Background
Despite the frequent occurrence of multiple parasite infections [
1], little is known how concurrent parasite infections influence immune responsiveness in patients and few studies addressed the impact of helminth and intestinal protozoa co-infections on immune responses in children. The intensity and prevalence of helminth parasite infections is age-dependent with children being often the most affected [
2,
3], and poly-parasitism being more frequent than single parasite infections [
1,
4,
5]. The existing epidemiological surveys on helminth co-infections in children indicate positive associations between schistosomes and soil transmitted helminths (STH) [
5] which means high prevalence of mixed infections, as well as higher intensities of infection in co-infected patients [
6]. For multiply infected patients, additive effects on the cellular reactivity and the down-modulation of cytokines are proposed [
6]. In human mono-infections with STH an increased secretion of Th2-type cytokines associated with decreased cellular proliferation to specific parasite antigens and mitogens has been observed [
7,
8]. Protective Th2-type associated mechanisms have been suggested which may act distinctly during parasite migration leading to a reduction in numbers, size, and motility of migratory larvae [
9-
11] mediating a partial protection which will prevent an endless accumulation of adult helminthes parasites in the host [
6]. In situations where several parasite species co-exist, where balanced and to some extent compromised immune responses are required, regulatory T cells and regulatory cytokines like IL-10 and IL-27 could represent the key components to prevent overwhelming inflammation and tissue destruction, but multiple and chronic infections may also drive immune responsiveness towards exhaustion. In poly-parasitized adults, parasite-specific cellular reactivity was significantly reduced in doubly infected individuals than in patients with a single filarial infection, and anti-parasite treatment greatly changed their cytokine and chemokine responses [
9,
12,
13]. Generally accepted, Th2 type cytokines and chemokines play an essential role in the pathogenesis of allergic inflammation. Th2-type cytokines like IL-4, IL-5, IL-9 and IL-13 contribute to the pathophysiological conditions of allergy and asthma, and chemokines like eotaxin/CCL11, RANTES/CCL5 and monocyte chemoattractant proteins (MCPs) contribute decisively to the recruitment of basophil and eosinophil granulocytes as well as mast cells in tissues of allergic inflammation [
14]. Chemokines attract Th2-type cells into bronchi and gut mucosal tissues in response to allergen exposure or intestinal helminthes parasite infection [
15,
16]. Intravascular parasite infections were described to ameliorate and even prevented allergen induced skin sensitization in humans [
17] as well as airway hyper-reactivity in experimental animal studies [
18]. Such an immune modulating capacities of pathogens has been extended to situations without active infection where exposure to environmental non-viable microbial products sufficed to reduce the occurrence of hay fever, atopic asthma, and atopic sensitization to environmental allergens [
19] In children, poly-parasite infections with
S. haematobium/S. mansoni, E. histolytica/E. dispar, and
N. americanus generated prominent pro-inflammatory cytokine and chemokine responses, and anti-helminth treatment lessened inflammatory chemokine responses whilst the Th2 responsiveness in co-infected children increased [
5]. Furthermore, long-term periodic anti-helminth treatments were associated with an increased prevalence of allergen skin test reactivity [
20] and eczema symptoms [
21].
In the present work, we analyzed in children infected with helminthes and protozoan parasites the cellular responses to protozoa or helminthes extracts and allergens, and observed distinct cytokine and chemokine production profiles; furthermore, in co-infected children prominent inflammatory chemokine and cytokine responses were observed together with enhanced allergen skin test reactivity.
Methods
Study participants
This study was conducted in the central region of Togo, Africa. All children examined were attending primary public schools in suburban quarters of the town of Sokodé. For stool and urine examinations, 50-mL polypropylene tubes were distributed to the pupils and collected the next morning; diagnostic procedures were performed by the laboratory staff at the Centre Hospitalier Régional (CHR), Sokodé.
