Institute for Animal Health, Compton, Berkshire RG20 7NN, UK1
Department of Animal and Food Sciences, University of Delaware, 531 South College Avenue, Newark, DE 19717-1303, USA2
Author for correspondence: Paul Wigley. Tel: +44 116 255 1551. Fax: +44 116 257 7631. e-mail: Microwig{at}aol.com
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ABSTRACT |
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Keywords: Salmonella, cytokines, interleukin-6, chicken, inflammatory response
Abbreviations: CKC, chick kidney cells; CM, conditioned medium; Ct, threshold cycle value; DMEM, Dulbeccos modified Eagles medium; FAM, 5-carboxyfluorescein; FBS, foetal bovine serum; IFN, interferon; IL, interleukin; PMN, polymorphonuclear cell; P/S, penicillin and streptomycin; rm, recombinant murine; TAMRA, N,N,N,N'-tetramethyl-6-carboxyrhodamine
The GenBank accession numbers for the sequences reported in this paper are AI982185 for chicken IL-6 cDNA and AJ250838 for the partial chicken IL-6 genomic sequence, respectively.
a Present address: School of Pharmacy and Pharmaceutical Sciences, DeMontfort University, Leicester LE1 9BH, UK.
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INTRODUCTION |
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Recent reports suggest that differences in the disease caused by typhoid-like restricted host range serotypes and enteritis caused by broad host range serotypes may be the results of differences in the early stages of pathogenesis (Weinstein et al., 1998 ; Henderson et al., 1999
). Following oral infection by S. typhimurium in mammals, Salmonella penetrates through the intestinal epithelium (Galán & Sansonetti, 1996
). Entry into epithelial cells is mediated by a type III secretion system encoded on Salmonella pathogenicity island 1 (Darwin & Miller, 1999
). The proteins secreted by this system interact with the epithelial cells, triggering a number of responses including the production of pro-inflammatory cytokines (Galán & Sansonetti, 1996
; Darwin & Miller, 1999
), leading to an influx of polymorphonuclear cells (PMNs) accompanied by increased fluid secretion. The interaction of Salmonella with epithelial cells results in a number of responses including damage to the intestinal epithelium and diarrhoea. S. typhimurium is also capable of causing gastroenteritis in young chicks and causes intestinal lesions, but not clinical disease, in older birds (Barrow et al., 1987
). Relatively little is known about the molecular mechanisms of Salmonella entry in the chicken gut, though the basic mechanisms of pathogenesis of S. typhimurium appear to be similar to those in mammals (Henderson et al., 1999
). Invasion causes rapid inflammation of the intestinal mucosa and infiltration of large numbers of heterophils, the avian equivalent of neutrophils, followed by macrophages, resulting in intestinal lesions. In contrast, following infection with S. pullorum, rapid inflammation does not occur, and only small numbers of heterophils are found associated with the intestinal epithelium (Henderson et al., 1999
). S. pullorum is less invasive than S. typhimurium in a range of avian and mammalian primary and continuous cell lines. S. gallinarum has also previously been shown to be less invasive than S. typhimurium in both avian and mammalian cells (Barrow & Lovell, 1989
).
Greater understanding of how Salmonella interacts with the host is needed to understand the disease and colonization processes in the chicken both in terms of animal and public health. Recent progress in the cloning of avian cytokines has led to the development of reagents with which to measure cytokine production in response to infection in the chicken, and this may allow a greater insight into interactions between the host and salmonellae at a cellular and molecular level. The avian orthologues of the Th1 cytokines interferon- (IFN-
) and interleukin-2 (IL-2) have recently been cloned (Digby & Lowenthal, 1995
; Sundick & Gill-Dixon, 1997
), as have the pro-inflammatory cytokines IL-1ß (Weining et al., 1998
) and IL-6 (accession no. AI982185). Reproducible, sensitive bioassays exist to measure chicken IFN-
-like (Lowenthal et al., 1995
) and IL-6-like (Lynagh, 1998
; Nakamura et al., 1998
) activities. The genomic sequences and gene structure for IFN-
(Kaiser et al., 1998
), IL-2 (Kaiser & Mariani, 1999
) and IL-1ß (accession no. AJ245728) have been fully determined. A partial genomic sequence for IL-6 has also recently been isolated (accession no. AJ250838). Gene structure information makes possible the design of probes and primers to specifically quantify cytokine mRNA levels using real-time quantitative RT-PCR.
