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      Epidemiology and antimicrobial resistance of Campylobacter spp. in animals in Sub-Saharan Africa: A systematic review

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          Abstract

          Introduction

          Low sanitary conditions characterize the rural and urban households in Sub-Saharan African region. Those environmental conditions propitiate the transmission of bacterial infections between animals and humans. Campylobacter spp. is a zoonotic bacterium and cause of human gastroenteritis worldwide, whose main symptom is diarrhea. It is normally found in the digestive tract of many farm animals as a commensal but some species cause diseases in animals. It is important to understand the occurrence of these bacteria in animals, as they may also play a role in transmission to humans. The main objective of this review was to describe the prevalence of Campylobacter in animals in Sub-Saharan Africa. We also report findings on antibiotic resistance.

          Methods

          We followed PRISMA guidelines to find studies about occurrence of Campylobacter spp. in animals in all countries from Sub-Saharan Africa. PubMed, Cochrane Library, CINAHL, African Index Medicus, African Journals Online, Google Scholar and Science Direct were searched for studies published between 2000 and 2019.

          Results

          We found 70 studies that described occurrence of Campylobacter spp. in animals in 18 out of 53 countries of Sub-Saharan Africa. Campylobacter jejuni and C. coli were the predominant species isolated. The majority of studies were found in Western Africa. Middle Africa had the lowest amount of data. Most records presented data from Nigeria (n = 25), South Africa (n = 14) and Tanzania (n = 11). Cattle and chickens appear to be important hosts and may be playing an important role in transmitting to humans. Most Campylobacter isolates were resistant to erythromycin (44%), ampicillin (39%), tetracycline (33%), nalidixic acid (31%) and ciprofloxacin (30%).

          Conclusion

          Several studies about Campylobacter spp. in animals have been published in the last 19 years but information on the epidemiology of campylobacteriosis is scarce in most Sub-Saharan African countries. Antibiotic resistance is an increasing concern in many countries. Measures should be taken to prevent infection by this pathogen in the region and to control antibiotic resistance.

          Abstract

          Microbiology; Epidemiology; Infectious disease; Public health; Campylobacter spp.; Antibiotic resistance; Africa.

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          Most cited references85

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          Campylobacter genotyping to determine the source of human infection.

          Campylobacter species cause a high proportion of bacterial gastroenteritis cases and are a significant burden on health care systems and economies worldwide; however, the relative contributions of the various possible sources of infection in humans are unclear. National-scale genotyping of Campylobacter species was used to quantify the relative importance of various possible sources of human infection. Multilocus sequence types were determined for 5674 isolates obtained from cases of human campylobacteriosis in Scotland from July 2005 through September 2006 and from 999 Campylobacter species isolates from 3417 contemporaneous samples from potential human infection sources. These data were supplemented with 2420 sequence types from other studies, representing isolates from a variety of sources. The clinical isolates were attributed to possible sources on the basis of their sequence types with use of 2 population genetic models, STRUCTURE and an asymmetric island model. The STRUCTURE and the asymmetric island models attributed most clinical isolates to chicken meat (58% and 78% of Campylobacter jejuni and 40% and 56% of Campylobacter coli isolates, respectively), identifying it as the principal source of Campylobacter infection in humans. Both models attributed the majority of the remaining isolates to ruminant sources, with relatively few isolates attributed to wild bird, environment, swine, and turkey sources. National-scale genotyping was a practical and efficient methodology for the quantification of the contributions of different sources to human Campylobacter infection. Combined with the knowledge that retail chicken is routinely contaminated with Campylobacter, these results are consistent with the view that the largest reductions in human campylobacteriosis in industrialized countries will come from interventions that focus on the poultry industry.
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            Campylobacter jejuni Is Not Merely a Commensal in Commercial Broiler Chickens and Affects Bird Welfare

