Advertisement
Research Article

Early Interferon-γ Production in Human Lymphocyte Subsets in Response to Nontyphoidal Salmonella Demonstrates Inherent Capacity in Innate Cells

  • Tonney S. Nyirenda equal contributor,

    equal contributor Contributed equally to this work with: Tonney S. Nyirenda, Anna E. Seeley

    Affiliations: Medical Research Council Centre for Immune Regulation and Clinical Immunology Service, Institute of Biomedical Research, School of Immunity and Infection, College of Medicine and Dental Sciences, University of Birmingham, Birmingham, United Kingdom, Malawi-Liverpool-Wellcome Trust Clinical Research Programme, College of Medicine, University of Malawi, Blantyre, Malawi

    X
  • Anna E. Seeley equal contributor,

    equal contributor Contributed equally to this work with: Tonney S. Nyirenda, Anna E. Seeley

    Affiliation: Medical Research Council Centre for Immune Regulation and Clinical Immunology Service, Institute of Biomedical Research, School of Immunity and Infection, College of Medicine and Dental Sciences, University of Birmingham, Birmingham, United Kingdom

    X
  • Wilson L. Mandala,

    Affiliations: Malawi-Liverpool-Wellcome Trust Clinical Research Programme, College of Medicine, University of Malawi, Blantyre, Malawi, Department of Biochemistry, College of Medicine, University of Malawi, Blantyre, Malawi

    X
  • Mark T. Drayson,

    Affiliation: Medical Research Council Centre for Immune Regulation and Clinical Immunology Service, Institute of Biomedical Research, School of Immunity and Infection, College of Medicine and Dental Sciences, University of Birmingham, Birmingham, United Kingdom

    X
  • Calman A. MacLennan mail

    c.maclennan@bham.ac.uk

    Affiliations: Medical Research Council Centre for Immune Regulation and Clinical Immunology Service, Institute of Biomedical Research, School of Immunity and Infection, College of Medicine and Dental Sciences, University of Birmingham, Birmingham, United Kingdom, Division of Medical Microbiology, School of Infection and Host Defence, University of Liverpool, Liverpool, United Kingdom

    X
  • Published: October 27, 2010
  • DOI: 10.1371/journal.pone.0013667

Abstract

Background

Nontyphoidal Salmonellae frequently cause life-threatening bacteremia in sub-Saharan Africa. Young children and HIV-infected adults are particularly susceptible. High case-fatality rates and increasing antibiotic resistance require new approaches to the management of this disease. Impaired cellular immunity caused by defects in the T helper 1 pathway lead to intracellular disease with Salmonella that can be countered by IFNγ administration. This report identifies the lymphocyte subsets that produce IFNγ early in Salmonella infection.

Methodology

Intracellular cytokine staining was used to identify IFNγ production in blood lymphocyte subsets of ten healthy adults with antibodies to Salmonella (as evidence of immunity to Salmonella), in response to stimulation with live and heat-killed preparations of the D23580 invasive African isolate of Salmonella Typhimurium. The absolute number of IFNγ-producing cells in innate, innate-like and adaptive lymphocyte subpopulations was determined.

Principal Findings

Early IFNγ production was found in the innate/innate-like lymphocyte subsets: γδ-T cells, NK cells and NK-like T cells. Significantly higher percentages of such cells produced IFNγ compared to adaptive αβ-T cells (Student's t test, P<0.001 and ≤0.02 for each innate subset compared, respectively, with CD4+- and CD8+-T cells). The absolute numbers of IFNγ-producing cells showed similar differences. The proportion of IFNγ-producing γδ-T cells, but not other lymphocytes, was significantly higher when stimulated with live compared with heat-killed bacteria (P<0.0001).

Conclusion/Significance

Our findings indicate an inherent capacity of innate/innate-like lymphocyte subsets to produce IFNγ early in the response to Salmonella infection. This may serve to control intracellular infection and reduce the threat of extracellular spread of disease with bacteremia which becomes life-threatening in the absence of protective antibody. These innate cells may also help mitigate against the effect on IFNγ production of depletion of Salmonella-specific CD4+-T lymphocytes in HIV infection.

Introduction

Nontyphoidal strains of Salmonella (NTS), in particular Salmonella enterica Typhimurium and Enteritidis (S. Typhimurium and S. Enteritidis) are a major cause of invasive disease, especially bacteremia and meningitis, in Africa [1], [2], [3], [4], [5], [6], [7], [8], [9], [10]. Children under two years of age [3], [6], [8] and HIV-infected adults [7], [9] are particularly susceptible and case-fatality rates for NTS bacteremia are high, being over 20% in children [6], [8] and up to 50% in adults [7]. A lack of typical clinical presentation for invasive NTS disease and affordable timely diagnostics [6], [8], [11], together with increasing levels of multi-drug resistance [4], [5], [11], [12] underlie the urgent need for new approaches to treat NTS.

In order to develop a vaccine against NTS, an improved understanding of the relevant modalities of protective immunity is required. We have previously shown the importance of antibody for complement-mediated cell-independent killing of NTS in the peripheral blood of young African children [3]. This protection can be lost in HIV-infected adults due to the presence of high titers of anti-LPS antibodies that block killing of Salmonella by antibodies against outer membrane proteins [13]. In addition to their capacity for extracellular survival, Salmonellae are facultative intracellular bacteria and their ability to survive within cells is essential for virulence [14]. The high susceptibility of individuals with chronic granulomatous disease, who lack normal phagocyte oxidative burst function, to infection with Salmonellae [15], [16] indicates the importance of cellular immune mechanisms against Salmonella in man. Therefore it is likely that control of intracellular infection moderates release of bacteria into body fluids and hence the dependence on antibodies against outer membrane proteins that protect against extracellular disease. Effective protection by a vaccine is likely to be achieved best by eliciting both these elements without inducing blocking antibodies. We have also recently demonstrated the importance of antibody acting as an opsonin for phagocyte cellular immunity against NTS in African children [17].

It is well established that IFNγ is a key cytokine for inducing mouse [18], [19], [20] and human [21], [22] macrophages to kill Salmonella through both oxidative burst and nonoxidative mechanisms. The importance of IFNγ in immunity to Salmonella in man is demonstrated by the heightened susceptibility of individuals with genetic deficiencies in the T helper 1 pathway, also known as the interleukin-(IL)12/23-interferon(IFNγ) axis, to recurrent infection with NTS [23], [24], [25], [26]. In those patients where the genetic defect is in the IL-12 or IL-12R genes [27], [28], [29] and in individuals with chronic granulomatous disease [30], subcutaneous IFNγ has successfully been used as an adjunct to antibiotic therapy in the treatment of invasive Salmonella disease. The presence of protective antibodies in these patients is the likely reason for the infections being manifest as local inflammatory lesions rather than fatal bacteremia or meningitis [24].