We aimed to determine the levels of cytokines, particularly the pro-inflammatory cytokines IL-6 and IL-1ß, produced following the invasion of the broad host range serotypes S. typhimurium and S. enteritidis, and the host specific serotype S. gallinarum, into chicken cells in vitro. Primary chick kidney cells (CKC) were chosen as the host cell for the invasion model; there is no current suitable chicken intestinal epithelium model. CKC contain a high proportion of epithelial cells, few phagocytic cells and have previously been shown to be invaded by a range of Salmonella serotypes (Barrow & Lovell, 1989 ). Different levels of cytokine production following invasion with the broad host range serotypes (S. typhimurium and S. enteritidis), compared to the host specific serotype (S. gallinarum), would provide insight into the mechanisms of immunopathogenesis of salmonellosis in the chicken.
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METHODS |
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Cell culture.
Primary CKC were prepared from the kidneys of 12 week old Rhode Island Red chicks as previously described (Barrow & Lovell, 1989 ). Briefly, kidneys were removed aseptically, teased apart and trypsinized with versene (0·8% NaCl, 0·02% KH2PO4, 0·15% Na2HPO4, 0·02% KCl and 0·02% EDTA). Cell concentrations were adjusted to 1x106 ml-1 in complete DMEM (Dulbeccos modified Eagles medium) supplemented with 12·5% (v/v) heat-inactivated foetal bovine serum (FBS), 10% (v/v) tryptose phosphate broth (Difco), 25 U nystatin ml-1, 100 U penicillin ml-1 and 1 µg streptomycin ml-1 (P/S), at pH 7·0 and grown in 1 ml per well in 24-well Nunclon plates (Nunc) for 72 h at 37 °C, 5% CO2. Two hours prior to use in invasion assays, the media was replaced with DMEM without antibiotics.
HD11 (a chicken macrophage cell line) cells (Beug et al., 1979 ) were seeded at 4x105 ml-1 and grown at 41 °C, 5% CO2 in RPMI 1640 medium (Life Technologies) containing 20 mM L-glutamine (Life Technologies), 2·5% FBS, 2·5% chicken serum, 10% tryptose phosphate broth and P/S. 7TD1 (an IL-6-dependent mouse plasmacytoma cell line) cells (van Snick et al., 1986
) were seeded at 2x105 ml-1 and grown at 37 °C, 5% CO2 in RPMI 1640 medium containing 20 mM L-glutamine, 10% FBS, 0·05 mM 2-mercaptoethanol and P/S. During routine culture, recombinant murine (rm) IL-6 was added at 10 pg ml-1.
Invasion of cells.
Bacterial cultures were diluted in LB to 1x108 ml-1 and 100 µl added to the CKC to give a m.o.i. of 10 bacteria per chicken cell. Cells were incubated for either 2 or 4 h at 37 °C, 5% CO2. After incubation, cell supernatants were removed, filtered through a 0·22 µm filter and stored at -20 °C prior to determination of cytokine production. Extracellular bacteria were then killed by incubating cells for 1 h at 37 °C in DMEM containing 100 µg gentamicin ml-1 (Sigma). Cells were washed three times in Hanks buffered saline solution (Life Technologies) and lysed with 1 ml 1% (v/v) Triton X-100 (Sigma) for 30 min at 37 °C. Viable counts of the intracellular bacteria in the lysate were made on LB agar. Each assay was performed in triplicate for each serotype. Statistical analysis of variance between species and serotypes was made using the Minitab for Windows v12.21 statistical program (Minitab). The probability level for significance was taken as P<0·05.
Real-time quantitative RT-PCR.
Cytokine mRNA levels in infected and control CKC cultures were quantified using a method based on that of Moody et al. (2000) .
Total RNA was prepared from CKC cultures using the RNeasy mini kit (Qiagen) following the manufacturers instructions. Purified RNA was eluted in 50 µl RNase-free water and stored at -70 °C.
For both cytokine and 28S rRNA-specific amplification, primers and probes were designed using the Primer Express software program (PE Applied Biosystems). Details of the probes and primers are given in Table 1. All cytokine probes were designed, from the sequence of the relevant genes, to lie across intronexon boundaries. Cytokine probes were labelled with the fluorescent reporter dye 5-carboxyfluorescein (FAM) at the 5' end and the quencher N,N,N,N'-tetramethyl-6-carboxyrhodamine (TAMRA) at the 3' end. The 28S probe was labelled with the fluorescent reporter dye VIC (PE Applied Biosystems) at the 5' end and TAMRA at the 3' end.