            INTRODUCTION Campylobacter jejuni is the most frequent cause of food-borne bacterial gastroenteritis in the world, estimated to infect 1% of the European Union (EU) population each year. Chicken is the single largest source of infection, with approximately 80% of retail poultry carcasses contaminated in the EU (1). C. jejuni colonizes the chicken gut, primarily the large blind ceca at the distal end of the gastrointestinal tract to levels in excess of 109 CFU/g. Campylobacter is rapidly transmitted horizontally through broiler (meat-producing) flocks as a consequence of fecal shedding of the bacterium and the coprophagic behavior of the chicken. Control of C. jejuni infection focuses on all stages of poultry production and has largely involved attempts to limit exposure of broilers during the rearing cycle and/or carcass treatments to reduce contamination levels at slaughter. To date, no interventions have been shown to be fully successful under commercial conditions. For control to be more effective, it is essential that the infection biology of C. jejuni in the chicken is well understood. However, at this time, our understanding is still surprisingly limited. Indeed, the immune response to C. jejuni in the chicken and the role that this plays in colonization, pathogenesis, and possible clearance of infection has not been well explored beyond a few descriptive studies. C. jejuni is often considered to be a harmless commensal inhabitant of the chicken gut, and the immune response to it in the intestinal tract is thought to be tolerogenic (2). However, it has been shown previously that C. jejuni is recognized by Toll-like receptor 4 (TLR4) and TLR21, the latter being the functional equivalent of mammalian TLR9. This leads to initiation of innate immune responses in the gut that cause an influx of inflammatory cells, including heterophils, the avian equivalent of the neutrophil (3 – 5). C. jejuni infection may also affect the structure of the chicken intestinal epithelium (6). The innate responses lead to adaptive responses that can be measured as both mucosal and systemic specific antibodies (7 – 9). Studies of T lymphocyte function in the gastrointestinal tract during C. jejuni infection are very limited, although T cell responses have been shown in the liver during invasive infections (10). One potential criticism of the past work is that many studies used specific-pathogen-free (SPF) chickens with high challenge doses that have only limited relevance to infection and immunity in commercial broiler breeds. Modern broilers, as exemplified by the A1 and A2 and the C line birds tested in this study, have been bred to grow rapidly and to convert feed into muscle tissue efficiently while keeping high conformity of size and shape to facilitate slaughter and production processes. Such birds reach slaughter weights of approximately 2.2 kg at ~36 days of age. The downside of selective breeding in order to achieve the above production goals are several welfare-associated conditions in these birds, ranging from musculoskeletal disorders to gastrointestinal problems. In contrast, traditional breeds such as the White Leghorn and Light Sussex used in SPF flocks grow far more slowly and have better health but greatly lower productivity levels than modern commercial breeds. Some commercial chicken production systems considered to be “higher welfare” use broilers that grow more slowly, reaching slaughter weight in 50 or more days and usually at reduced stocking densities, typically 30 to 34 kg/m2, and with natural light sources. The same breeds may also be used in extensive production. However, such “higher-welfare” systems constitute only a small fraction of total commercial production at present, and faster-growing birds are used in the majority of “standard” intensive production systems where stocking densities of up to 40 kg/m2 are employed. Our previous work on commercial produced broilers found that high levels of hock marks and pododermatitis in flocks were highly significant risk factors for Campylobacter colonization. Hock marks or hock burn are marks found on the legs of chickens where ammonia from the waste of other chickens within the litter causes burns. Pododermatitis or foot pad dermatitis is a thickening (keratitis) and discoloration of the foot pad and in more severe cases, lesions of the foot pad of the bird caused through poor-quality or wet litter with high ammonia content. These conditions are more common in the faster-growing broilers, as is Campylobacter infection (11, 12). Colles et al. (13) also found an association between hock marks and Campylobacter infection in a free-range flock in the United Kingdom. Conditions such as hock marks and pododermatitis can be indicative of poor gut health, leading to wet feces and poor-quality litter that in turn lead to damage of the feet and lower legs of the chickens. It was our assumption that the link with Campylobacter was associated with the bacterium better colonizing the