On the basis of the diagnostic results 4 infection groups were formed. All children who did not have a parasite infection and were apparently healthy (no fever, headache, vomiting, abdominal pain, diarrhea, dizziness, or skin lesions) were considered to be control children (Group G0 = NEG). Children with single infection Group G1, those with double infection Group G2 and with three and parasite infections are Group G3+.
In Tables
1 and
2 the children infection groups G0, G1, G2 and G3+ are listed from whom peripheral blood mononuclear cells (PBMC) were isolated (n = 87) and studied
in vitro for cytokine and chemokine responses to parasite antigens and fungus and mite allergens. Demographic data and infection details from participating children are shown in Tables
1 and
2; the infection groups G0, G1, G2 and G3+ are listed by parasite species and abbreviations are indicated: Na = Necator americanus; Eh = Entamoeba histolytica/dispar; Gl = Giardia lamblia; Hn = Hymenolepis nana; Sh = Schistosoma haematobium; Sm = Schistosoma mansoni; Ti-Trichomonas intestinalis. Children from whom PBMC were isolated were invited with their parents or legal guardians to the CHR Sokodé for blood sample collection. Children who showed signs of malaria (thick blood smears positive for
Plasmodium species and fever), or who had diarrhea were excluded from the study. None of the children presented with
E. histolytica trophozoites containing ingested red blood cells in stool samples, bloody stool, or clinical signs of invasive amoebiasis. Eight weeks after treatment, stool, urine, and blood samples from G0, G1, and G3+ children (
n = 22) were re-examined in the same fashion as before treatment.
Table 1
Demographic data of children from whom peripheral blood mononuclear cells (PBMC) were isolated and PBMC used in cell culture experiments for the evaluation of cytokine and chemokine responses to parasite antigens and fungus and mite allergens
G0 = NEG (14) | f | 8 | 11 | 10 | 12 |
| m | 6 | 11 | 10 | 12 |
G1 (32) | f | 15 | 10 | 9 | 13 |
| m | 17 | 12 | 10 | 13 |
G2 (18) | f | 5 | 11 | 9 | 12 |
| m | 13 | 11 | 10 | 13 |
G3+ (23) | f | 4 | 12 | 11 | 12 |
| m | 19 | 11 | 10 | 13 |
Table 2
Infections listed by parasite species in children from whom peripheral blood mononuclear cells (PBMC) were isolated and PBMC studied
in vitro
for cytokine and chemokine responses to parasite antigens and fungus and mite allergens
G0 | NEG | | | | | | | | | 14 | NEG = 16% |
G1 | | | | | | | | | Ss | 1 | |
G1 | | | | | | | Ti | | | 1 | |
G1 | | | | | Sm | | | | | 1 | |
G1 | | | | Sh | | | | | | 4 | |
G1 | | | Na | | | | | | | 4 | |
G1 | | Eh | | | | | | | | 21 | G1 = 37% |
G2 | | | | | | Gl | | Hn | | 1 | |
G2 | | | | Sh | Sm | | | | | 1 | |
G2 | | | Na | | | Gl | | | | 2 | |
G2 | | | Na | Sh | | | | | | 2 | |
G2 | | Eh | | | | | Ti | | | 1 | |
G2 | | Eh | | | | Gl | | | | 4 | |
G2 | | Eh | | | Sm | | | | | 2 | |
G2 | | Eh | | Sh | | | | | | 1 | |
G2 | | Eh | Na | | | | | | | 4 | G2 = 21% |
G3+ | | | Na | Sh | | Gl | | | | 1 | |
G3+ | | | Na | Sh | Sm | | | | | 1 | |
G3+ | | Eh | | | | Gl | Ti | | | 1 | |
G3+ | | Eh | | Sh | Sm | | | | | 7 | |
G3+ | | Eh | Na | | | | Ti | | | 1 | |
G3+ | | Eh | Na | | | | Ti | Hn | | 1 | |
G3+ | | Eh | Na | | | Gl | Ti | | | 1 | |
G3+ | | Eh | Na | | Sm | | | | | 3 | |
G3+ | | Eh | Na | Sh | | | | | | 4 | |
G3+ | | Eh | Na | Sh | Sm | | | | | 2 | |
G3+ | | Eh | Na | Sh | Sm | | Ti | | | 1 | G3 = 26% |
| | | | | | | | | | 87 | |
Infected (n) | | 54 | 27 | 24 | 18 | 10 | 7 | 2 | 1 | | |
Infection (%) | 62 | 31 | 28 | 21 | 11 | 8 | 2 | 1 | | |
In Tables
3 and
4 the children infection groups G0, G1, G2 and G3+ are listed in whom skin prick test reactivity was evaluated (n = 509); demographic data and infection details from participating children are shown.