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Quantification was based on the increased fluorescence detected by the ABI PRISM 7700 Sequence Detection System due to hydrolysis of the target-specific probes by the 5' nuclease activity of the rTth DNA polymerase during PCR amplification. The passive reference dye 6-carboxy-x-rhodamine, which is not involved in amplification, was used to correct for fluorescent fluctuations resulting from changes in the reaction conditions, for normalization of the reporter signal. Results are expressed in terms of the threshold cycle value (Ct), the cycle at which the change in the reporter dye (Rn) passes a significance threshold. In this work, the threshold values of
Rn are as shown in Table 2
, for all reactions described.
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Macrophage activation factor assay.
Macrophage activation factor activity, typically used in the chicken as a measure of IFN- activity (Lowenthal et al., 1995
), was assayed by the production of nitric oxide by stimulated HD11 cells (Beug et al., 1979
), quantitated by the accumulation of nitrite (
) in the culture medium (Ding et al., 1988
; Sung et al., 1991
). HD11 cells were seeded at a density of 5x104 cells per well in flat-bottomed 96-well microtitre plates (Corning) in growth medium (as described above). Subsequently, triplicate 100 µl samples of twofold serial dilutions of CKC conditioned medium (CM) were added and the cells cultured for 48 h at 41 °C, 5% CO2. The nitrite concentration was assayed by mixing 100 µl cell-free culture supernatant with 100 µl Griess reagent [0·3%, w/v, naphthylethylenediamine dihydrochloride (Sigma), 1% (w/v) sulphanilamide (Sigma) in 2·5% H3PO4 (BDH)] and incubating for 10 min at room temperature. The absorbance of the reaction product was measured in a Titretek Multiscan MCC/340 ELISA reader (ICN) at 543 nm. Serial dilutions of sodium nitrite (Sigma) were used to determine a standard curve. Data are expressed as µM
(5x104 cells)-1 (48 h)-1. IFN-
-like activity of the test samples was determined using log-linear regression analysis against the
standard curve.
To confirm the specificity of the -inducing activity, the CM were also pre-incubated for 1 h, prior to their addition to the HD11 cells, with either 1E12, an anti-chicken IFN-
neutralizing mAb (Lambrecht et al., 2000
), or the LPS inhibitor polymyxin B.
7TD1 bioassay.
The 7TD1 bioassay was based on that described by van Snick et al. (1986) . Cells were plated at 2x103 cells per well in 96-well plates and then cultured at 37 °C, 5% CO2 for 72 h in the presence of a variety of stimuli. The presence of IL-6-like activity was indicated by proliferation, as measured by the incorporation of [3H]thymidine (0·5 µCi [3H]thymidine per well) during the final 6 h incubation. IL-6-like factor activity of the test samples was determined using log-linear regression analysis against rmIL-6 standards. The dynamic range of the rmIL-6 standard was determined from the linear part of the curve and plotted on the same dilution scale as the samples. This range was then used to regress the curve of the test sample back to the level of half maximal proliferation seen in the rmIL-6 standard curve. The dilution of test sample required to bring about this level of proliferation was referred to as one dilution unit. Taking into account the dilution factor, the number of dilution units in each test sample was determined. The number of dilution units in samples run in separate assays was compared by regressing each sample using the standard curve run within the same assay.
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RESULTS |
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Attempts were made to set up multiplex RT-PCRs, in which a cytokine-specific and 28S rRNA-specific reaction were carried out on the same sample in the same tube. However, there were significant differences in the cytokine-specific Ct values from the multiplex RT-PCRs compared to the single RT-PCRs. Also, the gradients generated from the regression analyses of the log10 dilution series following multiplex and single RT-PCRs were quite different. Multiplex RT-PCR therefore seemed to significantly affect the quantification of cytokine RNA. It was therefore decided to continue with single RT-PCRs, but to run both cytokine-specific and 28S rRNA-specific reactions on the same samples, in triplicate, in the same experiment, with replicate experiments.
