinal lining with dilated intercellular space between enterocytes10. In a study by Boosinger and Powe, C. jejuni was also detected on the surface of epithelial cells as well as sub-mucosal12. These studies demonstrated that gnotobiotic piglets represent a suitable model to investigate disease mechanisms of C. jejuni as their gastrointestinal anatomy and physiology is similar to humans as well as their susceptibility to many enteric pathogens6,7,8,10,12,13,14.
The availability of various genome-wide screening methods employing next-generation sequencing technologies enabled detailed assessment of the molecular mechanisms involved in colonisation of chickens and the invasion of epithelial cells15,16. However, no such studies have been performed in models mimicking human campylobacteriosis.
In this study we have re-established and characterised in detail a gnotobiotic piglet model to investigate diarrhoeal disease caused by C. jejuni and combined transposon (Tn) mutagenesis with Tn-seq (transposon insertion site sequencing) to identify genes implicated in infection of the piglet gastrointestinal tract.
Results and Discussion
Characterisation of the gnotobiotic piglet model of C. jejuni infection
Piglets were surgically delivered through hysterectomy via a sterile plastic bubble into a sterile isolator and fed a sterile diet, consequently the piglets are gnotobiotic and thus lack a commensal flora. One day post-delivery, piglets were orally challenged with ~5 × 109 colony forming units (CFU) of C. jejuni strains 11168, a human enteritis isolate17, 81–176, a human campylobacteriosis outbreak isolate18, or strain L115 that was isolated from a paediatric diarrhoeal disease case19. All three tested C. jejuni strains did successfully establish infection of the gnotobiotic piglet gastrointestinal tract at day 3 post-infection (p.i.), with bacterial loads at 5 days p.i. reaching approximately 108 CFU/g of ileal content, 1010 CFU/g of colonic content, and 1012 CFU/g in the faeces collected from the last inch of the rectum (Fig. 1). Bacterial loads were found to be higher in the colon and faeces than in the ileum.
Despite comparable bacterial loads for all three C. jejuni strains, the piglets infected with strains 81–176 and L115 developed increased rectal temperatures at day 1, 2 and 3 p.i. whereas this effect was less pronounced after infection with 11168 (Fig. 2). At day 3 p.i., 9 out of 11 piglets infected with 11168 suffered from watery diarrhoea (scour) and 28 out of 33 piglets infected with 81–176 (Fig. S1). Over the course of the experiment (5 days), infected piglets failed to put on weight (failure to thrive) or lost weight compared to uninfected gnotobiotic animals. These clinical characteristics resemble those observed in C. jejuni enteritis in experimental studies in humans and in natural human cases5.
There was little evidence of severe inflammatory enterocolitis in the histological assessment of piglets that developed diarrhoea (Fig. 3). Compared to uninfected controls (Fig. 3a), histology on ileal tissue from infected piglets showed relatively shorter and blunter villi with mitotic figures in the crypts, an increase in mucous cells, and a minimal neutrophil infiltrate into the lamina propria and expansion of sub-mucosal lymphoid tissue as denoted by well populated Peyer’s patches (Fig. 3b,c). There was an increase in mucous secretory cells, evidence of shortening and blunting of villi and some villous cells showing damaged nuclei (Fig. 3b,c). The vacuolation of mucosal epithelial cells, especially those at the apex of villi (Fig. 3b,c), was most likely due to the high fat content of the diet. In the caecum some crypt abscesses were present (Fig. 3d). In the colon of the infected piglets there was oedema in the lamina propria and some tissue damage compared to uninfected controls (Fig. 3e,f), in line with findings reported by Vitovec et al.10. Typical colonic findings included occasional bacterial colonies present, pyknotic nuclei and a mild increase in cellularity in the lamina propria, due to predominantly lymphocytic infiltration with the occasional polymorphonuclear leukocytes (PMN) also present (Fig. 3b,c). Detailed examination of the ileal tissue using immunohistochemistry specific for Campylobacter spp. showed the presence of C. jejuni microcolonies on the villi and revealed the presence of intracellular bacteria in the villous lamina propria (Fig. 3g,h).
Features associated with C. jejuni 81–176 infection also include the gross changes in colour of the infected tissue and the shape of the villi compared to uninfected tissue (Fig. 4). Infected tissues were noticeably paler than control tissues, showing reduced bile-staining together with shortened and broad villi, whereas uninfected piglet ileum exhibited normal, ‘leaf-like’ villous architecture and brown, bile-stained mucosa. This suggests that C. jejuni infection prevents bile re-absorption in the ileum. In mammals, resorption of 90% of the bile acids released from the gall bladder after a meal occurs in the ileum. When not re-absorbed excess bile acids cause acute watery diarrhoea20. Bile acid malabsorption (BAM) is a well-known syndrome that usually results in chronic watery diarrhoea, with excess faecal bile acids. Furthermore, bile constituents have been shown to induce pathogenicity determinants of C. jejuni consistent with a role for decreased bile re-absorption enhancing colonisation21.