damaged gut. This may be the case, but previous preliminary studies have shown that C. jejuni directly contributes to poor gut health. These studies found that broilers experimentally infected with C. jejuni M1 had significantly higher levels of hock marks and pododermatitis than uninfected controls did. The effects of infection were especially marked in one of the breeds tested (14). We hypothesize that in some modern broiler breeds, C. jejuni infection compromises gut health, leading to diarrhea, which indirectly, through wet litter, causes leg health problems in these birds. These conditions are a major bird welfare issue in international chicken production. The aims of the work presented here were to identify mechanisms underlying the observed differences in broiler types in their responses to C. jejuni and to examine the impact of infection on gut health and animal welfare. RESULTS Broiler breed has little impact on C. jejuni colonization of the ceca following experimental infection. Broiler breed had no significant impact on C. jejuni M1 levels in ceca following experimental infection of broiler chickens (Table 1), nor was there a statistically significant (P = 0.068) impact on C. jejuni numbers in this gut compartment at slaughter age (Table 2). Performance data for the birds are summarized in Materials and Methods. TABLE 1  Broiler breed does not significantly affect cecal colonization with C. jejuni M1 Breed Median C. jejuni M1 cecal content (CFU ⋅ g−1) [range] Colonization rate (no. of chickens/total no. of chickens) 2 dpi 5 dpi 12 dpi 2 dpi 5 dpi 12 dpi A1 4.62 × 107 [0.00−3.73 × 108] 5.67 × 107 [1.14 × 106−5.00 × 108] 4.34 × 107 [1.74 × 106−1.35 × 108] 9/10 10/10 10/10 A2 3.14 × 107 [1.67 × 106−7.58 × 108] 1.37 × 108 [0.00−3.29 × 108] 5.98 × 107 [5.04 × 105−2.71 × 108] 9/9 7/9 9/9 B1 1.88 × 108 [0.00−7.58 × 108] 1.13 × 108 [0.00−3.04 × 109] 2.20 × 107 [7.44 × 105−1.32 × 108] 8/10 7/10 10/10 B2 1.86 × 108 [2.06 × 104−6.87 × 108] 2.62 × 105 [0.00−7.60 × 108] 1.30 × 107 [0.00−6.36 × 107] 10/10 5/10 9/10 TABLE 2  Levels of C. jejuni M1 in ceca of broilers grown to commercial slaughter age under experimental conditions Breed Slaughter age (days) Median C. jejuni M1 cecal content (CFU ⋅ g−1) [range] A1 35 2.88 × 107 [4.58 × 105−1.93 × 108] C 36 3.84 × 107 [8.78 × 105−6.86 × 108] A2 39 4.94 × 106 [3.08 × 104−2.00 × 107] B1 48 5.30 × 106 [3.38 × 103−2.00 × 108] B2 56 1.22 × 107 [1.49 × 105−5.77 × 108] C. jejuni elicits early innate immune activation and an inflammatory response in broilers, which remains elevated for longer in the fast-growing breed A1. The innate immune responses to C. jejuni M1 was examined in detail in birds from the A1, A2, B1, and B2 lines. Infection elicited expression of the proinflammatory chemokines CXCLi1 (chemokine [C-X-C] motif) ligand i1) (Fig. 1a.i), CXCLi2 (Fig. 1b.i), and interleukin-1β (IL-1β) (Fig. 1c.i) in the ceca of all breeds at 2 days postinfection (dpi). CXCLi2 expression was also detected in the ileum (Fig. 2a). By 5 dpi, these responses were reduced (Fig. 1a.ii,  b.ii, and c.ii) with the exception of the A1 birds in which the levels of expression of all three inflammatory mediators remained significantly higher than in the other birds (CXCLi1 [P = 0.017], CXCLi2 [P < 0.000], and IL-1β [P = 0.012]). By 12 dpi, expression of CXCLi2 remained higher in the C. jejuni-infected A1 group than in the other bird types (A2 [P = 0.027] and B2 [P = 0.019]), although IL-1β expression was reduced (Fig. 1b.iii and c.iii). All four bird breeds showed expression of CXCLi1 at 12 dpi, but with no significant differences (P = 0.339) between them (Fig. 1a.iii). FIG 1  Expression of proinflammatory cytokines and chemokines in cecal tissue following C. jejuni M1 infection. (a to c) Fold changes in expression of chemokines CXCLi1 (a) and CXCLi2 (b) and cytokine IL-1β (c) in cecal tissue were examined at 2 (i), 5 (ii), and 12 (iii) dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. A white bar represents the median value for each group. Significance of differences between the groups was examined using a Kruskal-Wallis test. FIG 2  Expression of proinflammatory chemokine CXCLi2 in ileal tissue following C. jejuni M1 infection. (a to c) Fold changes in expression of CXCLi2 in ileal tissue were examined at 2 (a), 5 (b), and 12 (c) dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. A white bar represents the median value for each group. Significance of differences between the groups was examined using a Kruskal-Wallis test. These findings show that the four breeds tested express key inflammatory signals in the innate immune system early after oral infection with C. jejuni, but these inflammatory signals are elevated in the A1 birds for much longer. There were no differences in basal constitutive expression of these genes in uninfected control birds of each breed. Considerable variation could be seen in the response between individuals within groups. This is perhaps not surprising, given that these are outbred