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Cytokine expression in dogs with natural Leishmania infantum infection

Published online by Cambridge University Press:  02 June 2009

M. A. PANARO ,
O. BRANDONISIO ,
A. CIANCIULLI ,
P. CAVALLO ,
V. LACASELLA ,
P. PARADIES ,
G. TESTINI ,
D. DE CAPRARIIS ,
V. MITOLO  and
D. OTRANTO
M. A. PANARO
Affiliation:
Department of Human Anatomy and Histology, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
O. BRANDONISIO
Affiliation:
Department of Internal Medicine, Immunology and Infectious Diseases, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
A. CIANCIULLI
Affiliation:
Department of Human Anatomy and Histology, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
P. CAVALLO
Affiliation:
Department of Human Anatomy and Histology, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
V. LACASELLA
Affiliation:
Department of Internal Medicine, Immunology and Infectious Diseases, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
P. PARADIES
Affiliation:
Department of Veterinary Public Health, Faculty of Veterinary Medicine, University of Bari, Strada Provinciale per Casamassima Km. 3, 70010 Valenzano, Bari, Italy
G. TESTINI
Affiliation:
Department of Veterinary Public Health, Faculty of Veterinary Medicine, University of Bari, Strada Provinciale per Casamassima Km. 3, 70010 Valenzano, Bari, Italy
D. DE CAPRARIIS
Affiliation:
Department of Veterinary Public Health, Faculty of Veterinary Medicine, University of Bari, Strada Provinciale per Casamassima Km. 3, 70010 Valenzano, Bari, Italy
V. MITOLO
Affiliation:
Department of Human Anatomy and Histology, Faculty of Medicine, University of Bari, Piazza G. Cesare, 70100 Bari, Italy
D. OTRANTO*
Affiliation:
Department of Veterinary Public Health, Faculty of Veterinary Medicine, University of Bari, Strada Provinciale per Casamassima Km. 3, 70010 Valenzano, Bari, Italy
*
*Corresponding author: Department of Veterinary Public Health, Faculty of Veterinary Medicine, University of Bari, Strada Provinciale per Casamassima Km. 3, 70010 Valenzano, Bari, Italy. Tel/fax: +39 080 4679839. E-mail: d.otranto@veterinaria.uniba.it
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Summary

The aim of this study was to evaluate cytokine expression in 22 Leishmania infantum naturally infected dogs, in order to correlate this parameter with the clinical status of infected animals. After 4 and 8 months from the first diagnosis of Leishmania infection, clinical and laboratory examination of dogs was performed and peripheral blood mononuclear cells (PBMC) were isolated. The cytokine profile was analysed in terms of IFN-gamma, IL-4, IL-10 and TNF-alpha mRNA expression in cultured PBMC by a semi-quantitative reverse transcriptase-PCR. Thirteen out of 22 Leishmania-infected dogs remained asymptomatic in the follow-up, while 9 showed clinical signs of leishmaniasis. IL-4, IL-10, TNF-alpha and IFN-gamma mRNA levels were not significantly different in asymptomatic compared to symptomatic animals 4 months from the diagnosis of Leishmania infection, but were significantly higher in symptomatic versus asymptomatic dogs after 8 months from diagnosis. In addition, IL-4, IL-10 and TNF-alpha mRNA levels significantly increased only in symptomatic dogs at 8 months, in comparison to the levels found at 4 months. These results show a mixed Th1 and Th2 cytokine response in Leishmania-infected dogs, with higher cytokine expression in dogs with manifest clinical disease, during the second follow-up after 8 months from the first diagnosis of infection.