The observed changes to the morphology of villi in infected piglets may reflect an alteration of the barrier function of the small bowel. In order to assess this, we conducted a series of Ussing chamber experiments to determine changes in short circuit current and transepithelial resistance across muscle stripped ileum as a measure of the secretory component and paracellular leak, respectively. No changes were observed in potential difference (Fig. 5a), or short circuit current (Fig. 5b), indicating that there was no active secretory component to the C. jejuni induced diarrhoeal disease. i.e. net secretion of chloride ions across the apical membrane of the ileum. Piglets infected with C. jejuni strain 81–176 showed loss of tissue resistance over the course of acute diarrhoeal disease compared to uninfected controls (Fig. 5c), indicating that the tight junctions of the ileum were leaky. Thus C. jejuni appears to inhibit absorption of water from the ileum in infected animals rather than to up-regulate secretion.
Genome-wide detection of genes implicated in piglet infection
We used the gnotobiotic piglet model to conduct a genome-wide Tn mutant library screen to identify genetic factors important for infection. Previous Tn mutant screens in chicken colonisation models showed extensive random dropout of colonisation-proficient Tn mutants and extensive between-experiment variation15,22,23,24, for example Johnson et al., reported a 51% loss of the Tn mutants present in the input pool after recovery from colonised 1-day-old chickens15. Unpredictable variations in population structure were even observed when birds were inoculated with just two competing wild-type isogenic-tagged strains (WITS) that have indistinguishable phenotypes in pure culture25. To determine whether this also applies to the gnotobiotic piglet model, piglets were infected with two C. jejuni M1 WITS that can be distinguished by a DNA tag inserted into a pseudogene. At various time-points the abundance of each WITS was determined by quantitative PCR (qPCR) and a log10 competitive index (CI) was calculated; a log10 CI score of 0 indicates that any confounding effects are unlikely to be present. Both after oral and rectal infection with two C. jejuni M1 WITS given as a single inoculum in a 1:1 ratio, both WITS were reliably recovered from piglets (Fig. S2). During the course of 4 days of infection, any bias towards one WITS was less than half a log (Fig. S2). These findings contrast sharply with previous chicken colonisation studies where biases of up to four orders of magnitude were seen when WITS were inoculated at 1:1 ratio25, and indicates that the gnotobiotic piglet model is suitable for screening a Tn mutant library.
To identify genes implicated in infection of piglets, the developed model was used to screen a mariner Tn mutant library in C. jejuni strain M1cam22,26. Consisting of 9,951 unique Tn insertion mutants. Two groups of piglets (isolator 1: n = 11 and isolator 2: n = 10) were infected with 109 CFUs of the Tn mutant library. Tn mutants that populated the gastrointestinal tract were recovered at five days p.i. To identify genes required for infection, the composition of the Tn mutant library in the inoculum (input) and the library recovered from infected piglets (output) was determined by Tn insertion site sequencing, referred to as Tn-seq27. Tn-seq read-out detected a total of 8,761 (7,414 ± 477) unique Tn mutants covered by more than 10 sequence reads in the input replicates (n = 3), with 999 out of 1,654 genes in the C. jejuni M1cam genome being represented by 1 or more Tn insertion mutants. For reference, a total of 512 genes in the C. jejuni M1cam genome are indispensable for in vitro growth (for more details see Methods and ref. 22), hence these were eliminated from downstream analyses. A total of 8,340 (5,484 ± 3,332) unique Tn mutants were detected in the output pools recovered from the piglets (isolator 1 and 2), representing 96% recovery of the Tn mutant library complexity from infected piglets. More specifically, 7,320 (5,136 ± 2,012) and 7,621 (5,395 ± 969) unique Tn mutants were recovered from piglets housed in isolator 1 and 2, respectively. On average, recovery of 74% of the Tn mutants were recovered per infected piglet. This is likely the consequence of mutants being lost due to their inability to infect the piglet gastrointestinal tract and/or loss due to an infection bottleneck. Our results indicated a reliable recovery of a large part of the Tn mutant library from infected gnotobiotic piglets and suggest that there may be no, or only a minor, infection bottleneck.
First, we analysed whether there was a difference in the behaviour of Tn mutants within isolator 1 and 2. A principal component analysis (PCA) based on the read counts per individual Tn mutant showed clustering of the input samples and indicated that there was no isolator-specific clustering of piglets (Fig. S3a). Both PCA and hierarchical clustering based on log2 fold-change per gene (output/input; average of inputs n = 3) also indicated the lack of isolator-specific clustering (Fig. S3b and Fig. 6a). We observed that piglet 8 showed the largest variability within the data set (Fig. S3a,b and Fig. 6a), this was likely to be the result of fewer Tn mutants (3,988) being recovered from this piglet compared to the other piglets. Importantly, there was a strong correlation (Pearson correlation of 0.93) between the log2 fold-change per gene for isolator 1 and 2 (Fig. 6b).
Next, genes required during infection were identified using data combined for piglets from both isolators. For this, we excluded genes that when inactivated by a Tn insertion displayed attenuated growth, referred to as “fitness” genes (for more details see Methods). Of the 1,140 non-fitness genes, only the 763 genes that were covered by more than 100 reads (combined for all Tn insertions in the gene) in the input (average read count, n = 3) were considered for further analysis. The Tn-seq screen identified 123 genes required for piglet infection as their corresponding Tn mutants were negatively selected from the Tn mutant library population, defined as a log2 fold-change of <−2 between output (recovered from pigs) and input (Benjamini and Hochberg adjusted P < 0.05) and a minimum of two Tn mutants per gene that showed a log2 fold-change of <−2; log2 fold-change cut-offs were determined based on a MA-plot (Fig. S4). A total of 14 genes were identified of which Tn mutants showed enhanced survival, with a log2 fold-change of >3-fold and >2 Tn mutants with a log2 fold-change of >3. It must be noted that genes that encode secreted proteins such as the Campylobacter invasion antigen B (CiaB)21 can be complemented in trans and hence are not identified in Tn library screens as shown here and by Gao et al., during the invasion of human gut epithelial tissue culture cells16. A detailed overview of the Tn-seq analysis and genes of which mutants were negatively or positively selected during piglet infection is presented as Table S1.