commercial animals with inherent genetic differences between individuals, although the use of a relatively large group size reduces the impact of such variation. Histological examination of the ilea and ceca of uninfected birds of all breeds identified an apparently constitutive mild diffuse lymphoplasmacellular mucosal infiltration (Fig. 3A, B, E and G). Following infection of the fastest (A1) and slowest (B2) growing birds, increased numbers of inflammatory cells, heterophils, and lymphocytes were seen (Fig. 3C, D, F, and H), commensurate with the cytokine responses seen at 5 dpi. In both breeds, there was evidence of mucosal damage, notably thickening, shortening, and fusion of villi in the ileum (Fig. 3C and D). This was more frequently observed and more intense in the A1 breed where such pathological changes were seen in 7 of 10 birds. In contrast, in the B2 group, only 3 of 10 birds showed morphological evidence of mucosal damage and inflammation. A similar pattern was seen at 12 dpi. These data indicate that the infection resulted in damage and inflammatory infiltration of the intestinal mucosa of both bird types, but that they were more common and more intense in the faster-growing breed (A1). FIG 3  Histological features in control and infected animals at day 5 postinfection. (A to D) Ileum sections from chickens. (A and B) Uninfected control animals of breed A1 (A) and B2 (B). Slim, slender villi with moderate (score 2) lymphocyte and plasma cell infiltration and mild (score 1) heterophil infiltration. (C and D) Infected animals. Villi are thickened (score 2) due to marked (score 3) lymphocyte and plasma cell infiltration and moderate (score 2) heterophil infiltration (arrows) and appear slightly shorter. (E to H) Cecum sections from breed A1 (E and F) and B2 (G and H). Control animals (E and G) exhibit moderate (score 2) lymphocyte and plasma cell infiltration and mild heterophil (score 1) infiltration. In infected animals (F and H), there is increased leukocyte infiltration, with marked (score 3) lymphocyte and plasma cell infiltration and moderate (score 2) heterophil infiltration. Prolonged inflammation in the intestines of faster-growing breeds of chickens results in diarrhea and affects their welfare. By 12 dpi, the infected A1 birds were found to have diarrhea when examined during twice-daily welfare checks and at ante mortem examination where fecal pasting of feathers around the cloaca consistent with diarrhea was found. Similar observations were also made in C birds infected to examine longer-term carriage. Although feces were generally wetter in A1 birds than in other breeds, no diarrhea was seen in the control group. Diarrhea was not seen in the A2 or B birds. At postmortem examination, A1 birds were found to have more watery intestinal contents and some evidence of inflammation, such as mild hyperemia of the cecal wall. Diarrhea in the A1 birds corresponds to the greater and prolonged inflammatory response seen in this breed. Furthermore, despite birds being maintained under experimental conditions, including regular changes of litter, 9 of 10 C. jejuni-infected A1 birds showed signs of pododermatitis at 12 dpi. In contrast, only 2 of 10 infected B1 bird and 2 of 9 infected A2 birds had pododermatitis. This condition was not seen in the infected B2 group. Disease in some broiler breeds is a consequence of immune dysregulation in the intestine. Differential expression of IL-10 in breeds was seen in the ceca at 12 dpi (Fig. 4a) with a median 50-fold increase in expression in the slower-growing B2 birds, significantly higher than the minimal levels in the A1 animals (P = 0.003) (see Fig. S1 in the supplemental material). Expression in the A2 and B1 birds was intermediate between these extremes. IL-10 is a key regulatory cytokine in controlling inflammation. The absence of IL-10 expression in the A1 birds indicates that inflammatory responses in the intestine are poorly regulated, leading to prolonged inflammation and diarrhea, as described above. A similar, but not statistically significant (P = 0.068) pattern of expression was also seen for gamma interferon (IFN-γ) (Fig. 4B), suggesting that there may be further variation between breeds in their T lymphocyte function (see Fig. S2 and S3 in the supplemental material). FIG 4  Expression of TH1 and regulatory cytokines in cecal tissue following C. jejuni M1 infection. (a) Fold changes in expression of the regulatory cytokine IL-10 in tissue were examined at 12 dpi. (b) Fold changes in expression of the TH1-biased cytokine IFN-γ were also examined at 12 dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. A white bar represents the median value for each group. Significance of differences between the groups was examined using a Kruskal-Wallis test. Although there was variation in inflammatory and regulatory responses in the gut, all breeds produced specific IgM and IgG antibodies at similar titers following infection (data not shown). DISCUSSION Our work shows that