Advertisement
Research Article

Macrophage and T-Cell Gene Expression in a Model of Early Infection with the Protozoan Leishmania chagasi

  • Nicholas A. Ettinger,

    Affiliations: Interdisciplinary Graduate Program in Molecular and Cellular Biology, University of Iowa, Iowa City, Iowa, United States of America, Medical Scientist Training Program, University of Iowa Carver College of Medicine, Iowa City, Iowa, United States of America

    X
  • Mary E. Wilson mail

    mary-wilson@uiowa.edu

    Affiliations: Interdisciplinary Graduate Program in Molecular and Cellular Biology, University of Iowa, Iowa City, Iowa, United States of America, Medical Scientist Training Program, University of Iowa Carver College of Medicine, Iowa City, Iowa, United States of America, Departments of Internal Medicine and Microbiology, University of Iowa Carver College of Medicine, Iowa City, Iowa, United States of America, Department of Epidemiology, University of Iowa College of Public Health, Iowa City, Iowa, United States of America, VA Medical Center, Iowa City, Iowa, United States of America

    X
  • Published: June 25, 2008
  • DOI: 10.1371/journal.pntd.0000252

Abstract

Visceral leishmaniasis is a potentially fatal infectious disease caused by the protozoan parasite Leishmania infantum/chagasi in the New World, or by L. donovani or L. infantum/chagasi in the Old World. Infection leads to a variety of outcomes ranging from asymptomatic infection to active disease, characterized by fevers, cachexia, hepatosplenomegaly and suppressed immune responses. We reasoned that events occurring during the initial few hours when the parasite encounters cells of the innate and adaptive immune systems are likely to influence the eventual immune response that develops. Therefore, we performed gene expression analysis using Affymetrix U133Plus2 microarray chips to investigate a model of early infection with human monocyte-derived macrophages (MDMs) challenged with wild-type L. chagasi parasites, with or without subsequent co-culture with Leishmania-naïve, autologous T-cells. Microarray data generated from total RNA were analyzed with software from the Bioconductor Project and functional clustering and pathway analysis were performed with DAVID and Gene Set Enrichment Analysis (GSEA), respectively. Many transcripts were down-regulated by infection in cultures containing macrophages alone, and the pattern indicated a lack of a classically activated phenotype. By contrast, the addition of autologous Leishmania-naïve T cells to infected macrophages resulted in a pattern of gene expression including many markers of type 1 immune cytokine activation (IFN-γ, IL-6, IL-1α, IL-1β). There was simultaneous up-regulation of a few markers of immune modulation (IL-10 cytokine accumulation; TGF-β Signaling Pathway). We suggest that the initial encounter between L. chagasi and cells of the innate and adaptive immune system stimulates primarily type 1 immune cytokine responses, despite a lack of classical macrophage activation. This local microenvironment at the site of parasite inoculation may determine the initial course of immune T-cell development.

Author Summary

Visceral leishmaniasis (VL) is a potentially fatal vector-borne infectious disease that leads to a variety of outcomes ranging from asymptomatic infection to symptomatic disease. In northeast Brazil, the etiological agent of VL is the protozoan Leishmania chagasi/infantum. Active VL is characterized by fevers, weight loss, hepatosplenomegaly and eventually immune suppression. Without treatment, most symptomatic patients die from secondary bacterial or viral super-infection. We hypothesized that a unique immune response to L. chagasi is initiated early during the initial interactions between the immune system cells that first encounter the parasite. These include macrophages and T-cells, elements of the innate and adaptive immune systems, respectively. We studied an in vitro model of these interactions in which human monocyte-derived macrophages were challenged with L. chagasi, and subsequently cultured with Leishmania-naïve, autologous T cells. Using microarray chips, we examined changes in global gene expression induced by these early interactions. Infection did not elicit a classical inflammatory program in macrophages. However, co-culture of infected macrophages and autologous T cells exhibited a pattern of gene expression, including many markers of acute inflammation or a type 1 immune response. These data suggest that early changes at the site of parasite infection would be conducive to the development of a protective type 1 response, followed by modulation of this same response.

Introduction

Visceral leishmaniasis (VL) is a potentially fatal infectious disease caused by the protozoan parasites Leishmania chagasi/infantum in the New or in parts of the Old World, or by L. donovani in other regions of the Old World.[1] Infection leads to a variety of outcomes ranging from asymptomatic infection to active disease, which is characterized by fevers, cachexia, hepatosplenomegaly and suppressed immune responses. Without treatment, most symptomatic patients die.[2] Investigations into the mechanism underlying the immunosuppression during acute VL have demonstrated defective antigen-specific proliferation and IFN-γ responses to parasite antigen,[3][5] high expression of IL-10 in the spleen and serum of symptomatic VL patients[6][10] and high serum levels of IL-4, TGF-β and IL-2 receptor.[11][13] In vitro infection with Leishmania parasites suppresses macrophage microbicidal responses and IFN-γ pathway signaling,[14][17] suggesting that these suppressive changes begin at the earliest stages of infection. Whether this defect in macrophage responses to Leishmania infection is communicated to local adaptive immune cells is not known.

We reasoned that events occurring during the initial few hours when the parasite encounters cells of the innate and adaptive immune systems are likely to influence the eventual immune response that develops. We hypothesized that the parasite would cause unique changes in gene expression in both innate and adaptive cells of the immune system encountered early in infection. To test this hypothesis, we analyzed gene expression with an in vitro model using human monocyte-derived macrophages (MDMs) challenged with L. chagasi promastigotes with or without subsequent co-culture with Leishmania-naïve, autologous T-cells. Gene expression analysis of RNA harvested from both MDMs alone and the MDM-T cell co-cultures indicated a surprising type 1 inflammatory cytokine response during the earliest stages of parasite invasion into the host.