Among the genes of which Tn mutants were negatively selected during infection of piglets were 26 flagellar system genes, which included genes involved in flagellar glycosylation, pseA, pseB, pseD (maf3), pseE, and maf-528,29,30 (Fig. 7a). Limited chromosomal clustering of genes implicated in piglet infection was observed, except for genes in the flagellar (glycosylation) system (Fig. 7a). Functional enrichment analysis based on Cluster of Orthologous Groups (COG) categories highlighted a central role for motility, i.e. the COG category “cell motility” was the only category that was enriched amongst genes required during piglet infection (Fig. 7b). Further, several chemotaxis genes (mcp4_2, mcp4_3, mcp4_4 and cheR) were identified, as well as genes implicated in N-linked glycosylation of membrane proteins (pglF and pglH_capM)31 and a putative capsular polysaccharide heptosyltransferase gene (CJM1cam_1374).
Central to the physiology of C. jejuni is its ability to utilise amino acids and organic acids such as lactate, pyruvate, acetate and tricarboxylic acid (TCA) cycle intermediates, reviewed in refs 32 and 33. We found that genes involved in these metabolic pathways may contribute to infection of the piglet gastrointestinal tract, although caution must be taken, as the availability of substrates/metabolites is dependent on the diet the piglets were fed on, i.e. the gnotobiotic piglets were fed a high-glucose evaporated milk diet (Carnation milk), and the metabolic conversions conducted by the resident microorganisms. This may be different in the gnotobiotic piglet compared to conventional piglets that posess a commensal microbiota. Amongst others we identified genes involved in lactate utilization (lutA_1; lactate to pyruvate), the lower part of the Embden-Meyerhof-Parnas pathway (pyk; pyruvate kinase and pycA; acetyl-CoA carboxylase), and in conversion of TCA cycle intermediates such as citrate (gltA), succinyl-coA (sucC), succinate/fumurate (frdA and frdC) and malate (mdh). The oxidation of succinate to fumurate is a key step in the oxidative TCA cycle and is primarily driven by fumurate dehydrogenase34. Interestingly, the importance of fumurate dehydrogenase was previously demonstrated using chicken colonization, with fumurate dehydrogenase genes (frdAB) being up-regulated during chicken colonization35 and frdA gene deletion mutants in C. jejuni 11168 show reduced chicken colonization34.
Linked to the TCA cycle are genes responsible for secretion or uptake of acetate (ackA; acetate kinase and pta; phosphate acetyltransferase); the direction of this pathway (anabolic or catabolic) is likely dependent on the growth-phase and nutrient availability36. Of these substrates, pyruvate, fumarate, succinate, malate and lactose have been reported to be chemoattractants for C. jejuni37. Of note, we observed that some genes, i.e. genes that encode PEP carboxykinase (pckA) and aconitase (acnB) in these central metabolic pathways were not identified in our screen due to them being required for full “fitness” (See Methods for further details).
Serine, aspartate, glutamate and proline are primary nutrient sources for growth of C. jejuni, which can be acquired during growth in the gastrointestinal tract. These amino acids are also in abundance in the evaporated milk-based diet38 that the piglets were fed on. Aspartate and serine are considered the preferred amino acids for growth, followed by glutamate and proline32,33, of which asparate, serine and glutamate are chemoattractants. In our screen we identified genes implicated in uptake of aspartate and glutamate (peb1a and artM_2/pebC) and TCA cycle influx of aspartate (aspA; conversion of aspartate to fumarate). In C. jejuni 11168, aspA was up-regulated during chicken colonization35, and an aspA gene deletion mutant in C. jejuni 81–176 was previously shown to be unable to use any amino acids except serine and was defective in colonization of chickens39. Interestingly, Tn inactivation of the serine utilization genes sdaA and sdaC (serine to pyruvate) appear to enhance piglet infection, this is in contrast to severely attenuated colonization of gastrointestinal and systemic tissues in a murine colonization model by C. jejuni strain 81–176 sdaA and sdaC defined gene deletion mutants19. This might be due to different substrate availability in piglets or related to strain-dependent metabolic preferences40. Branched-chain amino acids (BCAA) are linked to chemotaxis, i.e. isoleucine interacts with the transducer-like protein 3 (Tlp3)41; the LIV (leucine, isoleucine, and valine) ABC-type BCAA transport system (livM, livH, livK, and livJ), isoleucine and valine biosynthesis (ilvH and ilvC), and homoserine dehydrogenase (hom; reduction of aspartate to homoserine, which is an intermediate in isoleucine biosynthesis), were implicated in piglet infection. C. jejuni harbors various pathways for anaerobic respiration, of which the genes that encode formate (fdhD and fdhG) and nitrate (napD) dehydrogenases were required during infection. Further, the genes of which products handle oxidative stress (catA; catalase) and acid stress (clpB; Clp protease ATP-binding subunit) appear to be important for the ability of C. jejuni to establish piglet infection42.