Additional support for an essential role for IFNγ in immunity to Salmonella comes from the mouse model of Salmonella infection. IFNγ-receptor-deficient mice are highly susceptible to attenuated Salmonella Typhimurium [31], as are mice that have been pretreated with antibodies to IFNγ [32], [33], [34], [35] or IL-12 [36]. Administration of recombinant IFNγ enhances killing of Salmonella in mice [32] and restores resistance to attenuated Salmonella after depletion of endogenous IL-12 using neutralizing anti-cytokine antibodies [36]. Blood levels of IFNγ increase both in Salmonella infections in mice [37], [38], [39], [40], [41] and in humans, particular in the case of systemic disease [42].

The course of untreated HIV infection is characterized by the loss of CD4+-T cells. Secretion of T helper 1 cytokines, in particular IFNγ, decreases during the course of HIV infection [43] and correlates with CD4 count [44]. There is downregulation of IFNγ production in both CD4+- and CD8+-T cell subsets [45] and a switch from a predominantly T helper 1 to a T helper 2 response [46]. In vitro infection of CD4+-T cells with HIV also results in downregulation of IFNγ expression [47], while commencement of HIV-infected patients on antiretroviral therapy leads to an increase in IFNγ production [48]. This reduction in IFNγ levels could, at least in part, account for the strong clinical association between invasive NTS disease and HIV/AIDS in Africa.

The clear importance for IFNγ in immunity to Salmonella and the ability of multiple lymphocyte subsets to produce this cytokine [24], led us to study IFNγ production in peripheral blood cells of healthy humans. We used intracellular cytokine staining (ICS) to identify the lymphocyte subsets that produce IFNγ when stimulated with NTS. We investigated lymphocytes in the innate arm of the immune system that do not use classical MHC-restricted antigen recognition (NK cells, γδ-T cells and NK-like T cells) as well as lymphocytes responsible for acquired cellular responses (CD4+- and CD8+-T cells). Identification of the cells that secrete this key cytokine will help in the design of new therapies against NTS.

Materials and Methods

Ethical Approval

Ethical approval for the use of anonymized blood samples in this study was granted by the Life and Health Sciences Ethical Review Committee of the University of Birmingham. Informed written consent was obtained from all participants.

Blood samples

Anonymized blood samples were obtained from healthy adults (5 male:5 female; ages 21 to 41 years). Blood samples anticoagulated with sodium heparin at 4 IU/ml and EDTA (collected in EDTA-anticoagulated tubes, Becton Dickinson, UK) were used for intracellular cytokine staining (ICS) and conventional immunophenotyping respectively. Serum, separated and stored in aliquots at -80°C immediately after clotting, was used for studies of humoral immunity.

Salmonella

The invasive Malawian S. Typhimurium isolate D23580 was used in all studies. Its genome has been sequenced at the Wellcome Trust Sanger Institute [12]. For experiments involving live Salmonella, D23580 was grown to log phase, washed twice with phosphate buffered saline (PBS) and added to heparin-anticoagulated whole blood or serum at 1/10th of the final volume giving 106 viable bacteria/ml. When required, the bacteria were heat-killed by incubating at 72°C for one hour. In the flow-cytometric antibody assay, D23580 in log growth phase was fixed with 1% formaldehyde in PBS. A whole-cell homogenate of D23580 was produced by disrupting washed D23580 using a Mini-Beadbeater (Biospec Products) as previously described [49]. This homogenate, at a final concentration of 10 µg/ml, was used to stimulate cells in heparinized-whole blood. Protein content of homogenates was determined by bicinchoninic acid (BCA) protein assay (Thermo Scientific).

Intracellular cytokine staining

Half ml aliquots of heparin-anticoagulated blood were stimulated with S. Typhimurium D23580 within one hour of collection in 15 ml tubes at 37°C for six hours unless otherwise specified. At the time of stimulation, 5 µl CD28/CD49d co-stimulatory antibodies (Becton Dickinson) was added to each tube, including control tubes, in order to ensure that lack of costimulation did not limit the production of cytokines, in particular, by αβ-T cells. 10 µl Brefeldin A (Becton Dickinson) diluted 1:10 with PBS was added to each tube after 2 hours. As positive control, blood was stimulated with phorbol 12-myristate 13-acetate (PMA) and ionomycin (both Sigma, UK) at final concentrations of 10 ng/ml and 1 µg/ml respectively. Negative control tubes were stimulated with PBS in place of Salmonella.

After the six hour stimulation period, adherent cells were resuspended by the addition of 50 µl EDTA (Becton Dickinson) to each tube. 50 µl aliquots of stimulated blood were incubated with a three-color panel of monoclonal antibodies (all Becton Dickinson) to the following cell-surface antigens in order to discriminate lymphocyte subsets and activated cells: PerCP-Cy5.5-conjugated CD4, CD8 or CD3 and APC-conjugated CD3, TCR-γδ or CD56, with PE-conjugated CD69 to indicate activated cells. Red cells were lysed with 10 volumes of 1X FACS Lysing Solution (Becton Dickinson) and samples washed with PBS 0.5% BSA prior to permeabilizing with 5 volumes of 1X FACS Permeabilizing Solution 2 (Becton Dickinson). Following a further wash with PBS 0.5% BSA, samples were incubated with the fourth color monoclonal antibody, FITC-conjugated anti-IFNγ antibody or an isotype control antibody followed by a final wash and resuspended in PBS 1% formaldehyde. Sample data were acquired and analyzed on a FACSCalibur flow cytometer using CellQuest Pro software (both Becton Dickinson). CD4+-T cells were defined as CD3+CD4+, CD8+-T cells as CD3+CD8+, γδ-T cells as CD3+TCRγδ+, NK cells as CD3-CD56+ and NK-like T cells as CD3+CD56+ lymphocytes.

Immunophenotyping

Conventional immunophenotyping for lymphocyte subset analysis was performed on 50 µl samples of EDTA-anticoagulated blood as previously described using the following combinations of monoclonal antibodies (all Becton Dickinson): 1) TCRγδ-FITC, CD4-PE, CD8-PerCP-Cy5.5, CD3-APC; 2) CD56-PE, CD3-PerCP-Cy5.5, CD19-APC. Sample data were acquired and analyzed on a FACSCalibur flow cytometer using CellQuest Pro software. Tube 2 was also used for internal quality assurance to check that the sum of T, B and NK lymphocyte subset percentages was within 100±6%. Absolute lymphocyte subset counts were calculated as the product of the subset percentage and total lymphocyte count determined on a standard laboratory hematological analyzer.