C. jejuni cannot be regarded as simply a harmless gut commensal of some modern commercial broiler chickens. Infection of broiler chickens is clearly associated with intestinal inflammation. While the possibility of this response involving some interaction with other bacteria in the intestinal microbiota cannot be ruled out, it is clear that the infection with C. jejuni is essential in causing the inflammation described. In the fast-growing A1 breed, this inflammation is prolonged, leading to diarrhea and subsequent associated pathology to the feet and legs of these birds. Diarrhea was also seen in breed C birds, but detailed innate immune responses in this breed were not examined because of logistical constraints. Detailed examination of responses to infection in four broiler breeds found that C. jejuni M1 elicited an inflammatory innate immune response in the intestinal tract, which led to a specific antibody response. Intestinal disease in the A1 birds appears to be a consequence of a poorly regulated immune response, as expression levels of proinflammatory signals such as CXCL chemokines and IL-1β remain higher than in the three other breeds at 5 and 12 dpi. In contrast, IL-10 expression is significantly higher in B2 birds at 12 dpi, suggesting that it is much better able to regulate its inflammatory response and that dysregulation of this in A1 birds leads to infection-mediated pathology in the lower intestinal tract. The importance of IL-10 in regulating C. jejuni enteritis has been shown in the C57BL/6 IL-10−/− mice used as model for acute enterocolitis (15, 16). While both control and IL-10-deficient C57BL/6 mice can be colonized by C. jejuni, only C57BL/6 IL-10−/− mice develop enteritis (17). The data presented here show that there is no intrinsic difference in the susceptibility of broiler breeds to C. jejuni under experimental conditions. As such, it is unclear as to whether any change in the current broiler breed type will have any impact on public health. However, breeding chickens resistant to Campylobacter infection is considered, along with vaccination, to be a potential long-term intervention in controlling these bacteria in chicken production (18, 19). Studies using inbred and outbred lines of chicken have indicated that differences in innate immunity, particularly β-defensins secreted in the gut, may hold the key to resistance (20). However, more-detailed transcriptional studies of the response to C. jejuni in two broiler lines differing in resistance to colonization indicate that there is greater activity of regulatory T lymphocytes in the more resistant line (20, 21). T regulatory cells (or TRegs) are important in maintaining gut homeostasis and regulating the response to infection of the chicken and other species through production of cytokines such as IL-10 and tumor growth factor beta (TGF-β). Taken with our data on expression of IL-10, it appears that regulation of responses through T regulatory lymphocytes is key to both maintaining a healthy gut and reducing colonization by C. jejuni following infection. As such, we suggest that certain faster-growing breeds of broiler chicken, such as the A1 breed, have a functional innate response to Campylobacter infection but do not have an effective T regulatory one, leading to the pathological changes we have seen. This dysfunction, if it occurs with other enteric pathogens, may also lead to inflammatory damage in the intestinal tract under production conditions. In our past work (11, 12), we did not ascertain whether pododermatitis and hock marks, linked to an increased risk of Campylobacter infection, preceded infection or occurred because of it. Data presented here show that C. jejuni makes a direct contribution to this condition. The immune dysfunction we have seen in response to C. jejuni does not seem to be linked to more rapid growth per se and is more likely to be related to the genetic background of the birds, as this will differ even in animals bred by the same company. Such information is commercially sensitive and therefore not freely available. In summary, we show that C. jejuni is not merely a harmless commensal of the broiler chicken and that infection can lead to diarrhea and inflammatory damage in the birds. Although previous studies have shown that there is an inflammatory response to Campylobacter infection in the chicken, the immune response in the gut has been considered largely “tolerogenic,” allowing the bacteria to remain in the intestine in the absence of any pathological changes or systemic infection. Indeed, it may be that the “natural” immune response to C. jejuni in the chicken is centered upon confining the pathogen to the intestine where it persists and that the response in the gut is tightly regulated to prevent excessive inflammation, which in traditional chicken breeds leads to little or no ill effect on the bird. However, in modern broiler breeds, the drive toward improved productivity and carcass conformity would appear to have had a