In this study, we set out to establish and characterize a gnotobiotic piglet model of gastrointestinal infection by the food-borne pathogen C. jejuni, with the aim to expand our knowledge about the molecular mechanisms underlying the lifestyle of C. jejuni during infection of host organisms.
In the gnotobiotic piglet model, infection with C. jejuni caused increased rectal temperatures and acute watery diarrhea with minimal inflammation. C. jejuni adhered to the luminal surface of the piglet small intestinal mucosa as microcolonies and localised intracellularly in the lamina propria and ileal crypts. In the piglet colon, the bacteria localised to the crypts, with only a few bacteria being present on the colonic luminal surface. Muscle-stripped ileum from the infected piglets had reduced transepithelial resistance compared with uninfected control tissue. This indicates that the tight junctions controlling paracellular fluxes of ions and water has been compromised since there was no increase in short-circuit current under a chloride gradient (representing transcellular ion movement of ions). This is consistent with similar results obtained in Caco-2 cells infected with C. jejuni43 and suggests that the lower small bowel in the infected animal will have a reduced absorptive ability than normal44. In addition, we found a greatly reduced or complete lack of bile staining in C. jejuni-infected animals. This indicates that C. jejuni infection may prevent bile acid re-absorption and that the excess of bile acids in the distal small intestine of infected piglets contributes to acute watery diarrhoea.
To understand the lifestyle of C. jejuni during infection of the piglet gastrointestinal tract at a molecular level, a genome-wide Tn mutant library screen was performed. The Tn library screen highlighted a crucial role for flagellar-mediated motility, chemotaxis and central metabolic pathways required to catabolise organic acids such as lactate, pyruvate, acetate, as well as TCA cycle intermediates and amino acids, mainly aspartate. Thus, it appears that the molecular mechanisms involved in C. jejuni intestinal infection of gnotobiotic piglets, overlap largely with those implicated in colonization of natural reservoir host organisms such as chickens but also with those required for invasion of human gut epithelial tissue culture cells. Our recent work revealed that 65 out of 172 genes required for colonisation of commercial broiler chickens and 34 out of 57 genes required for invasion of Caco-2 cells and were also found to play a role during the infection of gnotobiotic piglets22. The large overlap suggests that this model presents an opportunity to inform us about the mechanisms of disease in humans, however a detailed molecular and immunological characterisation of the model system would be required, for example through monitoring the transcriptional response of C. jejuni and the host during infection. Future work on elucidating the link between nutrient availability, chemotaxis, motility and colonisation/infection of host organisms will contribute to our understanding of C. jejuni pathogenesis.
In summary, these results underline the potential of the gnotobiotic pig model of C. jejuni intestinal infection to study molecular mechanisms of infection and host-pathogen interaction in a model that is clinically relevant and mimics human disease.
Bacterial strains, media and growth conditions
C. jejuni strains were cultured in Mueller-Hinton (MH) broth or MH blood agar (Oxoid) and incubated at 37 °C in a variable atmosphere incubator (VAIN, Don Whitley Scientific) in an atmosphere of hydrogen 6%, carbon dioxide 5%, oxygen 5% and nitrogen 84%. C. jejuni M1cam was cultured on Brain Heart Infusion (BHI, Oxoid) agar plates supplemented with 5% defibrinated horse blood (Oxoid) and 5 μg/ml trimethoprim (TrM). The mariner Tn mutant library was cultured in the presence of 10 μg/ml chloramphenicol (Cm). Bacterial strains and plasmids used in this study are detailed in Table S2.
Piglet infection model
Gnotobiotic piglets were surgically delivered by hysterectomy through a sterile plastic bubble into a sterile isolator (Bell Isolation Systems Ltd, Livingston, UK). The piglets navels were treated with a strong iodine solution and the navels tied with cotton tape to stop blood loss. Piglets were ear tagged for identification 3 h post-delivery (p.d.). All piglets had an iron injection (deep intramuscular injection on the rump) at 24 h p.d., because of the sterile diet they are fed on, which is low in iron. The piglets were bottle fed for the first 24 hp.d. using a 1:1 mixture of Carnation milk (Nestle, Switzerland) and 10% autoclaved glucose solution. After 24 hp.d. the piglets were bottle fed a 1:1 mixture of Carnation milk and autoclaved water. At 3 days p.d. the piglets were introduced to trough feeding within the isolators. The piglets were subsequently fed on sterile Carnation milk plus B vitamin supplements within the isolators, and had access to sterile water at all times for the duration of the study.
Piglets were orally infected one day p.d. with 5 × 109 CFU of C. jejuni strains 11168, 81–176 and L115; the dose was chosen based on the published literature of similar studies10,12,14. Rectal swabs were taken daily before and after the onset of diarrhoea to detect C. jejuni in faeces. C. jejuni WITS were inoculated by both oral and rectal gavage. For the C. jejuni M1cam Tn mutant library screen 4.7 × 108 cfu/ml was administered by oral gavage per piglet in a 1 ml volume. Piglets were examined at relevant times post infection (p.i.) for clinical signs including increased rectal temperature, diarrhoea, decreased movement and hunching. They were clinically monitored daily with rectal temperatures taken and the extent of scouring recorded. On day 5 p.i. animals were euthanized by lethal injection of Pentobarbitone sodium B.P. (approx. 200 mg/kg, Rhone Merieux) and both ileal and colonic tissue were sampled for microbiological, physiological and histopathological analysis.