Table 3
Demographic data (age, sex) of children evaluated for skin prick test reactivity
G0 = NEG (287) | f | 121 | 11 | 7 | 12 |
| m | 166 | 11 | 9 | 12 |
G1 (137) | f | 51 | 11 | 8 | 12 |
| m | 86 | 11 | 8 | 12 |
G2 (58) | f | 25 | 12 | 9 | 12 |
| m | 33 | 12 | 9 | 12 |
G3+ (27) | f | 9 | 12 | 11 | 12 |
| m | 18 | 11 | 10 | 12 |
Table 4
Parasite infections in children evaluated for skin prick test reactivity
| G0 = NEG | | | | | | | | 287 | G0 = 56.4% |
| G1 | | | | | | | Hn | 7 | |
| G1 | | | | | | Ti | | 5 | |
| G1 | | | | | Gl | | | 1 | |
| G1 | | | | Na | | | | 43 | |
| G1 | | | Sm | | | | | 12 | |
| G1 | | Sh | | | | | | 18 | |
| G1 | Eh | | | | | | | 51 | G1 = 26.9% |
| G2 | | | | | Gl | Ti | | 2 | |
| G2 | | | | Na | | | Hn | 1 | |
| G2 | | | | Na | | Ti | | 3 | |
| G2 | | | | Na | Gl | | | 1 | |
| G2 | | | Sm | Na | | | | 3 | |
| G2 | | Sh | | | | Ti | | 1 | |
| G2 | | Sh | | Na | | | | 6 | |
| G2 | | Sh | Sm | | | | | 3 | |
| G2 | Eh | | | | | | Hn | 1 | |
| G2 | Eh | | | | | Ti | | 12 | |
| G2 | Eh | | | | Gl | | | 6 | |
| G2 | Eh | | | Na | | | | 10 | |
| G2 | Eh | | Sm | | | | | 1 | |
| G2 | Eh | Sh | | | | | | 8 | G2 = 11.4% |
| G3+ | | | Sm | Na | Gl | | | 1 | |
| G3+ | | Sh | | | Gl | Ti | | 1 | |
| G3+ | | Sh | | Na | | Ti | | 1 | |
| G3+ | | Sh | Sm | | | | Hn | 1 | |
| G3+ | Eh | | | | | Ti | Hn | 2 | |
| G3+ | Eh | | | | Gl | Ti | | 3 | |
| G3+ | Eh | | | Na | | Ti | | 3 | |
| G3+ | Eh | | Sm | | | Ti | | 2 | |
| G3+ | Eh | | Sm | Na | | | | 2 | |
| G3+ | Eh | | Sm | Na | | Ti | | 1 | |
| G3+ | Eh | | Sm | Na | Gl | Ti | | 1 | |
| G3+ | Eh | Sh | | | | Ti | | 1 | |
| G3+ | Eh | Sh | | | Gl | | | 1 | |
| G3+ | Eh | Sh | | Na | | | | 4 | |
| G3+ | Eh | Sh | Sm | | | | | 2 | |
| G3+ | Eh | Sh | Sm | Na | | Ti | | 1 | G3+ = 5.3% |
| | | | | | | | | 509 | |
Infeted(n) | | 112 | 48 | 30 | 81 | 17 | 39 | 12 | | |
Infection (%) | 22 | 9 | 6 | 16 | 3 | 8 | 2 | | |
All children examined received a single dose of albendazole (400 mg), and those infected with S. haematobium or S. mansoni were treated with praziquantel according to the guidelines of the Togolese Ministry of Health. Diagnostic procedures to distinguish E. histolytica from E. dispar are not available at the laboratory facilities at the CHR, Sokodé, and treatment of E. histolytica/E. dispar is recommended on evidence of invasive amoebiasis (i.e., E. histolytica trophozoites containing ingested red blood cells in stool samples, bloody stool, or clinical signs of invasive amoebiasis).