Monocyte activation assay

The ability of IFNγ, produced during the stimulation of whole blood with Salmonella, to activate monocytes, was assessed by stimulating fresh blood with plasma prepared from the whole blood stimulations and measuring CD38 expression on monocytes in these fresh blood samples. In order to allow the secretion of newly-synthesized IFNγ into the plasma, whole blood (or plasma, as control) was stimulated with Salmonella or PBS (negative control) as described above, but without the addition of Brefeldin A. After six hours, plasmas were collected by centrifugation and bacteria removed by sterilizing through 0.2 µm filters. 200 µl of each plasma was added to 500 µl fresh heparin-anticoagulated blood and incubated at 37°C for five hours. 50 µl samples of blood were labeled as described above, but using CD38-PE and CD14-APC antibodies. Monocytes were discriminated by CD14 against side-scatter histogram, and CD38 expression designated as the geometric mean fluorescent intensity (GMFI) in the FL2 histogram.

Serum bactericidal assay and anti-Salmonella antibody assay

The serum bactericidal assay for the ability of serum to kill S. Typhimurium D23580 and flow cytometric assay for measurement of titer of anti-D23580 IgG and IgM were as previously described [3]. Briefly, viable D23580 in log growth phase at a 1/10th volume was added to serum in a final volume of 100 µl and final concentration of 106 cfu/ml. Killing of Salmonella at 37°C was measured over a three hour time course. For Salmonella-specific antibody determination, serum diluted 1:10 with PBS was mixed with 1/10th volume of formaldehyde-fixed D23580 at a final concentration of 2×108 bacteria/ml, prior to detection of bound antibody with FITC-conjugated anti-human IgG and IgM (Sigma) and acquisition and analysis of data by flow cytometry.

Statistical methods

Student's t test was used to compare percentages and absolute numbers of IFNγ-producing cells in different lymphocyte subsets. Log-transformation was used to normalize absolute cell counts within subsets.

Results

Detection of IFNγ-production by peripheral blood lymphocytes in response to stimulation with Salmonella using an optimized intracellular cytokine staining technique

We looked for IFNγ production by healthy adult peripheral blood lymphocytes stimulated with S. Typhimurium homogenate and PMA (Figure 1). Background numbers of IFNγ-producing cells were typically less than 0.1% (Figure 1A–B), while positive control PMA-stimulated cells gave responses of between 20% and 50% IFNγ-producing cells (Figure 1C–D). Cells producing IFNγ in response to stimulation with NTS also expressed the early activation antigen CD69, though not all CD69+ lymphocytes produced IFNγ (Figure 1E–F).

thumbnail

Figure 1. Detection of IFNγ-producing lymphocytes by flow cytometry following stimulation with Salmonella.

Dot plots of CD4+-T cells (A, C and E) and γδ-T cells (B, D and F) from human peripheral blood from one healthy adult, either unstimulated (A and B), or stimulated with PMA (C and D) or S. Typhimurium D23580 homogenate (E and F), showing intracellular production of IFNγ and expression of CD69. Numbers within gates indicate percentage of IFNγ-producing cells. Each dot represents one cell.

doi:10.1371/journal.pone.0013667.g001

Kinetics of IFNγ production by peripheral blood lymphocytes in response to stimulation with Salmonella

IFNγ production by different lymphocyte subsets was examined in relation to duration of stimulation with Salmonella homogenate in the blood of healthy adult donors using the ICS method described (Figure 2). Little, if any, cytokine production was detected after two hours of stimulation, though by four hours IFNγ production was present in cells of all four subsets examined: CD4+-, CD8+- and γδ-T cells, and NK cells. The percentage of IFNγ-producing cells plateaued at six hours for CD8+- and γδ-T cells, and NK cells (Figure 2B–D). By contrast, this percentage continued to increase over the next two hours for CD4+-T cells (Figure 2A). Based on these findings, we choose to stimulate blood with Salmonella for six hours in subsequent ICS assays. The percentage of IFNγ-producing cells was markedly higher in the γδ-T cells and NK cells subsets compared with CD4+- and CD8+-T cells.

thumbnail

Figure 2. Kinetics of IFNγ production by peripheral blood lymphocytes in response to stimulation with Salmonella.

Percentage of IFNγ-producing CD69+ (A) CD4+-T cells, (B) CD8+-T cells, (C) γδ-T cells and (D) NK cells over an eight hour time course following stimulation with S. Typhimurium D23580 homogenate added at 0 hours with addition of Brefeldin A at 2 hours. Data are mean ± sd of three experiments.

doi:10.1371/journal.pone.0013667.g002

Immunity to Salmonella in peripheral blood from healthy adult donors

In order to provide an indication of the prior immunity and/or exposure to NTS in the ten anonymized healthy adult blood donors, we performed flow cytometric antibody assays to determine titers of IgG and IgM against S. Typhimurium isolate D23580 and serum bactericidal assays with D23580 (Figure 3). Sera from all ten donors contained anti-D23580 antibodies (>1.5 U) in the form of IgG or IgM or both classes of antibody. All sera were able to effect an approximately 90% or greater kill (1 log10 kill) of Salmonella in the serum bactericidal assay indicating that these anti-Salmonella antibodies are functional.

thumbnail

Figure 3. Anti-Salmonella antibody content and Salmonella-killing ability of serum from peripheral adult blood.

(A) Anti-S. Typhimurium D23580 IgG and (B) anti-D23580 IgM titers determined by flow cytometry compared with Salmonellae D23580-killing ability determined by serum bactericidal assay at 180 minutes using serum prepared from peripheral blood from ten healthy adults. Negative values on y axis indicate reduction in viable Salmonellae with -1.0 corresponding to a 90% reduction in viable Salmonellae [3]. Each symbol corresponds to serum from one individual.

doi:10.1371/journal.pone.0013667.g003

IFNγ-production by peripheral blood lymphocyte subsets in response to stimulation with Salmonella

Next we investigated the response of blood lymphocytes from the ten healthy adult donors to stimulation with live S. Typhimurium D23580 for six hours (Figure 4A). Over this time course, significantly higher percentages of the innate/innate-like lymphocyte subsets (NK cells, NK-like T cells and γδ-T cells) produced IFNγ compared with the adaptive T cell subsets (CD4+- and CD8+-T cells), despite evidence of prior exposure to Salmonella in these donors from the studies of their humoral immune response. Using Student's t test, P<0.001 was obtained for difference in percentage of IFNγ-producing cells in each innate and innate-like lymphocyte subset compared with percentage of IFNγ-producing CD4+-T cells. P≤0.02 was obtained for difference in percentage of IFNγ-producing cells in each innate/innate-like lymphocyte subsets compared with CD8+-T cells.

thumbnail

Figure 4. IFNγ production by lymphocyte subsets in response to stimulation with live and heat-killed Salmonella.