Approximately 1 gram of weighed faeces per sample was homogenised and diluted for a surface plate viable count on MH blood agar. Infected tissues were washed in sterile phosphate buffered saline (PBS), cut into 1 inch sections and homogenised in sterile PBS in a stomacher. Serial dilutions of the homogenised tissue were surface plated onto MH blood agar for viable counting.
All animals were handled in strict accordance with good animal practice as defined by the relevant international (Directive of the European Parliament and of the Council on the protection of animals used for scientific purposes, Brussels 543/5) and local (Moredun Research Institute, Edinburgh, UK) animal welfare guidelines. All animal work was approved by the local ethical review committee of the Moredun Research Institute, Edinburgh, UK (Permit E37/14, Project licence number 60/4471) and was licensed by the UK Government Home Office under the Animals (Scientific Procedures) Act 1986.
Microbiology and histopathology
Ileal and colonic tissue was fixed in 10% buffered formalin solution and processed by routine methods prior to embedding in paraffin wax. Subsequently the tissue was sectioned at 5 μm and stained with haematoxylin and eosin for assessment by light microscopy.
Immunohistochemical localisation of Campylobacter spp. bacteria was performed on serial sections of ileal and colonic samples which were mounted onto Superfrost™ slides (Menzel-Gläser) and allowed to dry before placing in a 37 °C oven overnight. Sections were dewaxed in xylene and rehydrated through graded alcohols to 95% alcohol, prior to blocking endogenous tissue peroxidase activity with 3% hydrogen peroxide in methanol (v/v) for 20 min at room temperature. Subsequent to this, slides were washed in water prior to antigen retrieval which was performed by placing the slides in an autoclave for 10 min in citrate buffer pH 6.0 at 121 °C. Slides were left to cool to 50 °C and were washed twice in PBS containing 0.05% Tween-20 (PBST) before blocking non-specific binding with 25% normal goat serum in PBST for 30 min at room temperature. Slides were incubated overnight at 4 °C with mouse monoclonal BGN/2E10 (Abcam, UK) directed against C. jejuni at 1.7 μg/ml. An identical mouse isotype (IgM) antibody (Sigma M5909) was used at equivalent dilution as a negative control. Slides were washed in PBST twice before visualisation of primary antibody by applying Envision polymer (goat α-mouse-HRP) for 30 min, washed twice with PBST prior to adding Vector Nova red (Vector labs) for 10 min and subsequently washed with water. Slides were counterstained with haematoxylin for 1 min, washed in water, dehydrated through alcohols then rinsed in xylene before mounting sections in DPX (Sigma). All samples were examined by light microscopy.
Analysis of tissue integrity
Intestinal tissue mounted vertically in Ringers solution was held in a secure chamber. The muscle layer was dissected off from the mucosa before mounting, this was to ensure that only the intestinal mucosal tissue ion movement was measured. The exposed area of tissue was 0.385 cm2 and the solutions were circulated using a gas lift with carbogen. Sylgard rings were used to minimise edge damage. Short circuit current (ISC) was monitored whilst voltage-clamping (VCC600 amplifier, Physiologic Instruments) the epithelium at 0 mV, with the mucosal bath as ground. The tissue was perfused by a mixture of 5% CO2 and 95% O2 for the duration of the experiment and the electric current measured using electrodes. Any change in the ISC was detected as a change in baseline current on a graphical interface. Trans-epithelial resistance (RT) was calculated using Ohm’s law from voltage pulses of 1 mV for 0.35 msec. All readings were automatically corrected for electrode offsets and solution resistance with a Powerlab/8SP (AD Instruments). The bathing solutions (pH 7.4) were gassed at 37 °C and contained 113 mM NaCl, 4.5 mM KCl, 25 mM NaHCO3, 1.2 mM Na2HPO4, 1.1 mM CaCl2, 1.2 mM MgCl2, 10 mM glucose. Reduced chloride Ringers (18 mM chloride) were the same as the standard Ringers except the NaCl was replaced with equimolar sodium gluconate and the CaCl2 was increased to 5.7 mM (to compensate for the chelating effect of gluconate on calcium). Chloride conductance at apical membranes was measured using a chloride gradient with reduced chloride in the mucosal bath.
Analysis of C. jejuni infection dynamics using wild-type isogenic tagged strains (WITS)
C. jejuni WITS strains CC001 and CC003 are derivatives of M1 that are phenotypically identical but can be distinguished by the presence of 40 bp DNA tags inserted into a pseudogene25. The abundance of each strain present in a mixed population can be determined by qPCR as described previously25. Briefly, total DNA was extracted and a qPCR was performed using primers CC069 and either CC065 (strain CC001) or CC067 (strain CC003) (Table S3). For each primer pair a standard curve of log10 (genome copies) vs CT (threshold cycle) was generated by linear regression using known quantities of DNA prepared from each strain (~101 to 107 copies). The regression lines were used to calculate the competitive index (CI) score.
