Influence of the Gut Microbiota Composition on Campylobacter jejuni Colonization in Chickens.

The Campylobacter jejuni-host interaction may be affected by the host's gut microbiota through competitive exclusion, metabolites, or modification of the immune response. To understand this interaction, C. jejuni colonization and local immune responses were compared in chickens with different gut microbiota compositions. Birds were treated with an antibiotic cocktail (AT) (experiments 1 and 2) or raised under germfree (GF) conditions (experiment 3). At 18 days posthatch (dph), they were orally inoculated either with 104 CFU of C. jejuni or with diluent. Cecal as well as systemic C. jejuni colonization, T- and B-cell numbers in the gut, and gut-associated tissue were compared between the different groups. Significantly higher numbers of CFU of C. jejuni were detected in the cecal contents of AT and GF birds, with higher colonization rates in spleen, liver, and ileum, than in birds with a conventional gut microbiota (P < 0.05). Significant upregulation of T and B lymphocyte numbers was detected in cecum, cecal tonsils, and bursa of Fabricius of AT or GF birds after C. jejuni inoculation compared to the respective controls (P < 0.05). This difference was less clear in birds with a conventional gut microbiota. Histopathological gut lesions were observed only in C. jejuni-inoculated AT and GF birds but not in microbiota-colonized C. jejuni-inoculated hatchmates. These results demonstrate that the gut microbiota may contribute to the control of C. jejuni colonization and prevent lesion development. Further studies are needed to identify key players of the gut microbiota and the mechanisms behind their protective role.

Morphological and immunological characterization of primary cultured chicken caecal epithelial cells.

Cell cultures are models in biological and medical research to understand physiological and pathological processes. Cell lines are not always available depending on cell type and required species. In addition, the immortalization process often affects cell biology. Primary cells generally maintain a greater degree of similarity in short-term culture to the cells in tissue. Goal of this study was to verify the suitability of chicken primary epithelial caecal cells (PECCs) for in vitro investigations of host‒pathogen interactions. Epithelial nature of PECCs was confirmed by detection of tight and adherens junctions and cobblestone-like cell morphology. Sialic acids distribution was similar to that in caecal cyrosections. To understand the capacity of PECCs to respond to microbial challenges, the Toll-like receptors (TLRs) repertoire was determined. Exposure of PECCs to polyinosinic-polycytidylic acid (poly(I:C)) or lipopolysaccharide (LPS) led to upregulation of type I and III interferon (IFN) as well as interleukin (IL-) 1ß, IL-6 and IL-8 mRNA expression. Overall, the PECCs showed properties of polarized epithelial cells. The presence of TLRs, their differential expression, as well as pattern recognition receptor dependent immune responses enable PECCs to act as suitable in vitro model for host‒pathogen interaction studies, which are difficult to conduct under in vivo conditions.

In vitro investigations on interference of selected probiotic candidates with Campylobacter jejuni adhesion and invasion of primary chicken derived cecal and Caco-2 cells.

BACKGROUND: Campylobacter (C.) jejuni is one of the most important bacterial foodborne pathogens worldwide. Probiotics such as Lactobacillus or Bacillus species are considered one option for reducing the colonization rate and magnitude in poultry, the most frequent source of human infections. Due to the lack of suitable avian in vitro models such as chicken intestinal cell lines, especially those derived from the cecum, most in vitro studies on C. jejuni host interaction have been conducted with human intestinal cell lines. In this study, we compared C. jejuni-cell interactions between primary chicken cecal cells and the human intestinal cell line Caco-2, which is derived from colorectal adenocarcinoma, and investigated possible interfering effects of selected probiotic candidates. RESULTS: We detected differences in adhesion and invasion between the two tested gut cell types and between different C. jejuni strains. The probiotic inhibition of C. jejuni adhesion and invasion of human and avian gut cells was affected by host cell type, investigated C. jejuni strain and time points of probiotic treatment. Additionally, our results suggest a possible correlation between C. jejuni invasion and the detected increase in IL-6 mRNA expression. CONCLUSIONS: Our results indicate distinct differences between avian and human gut cells in their interaction with C. jejuni. Therefore, data obtained in one host species on C. jejuni-host interaction may not easily be transferrable to another one. The factors influencing the variable efficacy of probiotic intervention in chicken and human derived cells should be investigated further.

Adhesion and invasion of Campylobacter jejuni in chickens with a modified gut microbiota due to antibiotic treatment.

Campylobacter jejuni (C. jejuni) is a predominant cause of foodborne illness in humans, while its colonization in chickens is usually asymptomatic. Antibiotics are not routinely used to treat chickens against C. jejuni, but in the face of other bacterial diseases, C. jejuni may be exposed to antibiotics. In this study, chickens were treated with antibiotics (AT) to modify the gut microbiota composition and compared with untreated chickens (Conv) with respect to changes in C. jejuni-colonization and bacterial-intestine interaction. Groups of AT and Conv chickens were inoculated after an antibiotic-withdrawal time of eight days with one of three different C. jejuni isolates to identify possible strain variations. Significantly higher numbers of colony forming units of C. jejuni were detected in the cecal content of AT birds, with higher colonization rates in the spleen and liver compared to Conv birds independent of the inoculated strain (p < 0.05). Clinical signs and histopathological lesions were only observed in C. jejuni-inoculated AT birds. For the first time we demonstrated C. jejuni invasion of the cecal mucosa in AT chickens and its inter- and intracellular localization by using antigen-straining, and electronic microscopy. This study provides the first circumstantial evidence that antibiotic treatment with lasting modification of the microbiota may provide a suitable environment for C. jejuni invasion also in chickens which may subsequently increase the risk of C. jejuni-introduction into the food chain.