Keywords

Leishmaniacanine leishmaniasisIFN-gammaIL-10IL-4TNF-alpha
Type
Research Article
Information
Parasitology , Volume 136 , Issue 8 , July 2009 , pp. 823 - 831
Copyright
Copyright © Cambridge University Press 2009

INTRODUCTION

Protozoa of the Leishmania genus infect phagocytes of several mammalian species, including humans. Human leishmaniasis comprises 2 major diseases, visceral leishmaniasis (VL), which is fatal if untreated, and the cutaneous form (CL) that can heal spontaneously but often leaves disfiguring scars. VL causes an estimated 59 000 deaths annually (a rate surpassed among parasitic diseases only by malaria), and the loss of 2 357 000 disability-adjusted life years (DALYs), with an estimated increasing burden in poor social and economic settings (Alvar et al. Reference Alvar, Yactayo and Bern2006) and in HIV-infected patients (Alvar et al. Reference Alvar, Aparicio, Aseffa, Den Boer, Cañavate, Dedet, Gradoni, Ter Horst, López-Vélez and Moreno2008). The incidence of Leishmania infection in humans and dogs has increased in Italy since the 1990s, with new foci being detected within the traditional boundaries of endemic transmission but also in northern regions previously regarded as non-endemic (Dujardin et al. Reference Dujardin, Campino, Cañavate, Dedet, Gradoni, Soteriadou, Mazeris, Ozbel and Boelaert2008; Maroli et al. Reference Maroli, Rossi, Baldelli, Capelli, Ferroglio, Genchi, Gramiccia, Mortarino, Pietrobelli and Gradoni2008; Schönian et al. Reference Schönian, Mauricio, Gramiccia, Cañavate, Boelaert and Dujardin2008).

The dog is the main reservoir host for Leishmania infantum, which is responsible for human leishmaniasis in China, Mediterranean countries and the Americas (Dantas-Torres, Reference Dantas-Torres2007). Infected dogs can be asymptomatic or symptomatic. The latter form ranges from limited to multifocal tissue damage which gives rise to a chronic, non-self-healing visceral disease (Baneth et al. Reference Baneth, Koutinas, Solano-Gallego, Bourdeau and Ferrer2008). Transmission of Leishmania spp. occurs when phlebotomine sandfly vectors feed on symptomatic or asymptomatic infected dogs, even if the infectiousness appears to be higher in dogs with clinical disease (Michalsky et al. Reference Michalsky, Rocha, da Rocha Lima, França-Silva, Pires, Oliveira, Pacheco, dos Santos, Barata, Romanha, Fortes-Dias and Dias2007). This highlights the importance of dogs in spreading human disease, also in the light of a possibly prolonged subpatent period (Oliva et al. Reference Oliva, Scalone, Foglia Manzillo, Gramiccia, Pagano, Di Muccio and Gradoni2006). In Southern Italy a yearly incidence rate of canine leishmaniasis (CanL) of 9·52% has been estimated in both farm and kennel dogs (Paradies et al. Reference Paradies, Capelli, Cafarchia, de Caprariis, Sasanelli and Otranto2006), with a high percentage (53·1%) of serologically positive asymptomatic animals (Brandonisio et al. Reference Brandonisio, Carelli, Ceci, Consenti, Fasanella and Puccini1992).

The current control strategies for VL include the detection and treatment of infected and diseased animals and humans (Chappuis et al. Reference Chappuis, Sundar, Hailu, Ghalib, Rijal, Peeling, Alvar and Boelaert2007), the development of an affordable and effective vaccine for humans and dogs (Palatnik-de-Sousa, Reference Palatnik-de-Sousa2008), and the use of insecticides and repellents to avoid sandfly bites (Otranto et al. Reference Otranto, Paradies, Lia, Latrofa, Testini, Cantacessi, Mencke, Galli, Capelli and Stanneck2007). In this respect, knowledge of the immune mechanisms involved in animal protection plays a pivotal role in understanding the pathogenesis and clinical course of the disease, as well as in fostering the development of vaccines. In particular, no conclusive data are available on the immunological mechanisms responsible for resistance or disease progression in canine leishmaniasis, and studies on the expression of different cytokines (reviewed by Barbiéri, Reference Barbiéri2006; Baneth et al. Reference Baneth, Koutinas, Solano-Gallego, Bourdeau and Ferrer2008; Carrillo and Moreno, Reference Carrillo and Moreno2008) have often yielded conflicting results. Cellular immune responses toward a Th1 subset mediated by IFN-γ and TNF-α seem to predominate in asymptomatic dogs, exhibiting apparent resistance to visceral leishmaniasis, while the role of Th2 cytokines, such as IL-4 and IL-10, in symptomatic animals is still controversial.