Percentages of IFNγ-producing lymphocyte subsets in peripheral blood from ten healthy adults following 6 hours of stimulation with (A) live and (B) heat-killed S. Typhimurium D23580. Each dot corresponds to the percentages of IFNγ-producing cells in each lymphocyte subset in blood from one individual. CD3+CD4+: CD4+-T cells; CD3+CD8+: CD8+-T cells; CD3+TCRγδ+: γδ-T cells; CD3CD56+: NK cells; CD3+CD56+: NK-like T cells.

doi:10.1371/journal.pone.0013667.g004

IFNγ-production by peripheral blood lymphocyte subsets in response to stimulation with live compared with heat-killed Salmonella

Previous reports indicate a difference in immune response to Salmonella depending on whether the bacteria are alive or dead [39], [50], [51]. To assess this in the context of the current study, IFNγ production by lymphocyte subsets stimulated with heat-killed D23580 was compared to that by cells stimulated with live D23580 (Figure 4B). No significant difference was found in the percentage of IFNγ-producing cells in each lymphocyte subset (t test, P>0.2), except for γδ-T cells where markedly reduced IFNγ-producing cells were generated by stimulation with dead bacteria (t test, P<0.0001).

Ability of IFNγ produced by peripheral blood lymphocytes to stimulate blood monocytes

In order to give an indication of whether IFNγ produced by peripheral blood lymphocytes in the ICS assays was functional, we measured the ability of plasmas from whole blood stimulated with Salmonella to activate monocytes. CD38 was chosen as an indicator of monocyte activation, because it is strongly upregulated on human monocytes by IFNγ, but not by other monocyte-activating factors, including other cytokines such as TNFα and GM-CSF, and bacterial components such as LPS [52]. Surface expression of CD38 on monocytes in four blood samples was measured by flow cytometry following 5 hours of stimulation with plasmas derived from Salmonella-whole blood stimulation assays. Mean GMFI expression of CD38 was 469 compared with 352 for monocytes from blood samples stimulated with plasma from unstimulated blood (negative control) (P = 0.004) (Figure 5).

thumbnail

Figure 5. Effect of plasma from Salmonella stimulation of whole peripheral blood on monocyte CD38 expression.

Plasma from S. Typhimurium-stimulated whole blood (NTS stimulated) was separated and filter-sterilized prior to adding to fresh blood for five hours followed by measurement of CD38 expression on monocytes. CD38 expression was significantly higher than for blood incubated with plasma taken from unstimulated blood (NC) or for blood incubated with plasma stimulated with NTS in the absence of cells (plasma control). P values are from Student's t test. Data are from four experiments.

doi:10.1371/journal.pone.0013667.g005

In order to ensure that raised CD38 expression was not due to direct bacterial stimulation, plasmas from whole blood stimulation assays were sterilized through 0.2 µm filters before adding to fresh blood samples. To confirm that bacterial components such as LPS in the plasmas were not the cause of raised monocyte CD38 expression, we also stimulated fresh whole blood with plasma samples that had been separated from cells prior to incubating with Salmonella for 6 hours (plasma control). Mean CD38 expression on monocytes from these samples was 374 and was significantly lower than observed with blood stimulated by plasmas collected from whole blood stimulated with Salmonella (P = 0.0001), but was no different to CD38 expression on monocytes in blood incubated with plasma from unstimulated blood (Figure 5).

Absolute numbers of IFNγ-producing lymphocytes in peripheral blood in response to stimulation with Salmonella

While our experiments so far show the proportion of lymphocytes in each subset producing IFNγ, we wanted to determine the absolute numbers of IFNγ-producing cells for each lymphocyte subset in peripheral blood. To do this, we first measured the absolute numbers of each lymphocyte subset, calculated from the percentage of each subset within the lymphocyte population by conventional immunophenotyping and the total lymphocyte count from the hematological analyzer. Then, the absolute numbers of IFNγ-producing lymphocytes was assessed as the product of each absolute count and percentage IFNγ-producing cells (Table 1).

thumbnail

Table 1. Percentage and absolute numbers of IFNγ-producing cells in different lymphocyte subsets in peripheral blood from ten healthy adults following stimulation with Salmonella.

doi:10.1371/journal.pone.0013667.t001

Geometric mean absolute counts for IFNγ-producing cells were approximately 10-fold lower for CD4+-T cells (1 cell/µl) and CD8+-T cells (3 cells/µl) compared with the innate/innate-like subsets (γδ-T cells 14 cell/µl, NK cells 25 cells/µl, NK-like T cells 5 cells/µl). Although a wide range of total IFNγ-producing lymphocytes (16 to 278 cells/µl) was found in peripheral blood across the ten donors, absolute numbers of IFNγ-producing lymphocytes in innate/innate-like subsets were significantly higher than those in the adaptive subsets (geometric means: 50 compared with 7 cells/µl, t test P<0.001).

Discussion

In the present study, we have used intracellular cytokine staining to examine the production of IFNγ by different lymphocyte subsets in response to stimulation with S. Typhimurium D23580, a well-characterized invasive African strain of NTS [12]. Having previously established an importance for antibody in protecting against NTS in Africans [3], [17], we wanted to investigate the cellular arm of the immune response to Salmonella in man. Since T helper 1 cell immunity is key for protection against invasive Salmonella disease [24] and IFNγ is the pre-eminent effector T helper 1 cytokine, we focused our attention on production of this cytokine.

Our choice of studying cytokine production in ex vivo peripheral blood was partly pragmatic, in view of the limited scope for in vivo studies of infection in man. Since the commonest presentation of invasive NTS disease in Africans is bacteremia, in vitro study of infection in peripheral blood arguably provides a reasonable model of this clinical problem. It could also be argued that a principal requirement for IFNγ in Salmonella infection is within the secondary lymphoid tissues, particularly in the context of recurrent intracellular infection observed in individuals with genetic T helper 1 pathway deficiencies. Investigation of IFNγ levels in man in such tissues would be difficult to conduct. The relatively short duration of the experimental model (hours as opposed to days) reflects the rapid time-course of invasive NTS disease in vivo. Approximately half of all African children who die from acute NTS bacteremia do so within the first 24 to 48 hours of admission (unpublished findings). This is similar to the length of time required for a positive blood culture result where facilities for this exist.