Materials and Methods

Parasites

A Brazilian isolate of L. chagasi (MHOM/BR/00/1669) was maintained in hamsters by serial intracardiac injection of amastigotes. Parasites were grown as promastigotes at 26°C in liquid hemoflagellate-modified minimal essential medium and used within 3 weeks of isolation.[18] Parasite sub-cultures were used on day 7 of growth for infections.

Infection protocol

On day zero, venous blood was drawn from four healthy, US resident adult male volunteers ages 24–64 in accordance with the human subjects guidelines approved by the University of Iowa Institutional Review Board. None of the donors have been exposed to Leishmania. Written consent was obtained from all donors. Only male donors were used to eliminate, as a variable in the analysis, the known effects of gender on VL.[2],[19] PBMCs were isolated from venous blood by density gradient sedimentation on Ficoll-Paque Plus (GE Healthcare, Uppsala, Sweden) and cultured in RPMI 1640 (Gibco) with 20% autologous serum in 60 ml Teflon wells (Savillex Corporation) at 37°C in 5% CO2. Serum was obtained from the volunteers using BD Vacutainer Serum Plus Blood Collection tubes (Becton Dickson). On day 6, human MDMs were purified by adherence to tissue culture plates (Corning) that had been pre-coated with poly-L-lysine (0.1 mg/ml; Sigma). After 4 hours culture in RPMI 1640 with 10% heat-inactivated fetal calf serum (Sigma), 2 mM L-glutamine, 100U/ml penicillin and 100 µg/ml streptomycin (Gibco) [RP-10] at 37°C, 5% CO2, non-adherent lymphocytes were rinsed off. MDMs were infected with stationary phase L. chagasi parasites at a 10:1 parasite:MDM ratio. Plates were immediately centrifuged at 60 g for 4 minutes at 4°C to synchronize the infections. After one hour, non-adherent parasites were rinsed off and cells were maintained in RP-10. PBMCs were again isolated from the same donor on day 7, and CD3+ cells were isolated by negative selection using either a cocktail of antibody-coated beads (anti-CD14, anti-CD19, anti-CD56; Miltenyi Biotec) or the Pan-T-Cell Isolation Kit II (Miltenyi Biotec) according to manufacturer's instructions. A small aliquot was fixed and stained for flow cytometry analysis with an anti-CD3-PE conjugated antibody (Miltenyi Biotec) to assess enrichment. The resultant enriched population should contain a mixed population of both Leishmania-naïve CD4+ and CD8+ T cells, but should be depleted of monocytes, dendritic cells, NK cells and NKT cells. Negative selection routinely resulted in a population of cells that was >90–95% CD3+ (data not shown). Autologous T cells were added to the infected macrophage cultures at an estimated 3:1 T cell:MDM ratio, and the plates were again spun at 4°C and 60 g for 4 minutes.

Assessment of infection

Macrophages were removed from the wells with citric saline [0.135M KCl, 0.015M Trisodium citrate); Fischer] for 5 minutes at 37°C. Infection efficiency was evaluated by manually counting ≥200 macrophages in cytospin preparations (Cytospin 4, Thermo-Shandon Fisher) stained with Diff Quik (Protocol Hema 3, Fisher Scientific). Experiments in which ≥70% macrophages were infected were used for RNA extraction. In the infection replicates used for the microarray studies, we averaged a percent infection (mean±SEM) of 79.9±7.2 for the infected macrophage only replicates and a percent infection of 76±7.7 for the infected macrophage-T-cell co-culture replicates.

RNA isolation, cDNA preparation and hybridization

Total RNA was isolated using Trizol (Invitrogen) as specified in the manufacturer's instructions. RNA was treated with DNaseI and further cleaned using the Qiagen RNeasy mini-kit (Qiagen, Hilden, Germany). RNA for microarrays was harvested from uninfected or infected macrophages and from uninfected or infected macrophage – T-cell co-cultures at 4 hours after the initiation of co-culture (28 hours after initiation of infection). RNAs for validation experiments were harvested after 4 hours, 24 hours, 2 days and 3 days of co-culture. RNA quality was assessed using the Agilent Model 2100 Bioanalyzer (Agilent Technologies, Palo Alto, CA). cRNA was generated from five µg of total RNA by using the Affymetrix GeneChip one-cycle target labeling kit (Affymetrix, Inc., Santa Clara, CA) according to the manufacturer's recommended protocols. The resultant biotinylated cRNA was fragmented and hybridized to the GeneChip Human Genome U133 Plus 2.0 Array (Affymetrix, Inc.). The arrays were washed, stained, and scanned using the Affymetrix Model 450 Fluidics Station and Affymetrix Model 3000 scanner using the manufacturer's recommended protocols by the University of Iowa DNA Core Facility. Each sample and microarray underwent standard quality control evaluations for cRNA amplification of more than 4-fold, percentage of probe sets reliably detecting between 40 and 60 percent present call, and a 3′-5′ ratio of GAPDH gene less than 3.