The aim of this study was to monitor cytokine expression in cultured peripheral blood mononuclear cells (PBMC) from asymptomatic and symptomatic dogs in the course of natural Leishmania infection, in order to correlate the cytokine pattern with the clinical status in these animals. In particular, interferon (IFN)-γ, interleukin (IL)-10, IL-4 and Tumour Necrosis Factor (TNF)-α gene expression was investigated in dog PBMC by a semi-quantitative reverse transcriptase-PCR (RT-PCR), after 4 and 8 months from the first diagnosis of Leishmania infection.

MATERIALS AND METHODS

Parasites

Parasites were isolated from the bone marrow of a Leishmania-infected dog and cultured on Tobie-Evans medium at 24°C. The isolated strain was typed by the Istituto Superiore di Sanità (Rome, Italy) and shown to belong to the L. infantum species, zymodeme MON1. Promastigotes at day 4 of culture were used, since the maximum percentage of metacyclic (virulent) promastigotes is detected on the 4th day of growth for L. infantum (Louassini et al. Reference Louassini, Adroher, Foulquie and Benitez1998). The liquid phase of the tubes was collected and centrifuged at 350 g for 10 min. Supernatants were then discarded and the pellets were suspended in phosphate-buffered saline (PBS) pH 7·2, and washed 3 times by centrifugation in PBS at 350 g for 10 min as previously described (Brandonisio et al. Reference Brandonisio, Panaro, Fumarola, Sisto, Leogrande, Acquafredda, Spinelli and Mitolo2002). Finally, promastigotes were counted using a haemocytometer after immobilization with 2–3 drops of 70% ethanol.

Leishmania soluble antigen (LSA) preparation

LSA was used as stimulator antigen for lymphocyte activation. LSA was prepared according to the method of Pinelli et al. (Reference Pinelli, Killick-Kendrick, Wagenaar, Bernadina, del Real and Ruitenberg1994). Briefly, washed cultured L. infantum promastigotes at a concentration of 2×108/ml in PBS were frozen and thawed 3 times, sonicated, centrifuged (8000 g, 30 min, 4°C) and the resulting supernatants were collected. The protein content in the supernatants was evaluated by the Bradford method (Bradford, Reference Bradford1976) and aliquots (1 mg/ml) of LSA were stored at −20°C until use.

Animal sampling and clinical examination

The animals came from 2 kennels in the Apulian region, southern Italy (latitude 42° and 39° North, longitude 15° and 18° East), where endemic CanL has been reported over the previous years (Paradies et al. Reference Paradies, Capelli, Cafarchia, de Caprariis, Sasanelli and Otranto2006). A total of 22 dogs that were negative for L. infantum (in parasitological and serological tests, see below) in March 2005 but newly infected by L. infantum by March 2006 (after one sandfly season) were enrolled in the study. All selected animals were positive at parasitological (i.e. PCR on skin biopsy and/or microscopic examination of lymph node smears) and/or serological tests for Leishmania but did not exhibit clinical signs of leishmaniasis or laboratory abnormalities in March 2006 (Otranto et al. Reference Otranto, Paradies, Lia, Latrofa, Testini, Cantacessi, Mencke, Galli, Capelli and Stanneck2007). Serological tests for the presence of anti-Leishmania antibodies (IFAT) and PCR were performed using the procedures already described (Paradies et al. Reference Paradies, Capelli, Cafarchia, de Caprariis, Sasanelli and Otranto2006; Otranto et al. Reference Otranto, Paradies, Lia, Latrofa, Testini, Cantacessi, Mencke, Galli, Capelli and Stanneck2007).

Clinical examination of dogs was performed monthly, in order to evaluate a possible disease progression. Clinical signs indicative of CanL (e.g. weight loss, alopecia, dermatitis, conjunctivitis, onychogryphosis, lymphadenopathy, etc.) were recorded on each dog's file. In July and November 2006, at 4 and 8 months from the diagnosis of Leishmania infection (first and second follow-up), 20 ml heparinized peripheral blood samples and serum samples were collected from the brachial or jugular vein of each dog. Animals were handled and sampled with the owners' consent, and approval was obtained from the Ethics Committee of the University of Bari. Serological tests for the presence of anti-Leishmania antibodies (IFAT) were performed at each follow-up time using the procedures already described (Paradies et al. Reference Paradies, Capelli, Cafarchia, de Caprariis, Sasanelli and Otranto2006).