Previous studies on cytokine production in response to Salmonella infection have tended to focus on a limited number of lymphocyte subsets and few studies have been performed on human tissue. We wanted to understand the immune response of a broader range of lymphocyte subsets. In particular, we sought to examine whether there were differences in responses between the innate/innate-like subsets compared to lymphocyte subsets of the acquired immune response (the TCR-αβ lymphocytes). Further subdivision of these subsets could be performed with a flow cytometer equipped with more than four fluorescence detector channels. Nevertheless, the panel of markers used in this study permitted us to differentiate the principle subsets of the T and NK lymphocyte lineages and to distinguish between innate and adaptive cells. Since lymphocyte subset sizes can vary considerably between individuals [53], we also wanted to determine absolute as well as relative numbers of IFNγ-producing cells in response to stimulation with Salmonella.

The principle finding of this study is the high inherent capacity within the innate immune system for IFNγ production relative to the adaptive immune system in response to NTS, even when peripheral blood from adults with evidence of existing immunity and/or prior exposure to Salmonella is examined. This latter point is important, since it reduces the possibility that the relative lack of acquired lymphocytes responsive to Salmonella was the result of immune naivety towards Salmonella, though higher levels of Salmonella-specific αβ-T lymphocytes would be expected among Africans where exposure to Salmonella is likely to be much higher.

In relation to percentages of cells in each subset that produce IFNγ, γδ-T cells, NK cells and NK-like T cells had significantly higher percentages of IFNγ-producing cells than CD4+- and CD8+-T cells. Given their smaller overall sizes, it is even more striking that when absolute cell counts are examined, the numbers of IFNγ-producing innate/innate-like subsets are still dominant. Geometric mean values for IFNγ-producing cell counts in the innate/innate-like subsets (14, 25 and 8 cells/µl) are higher than those for the classical adaptive subsets (1 and 3 cells/µl), with a 7-fold overall difference in IFNγ-producing cells between the two broad categories (7 cells/µl for adaptive lymphocytes and 50 cells/µl for innate/innate-like cells).

Whilst our understanding of Salmonella infections in individuals with genetic deficiencies of the T helper 1 pathway demonstrates the importance of T helper 1 immunity and IFNγ for protection against Salmonella, it does not indicate which of the IFNγ-producing cell subsets are needed for this protection. Our finding of capacity within the innate system for IFNγ production suggests that during acute infections with Salmonella, this capacity may suffice and priming of the acquired T cell response through prior exposure/infection or vaccination may not be essential. The functionality of the secreted IFNγ demonstrated by the upregulation of CD38 expression on blood monocytes adds further significance to these observations.

Using the mouse model of Salmonella infection, IFNγ production has been demonstrated in a variety of individual lymphocyte subsets. A strong T helper 1 response is characteristic of S. Typhimurium infection in the mouse, with a large expansion in numbers of activated IFNγ-secreting CD4+- and CD8+-T cells in the blood, though this response takes a week to develop during primary infection [54], [55], [56]. However, splenic cells from mice with severe combined immunodeficiency (SCID) that lack T cells produce elevated levels of IFNγ after stimulation with S. Typhimurium [57], suggesting that NK or other innate cells are responsible for IFNγ production. NK cell numbers are elevated post infection with Salmonella [58], [59], [60] and are an early source of IFNγ [59] and mice depleted of NK cells show diminished resistance to Salmonella infection [58], [61]. Human NK cells have also been shown to produce IFNγ in vitro in response to stimulation with Salmonella and to clear macrophages of Salmonella infection [61].

An important subset in the innate response to NTS is the γδ-T cell subset. Since these cells can produce both innate and adaptive responses, it is probably more accurate to describe them as ‘innate-like’, since although in the current study they are most likely mounting an innate response, they have the capacity to respond specifically through their T cell receptors. Expansion of the γδ-T cell subset in peripheral blood has been found during Salmonella infection in man, particularly with systemic disease [62], as has enlargement of the NK-like T cell subset [63]. γδ-T cells from patients with Salmonella infection produce high levels of IFNγ [42]. Likewise, increased numbers of γδ-T cells are found in murine salmonellosis [60], [64], [65], [66], particularly in the peritoneal cavity, and these produce IFNγ in response to Salmonella-infected macrophages. Depletion of γδ-T cells in the mouse results in increased susceptibility to Salmonella infection [67].

While the response of other subsets investigated was independent of whether live or dead bacteria were used for stimulation, it is intriguing that a much higher proportion of γδ-T cells produced IFNγ in response to live Salmonella compared with heat-killed Salmonella. The necessity of live Salmonella for induction of a T helper 1 response in the mouse has previously been described [39], [50], [68] and attributed to better IL-12 induction by live bacteria [51]. Our finding in relation to IFNγ production by γδ-T cells in man suggests that the γδ-T cell subset may have an important role in protecting individuals from acute Salmonella infections.

IFNγ production by the innate arm of the immune system produces a rapid response that may be key in controlling the early stages of infection. This, by itself, may not always be sufficient to clear Salmonella infection in man and prevention of persistent infection in the macrophage beds that can lead to recrudescence of infection. Studies in the mouse indicate that αβ-T cells are not required during the first week of Salmonella infection [69], [70] and IFNγ is produced in response to IL12 and IL18 in rag−/− and SCID mice that lack T cells [71]. These findings all support the concept that cells other than αβ-T cells are responsible for production of the IFNγ required for survival in the first week of Salmonella infection. Nevertheless, mice lacking αβ-T cells fail to clear Salmonella and die later during Salmonella infection [31], [70], [72], [73], [74], [75]. Surprisingly, this clearance does not appear to involve IFNγ, since depletion of this cytokine from day 6 of Salmonella infection in the mouse does not prevent bacterial clearance [76]. This raises the possibility that in many instances IFNγ-production by αβ-T cells is not required for immunity to Salmonella. In contrast, IL-2 has been found to enhance clearance of Salmonella in the mouse raising the possibility that this cytokine is more important than IFNγ during the late response to Salmonella infection [77].

Our study has potential implications in relation to the reduction of IFNγ levels seen in HIV infection and the high susceptibility of Africans living with HIV/AIDS to NTS bacteremia. Since HIV targets cells that express CD4, especially CD4+-T cells, and decreased IFNγ production in the context of HIV infection occurs in cells of the acquired immune system [45], [47] the finding of inherent capacity for IFNγ production among innate cells could be exploited to therapeutic advantage. Expansion of non-CD4-expressing cells of the innate immune system with IFNγ-producing capacity, in particular NK cells and γδ-T cells, could compensate for lost IFNγ production by CD4+-T cells, particularly in advanced HIV/AIDS. This could be used both in the prevention and treatment of invasive NTS disease in such individuals.