negative impact on T lymphocyte function, leading to a loss of immune regulation in the gut. The result of this imbalance is that C. jejuni infection results in poorly controlled inflammation, leading to intestinal mucosal damage and diarrhea. MATERIALS AND METHODS Bacterial strains and culture conditions. C. jejuni M1 was kindly provided by Lisa Williams (University of Bristol). Bacteria were grown from stocks maintained at −80°C on Columbia blood agar (Lab M, Heywood, Lancashire, United Kingdom) supplemented with 5% defibrinated horse blood (Oxoid, Basingstoke, Hampshire, United Kingdom) for 48 h in microaerobic conditions (80% N2, 12% CO2, 5% O2, and 3% H2) at 41.5°C. Liquid cultures were grown for 24 h in 10 ml of Mueller-Hinton broth (MHB) in microaerobic conditions at 41.5°C and adjusted by dilution in fresh MHB to a final concentration of 106 CFU/ml. Experimental animals. All work was conducted in accordance with United Kingdom legislation governing experimental animals under project licenses PPL 40/3063 (experiment 1) and 40/3652 (experiment 2) and was approved by the University of Liverpool ethical review process prior to the award of the licenses. All animals were checked a minimum of twice daily to ensure their health and welfare. Five common broiler breeds were used. Data from the breeding companies state that the A1 bird reaches live slaughter weight (2.2 kg) at 36 days of age, as does the breed C bird. The A2 bird reaches 2.2 kg at 37 days, while the B1 and B2 birds take 48 and 56 days to reach this weight, respectively. Not all breeds were used in all experiments, and the decision to use breed A birds for detailed examination, rather than the C line, was based on current market share in the United Kingdom, where many more breed A birds are reared. Age-matched, 1-day-old chicks of broiler chickens were obtained from a commercial hatchery. Chicks were housed in the University of Liverpool high-biosecurity poultry unit. Chicks were maintained in floor pens at stocking levels recommended by the Home Office, allowing floor space of 2,000 cm2 per bird for all groups and were given ad libitum access to water and a pelleted laboratory-grade vegetable protein-based diet (SDS, Witham, Essex, United Kingdom) with a feeder and drinker available per 15 birds. Chicks were housed in separate groups at a temperature of 30°C, which was reduced to 20°C at 3 weeks of age. Each infected group was housed in a single room with filtered air supply with lobbied entry to each room and dedicated protective clothing and boots. Two control groups were housed in separate pens in an individual room. Prior to experimental infection, all birds were confirmed as Campylobacter free by taking cloacal swabs, which were streaked onto selective blood-free agar (modified charcoal-cefoperazone-deoxycholate agar [mCCDA]) supplemented with Campylobacter Enrichment Supplement (SV59; Mast Group, Bootle, Merseyside, United Kingdom) and grown for 48 h in microaerobic conditions at 41.5°C. All microbiological media were purchased from Lab M (Heywood, Lancashire, United Kingdom). Throughout the experiment, litter was changed every 4 days, and pens were cleaned to limit retransmission within groups and to reduce problems associated with wet litter. Effect of broiler breed on C. jejuni infection (experiment 1). When the chicks were 21 days old, A1 (n = 40), A2 (n = 38), B1 (n = 40), and B2 (n = 40) broilers were orally infected with 105 cells of C. jejuni M1 in 0.2 ml of MHB. Control birds (A1 [n = 16], A2 [n = 15], B1 [n = 15], and B2 [n = 16]) received 0.2 ml of sterile MHB. At 2, 5, and 12 dpi, 10 infected birds and 5 control birds of each breed were killed by cervical dislocation. At postmortem examination, samples of tissue and gut contents were taken and processed for host gene expression analysis, histology, and Campylobacter enumeration. Assessment of C. jejuni load. In order to determine the levels of C. jejuni colonization in each of the breeds, cecal contents were collected from individual birds at necropsy and diluted in 9 volumes of maximal recovery diluent (MRD). Serial 10-fold dilutions were made of each sample in MRD, and using the method of Miles et al. (22), duplicate 50-µl spots were plated onto mCCDA agar supplemented with SV59. The plates were incubated under microaerobic conditions at 41.5°C for 48 h, and Campylobacter colonies were enumerated to give CFU/g of cecal contents. RNA extraction and real-time qRT-PCR. Samples of ileal and cecal tissue from infected and control birds were collected and stored in 500 µl of RNAlater at −20°C (Sigma, Poole, Dorset, United Kingdom). Total RNA was isolated from 20 to 30 mg of tissue using an RNeasy minikit (Qiagen, West Sussex, United Kingdom) according to the manufacturer’s instructions. Isolated RNA was eluted into 50 µl RNase-free water and stored at −80°C. The yield of total RNA was determined using a NanoDrop (ND-1000) spectrophotometer. Expression of mRNA for the cytokines interleukin-1β (IL-1β), gamma interferon (IFN-γ), IL-10, and IL-4 and the chemokines CXCLi1 (chemokine [C-X-C motif] ligand i1) and CXCLi2 in these tissues was measured by real-time quantitative reverse transcription-PCR (qRT-PCR), using primer and probe sequences described by Shini and Kaiser (23). 