To control for variation in sampling and RNA preparation, the Ct values for cytokine-specific product for each sample were standardized using the Ct value of 28S rRNA product for the same sample from the reaction run simultaneously. The Ct values for 28S rRNA did not alter significantly from sample to sample; the mean 28S rRNA Ct values for uninfected or infected CKC ranged from 8·58 to 8·94. Cytokine-specific Ct values varied from sample to sample, and from cytokine to cytokine. The Ct values for 28S rRNA thus appeared to be independent of cytokine production and infection. They were therefore taken to be representative of the level of RNA extracted from the CKC cultures. To normalize RNA levels between samples within an experiment, the mean Ct value for 28S rRNA-specific product was calculated by pooling values from all samples in that experiment. Tube to tube variations in 28S rRNA Ct values about the experimental mean were calculated. The slope of the 28S rRNA log10 dilution series regression line was used to calculate differences in input total RNA. Using the slopes of the respective cytokine log10 dilution series regression lines, the difference in input total RNA, as represented by the 28S rRNA, was then used to adjust cytokine-specific Ct values. Fig. 1(a) shows the effect of standardizing cytokine-specific Ct values to correct for tube to tube variation in RNA levels. Standardization does not dramatically alter the distribution of the results as a whole. Fig. 1(b)
shows the standardized data expressed as fold changes in mRNA levels in samples from infected CKC compared to those from uninfected CKC, which was set at a basal level of 1. For statistical comparisons, cytokine mRNA changes following Salmonella infection were compared to those following E. coli infection. In terms of levels of IFN-
and IL-2 mRNA expression, there was very little effect following infection, except that, in the case of S. enteritidis, there was an approximately fivefold decrease in IL-2 mRNA (P<0·01). For IL-1ß mRNA expression, infection of CKC with E. coli caused a reduction in IL-1ß mRNA levels compared to uninfected CKC. Infection with S. gallinarum or S. enteritidis had similar effects to the E. coli infection. However, compared to the E. coli infection, infection with S. typhimurium or S. dublin gave significant levels of IL-1ß mRNA expression (P<0·01), similar to the uninfected controls. The most striking results were seen with regard to IL-6 mRNA expression levels. Infection of CKC with S. typhimurium, S. dublin or S. enteritidis caused a seven- to tenfold increase in IL-6 mRNA expression (P<0·01). However, following S. gallinarum infection there was a threefold decrease in IL-6 mRNA expression (P<0·01).
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CM from all CKC cultures were harvested after 4 h culture and assayed for IFN--like activity using the macrophage activation factor assay. Fig. 2
shows the amount of nitrite, expressed as µM
(5x104 cells)-1 (48 h)-1, produced by macrophages grown in the presence of CM from uninfected CKC, and CKC infected either with one of the four species of Salmonella, or with E. coli. As a positive control, macrophages were also grown in the presence of a 1:1000 dilution of recombinant chicken IFN-
. Only very low (background) levels of nitrite were produced by HD11 cells cultured in the presence of CM from uninfected CKC, regardless of the dilution of the CM. Nitrite was produced by HD11 cells grown in the presence of CM from all the infected CKC. The quantity of
produced titred out with increasing dilution of the CM down to background levels. CM from CKC infected with S. typhimurium contained most
, followed by that from S. enteritidis-infected CKC, with that from S. gallinarum-infected CKC containing least
. CM from CKC infected with S. dublin or E. coli gave intermediate levels of
.
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Levels of IL-6-like factor activity in the CM from the same CKC cultures were measured using the 7TD1 bioassay (van Snick et al., 1986 ). 7TD1 cells are dependent on the presence of IL-6 for growth and proliferation, and the assay can detect IL-6 levels as low as 0·1 pg ml-1. This assay has been used to measure the presence of chicken IL-6-like activity in the CM from LPS-stimulated fibroblasts and HD11 cells (Lynagh, 1998
), and in serum (Nakamura et al., 1998
; Lynagh, 1998
). Table 4
shows IL-6-like activity in the CM analysed by the 7TD1 assay, expressed as dilution units. CM from CKC infected with the broad host range serotypes (S. enteritidis, S. dublin or S. typhimurium) contained significantly more IL-6-like activity (P<0·01), than CM from CKC infected with E. coli. CM from S. gallinarum-infected CKC contained least IL-6-like activity, significantly less (P<0·01) than CM from CKC infected with E. coli.
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DISCUSSION |
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By contrast, assays which measure IFN--like and IL-6-like activity in the chicken are available, allowing quantification of IFN-
- and IL-6-like activities in the CM from Salmonella- and E. coli-infected CKC. The real-time quantitative RT-PCR results showed little or no induction of IFN-
mRNA expression in infected CKC compared with uninfected controls. However, the bioassay showed significant IFN-
-like activity in the CM from all infected CKC. This activity was not removed by pre-treating the CM with an anti-chicken IFN-
neutralizing antibody (Lambrecht et al., 2000
), but was removed by pre-treatment with the LPS inhibitor polymyxin B (see Fig. 2
). The most likely explanation for these results is contamination of the CM from infected CKC with bacterial LPS (LPS stimulates HD11 cells to produce
), especially as the IFN-
-like activity in the CM of uninfected CKC was very low, as were the IFN-
mRNA levels in the uninfected CKC themselves.