Microarray data analysis

Raw data analysis was performed using code written in R and software from the open-source Bioconductor Project.[20] Preliminary data quality control assessments were performed with affyQCReport. The raw fluorescence data were background adjusted, normalized and converted to expression-level data using gcRMA.[21],[22] For each donor, the log2 gcRMA expression data from the uninfected sample were subtracted from the log2 gcRMA expression data from the infected sample and then these paired data were analyzed with RankProd[23],[24] using the one-class model. Macrophage-only data were analyzed separately from the macrophage-T cell co-culture data. Both raw and normalized data have been deposited with ArrayExpress (http://www.ebi.ac.uk/microarray-as/aer/?​#ae-main[0]) under accession number E-MEXP-1290. Briefly, RankProd rank orders all probe sets within each replicate by expression level and then calculates an ‘RP-Value’ for each probe set based on the amount that a particular probe set appears at the top or at the bottom of the ranked list. The RP-Value for each probe set then increases if the probe set is consistently present at the top or the bottom of the list. The software then re-sorts all the probe sets based on RP-Value, taking into account all pair-wise comparisons and adjusts for multiple hypothesis testing via permutation of the replicate labels. For each probe set, a “Percent False Positive” (PFP) value is calculated as an estimate of the false discovery rate.[23],[25] The cutoff for significance was chosen to be all genes with a PFP rate of 5% or less. These genes, adjusted by permutation for multiple hypothesis testing, had less than a 5% chance of representing a false positive signal of statistically significant differential expression. After significant genes were identified, annotation and functional clustering was performed using DAVID.[26] The raw list of AffyIDs for each condition (MDM vs. MDM-T cell co-culture; up vs. down regulated by infection) was submitted as a “Gene List” to DAVID and then the data were analyzed using the “Functional Annotation Clustering” tool using the “Highest” classification stringency setting.

Pathway analysis was performed using Gene Set Enrichment Analysis,v.2.[27] GSEA takes a list of genes and tests whether, within that queried list of genes, there is statistically significant enrichment or not of pre-defined groups of genes, or “gene sets.” Gene sets examined through GSEA include canonical metabolic and signaling pathways, groups of genes previously identified and validated to be up- or down-regulated when cells are given a particular stimulus, or genes present at a similar physical location (e.g. within a particular cytoband). This type of analysis can detect subtle changes present in the data. For example, if several key members of a particular signaling pathway are all up-regulated by 5% these changes may not be detected by traditional analyses, although these changes could biologically represent a substantial increase in the net “flux” of the signaling pathway. GSEA settings were default except for 1000 permutations, “phenotype” permutation and calculating differential expression based on the mean expression value for each phenotype.

Real-time PCR

cDNA was generated from the cleaned up total RNA samples using the Superscript III First Strand Synthesis System kit (Invitrogen) using random hexamer primers and an RNaseH-treatment step following the manufacturer's instructions. TaqMan real-time PCR gene expression assays were purchased from Applied Biosystems, Inc. (ABI) and were performed according to the manufacturer's instructions. Data were analyzed using the Δ(ΔCt) method.[28]

Cytokine assays

Supernatants from three independent infections, each from a separate individual, were assayed. The supernatants were stored at −20°C before use. Cytokine levels in the supernatants were assessed using a panel and controls samples, from Lincoplex (Millipore, Billerica, MA), according to the manufacturer's instructions. Data were generated on a BioRad Bio-Plex Assay Reader 200 (BioRad).

Statistics

RT-PCR and cytokine data were plotted as the mean of three independent experiments. Statistical significance was assessed with GraphPad Prism, v.5 using a 1-way ANOVA and Tukey's Multiple Comparison Test or a 2-way ANOVA test.

Results

To test our hypothesis that the parasite induces unique changes in gene expression in both innate and adaptive cells of the immune system encountered early in infection, we examined gene expression in four parallel conditions: (a) Uninfected MDMs, (b) Infected MDMs, (c) Uninfected MDMs co-cultured with autologous T-cells and (d) Infected MDMs co-cultured with autologous T-cells. A box plot of the log2 ratios of the Uninfected expression values subtracted from the Infected expression values for all probe sets plotted separately for each donor demonstrated that although there was slightly more variation present in the MDM-only ratios for Donor 4, overall there did not appear to be substantial inter-donor variation (Figure 1). Most genes did not appear to change markedly from zero as evidenced by the narrow range of most of the inter-quartile boxes. Although the analyses presented below were generated employing all 4 donors' data, the analyses were also tested leaving donor 4 out and did not differ substantially (data not shown). To generate the RNA samples, we only used infections where there was >70% infected macrophages at the 4 hour co-culture time point (MDM: 79.9±7.2% infection; MDM-T-cell: 76±7.7;see Methods). For subsequent experiments over longer time intervals, the percent of infected cells stayed roughly constant over the time intervals measured (see figure legends).

thumbnail

Figure 1. BoxPlot of Ratios [Infected:Uninfected] of gcRMA-transformed microarray expression data.

The value of the log2(Infected expression value ÷ Uninfected expression value) for each probe set in both the MDM only condition and the MDM-T cell co-culture was calculated and plotted separately for each donor. The central box represents the interquartile range and the solid black bar represents the median probe set. Downstream analyses were performed using all four donor data sets.

doi:10.1371/journal.pntd.0000252.g001

Data generated from the analysis of RNA from cultured MDMs alone were analyzed separately by RankProd from the data from MDM-T cell co-cultures. The numbers and identity of genes either up-regulated or down-regulated in infected samples compared to uninfected samples that had a particular estimated PFP were computed. In both culture conditions, statistically significant differentially-regulated genes were considered if genes met a 5% PFP cutoff. Out of 54,675 total probe sets, in the MDM only condition RankProd identified 9 probe sets with a PFP cutoff of ≤5% that were up-regulated by infection with L. chagasi and 72 probe sets that were down-regulated. In the MDM-T cell co-culture condition, RankProd identified 116 probe sets with a PFP cutoff of ≤ 5% that were up-regulated by infection with L. chagasi and 19 down-regulated probe sets. A complete list of all probe sets identified by RankProd is provided in Table S2.