28S rRNA was used as the housekeeping gene. Twenty-microliter  reaction mixtures for one-step qRT-PCR were prepared using the RotorGene Probe RT-PCR kit (Qiagen, West Sussex, United Kingdom) and contained 1 µl of total RNA (at 20 ng/µl), 10 µl of RotorGene Probe RT-PCR master mix, 0.2 µl of RotorGene reverse transcriptase enzyme mix, 1.6 µl of each primer (at 10 µM), 0.8 µl of probe (at 5 µM), and 4.8 µl of RNase-free water. Triplicate reactions were set up for each sample using an automated QIAgility system (Qiagen, West Sussex, United Kingdom). Real-time RT-PCR was performed on a RotorGene Q system (Qiagen, West Sussex, United Kingdom) with the following reaction profile: 50°C for 10 min to facilitate reverse transcription of RNA to cDNA, followed by 95°C for 5 min, and 40 repeat cycles, with 1 cycle consisting of 95°C for 5 s and 60°C for 10 s. Expression of the target gene was determined using the cycle threshold (C T ) value relative to that for the 28S rRNA reference gene (ΔC T ). Results are expressed as fold changes in corrected target gene expression (ΔC T ) in infected animals relative to the control animals (2−ΔΔCT). Histology. Samples of ileum and cecum from the two breeds displaying the most extreme differences in cytokine response in the experiments, A1 and B2, were examined for histological assessment. These samples were obtained from the same infected and uninfected birds used for cytokine analysis. Tissue samples were fixed in 4% (wt/vol) paraformaldehyde in phosphate-buffered saline (PBS) and routinely embedded in paraffin wax. Sections (3 to 5 µm thick) were prepared and stained with hematoxylin and eosin (H&E) using standard protocols. Tissue sections were assessed in a blind manner by veterinary pathologists for any pathological changes and the semiquantitative analysis of the inflammatory infiltrate, represented by grading the degree of heterophil and lymphoplasmacellular infiltration as follows: 1 for slight infiltration, 2 for mild infiltration, 3 for moderate infiltration, 4 for marked infiltration, and 5 for severe infiltration. C. jejuni carriage at slaughter age (experiment 2). When the chicks were 21 days old, A1 (n = 7), C (n = 9), A2 (n = 9), B1 (n = 9), and B2 (n = 10) birds were orally infected with 105 cells of C. jejuni M1 in 0.2 ml of MHB. The birds were grown to their commercial slaughter ages (36 days for A1 breed, 36 days for C, 37 days for A2, 48 days for B1, and 56 days for B2]) and were killed by cervical dislocation. At postmortem examination, the contents were taken from both ceca for Campylobacter enumeration using the method described above. Original groups contained 10 birds, but because of welfare concerns unrelated to C. jejuni infection, some birds were culled prior to the end of the experiment. Statistical analyses. Statistical analyses were performed using SPSS v20 (IBM). For comparison of bacterial loads between infected groups and fold changes in cytokine expression between breeds, the Kruskal-Wallis (nonparametric analysis of variance [ANOVA]) test was applied, as the data were not normally distributed. Differences were considered significant where P < 0.05. SUPPLEMENTAL MATERIAL Figure S1 Expression of IL-10 in ileal tissue following C. jejuni M1 infection. (a to c) Fold changes in expression of IL-10 in ileal tissue were examined at 2 (a), 5 (b) and 12 (c) dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. Each bar represents the median value for each group. Significance of differences between the groups was examined using a Kruskal-Wallis test. Download Figure S1, TIF file, 4.4 MB Figure S2 Expression of IFN-γ in ileal tissue following C. jejuni M1 infection. (a to c) Fold changes in expression of IFN-γ in ileal tissue were examined at 2 (a), 5 (b) and 12 (c) dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. Each bar represents the median value for each group. Significance of differences between the groups was examined using a Kruskal-Wallis test. Download Figure S2, TIF file, 4.4 MB Figure S3 Expression of IL-4 in cecal tissue following C. jejuni M1 infection. (a to c) Fold changes in expression of IL-4 in cecal tissue were examined at 2 (a), 5 (b), and 12 (c) dpi. At each time point, group sizes were as follows for the different breeds: n = 10 for breed A1, n = 9 for breed A2, n = 10 for breed B1, and n = 10 for breed B2. Each symbol represents the value for an individual chicken. Each bar represents the median value for each group.Significance of differences between the groups was examined using a Kruskal-Wallis test. Download Figure S3, TIF file, 4.4 MB
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              Cryptic ecology among host generalist Campylobacter jejuni in domestic animals