Tn mutant library screen during piglet infection
A mariner Tn mutant library suitable for read-out by Tn insertion site sequencing (Tn-seq) was generated in C. jejuni M1cam26 (derivative of M1 as reported in by Friis et al.44). Briefly, the Himar1-C9 transposase was purified as described in ref. 45 and used for the mutagenesis of C. jejuni M1cam genomic DNA with the pSV006 plasmid (mariner Tn element carrying a chloramphenicol resistance cassette with MmeI restriction sites in the inverted repeats). The mutagenized DNA was repaired by T4 DNA polymerase and E. coli DNA ligase and introduced into C. jejuni M1cam through an adapted biphasic natural transformation method46,47. Tn mutants that were obtained by selective plating were pooled to generate a large Tn mutant library of 9,951 unique Tn insertion mutants22.
The C. jejuni M1cam Tn mutant library was plated onto MH blood agar plates, grown for 48 h, re-plated onto fresh MH blood agar, grown for another 48 h, and harvested in PBS. Two groups of piglets (isolator 1: n = 11 and isolator 2: n = 10) were infected with 1 ml (=4.7 × 108 CFU) of the Tn mutant library suspension per piglet. Five days p.i., piglets were euthanized and faeces were collected from the last inch of the rectum, mixed with 5–10 ml of PBS, and 100 μl of this suspension was plated on MH blood agar. After 3 days, the recovered Tn mutants were harvested from plates in PBS and DNA was extracted using Genomic-tip 20/G columns (Qiagen).
Tn-seq27 was used to determine the relative abundance of each Tn mutant within the C. jejuni M1cam Tn library, essentially as described in ref. 48 with minor adjustments. Briefly, Tn mutant library genomic DNA was fragmented by MmeI restriction digestion, custom Tn-seq adapters with inline barcodes were ligated to the MmeI fragments, and Tn flanking sequences were amplified by PCR (see Table S3 for an overview of the oligonucleotides used). PCR amplification was performed using NEBNext High-Fidelity 2X PCR master mix (New England Biolabs). Tn-seq sequencing libraries were sequenced (50 bp single-end) on the Illumina HiSeq 2500 platform at Cancer Research UK (Cambridge). FastQ files were demultiplexed using the FastX toolkit barcode splitter and further analysed using ESSENTIALS49. The following analysis parametere were used in the ESSENTIALS analysis: sequence reads were aligned with a minimal match of 16 nt to the C. jejuni M1cam reference genome26, repeat regions were filtered, reads mapping to the 3′ end of the gene were removed, genomic position bias was corrected through Loess normalisation, read counts were normalised with the trimmed mean of M-values normalisation method (TMM). In the implemented EdgeR statistical analysis part of ESSENTIALS, the dispersion was estimated with the quantile-adjusted conditional maximum likelihood method and the variance was modelled using moderate tagwise dispersion. To identify genes of which Tn mutants showed attenuated or enriched infection of piglets, read counts were collected per gene and compared between output (piglets group 1; n = 4 and piglets group 2; n = 5) and the input (inoculum; n = 3). Selection criteria were as follows: genes represented >100 sequence reads in the input, a log2 fold-change (FC) of <−2 (attenuated survival) or >3 (enhanced survival), Benjamini & Hochberg false discovery rate <0.05, and 2 or more Tn mutants showing a log2 fold-change of <−2 or >3 (analysed using a custom Python script). The log2 fold-change cut-off was selected based on an MA-plot (Fig. S4).
In addition, 512 genes that were required for in vitro growth (“fitness” genes) were eliminated from our analysis; identified by analysing 23,334 unique C. jejuni M1 Tn insertion mutants22 using ESSENTIALS49. PCA of reads per Tn mutant, and hierarchical clustering (single linkage Euclidean distance) of log2 FC output/input was performed in the CLC Main Workbench v7.6.4. Functional class enrichment of genes implicated during infection of piglets was analysed using a Fisher-exact test and corrected for multiple testing using Q-value50. Visualization of genes required for colonisation or infection during piglet infections was performed in DNAplotter51.
Tn-seq sequencing data has been deposited in the European Nucleotide Archive (http://www.ebi.ac.uk/ena) and are available via study accession number PRJEB14716.
Statistical analysis was performed in GraphPad Prism v6.
How to cite this article: Vries, S. P. W.d. et al. Analysis of Campylobacter jejuni infection in the gnotobiotic piglet and genome-wide identification of bacterial factors required for infection. Sci. Rep. 7, 44283; doi: 10.1038/srep44283 (2017).
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Kirk, M. D. et al. World Health Organization Estimates of the Global and Regional Disease Burden of 22 Foodborne Bacterial, Protozoal, and Viral Diseases, 2010: A Data Synthesis. PLoS Med. 12, e1001921 (2015).
Taylor, D. N. Campylobacter infections in developing countries, Campylobacter jejuni: Current Status and Future Trends, eds Nachamkin, I., Blaser, M. J., Tompkins, L. S. American Society for Microbiology. New York, 20–30 (1992).
Skirrow, M. & Blaser, M. Clinical aspects of Campylobacter infection. In Nachamkin, I. Blaser, M. J. (eds) Campylobacter. Washington DC: ASM Press, pp-68-88 (2000).
Wassenaar, T. M. & Blaser, M. J., Pathophysiology of Campylobacter jejuni infections of humans. Microbes Infect. 1, 1023–1033 (1999).