After identification of the differentially expressed probe-sets using RankProd, the lists of AffyIDs for the up- and down-regulated probe-sets were submitted to the DAVID bioinformatics website to functionally cluster the various probe-sets by Gene Ontology categories and other functional annotation.[26] Tables 1 and 2 show a selected list of the identified differentially expressed genes grouped by functional annotation. In the MDM cultures (Table 1), infection led to many more down-modulated than up-regulated transcripts. In contrast to macrophage infection with bacterial pathogens,[29] Leishmania infection of MDMs did not lead to up-regulation of transcripts encoding proteins characteristic of classical inflammation. Infection with L. chagasi down-modulated several transcripts encoding proteins involved in cellular regulation. Down-modulated gene transcripts included those corresponding to YAF2, which encodes a protein that binds the transcription factor YY1, eIF2C3, an initiation factor belonging to the PIWI family that is essential for mammalian cell siRNA-mediated gene silencing,[30] Cdc42, whose protein product is involved in actin regulation, a guanine nucleotide exchange factor, and a gene involved in autophagy. There was also significant down-modulation of transcripts encoding classical inflammatory receptors (IL-1R2 and CSF2),[29] and Peroxiredoxin 6, a protein involved in redox cycling and oxidative defense.[31] Transcripts encoding proteins associated with classical macrophage activation, such as TNF-α, IL-10, MIP-1-α, IP-10, IL-6, iNOS, MHC II and CIITA,[32] were not differentially regulated.

thumbnail

Table 1. Modulation of MDM gene expression caused by L. chagasi infection

doi:10.1371/journal.pntd.0000252.t001
thumbnail

Table 2. Modulation of gene expression in MDM-T cell co-cultures induced by L. chagasi infection

doi:10.1371/journal.pntd.0000252.t002

The MDM-T cell co-culture condition provided a model of the initial interaction between Leishmania-infected macrophages and circulating T cells, using a mixed population of peripheral blood-derived Leishmania-naïve T cells.[33] We chose an early time point (4 hours of co-culture; 28 hours total infection time) to study the gene expression initiated by this initial contact. In contrast to our study of infected MDMs, the addition of T-cells to the co-culture increased the proportion of genes that were differentially regulated (Table 2). Of note, the mRNA encoding the early activation T-cell marker CD69 was significantly induced in the co-culture replicates, suggesting that we were able to successfully extract mRNA from both the infected macrophages as well as the added T cells. Among the many transcripts that were up-regulated by co-culture were those that encoded proteins that promote acute inflammation, including chemokines that attract neutrophils (CXCL-2, 3) and resting T cells/NK cells (CXCL-10). The latter, also called IP-10, promotes Th1-type immunity. Cytokines and interleukins expressed uniquely in the infected co-culture condition included IL-1α, IL-1β, and IL-6 which are pro-inflammatory, and IFN-γ and IL-2 which are both produced by and promote the development of a Th1-type cells. Consistently, the mRNA for STAT1, a key signaling molecule in the IFN-γ pathway, also increased. Transcripts encoding other chemokines (CCL-8, 20; CXCL-9, 11) were also induced in the co-culture. As such, the “flavor” of transcripts induced uniquely in co-cultures with the addition of T-cells to infected MDMs reflects an environment favorable for the development of type 1 immune cytokine responses.

Similar to the results in the MDM-only condition, transcripts for several isoforms of the MT-1 gene were highly up-regulated in co-cultures containing infected MDMs. Due to their up-regulation either with or without T-cells present, we presume these most likely reflect changes in MT gene expression occurring in the infected MDMs, although it is possible that these transcripts were also up-regulated in the co-cultured T-cells.[34]

In order to validate some of the above data using a more quantitative method, we performed TaqMan-based reverse transcriptase-PCR experiments on 6 differentially regulated genes. The relative mRNA expression levels were verified using the same RNA samples that had been analyzed in microarrays for two donors (Figure 2). With the exception of SNX13 which yielded equivocal results, the direction and magnitude of calculated change comparing infected samples to uninfected samples corresponded to the change predicted by the microarray expression data for both donors. SNX13 had been identified as an up-regulated gene by microarray analysis, but did not change appreciably above baseline by RT-PCR. In addition to the six transcripts illustrated in Figure 2, we also validated by RT-PCR the up-regulation of the metallothionein gene, MT1M. The relative mRNA levels of this gene were increased roughly six-fold after four hours of co-culture (data not shown).

thumbnail

Figure 2. Validation of microarray data with TaqMan RT-PCR of selected differentially expressed genes.

RNA was extracted from human MDM-T cell co-cultures 4 hours after the addition of T-cells to infected or uninfected macrophages (28 total hours of L. chagasi infection). The relative expression of genes in infected compared to uninfected levels, in two separate donors, was examined using TaqMan RT-PCR. Six genes identified to be differentially expressed in the primary microarray analysis were selected for validation. Relative expression of infected samples is displayed in reference to a line at y = 1, signifying no change. Bars below y = 1 signify genes that have decreased expression relative to uninfected samples. The black arrows at the bottom indicate the relative magnitude and direction of change anticipated from the microarray data.

doi:10.1371/journal.pntd.0000252.g002

In addition to the functional clustering using DAVID, we investigated the data using the pathway software, Gene Set Enrichment Analysis (GSEA).[27] We examined separately the MDM only and the MDM-T cell co-culture data sets. Selected results from this analysis are represented in Table S1. When corrected for multiple hypothesis testing (FDR q-value <0.02[25]), the MDM only data did not show statistically significant enrichment of any gene sets, consistent with infected MDMs exhibiting a “quiescent” phenotype. In contrast, the MDM-T cell data demonstrated enrichment of several gene sets annotated to be canonical immune cytokine signaling pathways as well as groups of genes up-regulated when different cell types are stimulated with a variety of conditions such as hypoxia, proliferation or cytokines. Of particular interest, IL-6 related gene sets appear several times on the list as KRETZSCHMAR_IL6_DIFF, BROCKE_IL6 and IL6_PATHWAY. The former two gene sets include genes that are differentially regulated when multiple myeloma cells are treated with recombinant IL-6.[35] The IL-6 Pathway and additionally the IL-12 Pathway gene sets (Biocarta) were both found to be enriched within the infected MDM-T cell co-culture data set. IL-6 mRNA itself, but not IL-12 subunits, were up-regulated in co-cultures (see Table 2). Furthermore, the GATA3 pathway (Biocarta) and TGF-β signaling pathway (Biocarta) were also enriched in the MDM-T-cell microarray data indicating that some genes not belonging to inflammatory pathways were induced. GATA3 is a transcription factor and “master regulator” of Th2 differentiation,[36] and TGF-β suppresses both Th1 and Th2 effector cell development.[37],[38] In the primary data, IL-4 mRNA was only up-regulated 1.7-fold in contrast to IFN-γ mRNA which went up almost 3-fold. In aggregate, these data suggest the infection induced primarily a type 1 immune cytokine activation phenotype, but other modulatory factors (i.e. TGF-β) may be secondarily activated.