Our present findings indicate that the innate cellular arm of the immune system has an inherent capacity for production of IFNγ. Taken in the context of other work on the role of antibody in protection against NTS bacteremia, these findings suggest that the primary requirement of a vaccine against NTS should be the induction of a protective antibody response against these bacteria. Without such antibody, serum bactericidal function [3] and the opsonic activity required for phagocyte cell function [17] are both abrogated leaving children vulnerable to both extracellular and intracellular growth of Salmonella. Prevention of persistent Salmonella infection with recrudescent disease, as commonly found in HIV-infected Africans [7], is also an important goal of vaccination and this may require the development of a robust adaptive cellular response to NTS. Further insight into the need for this will be gained through the study of at-risk populations where the disease is most prevalent: young children and HIV-infected adults in sub-Saharan Africa.

Acknowledgments

The authors would like to thank Mr Timothy Plant, Mr John Pravin and the staff at the Clinical Immunology Service, University of Birmingham, for technical help. We are grateful to Professor Robert S. Heyderman for helpful comments on the manuscript.

Author Contributions

Conceived and designed the experiments: TSN AES WLM MTD CAM. Performed the experiments: TSN AES CAM. Analyzed the data: TSN AES WLM MTD CAM. Wrote the paper: CAM.

References

  1. 1. Morpeth SC, Ramadhani HO, Crump JA (2009) Invasive non-Typhi Salmonella disease in Africa. Clin Infect Dis 49: 606–611.
  2. 2. Sigauque B, Roca A, Mandomando I, Morais L, Quinto L, et al. (2009) Community-acquired bacteremia among children admitted to a rural hospital in Mozambique. Pediatr Infect Dis J 28: 108–113.
  3. 3. MacLennan CA, Gondwe EN, Msefula CL, Kingsley RA, Thomson NR, et al. (2008) The neglected role of antibody in protection against bacteremia caused by nontyphoidal strains of Salmonella in African children. J Clin Invest 118: 1553–1562.
  4. 4. Gordon MA, Graham SM, Walsh AL, Wilson L, Phiri A, et al. (2008) Epidemics of invasive Salmonella enterica serovar Enteritidis and S. enterica serovar Typhimurium infection associated with multidrug resistance among adults and children in Malawi. Clin Infect Dis 46: 963–969.
  5. 5. Kariuki S, Revathi G, Kariuki N, Kiiru J, Mwituria J, et al. (2006) Characterisation of community acquired non-typhoidal Salmonella from bacteraemia and diarrhoeal infections in children admitted to hospital in Nairobi, Kenya. BMC Microbiol 6: 101.
  6. 6. Brent AJ, Oundo JO, Mwangi I, Ochola L, Lowe B, et al. (2006) Salmonella bacteremia in Kenyan children. Pediatr Infect Dis J 25: 230–236.
  7. 7. Gordon MA, Banda HT, Gondwe M, Gordon SB, Boeree MJ, et al. (2002) Non-typhoidal Salmonella bacteraemia among HIV-infected Malawian adults: high mortality and frequent recrudescence. AIDS 16: 1633–1641.
  8. 8. Graham SM, Molyneux EM, Walsh AL, Cheesbrough JS, Molyneux ME, et al. (2000) Nontyphoidal Salmonella infections of children in tropical Africa. Pediatr Infect Dis J 19: 1189–1196.
  9. 9. Gilks CF, Brindle RJ, Otieno LS, Simani PM, Newnham RS, et al. (1990) Life-threatening bacteraemia in HIV-1 seropositive adults admitted to hospital in Nairobi, Kenya. Lancet 336: 545–549.
  10. 10. Mtove G, Amos B, von Seidlein L, Hendriksen I, Mwambuli A, et al. (2010) Invasive salmonellosis among children admitted to a rural Tanzanian hospital and a comparison with previous studies. PLoS One 5: e9244.
  11. 11. Nadjm B, Amos B, Mtove G, Ostermann J, Chonya S, et al. (2010) WHO guidelines for antimicrobial treatment in children admitted to hospital in an area of intense Plasmodium falciparum transmission: prospective study. BMJ 340: c1350.
  12. 12. Kingsley RA, Msefula CL, Thomson NR, Kariuki S, Holt KE, et al. (2009) Epidemic multiple drug resistant Salmonella Typhimurium causing invasive disease in sub-Saharan Africa have a distinct genotype. Genome Res 19: 2279–2287.
  13. 13. MacLennan CA, Gilchrist JJ, Gordon MA, Cunningham AF, Cobbold M, et al. (2010) Dysregulated humoral immunity to nontyphoidal Salmonella in HIV-infected African adults. Science 328: 508–512.
  14. 14. Fields PI, Swanson RV, Haidaris CG, Heffron F (1986) Mutants of Salmonella Typhimurium that cannot survive within the macrophage are avirulent. Proc Natl Acad Sci U S A 83: 5189–5193.
  15. 15. Mouy R, Fischer A, Vilmer E, Seger R, Griscelli C (1989) Incidence, severity, and prevention of infections in chronic granulomatous disease. J Pediatr 114: 555–560.
  16. 16. Lazarus GM, Neu HC (1975) Agents responsible for infection in chronic granulomatous disease of childhood. J Pediatr 86: 415–417.
  17. 17. Gondwe EN, Molyneux ME, Goodall M, Graham SM, Mastroeni P, et al. (2010) Importance of antibody and complement for oxidative burst and killing of invasive nontyphoidal Salmonella by blood cells in Africans. Proc Natl Acad Sci U S A in press.
  18. 18. Kagaya K, Watanabe K, Fukazawa Y (1989) Capacity of recombinant γ-interferon to activate macrophages for Salmonella-killing activity. Infect Immun 57: 609–615.
  19. 19. Vazquez-Torres A, Jones-Carson J, Mastroeni P, Ischiropoulos H, Fang FC (2000) Antimicrobial actions of the NADPH phagocyte oxidase and inducible nitric oxide synthase in experimental salmonellosis. I. Effects on microbial killing by activated peritoneal macrophages in vitro. J Exp Med 192: 227–236.
  20. 20. Foster N, Hulme SD, Barrow PA (2003) Induction of antimicrobial pathways during early-phase immune response to Salmonella spp. in murine macrophages: γ-interferon (IFNγ) and upregulation of IFNγ receptor alpha expression are required for NADPH phagocytic oxidase gp91-stimulated oxidative burst and control of virulent Salmonella spp. Infect Immun 71: 4733–4741.