Isolation and stimulation of peripheral blood mononuclear cells (PBMC)

PBMC were isolated from 20 ml of heparinized peripheral blood, diluted with sterile Hanks' balanced salt solution (HBSS; Gibco-Invitrogen, Carlsbad, CA, USA) at a 1:1 (v/v) ratio and centrifuged on the cell separation medium Lympholyte-H (CEDARLANE, Burlington, Ontario, Canada) at 700 g for 15 min at room temperature. Then, isolated PBMC were extensively washed and suspended in RPMI-1640 complete medium, supplemented with 2 mm glutamine, 10% heat-inactivated (56°C for 30 min) foetal calf serum (FCS), 100 μl/ml streptomycin and 100 IU/ml penicillin. Cell viability was evaluated by trypan blue dye exclusion and resulted higher than 98%. Isolated cells were cultured at a density of 10×106/ml in 25 cm2 ventilated tissue culture flasks (Falcon) at 37°C in 5% CO2 supplemented with 200 mm glutamine, 10% FCS, 100 μg/ml streptomycin and 100 IU/ml penicillin.

After 24 h of incubation in order to stabilize cell culture (Schmelzer et al. Reference Schmelzer, Lorenz, Rimbach and Döring2009), PBMC were submitted to the following in vitro treatments (1) stimulation with LSA (10 μg/ml) (2) stimulation with the mitogen phytohaemagglutinin (PHA, Sigma-Aldrich) (5 μg/ml). Unstimulated cells were incubated as negative controls.

Detection of dog cytokine gene expression by reverse transcription (RT)-PCR

After 48 h of incubation in the same culture conditions, total cellular RNA was extracted from PBMC cultured in tissue flasks as indicated above, by the RNAzolTMbee isolation reagent (Tel-Test, Inc., Friendswood, TX, USA), according to the manufacturer's instructions. The RNA extracted was stored at −80°C until use. The expression of dog cytokine genes was analysed by RT-PCR. Briefly, total cellular RNA extracted from dog PBMC cultures was submitted to reverse transcription to obtain the cDNA. Reverse transcription was performed in a final volume of 20 μl containing 3 μg of total RNA, 40 U of RNase Out (Recombinant Ribonuclease Inhibitor, Life Technologies, Milan, Italy), 40 mU of oligo dT with 0·5 mm dNTP (PCR Nucleotide Mix, Roche Diagnostics, Mannheim, Germany), 40 U of Moloney Murine Leukemia Virus Reverse Transcriptase (Roche Diagnostics). The reaction tubes were incubated at 37°C for 60 min, then at 95°C for 5 min and at 4°C to stop the reaction. The obtained cDNAs were then amplified by a Perkin Elmer 2400 thermal cycler under the following conditions: 95°C for 4 min, 95°C for 1 min, annealing temperature according to the primers used for 1 min and 72°C for 1 min (40 cycles of amplification). At the end of the reaction, tubes were incubated at 72°C for 7 min and then at 4°C to stop the reaction. Each tube contained, in a final volume of 50 μl, 2 μl of cDNA, 200 μm dNTP (PCR Nucleotide Mix), 4 U TaqDNA Polymerase (both from Roche Diagnostics), 5 μl of MgCl2 buffer stock solution, and 50 pmol of primers (Invitrogen, Paisley, UK) specific for dog cytokine genes, whose GenBank Accession numbers were AF 327899 for TNF-α; AF 327901 for IFN-γ; AF 328930 for IL-10; AF 239917 for IL-4, and AF 327898 for GADPH, used as housekeeping gene control. The resulting products were separated with agarose gel (1·2%) and stained with ethidium bromide.