Black, R. E., Levine, M. L., Clements, T. P., Hughes, M. M. & Blaser, M. J. Experimental Campylobacter jejuni infection in humans. J. Infect. Dis. 157, 472–479 (1988).
Newell, D. Animal models of Campylobacter jejuni colonization and disease and the lessons to be learned from similar Helicobacter pylori models. Symp. Ser. Soc. Appl. Microbiol. 30, 57S–67S (2001).
Stahl, M. et al. A Novel Mouse Model of Campylobacter jejuni Gastroenteritis Reveals Key Pro-inflammatory and Tissue Protective Roles for Toll-like Receptor Signaling during Infection. PLoS Pathog. 10, e1004264 (2014).
Stahl, M. & Vallance, B. A. Insights into Campylobacter jejuni colonization of the mammalian intestinal tract using a novel mouse model of infection. Gut. Microbes 6, 143–148 (2015).
Leblanc Maridor, M. et al. Experimental infection of specific pathogen-free pigs with Campylobacter: excretion in faeces and transmission to non-inoculated pigs. Vet Microbiol 131, 309–317 (2008).
Vitovec, J. et al. The gnotobiotic piglet as a model for the pathogenesis of Campylobacter jejuni infection. Zentralbl. Bakteriol. 271, 91–103 (1989).
Babakhani, F. K., Bradley, G. A. & Joens, L. A. Newborn piglet model for campylobacteriosis. Infect Immun. 61, 3466–3475 (1993).
Boosinger, T. R. & Powe, T. A. Campylobacter jejuni infections in gnotobiotic pigs. Am. J. Vet. Res. 49, 456–458 (1988).
Meurens, F., Summerfield, A., Nauwynck, H., Saif, L. & Gerdts, V. The pig: a model for human infectious diseases. Trends. Microbiol. 20, 50–57 (2012).
Tomancova, I., Koudela, B., Matyas, Z. & Vitovec, J. Dynamics of Campylobacter jejuni invasion in gnotobiotic piglets. Vet. Med. 34, 553–558 (1989).
Johnson, J. G., Livny, J. & DiRita, V. J. High-throughput sequencing of Campylobacter jejuni insertion mutant libraries reveals mapA as a fitness factor for chicken colonization. J. Bacteriol. 196, 1958–1967 (2014).
Gao, B., Lara-Tejero, M., Lefebre, M., Goodman, A. L. & Galan, J. E. (2014). Novel components of the flagellar system in epsilonproteobacteria. MBio. 5, e01349–01314 (2014).
Parkhill, J. et al. The genome sequence of the food-borne pathogen Campylobacter jejuni reveals hypervariable sequences. Nature 403, 665–668 (2000).
Korlath, J. A., Osterholm, M. T., Judy, L. A., Forfang, J. C. & Robinson, R. A. A point-source outbreak of campylobacteriosis associated with consumption of raw-milk. J. Infect. Dis. 152, 592–596 (1985).
Everest, P. et al. Differentiated Caco-2 cells as a model for enteric invasion by Campylobacter jejuni and Campylobacter coli . J. Med. Microbiol. 37, 319–325 (1992).
Westergaard, H. Bile acid malabsorption. Curr. Treat Options Gastroenterol. 10, 28–33 (2007).
Malik-Kale, P., Parker, C. T. & Konkel, M. E. Culture of Campylobacter jejuni with sodium deoxycholate induces virulence gene expression. J. Bacteriol. 190, 2286–2297 (2008).
de Vries, S. P. et al. Genome-wide fitness analyses of the foodborne pathogen Campylobacter jejuni in in vitro and in vivo models. Preprint available at BioRxiv http://dx.doi.org/10.1101/085720 (2016).
Grant, A. J. et al. Signature-tagged transposon mutagenesis studies demonstrate the dynamic nature of cecal colonization of 2-week-old chickens by Campylobacter jejuni . Appl. Environ. Microbiol. 71, 8031–41 (2005).
Hendrixson, D. R. & DiRita, V. J. Identification of Campylobacter jejuni genes involved in commensal colonization of the chick gastrointestinal tract. Mol. Microbiol. 52, 471–84 (2004).
Coward, C. et al. Competing isogenic Campylobacter strains exhibit variable population structures in vivo . Appl. Environ. Microbiol. 74, 3857–3867 (2008).
de Vries, S. P. et al. Motility defects in Campylobacter jejuni defined gene deletion mutants caused by second-site mutations. Microbiology 161, 2316–2327 (2015).
van Opijnen, T. Bodi, K. L. & Camilli, A. Tn-seq: high-throughput parallel sequencing for fitness and genetic interaction studies in microorganisms. Nat. Methods 6, 767–772 (2009).
Ewing, C. P., Andreishcheva, E. & Guerry, P. Functional characterization of flagellin glycosylation in Campylobacter jejuni 81–176. J. Bacteriol. 19, 7086–7093 (2009).
Karlyshev, A. V., Linton, D., Gregson, N. A. & Wren, B. W. A novel paralogous gene family involved in phase-variable flagella-mediated motility in Campylobacter jejuni . Microbiology 148, 473–480 (2002).
McNally, D. et al. Functional characterization of the flagellar glycosylation locus in Campylobacter jejuni 81-176 using a focused metabolomics approach. J. Biol. Chem. 281, 18489–18498 (2006).