Invasion of S. typhimurium and S. enteritidis into avian cells produces an inflammatory acute phase response
Infection with S. typhimurium, S. dublin and S. enteritidis gave both high levels of IL-6-like activity in the CM and induced high levels of IL-6 mRNA expression in the CKC. E. coli infection gave slightly higher levels of both IL-6 mRNA and IL-6-like activity, compared to those from uninfected CKC. Finally, S. gallinarum infection seems to result in down-regulation, or non-induction, of IL-6 expression. Both IL-6 mRNA levels, and levels of IL-6-like activity, were lower in CKC infected with S. gallinarum than in uninfected CKC. There is good correlation between IL-6 mRNA levels in the CKC and IL-6-like activity in the CM from the CKC, following infection.
It would appear that production of IL-6 is not simply due to invasion. Higher levels of IL-6 were produced by CKC incubated with the non-invasive E. coli K-12. It appears that the down-regulation of IL-6 is a specific effect of S. gallinarum. IL-6 is a multifunctional cytokine that has pro-inflammatory activity via the induction of acute phase protein synthesis, and is important in the development of adaptive immune responses leading to the differentiation of B lymphocytes, cytotoxic T cells and the growth of T cells (Hirana, 1994 ). The role of IL-6 in the pathogenesis of S. typhi and S. typhimurium has been investigated in human and murine epithelial cell lines (Weinstein et al., 1998
). The invasion of S. typhi into human or murine epithelial cells results in the production of high levels of IL-6. In contrast, invasion of S. typhimurium into mice and humans results in only low levels of IL-6 production. The data presented here indicate that the invasion of S. gallinarum into non-phagocytic chicken cells results in a low level of IL-6 production, and suggests that early pathogenesis of fowl typhoid, at least in terms of IL-6 production, may more closely resemble the typhoid-like disease found in S. typhimurium-infected mice than human typhoid fever.
The high levels of IL-6 production following invasion by S. typhimurium, S. enteritidis and S. dublin also suggest differences in the early interactions and pathogenesis of these broad host range serotypes compared with the chicken-specific serotype S. gallinarum. S. typhimurium does not frequently cause clinical disease except in very young chicks (Barrow et al., 1987 ), where it has been shown to cause damage to the intestinal mucosa, particularly flattening of the microvilli structure (Nagaraja et al., 1991
). Although older birds rarely show clinical disease following S. typhimurium infection, 1-d-old birds infected orally with S. typhimurium develop intestinal lesions and flattened microvilli 23 d following infection (Henderson et al., 1999
). Increased numbers of heterophils and mononuclear cells in the gut accompany the intestinal damage, suggesting that the mechanisms of disease resemble those found in mammals (Darwin & Miller, 1999
). In contrast, S. gallinarum does not cause intestinal damage in the early stages of infection but causes an acute and virulent systemic disease with lesions of the spleen, liver and heart often accompanied by bacteraemia (Smith, 1956
; Pomeroy & Nagaraja, 1991
). The differences in IL-6 production found in this study indicate that invasion by S. typhimurium, S. enteritidis or S. dublin induces a strong acute phase inflammatory response and activation of innate and adaptive immune responses. This may contribute to both the damage of the intestinal epithelium observed following in vivo infection (Henderson et al., 1999
) and also to an effective immune response that prevents systemic disease. The increased levels of heterophils found following S. typhimurium infection are also likely to play a major role in disease pathogenesis and immune protection. Heterophils have been demonstrated to play an important role in protection against S. enteritidis infection in the chicken (Kogut et al., 1994c
). In mammals it has been shown that IL-8 is produced in response to Salmonella invasion (Eckman et al., 1993
), along with a pathogen-elicited epithelial chemoattractant (PEEC) (McCormick et al., 1998
). These act to induce an influx of PMNs that are involved in the pathogenesis of Salmonella gastroenteritis (Darwin & Miller, 1999
). However, no equivalent of PEEC has yet been found in the chicken, and there are as yet no specific assays to measure IL-8 in the chicken. However, it seems likely that invasion by S. typhimurium or S. enteritidis may induce IL-8 production, and hence heterophil influx in the chicken gut.