Densitometric analysis

PCR product bands were analysed and the average intensity of the bands was determined using software 1D Image Analysis Software (Kodak Digital Science) in a grey-scale mode. The image was digitally inverted, so that the integration of bands was reported as positive values. The pixel density was determined after background subtraction and used to calculate the integrated density of a selected band. Values of integrated density were reported as Arbitrary Units (AU), corresponding to volume units of pixel intensity per mm2. The integrated density of each band was reported as the mean of 3 different measurements of the same band for each sample run in triplicate. The amount of cytokine expression was established as a ratio referred to GADPH, a housekeeping gene, which is expressed at a constant rate independent of the immunological activation state (Gröne et al. Reference Gröne, Weckmann, Capen and Rosol1996). Data were collected in terms of average intensity of bands of the different cytokines per average intensity of bands of GADPH, and imported to a spreadsheet (Excel; Microsoft, Redmond, Washington, USA). Data plotted in the final graphs represent the mean and standard deviation (s.d.) of the 3 mean values obtained for each experimental set.

Statistical analysis

Our data do follow a normal distribution, therefore, the results were analysed by one-way ANOVA and a P-value <0·05 was considered statistically significant. The statistical analysis was performed using the software package MINITAB® Release 14.1 (Minitab Ltd, Coventry, UK).

RESULTS

Thirteen out of 22 Leishmania-infected dogs enrolled in the study remained asymptomatic during the follow-up, while 9 developed clinical signs of leishmaniasis (i.e. dermatitis, lymphadenopathy, conjunctivitis, and skin ulcers) and/or hypergammaglobulinaemia within the first 4 months after the diagnosis of infection; these symptoms were still present 8 months after diagnosis. Six (66·6%) and 4 (30·7%) symptomatic and asymptomatic dogs, respectively, were positive in IFAT at the first and/or second follow-up, whereas the rest remained negative (data not shown).

The expression of the cytokines IL-4, IFN-γ, IL-10 and TNF-α in PBMC was investigated by RT-PCR in both symptomatic and asymptomatic dogs.

Analysis of IL-4 expression

Results of densitometric analysis of bands obtained by electrophoresis of RT-PCR products demonstrated that IL-4 mRNA levels obtained from LSA-stimulated PBMC were not significantly different in asymptomatic (0·02±0·01, mean±S.D.) compared to symptomatic animals (0·01±0·00) 4 months from the diagnosis of Leishmania infection, but were significantly (P=0·02) higher in LSA-stimulated PBMC from symptomatic (0·10±0·01) versus asymptomatic (0·04±0·02) dogs after 8 months from diagnosis (Fig. 1A).

Fig. 1. IL-4 (Panel A), IL-10 (Panel B), TNF-α (Panel C), IFN-γ (Panel D) mRNA expression in PBMC from 13 asymptomatic (black columns) and 9 symptomatic (white columns) dogs in samples taken at first and second follow-up (i.e. 4 and 8 months after the diagnosis of canine leishmaniasis). Results of densitometric analysis of RT-PCR bands are expressed as arbitrary units (means±S.D.). CTL, controls; PHA, phytohaemagglutinin; LSA, Leishmania soluble antigen. See text for statistically significant differences.

In addition, IL-4 mRNA levels were significantly (P=0·001) increased in LSA-stimulated PBMC from symptomatic dogs from 4 months in comparison to 8 months after diagnosis of infection. No significant differences were observed in LSA-stimulated PBMC from asymptomatic dogs between 4 and 8 months after diagnosis of infection.

However, expression of IL-4 by LSA-stimulated PBMC was very low and not significantly different from unstimulated PBMC (used as controls) both in symptomatic dogs at 4 months and in asymptomatic dogs after 8 months from diagnosis of infection.

Analysis of IL-10 expression

Results of densitometric analysis of RT-PCR products demonstrated that IL-10 mRNA levels obtained from LSA-stimulated PBMC were not significantly different in asymptomatic (0·55±0·06) compared to symptomatic animals (0·30±0·09) 4 months from the diagnosis of Leishmania infection, but were significantly (P=0·001) higher in LSA-stimulated PBMC from symptomatic (0·97±0·27) versus asymptomatic dogs (0·45±0·06) after 8 months from diagnosis (Fig. 1B).