To determine the duration of transcript and protein up-regulation, selected cytokines associated with inflammatory responses were measured. We chose IFN-γ and IL-6, whose transcripts were up-regulated according to microarray data (Table 2). We also examined IL-10, a cytokine that promotes progressive VL disease, based upon the hypothesis that important modifying factors are secondarily up-regulated in response to the initial type 1 response.[10] The relative mRNA abundance at time points between 4 h of co-culture (i.e. 28 hours of infection) and 3d of co-culture were measured using TaqMan based RT-PCR gene expression assays and normalized to GAPDH (Figure 3A, Δ(ΔCt) method). The IFN-γ mRNA peaked at 24 h at roughly three-fold above background (p<0.05) and then declined back to baseline. IL-6 mRNA showed a trend toward increased expression during infection, although the changes were not statistically significant. IL-10 mRNA did not demonstrate any significant change, consistent with our microarray findings.

thumbnail

Figure 3. RT-PCR and cytokine assays of IFN-γ, IL-6 and IL-10 in MDM-T-cell co-cultures.

MDMs were infected with L. chagasi for 24 hours, and autologous Leishmania-naïve T-cells were added for the indicated times. (A) Gene expression was examined comparing RNA harvested at the same time point from infected versus uninfected co-cultures. All mRNA levels were normalized to GAPDH. (B) Supernatants were collected after the indicated times of co-culture from uninfected (−) versus infected (+) MDM-T cell co-cultures. Cytokine concentrations were measured using Lincoplex (Millipore) cytokine beads. Standard curves were generated using standards provided by the company. Data for relative mRNA levels or cytokine concentrations represent the mean±SEM of three independent infection experiments from different human donors. * = p<0.05. Statistical analysis was performed using (A) 1-way ANOVA and Tukey's Multiple Comparison Test or a (B) 2-way ANOVA test, respectively.

doi:10.1371/journal.pntd.0000252.g003

Changes in the levels of IFN-γ, IL-6 and IL-10 in the supernatants of MDM-T cell co-culture wells were measured at the same time points (Figure 3B). In all cases, infected co-cultures showed significant accumulation of cytokine (p<0.05) comparing 4h of co-culture to 3d of co-culture, whereas there was no similar accumulation of cytokine in uninfected wells. IFN-γ cytokine accumulation peaked at about 4-fold above uninfected cells at 72 hours whereas IL-10 accumulated to approximately 2.5-fold above uninfected cells. The mean percent infection levels for these replicates were 83.2±2.7, 81.1±1.8, 71.2±1.3 and 63.8±7.3% at 4, 24, 48 and 72 hours of co-culture, respectively. Thus, despite the fact that the levels of IFN-γ increased out to 3d of co-culture, the percent of infected cells stayed roughly constant over the same time interval.

Discussion

Our study was designed to test the hypothesis that a unique immune response to L. chagasi/infantum is initiated early during the initial interactions between the first immune system cells that encounter the parasite. These include macrophages and T-cells, elements of the innate and adaptive immune systems, respectively. To that end, we used microarrays to examine early gene expression patterns in purified Leishmania-naïve human T cells during their first encounter with infected human macrophages. The data suggested that macrophages exhibit a quiescent phenotype 24 hrs after infection with Leishmania, but Leishmania-naïve T cells respond to infected MDMs primarily with an inflammatory or a type 1 immune cytokine response. These in vitro data suggest that the initial microenvironment created at the site of Leishmania infection may be conducive to development of a type 1 adaptive immune response.

Immune responses during symptomatic VL are dominated by suppression of antigen-specific IFN-γ responses[3] and patients have high levels of the suppressive cytokines IL-10 and TGF-β in their serum with a negative Montenegro reactions.[8][10],[13],[19] Whether this immunosuppression initiates early in the process of macrophage:T cell interactions is not fully known.

Several studies have previously profiled transcriptional responses of phagocytic cells to Leishmania infection. Buates and Matlashewski[14] showed that in L. donovani infected BALB/c macrophages, ~40% of the examined genes in a modified array are down-regulated 4 hours after infection. Rodriguez et al.[39] reported that murine macrophages exhibited a novel non-classical, non-alternative activation profile at early time points after L. chagasi infection. More recently, Chaussabel et al.[40] used microarrays to compare gene expression in human macrophages or dendritic cells infected for 16 hours with a variety of parasitic and bacterial pathogens including L. major and L. donovani. These authors showed that Leishmania infection invokes the expression of a novel set of genes that is Leishmania species-specific. Notably, L. major-infected macrophages down-regulated IFN-γ induced genes yet overall induce a stronger inflammatory profile than does L. donovani. Both Leishmania species induce IL6 gene expression.