Karlyshev, A. V. et al. The Campylobacter jejuni general glycosylation system is important for attachment to human epithelial cells and in the colonization of chicks. Microbiology 150, 1957–1964 (2004).
Stahl, M., Butcher, J. & Stintzi, A. Nutrient acquisition and metabolism by Campylobacter jejuni . Front Cell Infect. Microbiol. 2, 5 (2012).
Hofreuter, D. Defining the metabolic requirements for the growth and colonization capacity of Campylobacter jejuni . Front Cell Infect. Microbiol. 4, 137 (2014).
Weingarten, R. A., Taveirne M. E. & Olson, J. W. The dual-functioning fumurate reductase is the sole succinate:quinone reductase in Campylobacter jejuni and is required for full host colonisation. J. Bacteriol. 191, 5293–5300 (2009).
Woodall, C. A. et al. Campylobacter jejuni gene expression in the chick cecum: evidence for adaptation for a low-oxygen environment. Infect. Immun. 73, 5278–5285 (2005).
Wright, J. A. et al. Metabolite and transcriptome analysis of Campylobacter jejuni in vitro growth reveals a stationary-phase physiological switch. Microbiology 155, 80–94 (2009).
Hugdahl, M. B., Beery, J. T. & Doyle, M. P. Chemotactic behavior of Campylobacter jejuni . Infect. Immun. 56, 1560–1566 (1988).
Hodson, A. Z. Amino acid content of evaporated milk on prolonged storage. Ind. Eng. Chem. 42, 694–695 (1950).
Guccione, E. et al. Amino acid-dependent growth of Campylobacter jejuni: key roles for aspartase (AspA) under microaerobic and oxygen-limited conditions and identification of AspB (Cj0762), essential for growth on glutamate. Mol. Microbiol. 69, 77–93 (2008).
Hofreuter, D., Novik, V. & Galán, J. E. Metabolic diversity in Campylobacter jejuni enhances specific tissue colonization. Cell Host Microbe 4, 425–433 (2008).
Rahman, H. et al. Characterisation of a multi-ligand binding chemoreceptor CcmL (Tlp3) of Campylobacter jejuni . PLoS. Pathog. 10, e1003822 (2014).
Reid, A. N., Pandey, R., Palyada, K., Naikare, H. & Stintzi, A. Identification of Campylobacter jejuni genes involved in the response to acidic pH and stomach transit. Appl. Environ. Microbiol. 74, 1583–1597 (2008).
MacCallum, A., Hardy, S. P. & Everest, P. H. Campylobacter jejuni Inhibits the Absorptive Transport Functions of Caco-2 Cells and Disrupts Cellular Tight Junctions. Microbiology 151, 2451–2458 (2005).
Friis, C. et al. Genomic characterization of Campylobacter jejuni strain M1. PLoS. One 5, e12253 (2010).
Akerley, B. J. & Lampe, D. J. Analysis of gene function in bacterial pathogens by GAMBIT. Methods Enzymol. 358, 100–108 (2002).
Holt, J. P., Grant, A. J., Coward, C., Maskell, D. J. & Quinlan, J. J. Identification of Cj1051c as a major determinant for the restriction barrier of Campylobacter jejuni strain NCTC11168. Appl. Environ. Microbiol. 78, 7841–7848 (2012).
van Vliet, A. H., Wood, A. C., Henderson, J., Wooldridge, K. G. & Ketley, J. M. Genetic manipulation of enteric Campylobacter species. In Methods in microbiology, pp. 405–419. Edited by P. Williams, J. Ketley & G. Salmond . London, England: Academic press (1998).
Burghout, P. et al. Streptococcus pneumoniae folate biosynthesis responds to environmental CO2-levels. J. Bacteriol. 195, 1573–1582 (2013).
Zomer, A., Burghout, P., Bootsma, H. J., Hermans, P. W. M. & van Hijum, S. A. ESSENTIALS: software for rapid analysis of high throughput transposon insertion sequencing data. PLoS. One. 7, e43012 (2012).
Storey, J. D. & Tibshirani, R. Statistical significance for genomewide studies. Proc. Natl. Acad. Sci. USA 100, 9440–9445 (2003).
Carver, T., Thomson, N., Bleasby, A., Berriman, M. & Parkhill, J. DNAPlotter: circular and linear interactive genome visualization. Bioinformatics 25, 119–120 (2009).
We thank Gemma Murray from the Department of Genetics, University of Cambridge for providing the R script used for COG assignment. The authors would like to thank Jeanie Finlayson (Moredun Research Institute) for expert histological and immunohistological preparations. This work was funded by BBSRC awards BB/F020988/1 and BB/K004514/1. Moredun Research Institute receives funding via Rural and Environment Science and Analytical Services (RESAS) division of the Scottish Government. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
The authors have read the journal’s policy and have the following conflicts: Dr. Chris Coward is currently employed by Discuva Ltd, though he was employed by the University of Cambridge at the time that the work was conducted.
About this article
Cite this article
de Vries, S., Linn, A., Macleod, K. et al. Analysis of Campylobacter jejuni infection in the gnotobiotic piglet and genome-wide identification of bacterial factors required for infection. Sci Rep 7, 44283 (2017). https://doi.org/10.1038/srep44283