  21. 21. Janssen R, Van Wengen A, Verhard E, De Boer T, Zomerdijk T, et al. (2002) Divergent role for TNF-α in IFN-γ-induced killing of Toxoplasma gondii and Salmonella Typhimurium contributes to selective susceptibility of patients with partial IFNγ receptor 1 deficiency. J Immunol 169: 3900–3907.
  22. 22. Gordon MA, Jack DL, Dockrell DH, Lee ME, Read RC (2005) γ-interferon enhances internalization and early nonoxidative killing of Salmonella enterica serovar Typhimurium by human macrophages and modifies cytokine responses. Infect Immun 73: 3445–3452.
  23. 23. Jouanguy E, Doffinger R, Dupuis S, Pallier A, Altare F, et al. (1999) IL-12 and IFNγ in host defense against mycobacteria and Salmonella in mice and men. Curr Opin Immunol 11: 346–351.
  24. 24. MacLennan C, Fieschi C, Lammas DA, Picard C, Dorman SE, et al. (2004) Interleukin (IL)-12 and IL-23 are key cytokines for immunity against Salmonella in humans. J Infect Dis 190: 1755–1757.
  25. 25. Bustamante J, Boisson-Dupuis S, Jouanguy E, Picard C, Puel A, et al. (2008) Novel primary immunodeficiencies revealed by the investigation of paediatric infectious diseases. Curr Opin Immunol 20: 39–48.
  26. 26. van de Vosse E, van Dissel JT, Ottenhoff TH (2009) Genetic deficiencies of innate immune signalling in human infectious disease. Lancet Infect Dis 9: 688–698.
  27. 27. Altare F, Lammas D, Revy P, Jouanguy E, Doffinger R, et al. (1998) Inherited interleukin 12 deficiency in a child with Bacille Calmette-Guerin and Salmonella Enteritidis disseminated infection. J Clin Invest 102: 2035–2040.
  28. 28. de Jong R, Altare F, Haagen IA, Elferink DG, Boer T, et al. (1998) Severe mycobacterial and Salmonella infections in interleukin-12 receptor-deficient patients. Science 280: 1435–1438.
  29. 29. Picard C, Fieschi C, Altare F, Al-Jumaah S, Al-Hajjar S, et al. (2002) Inherited interleukin-12 deficiency: IL12B genotype and clinical phenotype of 13 patients from six kindreds. Am J Hum Genet 70: 336–348.
  30. 30. Ezekowitz RA, Dinauer MC, Jaffe HS, Orkin SH, Newburger PE (1988) Partial correction of the phagocyte defect in patients with X-linked chronic granulomatous disease by subcutaneous interferon-γ. N Engl J Med 319: 146–151.
  31. 31. Hess J, Ladel C, Miko D, Kaufmann SH (1996) Salmonella Typhimurium aroA- infection in gene-targeted immunodeficient mice: major role of CD4+ TCR-αβ cells and IFNγ in bacterial clearance independent of intracellular location. J Immunol 156: 3321–3326.
  32. 32. Muotiala A, Makela PH (1990) The role of IFNγ in murine Salmonella Typhimurium infection. Microb Pathog 8: 135–141.
  33. 33. Mastroeni P, Villarreal-Ramos B, Hormaeche CE (1992) Role of T cells, TNFα and IFNγ in recall of immunity to oral challenge with virulent Salmonellae in mice vaccinated with live attenuated aro- Salmonella vaccines. Microb Pathog 13: 477–491.
  34. 34. Gulig PA, Doyle TJ, Clare-Salzler MJ, Maiese RL, Matsui H (1997) Systemic infection of mice by wild-type but not Spv- Salmonella Typhimurium is enhanced by neutralization of γ-interferon and tumor necrosis factor-α. Infect Immun 65: 5191–5197.
  35. 35. Nauciel C, Espinasse-Maes F (1992) Role of γ-interferon and tumor necrosis factor-α in resistance to Salmonella Typhimurium infection. Infect Immun 60: 450–454.
  36. 36. Mastroeni P, Harrison JA, Robinson JH, Clare S, Khan S, et al. (1998) Interleukin-12 is required for control of the growth of attenuated aromatic-compound-dependent Salmonellae in BALB/c mice: role of γ-interferon and macrophage activation. Infect Immun 66: 4767–4776.
  37. 37. Ramarathinam L, Shaban RA, Niesel DW, Klimpel GR (1991) γ-interferon (IFNγ) production by gut-associated lymphoid tissue and spleen following oral Salmonella Typhimurium challenge. Microb Pathog 11: 347–356.
  38. 38. Matsui K, Arai T (1992) The comparison of cell-mediated immunity induced by immunization with porin, viable cells and killed cells of Salmonella Typhimurium. Microbiol Immunol 36: 269–278.
  39. 39. Thatte J, Rath S, Bal V (1993) Immunization with live versus killed Salmonella Typhimurium leads to the generation of an IFNγ-dominant versus an IL-4-dominant immune response. Int Immunol 5: 1431–1436.
  40. 40. Eckmann L, Fierer J, Kagnoff MF (1996) Genetically resistant (Ityr) and susceptible (Itys) congenic mouse strains show similar cytokine responses following infection with Salmonella Dublin. J Immunol 156: 2894–2900.
  41. 41. Pie S, Truffa-Bachi P, Pla M, Nauciel C (1997) Th1 response in Salmonella Typhimurium-infected mice with a high or low rate of bacterial clearance. Infect Immun 65: 4509–4514.
  42. 42. Mizuno Y, Takada H, Nomura A, Jin CH, Hattori H, et al. (2003) Th1 and Th1-inducing cytokines in Salmonella infection. Clin Exp Immunol 131: 111–117.
  43. 43. Kedzierska K, Crowe SM (2001) Cytokines and HIV-1: interactions and clinical implications. Antivir Chem Chemother 12: 133–150.
  44. 44. Bailer RT, Holloway A, Sun J, Margolick JB, Martin M, et al. (1999) IL-13 and IFNγ secretion by activated T cells in HIV-1 infection associated with viral suppression and a lack of disease progression. J Immunol 162: 7534–7542.
  45. 45. Imami N, Antonopoulos C, Hardy GA, Gazzard B, Gotch FM (1999) Assessment of type 1 and type 2 cytokines in HIV type 1-infected individuals: impact of highly active antiretroviral therapy. AIDS Res Hum Retroviruses 15: 1499–1508.
  46. 46. Clerici M, Shearer GM (1993) A TH1—>TH2 switch is a critical step in the etiology of HIV infection. Immunol Today 14: 107–111.
  47. 47. Fan J, Li P, Kok TW, Burrell CJ (1997) AZT blocks down-regulation of IL-2 and IFNγ gene expression in HIV acutely infected cells. Arch Virol 142: 1035–1043.
  48. 48. Kelleher AD, Sewell WA, Cooper DA (1999) Effect of protease therapy on cytokine secretion by peripheral blood mononuclear cells (PBMC) from HIV-infected subjects. Clin Exp Immunol 115: 147–152.