Prior studies of PBMCs incubated with species of Leishmania causing cutaneous leishmaniasis, called in vitro priming systems, demonstrated the prominent production of type 1 cytokines (IL-12 and IFN-γ) but lower levels of type 2 cytokines such as IL-5.[41] In contrast, infection of PBMCs with L. donovani, which causes visceral leishmaniasis, inhibits the of production of pro-inflammatory cytokines such as IL-1 or TNF-α[42] and leads to interruption of IFN-γ signaling pathways.[43] During the current study, we pursued a global analysis of gene expression shortly after human peripheral blood derived macrophages first encounter Leishmania-naïve T-cells. Based on previously published work from our laboratory, promastigotes convert to amastigotes by 24–48 hours after infection of human macrophages.[44] Furthermore, during infection of murine macrophages with wild-type L. chagasi, fusion of developing phagosomes with lysosomes is delayed for 24–48 hours.[45] At the 28 hour post infection time point examined in this assay, it is therefore reasonable to assume that most if not all parasites will have converted to amastigotes and reside within phagolysosomes.

Examination of genes expressed in the infected-macrophages-only condition revealed more genes were down-regulated than were induced. Macrophage activation patterns can be divided into classical, alternative, and Type II activation. Alternatively activated macrophages up-regulate IL-1RA, mannose receptor (MRC1), scavenger receptor (CD36), the low-affinity IgE receptor (CD23) and exhibit high arginase activity. Type II macrophages up-regulate sphingosine kinase 1 (SPHK1), LIGHT, TNF-SF14, FIZZ1 and IL-10, have high NO. production but remain arginase low.[32],[39],[46] Of the above characteristic macrophage activation transcripts, none were significantly up- or down-regulated after 28 hours of L. chagasi infection. It is possible that some of the above defining macrophage activation markers would have been up- or down-regulated if samples had been taken earlier after the initiation of infection. Nonetheless, the time point chosen for this study captured macrophages harboring converted intracellular amastigotes[44] and the MDM alone condition allowed us to compare background gene expression by infected macrophages with the macrophage-T cell co-culture condition.

To our surprise, and in contrast with the quiescent phenotype of the infected-macrophages, four hours after the addition of Leishmania-naïve T cells to infected macrophages, multiple genes characteristic of a type 1 immune cytokine response were up-regulated. Highlights of up-regulated transcripts included IFN-γ, STAT-1, IL-1α, IL-1β, TNF-α and IL-6. Further bioinformatics analysis using GSEA confirmed the fact that genes and pathways initiated by pro-inflammatory cytokines and chemokines were up-regulated. Additionally, using GSEA we also observed enrichment of the TGF-β pathway; a cytokine that is suppressive of both Th1-type and Th2-type immune responses.[37],[38] Although we cannot discern exactly which cell type (MDM or T cell) contributed most highly to the above transcripts, comparison with the MDM alone conditions suggests that at least some of the cytokines such as IFN-γ may have been derived from T-cells. It should be emphasized that other cell types such as dendritic cells and NK cells should have been largely excluded from the co-culture through the positive selection on the purification column.

Direct measurements of mRNA and protein levels in the co-cultured infected macrophages and T cells showed that the steady state abundance of both the mRNA and protein of IFN-γ and IL-6 accumulated significantly by 3d in the co-cultures (Figure 3). Although IL10 mRNA did not appreciably increase at 3d of infection, we observed a significant increase in levels of IL-10 in culture supernatants after 3 days of co-cultivation (Figure 3). The infection-induced accumulation of IL-6 and IFN-γ would be predicted by their respective mRNA abundance, whereas the accumulation of IL-10 was unexpected. This finding could reflect that we missed a transient peak of IL-10 mRNA during MDM infection. Nonetheless since the IL-10 pathway was not enriched using GSEA, it is reasonable to hypothesize that the accumulation of IL-10 could be a secondary, modifying response to the increase in IFN-γ and IL-6 rather than a primary response to Leishmania infected macrophages. The same scenario could be hypothesized for TGF-β.

The present data suggest that the initial interactions of L. chagasi-infected macrophages with the adaptive immune system results primarily in up-regulation of type 1 immune cytokine responses. There was little evidence for type 2 activation, as IL-4 was only up-regulated slightly less than two-fold in the primary microarray co-culture data and characteristic type 2 chemokine receptors such as CCR3[47] were, in fact, down-regulated. It remains to be determined at what point L. chagasi parasites begin to tip the balance of immunity away from a curative type 1, IFN-γ response to cause symptomatic disease.

Supporting Information

Supplementary Table S1.

Gene Sets enriched during L. chagasi infection of MDM-T-cell co-cultures according to the Genes Set Enrichment Analysis (GSEA).

doi:10.1371/journal.pntd.0000252.s001

(0.12 MB DOC)

Supplementary Table S2.

Complete list of all probe sets identified by RankProd as differentially regulated upon infection by L. chagasi for both the MDM-only and MDM-T co-culture conditions.

doi:10.1371/journal.pntd.0000252.s002

(0.46 MB DOC)

Acknowledgments

The authors would like to graciously thank all the dedicated staff of the University of Iowa Core DNA and Flow Cytometry Facilities for their crucial technical assistance in the preparation of this manuscript.

Author Contributions

Conceived and designed the experiments: NE. Performed the experiments: NE. Analyzed the data: NE MW. Contributed reagents/materials/analysis tools: MW. Wrote the paper: NE MW.