Authorization and approval for the present work was granted by the Togolese Ministry of Health (292/99/MS/CAB and 0407/2007/MMS/CAB/DGS), the regional ministry of education (MENR/SG/DRERC/13.06.2001), the regional health authority (MS/DGS/DRS/RC/No.220 and MS/DGS/DRS/RC/No.261) and the Ethik Kommission at University Clinics Tübingen/Germany (No. 188/2008/BO2). Oral informed consent was given by all participating children, and written consent was provided by all parents or legal guardians after thorough explanation of the procedures, aims, and risks of the study; moreover, to ensure informed understanding, explanations were always given in the local language by the medical staff at the CHR, Sokodé.
Parasitological analysis
For determination of intestinal helminth and protozoan infections, fresh stool samples (0.5 g) were mixed with saline and dispersed on 2 microscope slides covered with a 24×48-mm slide; samples were examined by laboratory technicians. All stool samples were examined using the Kato-Katz technique for quantification of helminth eggs per gram of stool (helm-TEST; Labmaster). To detect S. haematobium infection, 10 ml of urine from each participant was filtered (polycarbonate membrane; pore size, 12 μm; Whatman); the filters were then examined under a microscope, and S. haematobium eggs were quantified. Thick blood smears were analyzed for the presence of Plasmodium species before and 8 weeks after anti parasite treatment of G0, G1, and G3+ children.
Skin prick test examination
Aspergillus fumigates and Dermatophagoides pteronysinus prick test solutions (Bencard Allergie GmbH, München, Germany) were used. Allergens and positive histamine and negative saline controls were pricked onto the volar surface of the forearm, and reactions were recorded after 15 min. A skin prick test (SPT) weal cut-off diameters of 3 mm or larger was considered as a positive reaction. All tests were conducted by the same observer (RGG); reactions below this level were considered as non-specific and not reproducible.
Isolation of peripheral blood mononuclear cells (PBMCs) and cell culture experiments
Venous blood (9 ml) was collected from participating children before and 8 weeks after anti-parasite treatments. PBMCs were isolated by ficoll-hypaque density gradient centrifugation at 340 g for 35 min at room temperature. Plasma samples were collected and frozen at −20°C until further use. PBMCs were cultured in RPMI 1640 medium (Gibco) supplemented with 0.025 mol/l HEPES buffer, 100 U/ml penicillin, 100 μg/ml streptomycin, and 0.25 μg/ml amphotericin B (Sigma). The cell suspension was adjusted to 2,5 × 106 cells/ml and 1,25 × 106 PBMC were cultured in 0.5 ml RPMI 1640 supplemented as described above plus 10% heat-inactivated fetal calf serum (Biochrom). PBMCs were cultured in 48-well plates at 37°C in 5% CO2 with saturated humidity in the presence of either Entamoeba histolytica strain HM1 antigen (EhAg; 10 μg/ml), Plasmodium falciparum schizont lysate (PfAg; 1 × 108 schizonts/ml), Schistosoma mansoni adult worm extract (SmAg; 10 μg/ml), Echinococcus multilocularis metacestode extract (EmAg; 30 μg/ml), Ascaris lumbricoides adult worm extract (AscAg; 5 μg/ml), Lipopolysaccharid from Escherichia coli 026:B6 (LPS; 10 μg/ml), Dermatophagoides pteronyssinus (Dp, 20 μg/ml), Dermatophagoides farinae (Df, 20 μg/ml), Aspergillus fumigatus (Af; 20 μg/ml), Candida albicans (Ca; 20 μg/ml) (Dp, Df, Af, and Ca extracts were all from Allergopharma, Reinbek, Germany), or PBMC were left unstimulated (baseline). Cell cultures were terminated after 48 hours, and cell-free supernatants were collected and stored below −20°C until further use.