              Homologous recombination between bacterial strains is theoretically capable of preventing the separation of daughter clusters, and producing cohesive clouds of genotypes in sequence space. However, numerous barriers to recombination are known. Barriers may be essential such as adaptive incompatibility, or ecological, which is associated with the opportunities for recombination in the natural habitat. Campylobacter jejuni is a gut colonizer of numerous animal species and a major human enteric pathogen. We demonstrate that the two major generalist lineages of C. jejuni do not show evidence of recombination with each other in nature, despite having a high degree of host niche overlap and recombining extensively with specialist lineages. However, transformation experiments show that the generalist lineages readily recombine with one another in vitro. This suggests ecological rather than essential barriers to recombination, caused by a cryptic niche structure within the hosts.
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                Author and article information

                Contributors
                Journal
                Heliyon
                Heliyon
                Heliyon
                Elsevier
                2405-8440
                09 March 2020
                March 2020
                09 March 2020
                : 6
                : 3
                : e03537
                Affiliations
                [a ]Department of Biological Sciences, Faculty of Sciences, Eduardo Mondlane University, Maputo, Mozambique
                [b ]Faculty of Veterinary Science, Eduardo Mondlane University, Maputo, Mozambique
                [c ]Centro de Investigação em Saúde de Manhiça, Maputo, Mozambique
                Author notes
                []Corresponding author. delfina.hlashwayo@ 123456uem.mz
                Article
                S2405-8440(20)30382-0 e03537
                10.1016/j.heliyon.2020.e03537
                7063338
                32181402
                98b1dcb2-b1e7-41f7-bfee-3e857cffd455
                © 2020 The Author(s)

                This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

                History
                : 21 October 2019
                : 20 November 2019
                : 2 March 2020
                Categories
                Article

                microbiology,epidemiology,infectious disease,public health,campylobacter spp.,antibiotic resistance,africa

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