References

  1. 1. Wilson ME, Jeronimo SMB, Pearson RD (2005) Immunopathogenesis of infection with the visceralizing leishmania species. Microb Pathog 38(4): 147–160.
  2. 2. Jeronimo SMB, Teixeira MJ, Sousa A, Thielking P, Pearson RD, et al. (2000) Natural history of Leishmania (Leishmania) chagasi infection in northeastern Brazil: Long-term follow-up. Clin Infect Dis 30(3): 608–609.
  3. 3. Carvalho EM, Bacellar O, Barral A, Badaro R, Johnson WD Jr. (1989) Antigen-specific immunosuppression in visceral leishmaniasis is cell mediated. J Clin Invest 83(3): 860–864.
  4. 4. Ghalib HW, Whittle JA, Kubin M, Hashim FA, el-Hassan AM, et al. (1995) IL-12 enhances Th1-type responses in human Leishmania donovani infections. J Immunol 154(9): 4623–4629.
  5. 5. Bacellar O, Brodskyn C, Guerreiro J, Barral-Netto M, Costa CH, et al. (1996) Interleukin-12 restores interferon-gamma production and cytotoxic responses in visceral leishmaniasis. J Infect Dis 173(6): 1515–1518.
  6. 6. Karp CL, el-Safi SH, Wynn TA, Satti MM, Kordofani AM, et al. (1993) In vivo cytokine profiles in patients with kala-azar: marked elevation of both interleukin-10 and interferon-gamma. J Clin Invest 91(4): 1644–1648.
  7. 7. Ghalib HW, Piuvezam MR, Skeiky YA, Siddig M, Hashim FA, et al. (1993) Interleukin 10 production correlates with pathology in human Leishmania donovani infections. J Clin Invest 92(1): 324–329.
  8. 8. Caldas A, Favali C, Aquino D, Vinhas V, van Weyenbergh J, et al. (2005) Balance of IL-10 and IFN-γ plasma levels in human visceral leishmaniasis: Implications in the pathogenesis. BMC Infect Dis 5: 113. 10.1186/1471-2334-5-113.
  9. 9. Peruhype-Magalhaes V, Martins-Filho OA, Prata A, Silva Lde A, Rabello A, et al. (2006) Mixed inflammatory/regulatory cytokine profile marked by simultaneous raise of interferon-gamma and interleukin-10 and low frequency of tumour necrosis factor-α+ monocytes are hallmarks of active human visceral leishmaniasis due to Leishmania chagasi infection. Clin Exp Immunol 146(1): 124–132. 10.1111/j.1365-2249.2006.03171.x.
  10. 10. Nylen S, Sacks D (2007) Interleukin-10 and the pathogenesis of human visceral leishmaniasis. Trends Immunol 28(9): 378–384. 10.1016/j.it.2007.07.004.
  11. 11. Barral-Netto M, Barral A, Santos SB, Carvalho EM, Badaro R, et al. (1991) Soluble IL-2 receptor as an agent of serum-mediated suppression in human visceral leishmaniasis. J Immunol 147(1): 281–284.
  12. 12. Atta AM, D'Oliveira , Correa J, Atta ML, Almeida RP, et al. (1998) Anti-leishmanial IgE antibodies: A marker of active disease in visceral leishmaniasis. Am J Trop Med Hyg 59(3): 426–430.
  13. 13. Nascimento ET, Gantt KR, Pontes NN, Bacelar O, Luz VE, et al. (2002) TGF-β in acute visceral leishmaniasis. Am J Trop Med Hyg 67(2): 262.
  14. 14. Buates S, Matlashewski G (2001) General suppression of macrophage gene expression during Leishmania donovani infection. J Immunol 166(5): 3416–3422.
  15. 15. Bertholet S, Dickensheets HL, Sheikh F, Gam AA, Donnelly RP, et al. (2003) Leishmania donovani-induced expression of suppressor of cytokine signaling 3 in human macrophages: A novel mechanism for intracellular parasite suppression of activation. Infect Immun 71(4): 2095–2101.
  16. 16. Misra S, Tripathi MK, Chaudhuri G (2005) Down-regulation of 7SL RNA expression and impairment of vesicular protein transport pathways by Leishmania infection of macrophages. J Biol Chem 280(32): 29364–29373. 10.1074/jbc.M504162200.
  17. 17. Dogra N, Warburton C, McMaster WR (2007) Leishmania major abrogates gamma interferon-induced gene expression in human macrophages from a global perspective. Infect Immun 75(7): 3506–3515.
  18. 18. Berens RL, Brun R, Krassner SM (1976) A simple monophasic medium for axenic culture of hemoflagellates. J Parasitol 62(3): 360–365.
  19. 19. Jeronimo SMB, Duggal P, Braz RF, Cheng C, Monteiro GR, et al. (2004) An emerging peri-urban pattern of infection with Leishmania chagasi, the protozoan causing visceral leishmaniasis in northeast Brazil. Scand J Infect Dis 36(6–7): 443–449.
  20. 20. Gentleman RC, Carey VJ, Bates DM, Bolstad B, Dettling M, et al. (2004) Bioconductor: Open software development for computational biology and bioinformatics. Genome Biol 5(10): R80. 10.1186/gb-2004-5-10-r80.
  21. 21. Irizarry RA, Hobbs B, Collin F, Beazer-Barclay YD, Antonellis KJ, et al. (2003) Exploration, normalization, and summaries of high density oligonucleotide array probe level data. Biostatistics 4(2): 249–264. 10.1093/biostatistics/4.2.249.
  22. 22. Wu Z, Irizarry RA, Gentleman RC, Martinez-Murillo F, Spencer F (2004) A model-based background adjustment for oligonucleotide expression arrays. J Am Stat Assoc 99(468): 909–917.
  23. 23. Breitling R, Armengaud P, Amtmann A, Herzyk P (2004) Rank products: A simple, yet powerful, new method to detect differentially regulated genes in replicated microarray experiments. FEBS Lett 573(1–3): 83–92. 10.1016/j.febslet.2004.07.055.