Determination of cytokine and chemokine production in cell culture supernatants
Quantitative enzyme-linked immune sorbent assay (ELISA) was performed with commercially available assays to determine in cell culture supernatants the levels of the cytokines IL-10, IL-27 and IL-33, as well as of the chemokines MIP3-α/CCL20 and MIG/CXCL19 (Duo-Set; R&D Minneapolis, MN, USA). Sample concentrations of each cytokine and chemokine were quantified from standard curves generated with recombinant chemokines/cytokines, and the lower limit for their detection was 30 pg/ml for IL-10, 170 pg/ml for IL-27, 25 pg/ml for IL-33, 15 pg/ml for MIP3-α/CCL20 and 60 pg/ml for MIG/CXCL9. ELISAs were performed as recommended by the manufacturer.
Statistical analysis
JMP software (versions 5.1; SAS Institute) was used for statistical analysis of data. Because of multiple comparisons, the level of significance was adjusted according to Bonferroni–Holm (alpha = 0.0018). For the cytokine and chemokine analyses, differences between groups were determined after logarithmic transformation to stabilize the variance of data (log [pg/ml + 1]). Paired data from patients were evaluated by t-test and unpaired data of patient groups were compared using Wilcoxon’s rank sum test.
Discussion
The present study revealed in children infected with helminthes and protozoan parasites distinctive cellular cytokine and chemokine response profiles to antigens of protozoa, helminthes, bacteria and allergens. The intestinal protozoa Entamoeba histolytica, bacterial LPS and mite-allergens stimulated the production of the regulatory cytokine IL-10 and monocyte-inflammatory MIP3-α/CCL20. The Plasmodium, helminthes and Candida extracts strongly induced the cellular release of MIG/CXCL9, a monokine inducible by IFN-γ, while pro-inflammatory IL-33 was inducible by Ascaris and Echinococcus antigens only.
The IL-10 production as observed in infection-free children (group G0) did not further enhance with double (G2) or poly-parasite (G3+) infections, however, it diminished post anti-parasite treatment. This we have similarly observed in hookworm, filaria and
E. histolytica co-infected adults [
12]. The regulatory cytokine IL-10 will modulate Th1-type responses to antigens by depressing pro-inflammatory TNF, IFN-γ and IL-12p70 [
22] contributing to active and general immune suppression and preventing inflammatory disease manifestations [
23-
25], but elevated IL-10 production levels may also facilitate the persistence of pathogens. Concurrent infections with several parasite species may counteract the regulatory effects of IL-10, notably when pathogens enhance the production of inflammatory cytokines and chemokines [
26], and therefore, not singular cytokines but rather distinct cytokine response profiles may define the expression of immunity and severity of disease [
27].
As a cytokine with regulatory capacity, IL-27 will initiate IFN-γ responses and promote IL-10 synthesis by regulatory T cells, then attenuate Th2 and Th17 cells [
28] and depress pro-inflammatory cytokines and chemokines [
29,
30]. In children, the production levels of regulatory IL-27 and also of inflammatory IL-33 rose with the number of infections (G0 < G < G3+) and these responses were inducible by mite-allergen extracts. IL-27 was shown to be a key regulator of IL-10 and IL-17 production by human CD4+ T cells thus providing a dual regulatory mechanism to control autoimmunity and tissue inflammation [
28-
31]. The cytokine IL-33 was suggested to function as an “alarmin” [
32]; in infants with severe malaria IL-33 levels were found enhanced, IL-33 concentrations in plasma correlated positively with parasite densities, and IL-33 diminished strongly following
P. falciparum clearance [
33].