Invasion by S. gallinarum does not induce an inflammatory response
In contrast, invasion by S. gallinarum results in little or no production of IL-6. This suggests that the entry of S. gallinarum does not trigger a strong immune or inflammatory response. Such a mechanism would allow entry without intestinal damage, and may fail to trigger an effective host response allowing the development of systemic disease. The closely related S. pullorum appears to enter through chicken epithelium without causing an inflammatory response, intestinal damage or heterophil infiltration, though the main route of entry appears to be through lymphoid tissue (Henderson et al., 1999 ). In addition, in a human cell-culture system S. pullorum is capable of both attachment and entry into epithelial cells, but does not induce transepithelial migration of PMNs (McCormick et al., 1995
). Depletion of PMNs in chickens results in systemic septicaemia following S. enteritidis infection (Kogut et al., 1994c
), resulting in disease akin to that caused by S. gallinarum. It appears that inflammatory responses and PMNs in the gut are important in protection against the development of systemic typhoid-like disease, though they may result in tissue damage in birds or gastroenteritis in mammals. The failure of S. gallinarum to induce an inflammatory response in invasion in the chicken may be an adaptation that contributes to its host specific nature. However, it is likely to be of secondary importance compared to the interaction with the hosts reticuloendothelial system, which has been shown to be of prime importance in host specificity in vivo in both the chicken and mouse (Barrow et al., 1994
).
It is interesting that there is a down-regulation of IL-1ß during Salmonella invasion. Little is known regarding the production of IL-1ß by non-phagocytic cells invaded by Salmonella. IL-1ß is a potent pro-inflammatory cytokine and high levels were produced in the early stages of invasion, which may act to inhibit Salmonella crossing the intestinal epithelium. This is in contrast to the production of IL-8 and PMN influx triggered by Salmonella invasion leading to damage of the gut mucosa, allowing bacterial entry (Galán & Sansonetti, 1996 ; Darwin & Miller, 1999
). In the mouse, IL-1ß is produced by macrophages following invasion across the gut epithelium and contributes to both the subsequent inflammation of the gut and pyrexia during Salmonella infection (Galán & Sansonetti, 1996
). IL-1ß is also produced by murine macrophages and dendritic cells when invaded by Salmonella in vitro (Marriott et al., 1999
). The production of IL-1ß by chicken macrophages in response to Salmonella is as yet undefined.
In this work we have demonstrated methods for investigating cytokine production by cultured chicken cells in response to challenge with bacterial pathogens, and, though limited by the current availability of assays in the chicken, have shown differential production of cytokines in response to host specific and broad host range Salmonella. These differences suggest that pathogenesis and host specificity of S. gallinarum infection in the chicken may be related to some extent to the lack of inflammatory response in the early stages of infection in the gut. Production of pro-inflammatory cytokines, including IL-6 and probably IL-8, may limit serotypes such as S. typhimurium and S. enteritidis to the gut by induction of a strong immune response, but as a result produce lesions and flatten intestinal microvilli, the same mechanism that produces gastroenteritis in mammals (Darwin & Miller, 1999 ). It appears that all serotypes down-regulate IL-1ß production in chicken cells, possibly to facilitate entry in vivo by inhibiting inflammation of the gut epithelium during invasion. It is anticipated that the quantitative RT-PCR techniques will be utilized to determine cytokine production from cells and tissues obtained from in vivo Salmonella infections of poultry. The interaction of Salmonella with eukaryotic cells is largely dependent on Type III secretion systems (Darwin & Miller, 1999
), and their secreted proteins. Although Type III secretion systems are conserved in different bacteria [for example, the inv/spa SPI1 system is present and conserved in all Salmonella serotypes tested (Ochman & Groisman, 1996
)], it is becoming more apparent that even closely related pathogens may have a different repertoire of secreted protein effectors (Hardt & Galán, 1997
; Mirold et al., 1999
). It is tempting to speculate that this may play a role in the differences in the early pathogenic behaviour of different Salmonella serotypes. Further work with the host-specific S. gallinarum and broad host range salmonellae in the chicken will concentrate on studies of this matter. In addition, the application of the techniques described here will help investigation of pathological mechanisms of avian salmonellosis and other diseases at a molecular level in the chicken.
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ACKNOWLEDGEMENTS |
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Received 2 March 2000;
revised 3 July 2000;
accepted 22 August 2000.