  24. 24. Hong F, Breitling R, McEntee CW, Wittner BS, Nemhauser JL, et al. (2006) RankProd: A Bioconductor package for detecting differentially expressed genes in meta-analysis. Bioinformatics 22(22): 2825–2827. btl476 [pii]; 10.1093/bioinformatics/btl476 [doi].
  25. 25. Storey JD, Tibshirani R (2003) Statistical significance for genomewide studies. Proc Natl Acad Sci U S A 100(16): 9440–9445. 10.1073/pnas.1530509100.
  26. 26. Dennis G Jr, Sherman BT, Hosack DA, Yang J, Gao W, et al. (2003) DAVID: Database for annotation, visualization, and integrated discovery. Genome Biol 4(5): P3.
  27. 27. Subramanian A, Tamayo P, Mootha VK, Mukherjee S, Ebert BL, et al. (2005) Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles. Proc Natl Acad Sci U S A 102(43): 15545–15550. 0506580102 [pii]; 10.1073/pnas.0506580102 [doi].
  28. 28. Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2−(Δ(Δ(CT)) method. Methods 25(4): 402–408. 10.1006/meth.2001.1262.
  29. 29. Nau GJ, Richmond JF, Schlesinger A, Jennings EG, Lander ES, et al. (2002) Human macrophage activation programs induced by bacterial pathogens. Proc Natl Acad Sci U S A 99(3): 1503–1508. 10.1073/pnas.022649799.
  30. 30. Doi N, Zenno S, Ueda R, Ohki-Hamazaki H, Ui-Tei K, et al. (2003) Short-interfering-RNA-mediated gene silencing in mammalian cells requires dicer and eIF2C translation initiation factors. Curr Biol 13(1): 41–46.
  31. 31. Manevich Y, Fisher AB (2005) Peroxiredoxin 6, a 1-cys peroxiredoxin, functions in antioxidant defense and lung phospholipid metabolism. Free Radic Biol Med 38(11): 1422–1432. 10.1016/j.freeradbiomed.2005.02.011.
  32. 32. Mosser DM (2003) The many faces of macrophage activation. J Leukoc Biol 73(2): 209–212.
  33. 33. Bofill M, Almirall E, McQuaid A, Pena R, Ruiz-Hernandez R, et al. (2004) Differential expression of the cytokine receptors for human interleukin (IL)-12 and IL-18 on lymphocytes of both CD45RA+ and CD45RO+ phenotype from tonsils, cord and adult peripheral blood. Clin Exp Immunol 138(3): 460–465. 10.1111/j.1365-2249.2004.02651.x.
  34. 34. Coyle P, Philcox JC, Carey LC, Rofe AM (2002) Metallothionein: The multipurpose protein. Cell Mol Life Sci 59(4): 627–647.
  35. 35. Brocke-Heidrich K, Kretzschmar AK, Pfeifer G, Henze C, Loffler D, et al. (2004) Interleukin-6-dependent gene expression profiles in multiple myeloma INA-6 cells reveal a bcl-2 family-independent survival pathway closely associated with Stat3 activation. Blood 103(1): 242–251. 10.1182/blood-2003-04-1048.
  36. 36. Sacks D, Noben-Trauth N (2002) The immunology of susceptibility and resistance to Leishmania major in mice. Nat Rev Immunol 2(11): 845–858.
  37. 37. Wilson ME, Young BM, Davidson BL, Mente KA, McGowan SE (1998) The importance of TGF-β in murine visceral leishmaniasis. J Immunol 161(11): 6148–6155.
  38. 38. Letterio JJ, Roberts AB (1998) Regulation of immune responses by TGF-β. Annu Rev Immunol 16: 137–161. 10.1146/annurev.immunol.16.1.137.
  39. 39. Rodriguez NE, Chang HK, Wilson ME (2004) Novel program of macrophage gene expression induced by phagocytosis of Leishmania chagasi. Infect Immun 72(4): 2111–2122.
  40. 40. Chaussabel D, Semnani RT, McDowell MA, Sacks D, Sher A, et al. (2003) Unique gene expression profiles of human macrophages and dendritic cells to phylogenetically distinct parasites. Blood 102(2): 672–681. 10.1182/blood-2002-10-3232.
  41. 41. Rogers KA, Titus RG (2004) The human cytokine response to Leishmania major early after exposure to the parasite in vitro. J Parasitol 90(3): 557–563.
  42. 42. Reiner NE, Ng W, Wilson CB, McMaster WR, Burchett SK (1990) Modulation of in vitro monocyte cytokine responses to Leishmania donovani: Interferon-gamma prevents parasite-induced inhibition of interleukin-1 production and primes monocytes to respond to Leishmania by producing both tumor necrosis factor-alpha and interleukin-1. J Clin Invest 85(6): 1914–1924.
  43. 43. Blanchette J, Racette N, Faure R, Siminovitch KA, Olivier M (1999) Leishmania-induced increases in activation of macrophage SHP-1 tyrosine phosphatase are associated with impaired IFN-gamma-triggered JAK2 activation. Eur J Immunol 29(11): 3737–3744.
  44. 44. Streit JA, Donelson JE, Agey MW, Wilson ME (1996) Developmental changes in the expression of Leishmania chagasi gp63 and heat shock protein in a human macrophage cell line. Infect Immun 64(5): 1810–1818.
  45. 45. Rodriguez NE, Gaur U, Wilson ME (2006) Role of caveolae in Leishmania chagasi phagocytosis and intracellular survival in macrophages. Cell Microbiol 8(7): 1106–1120. 10.1111/j.1462-5822.2006.00695.x.
  46. 46. Edwards JP, Zhang X, Frauwirth KA, Mosser DM (2006) Biochemical and functional characterization of three activated macrophage populations. J Leukoc Biol 80(6): 1298–1307. 10.1189/jlb.0406249.
  47. 47. Sallusto F, Lenig D, Mackay CR, Lanzavecchia A (1998) Flexible programs of chemokine receptor expression on human polarized T helper 1 and 2 lymphocytes. J Exp Med 187(6): 875–883.