Establishment of an In Vitro Intestinal Epithelial Cell Culture Model of Avian Origin.

The role of intestinal epithelial cells (IECs) in the physiology of the gastrointestinal tract (GIT) of chickens and pathogenesis of various diseases in chickens is still poorly understood. IECs line the GIT and represent the border between the unsterile environment and the sterile internal tissues. Bacterial, viral, fungal, or parasitic pathogens are able to invade or pass IECs under certain circumstances and cause various diseases. Pathogen-host interactions in the chicken gut are poorly understood because of the lack of suitable in vitro and ex vivo models. In this context, there is a need to optimize the cell isolation and culture conditions to be able to provide reproducible IEC cultures with defined epithelial characteristics. We compared different mechanical IEC isolation protocols and cell culture media and established a reproducible primary intestinal epithelial cell culture model from specific-pathogen-free layer-type chickens. By using isolated crypts from the duodenum of 5- to 12-wk-old birds to create the starting material, we were able to culture replicating cells between 7 and 10 days. Cells built an almost closed monolayer and showed epithelial-like characteristics, such as the expression of cytokeratin and epithelial cadherin. The primary IEC cultures described in this study represent a suitable model with which to investigate in vitro pathogen-host interactions relevant to the chicken gut.

Differences in host breed and diet influence colonization by Campylobacter jejuni and induction of local immune responses in chicken.

BACKGROUND: Chickens are regarded as the main reservoir for human campylobacteriosis. Little is known about the interaction between Campylobacter jejuni (C. jejuni) and chickens. This interaction may be influenced by the stage of maturation of the immune system, developing gut microbiota composition and other factors including breed and diet. Our aim was to investigate the impact of breed, and diet on C. jejuni colonization and host immune responses in chickens. Birds were inoculated with 104 colony forming units (CFU) of C. jejuni or diluent at one (Exp. 1) or 22 (Exp. 2) days post hatch. We compared local immune cell subpopulations, cytokine expression levels, and gut microbiota composition between broiler-type (BT) and layer-type (LT) birds fed with either commercial broiler feed (bf) or layer feed (lf). RESULTS: Lower colonization rates were observed in the older age group independent of breed and diet. Independent of breed, birds fed with bf showed higher CFU of C. jejuni compared to lf-fed groups. Campylobacter jejuni-inoculation had a significant effect on lymphocyte numbers and cytokine expression levels in BT birds independent of feeding strategy (p < 0.05). These effects were not detected in LT birds, only LT birds fed with bf showed a significant increase in IL-8-expression at 7 days post C. jejuni inoculation compared to LT-control birds (p < 0.05). Diet influenced gut microbiota composition in a comparable manner between BT and LT birds, but changes in microbiota composition associated with C. jejuni inoculation varied between breeds. CONCLUSIONS: Diet and breed influenced C. jejuni colonization, immune responses and microbiota composition to a different extent comparing between LT and BT birds. The mechanisms behind these differences have to be elucidated further. Our results suggest that selection for more resistant breeds in combination with adapted feeding strategies may help to reduce Campylobacter colonization levels in commercial poultry in the future.

Susceptibility of primary chicken intestinal epithelial cells for low pathogenic avian influenza virus and velogenic viscerotropic Newcastle disease virus.

Avian influenza virus (AIV) and Newcastle disease virus (NDV) share a high tropism for the avian respiratory epithelium and may cause severe clinical disease associated with high mortality. Both viruses have different pathotypes, which may lead to differences in the severity of the disease. Respiratory epithelial cells were shown to be the primary target cells for infection and replication. Nevertheless, intestinal epithelial cells (IECs) were also suggested as target cells for both viruses in avian species. Most studies on AIV and NDV focused on the respiratory tract, while information regarding the virus-host interaction at the intestinal epithelial cell interface is lacking. We established a primary chicken IEC culture model. Primary chicken embryo fibroblast cultures (CEFs) were used for comparison. IECs and CEFs were infected with a low infectious dose (LID; multiplicity of infection, MOI, of 0.01) or high infectious dose (HID, MOI of 1), of low pathogenic AIV (LPAIV) H9N2 or velogenic viscerotropic NDV (vvNDV) Herts 33/56. Virus replication, mRNA expression pattern of the type I and type III interferon (IFN) and related genes IFIT5 (interferon-induced protein with tetratricopeptide repeats 5) and ISG12 (interferon stimulated gene 12) were investigated at four, 16, and 24h post infection (hpi). The results suggest high susceptibility of primary chicken IECs for these AIV and NDV strains. Replication rates and expression pattern of IFNs as well as related genes differed between the infecting viruses as well as cell culture systems. Both viruses induced an IFN λ-increase of more than 30-fold in IECs, while IFN-α and IFN-ß mRNA expression was either downregulated or only slightly increased with up to 10fold changes for the latter at 24h post LPAIV-infection. These results suggest a possible role of IFN λ in the control of viruses at the gut epithelial surface. LPAIV induced upregulation of IFIT5 as well as ISG12 expression in a dose and time dependent manner, while vvNDV infection only led to slight upregulation of IFIT5 and downregulation of ISG12, indicating differences in the down-stream regulation of the antiviral immune response between investigated viruses. Overall, our data demonstrate that IECs are a suitable model to investigate selected parameters of virus-host interaction for AIV and NDV and may be used to study other strains as well as other host species.