The cellular production of the pro-inflammatory chemokines MIP3-α/CCL20 and MIG/CXCL9 was inducible by protozoan parasite antigens and mite and yeast allergens, and this wide range of responsiveness to allergens and parasite antigens may augment inflammatory cellular responsiveness. Indeed, the macrophage inflammatory protein MIP3-α/CCL20 and the monokine induced by interferon-gamma MIG/CXCL9 were found elevated in infants with severe malaria [
33] and in patients with atopic dermatitis [
34,
35]. In contrast, helminthes parasites are considered as masterful regulators of specific immune responses [
11,
36,
37], helminth parasite-induced IL-10 may modulate atopic responses in schistosoma-infected children [
17], and in filaria-infected mice regulatory T cells will inhibit atopic and airway hyper-reactivity following allergen exposure [
18].
Here, in children exposed to and infected with several parasite species not only regulatory IL-10 and anti-inflammatory IL-27 was produced by their PBMC, but also pro-inflammatory IL-33, MIP-3a/CCL20 and MIG/CXCL9 responses were observed, and with an increasing number of parasite infections these pro-inflammatory cytokines and chemokines responses enhanced.
Helminthes infections will active prominent Th2-type cytokines and immune regulatory processes [
23] and chronic geo-helminthes infection with high total IgE and anti-
Ascaris IgG4 may reduce the risk of atopy in school-age children [
38], but parasite infections do not in general protect against asthma while hookworm infection may reduce the risk of this disease [
39]. In the present study none of the participating children was infected with
Ascaris lumbricoides and it should be considered that hookworm and
S. haematobium and
S. mansoni infections will cause intestinal and urinary tract tissue damage resulting in bloody urines and mostly occult blood in stools; these helminthes will always cause gastrointestinal inflammation. As previously observed, in infants and children with helminth and protozoa infections regulatory cytokine and chemokine responses were not evolved to levels as observed in adults [
40], and such immune response profiles may develop with ageing and repeated episodes of exposure and persistent parasite infections. In the present study, allergen-specific positive skin prick test (SPT) responses were more frequent in co-infected children than in infection-free pupils suggesting that parasite co-infections may have triggered or even amplified pro-inflammatory reactivity to allergens.
Furthermore, in the present study we could show that helminthes and protozoan parasite antigen extracts will influence cellular in vitro responses to allergens. When PBMC were simultaneously stimulated with Ascaris lumbricoides antigens and allergen extracts the production of IL-27, IL-33 and MIP3-α/CCL20 lessened to levels as observed with Ascaris antigen exposure alone, suggesting anti-inflammatory effects mediated by the Ascaris antigen extract. The potential of Ascaris antigen to dampen the cellular production of pro-inflammatory cytokines and chemokines, while regulatory IL-10 remained unaffected, may help to reduce inflammation and hyper reactivity responses. In contrast, the protozoan Entamoeba antigen extract enhanced IL-10, lessened the IL-33 release and left IL-27 and MIP3-α/CCL20 production unaffected, again disclosing divergent immune activation patterns to parasite antigen extracts. Thus, the molecular composition of individual parasite species, here helminthes or protozoa, will stimulate distinct cytokine and chemokine responses which may also influence immune responsiveness to allergens.
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Competing interest
The authors declare that they have no competing interest.
Authors’ contributions
JH, CJL, XH, RGG, PTS and CK conceived, designed and performed the experiments. RGG, JH, AA, YFA, and PTS recruited, examined and treated patients. JH, PTS, CJL, XH and CK analyzed the data. JH, PTS, CJL, XH and CK wrote the manuscript. All authors read and approved the final manuscript.