  49. 49. Cunningham AF, Gaspal F, Serre K, Mohr E, Henderson IR, et al. (2007) Salmonella induces a switched antibody response without germinal centers that impedes the extracellular spread of infection. J Immunol 178: 6200–6207.
  50. 50. Pashine A, John B, Rath S, George A, Bal V (1999) Th1 dominance in the immune response to live Salmonella Typhimurium requires bacterial invasiveness but not persistence. Int Immunol 11: 481–489.
  51. 51. John B, Rajagopal D, Pashine A, Rath S, George A, et al. (2002) Role of IL-12-independent and IL-12-dependent pathways in regulating generation of the IFNγ component of T cell responses to Salmonella Typhimurium. J Immunol 169: 2545–2552.
  52. 52. Musso T, Deaglio S, Franco L, Calosso L, Badolato R, et al. (2001) CD38 expression and functional activities are up-regulated by IFNγ on human monocytes and monocytic cell lines. J Leukoc Biol 69: 605–612.
  53. 53. Mandala WL, MacLennan JM, Gondwe EN, Ward SA, Molyneux ME, et al. (2010) Lymphocyte subsets in healthy Malawians: implications for immunologic assessment of HIV infection in Africa. J Allergy Clin Immunol 125: 203–208.
  54. 54. Mittrucker HW, Kohler A, Kaufmann SH (2002) Characterization of the murine T-lymphocyte response to Salmonella enterica serovar Typhimurium infection. Infect Immun 70: 199–203.
  55. 55. Srinivasan A, Foley J, McSorley SJ (2004) Massive number of antigen-specific CD4 T cells during vaccination with live attenuated Salmonella causes interclonal competition. J Immunol 172: 6884–6893.
  56. 56. Ugrinovic S, Menager N, Goh N, Mastroeni P (2003) Characterization and development of T-Cell immune responses in B-cell-deficient (Igh-6(-/-)) mice with Salmonella enterica serovar Typhimurium infection. Infect Immun 71: 6808–6819.
  57. 57. Ramarathinam L, Niesel DW, Klimpel GR (1993) Salmonella Typhimurium induces IFNγ production in murine splenocytes. Role of natural killer cells and macrophages. J Immunol 150: 3973–3981.
  58. 58. Schafer R, Eisenstein TK (1992) Natural killer cells mediate protection induced by a Salmonella aroA mutant. Infect Immun 60: 791–797.
  59. 59. Harrington L, Srikanth CV, Antony R, Shi HN, Cherayil BJ (2007) A role for natural killer cells in intestinal inflammation caused by infection with Salmonella enterica serovar Typhimurium. FEMS Immunol Med Microbiol 51: 372–380.
  60. 60. Hirose K, Nishimura H, Matsuguchi T, Yoshikai Y (1999) Endogenous IL-15 might be responsible for early protection by natural killer cells against infection with an avirulent strain of Salmonella Choleraesuis in mice. J Leukoc Biol 66: 382–390.
  61. 61. Lapaque N, Walzer T, Meresse S, Vivier E, Trowsdale J (2009) Interactions between human NK cells and macrophages in response to Salmonella infection. J Immunol 182: 4339–4348.
  62. 62. Hara T, Mizuno Y, Takaki K, Takada H, Akeda H, et al. (1992) Predominant activation and expansion of Vγ9-bearing γδ-T cells in vivo as well as in vitro in Salmonella infection. J Clin Invest 90: 204–210.
  63. 63. Jason J, Buchanan I, Archibald LK, Nwanyanwu OC, Bell M, et al. (2000) Natural T, γδ, and NK cells in mycobacterial, Salmonella, and human immunodeficiency virus infections. J Infect Dis 182: 474–481.
  64. 64. Emoto M, Danbara H, Yoshikai Y (1992) Induction of γδ-T cells in murine salmonellosis by an avirulent but not by a virulent strain of Salmonella Choleraesuis. J Exp Med 176: 363–372.
  65. 65. Nishimura H, Hiromatsu K, Kobayashi N, Grabstein KH, Paxton R, et al. (1996) IL-15 is a novel growth factor for murine γδ-T cells induced by Salmonella infection. J Immunol 156: 663–669.
  66. 66. Skeen MJ, Ziegler HK (1993) Induction of murine peritoneal γδ-T cells and their role in resistance to bacterial infection. J Exp Med 178: 971–984.
  67. 67. Mixter PF, Camerini V, Stone BJ, Miller VL, Kronenberg M (1994) Mouse T lymphocytes that express a γδ-T cell antigen receptor contribute to resistance to Salmonella infection in vivo. Infect Immun 62: 4618–4621.
  68. 68. Harrison JA, Villarreal-Ramos B, Mastroeni P, Demarco de Hormaeche R, Hormaeche CE (1997) Correlates of protection induced by live Aro- Salmonella Typhimurium vaccines in the murine typhoid model. Immunology 90: 618–625.
  69. 69. Hormaeche CE, Mastroeni P, Arena A, Uddin J, Joysey HS (1990) T cells do not mediate the initial suppression of a Salmonella infection in the RES. Immunology 70: 247–250.
  70. 70. Weintraub BC, Eckmann L, Okamoto S, Hense M, Hedrick SM, et al. (1997) Role of αβ- and γδ-T cells in the host response to Salmonella infection as demonstrated in T-cell-receptor-deficient mice of defined Ity genotypes. Infect Immun 65: 2306–2312.
  71. 71. Mastroeni P, Clare S, Khan S, Harrison JA, Hormaeche CE, et al. (1999) Interleukin 18 contributes to host resistance and γ-interferon production in mice infected with virulent Salmonella Typhimurium. Infect Immun 67: 478–483.
  72. 72. O'Brien AD, Metcalf ES (1982) Control of early Salmonella Typhimurium growth in innately Salmonella-resistant mice does not require functional T lymphocytes. J Immunol 129: 1349–1351.
  73. 73. Mittrucker HW, Kohler A, Mak TW, Kaufmann SH (1999) Critical role of CD28 in protective immunity against Salmonella Typhimurium. J Immunol 163: 6769–6776.
  74. 74. Sinha K, Mastroeni P, Harrison J, de Hormaeche RD, Hormaeche CE (1997) Salmonella Typhimurium aroA, htrA, and aroD htrA mutants cause progressive infections in athymic (nu/nu) BALB/c mice. Infect Immun 65: 1566–1569.
  75. 75. Nauciel C (1990) Role of CD4+ T cells and T-independent mechanisms in acquired resistance to Salmonella Typhimurium infection. J Immunol 145: 1265–1269.
  76. 76. Muotiala A, Makela PH (1993) Role of γ-interferon in late stages of murine salmonellosis. Infect Immun 61: 4248–4253.
  77. 77. al-Ramadi BK, Al-Dhaheri MH, Mustafa N, Abouhaidar M, Xu D, et al. (2001) Influence of vector-encoded cytokines on anti-Salmonella immunity: divergent effects of interleukin-2 and tumor necrosis factor-α. Infect Immun 69: 3980–3988.