In addition, IL-10 mRNA levels were significantly (P=0·002) increased in LSA-stimulated PBMC from symptomatic dogs, 8 months in comparison to 4 months after diagnosis of infection. No significant differences were observed in LSA-stimulated PBMC from asymptomatic dogs between 8 and 4 months after diagnosis of infection.

Comparison between unstimulated PBMC and LSA-stimulated PBMC showed that stimulation induced a significant increase of IL-10 expression in all examined dog samples.

Analysis of TNF-α expression

Results of RT-PCR products demonstrated that TNF-α mRNA levels obtained from LSA-stimulated PBMC were not significantly different in asymptomatic (0·24±0·04) compared to symptomatic animals (0·13±0·05) at the first follow-up from the diagnosis of Leishmania infection, but were significantly (P=0·03) higher in LSA-stimulated PBMC from symptomatic (0·57±0·15) versus asymptomatic dogs (0·28±0·05) at the second follow-up from diagnosis (Fig. 1C).

In addition, TNF-α mRNA levels were significantly (P<0·01) increased in LSA-stimulated PBMC of symptomatic dogs at the second follow-up, in comparison to the levels found at the first follow-up, but were not significantly different during follow-up in asymptomatic dogs.

Comparison between unstimulated PBMC and LSA-stimulated PBMC showed that stimulation induced a significant increase of TNF-α mRNA levels in all examined samples.

Analysis of IFN-γ expression

IFN-γ mRNA levels in LSA-stimulated PBMC were not significantly different in asymptomatic (0·26±0·11) compared to symptomatic animals (0·43±0·14) 4 months from diagnosis of the infection, but were significantly (P=0·001) higher in PBMC of symptomatic dogs (0·71±0·22) in comparison to asymptomatic animals (0·19±0·08) after 8 months from diagnosis. However, no significant differences in the IFN-γ mRNA levels were observed between the first and second follow-up in either asymptomatic or sick dogs (Fig.1D).

Comparison between unstimulated PBMC and LSA-stimulated PBMC showed that stimulation induced a significant increase of IFN-γ mRNA expression in all examined samples.

Fig. 2 shows results of a representative experiment of agarose gel electrophoresis of RT-PCR products and staining with ethidium bromide.

Fig. 2. Gel electrophoretic analysis of RT-PCR products derived from PBMC total mRNA of asymptomatic (left) and symptomatic (right) dogs. Lanes 1 and 4: unstimulated PBMC; lanes 2 and 5: PHA stimulated PBMC; lanes 3 and 6: LSA stimulated PBMC. The figure is representative of 22 experiments carried out on 13 asymptomatic and 9 symptomatic dogs.

Overall, PBMC from both asymptomatic and symptomatic dogs expressed IL-10, TNF-α and IFN-γ cytokines mRNA levels after LSA stimulation at 4 and 8 months after diagnosis. However, mRNA levels for all cytokines tested were significantly higher in LSA-stimulated PBMC of symptomatic dogs in comparison to asymptomatic ones at 8 months post-diagnosis. Moreover, an increased expression of IL-4, IL-10 and TNF-α in LSA-stimulated PBMC was recorded in symptomatic dogs at the second follow-up after the diagnosis of infection. Conversely, no increase in cytokine expression was observed in asymptomatic dogs during the follow-up. However, it should be noted that the very low IL-4 production observed in symptomatic dogs after LSA stimulation when compared to controls does not allow drawing any definitive conclusion about this cytokine production.

DISCUSSION

It is well known that in the murine model of infection with Leishmania major, a clear dichotomy is observed between cytokine production by draining lymph node cells of susceptible versus resistant mouse strains (Wilson et al. Reference Wilson, Jeronimo and Pearson2005). In resistant mouse strains, infection with L. major results in the development of a protective T helper-1 (Th1) immune response with high levels of IFN-γ and resistance to re-infection. By contrast, infection of susceptible mouse strains leads to the development of a Th2 immune response characterized by the production of IL-4, IL-6, IL-10 and IL-13, whose role can differ according to the Leishmania species (Tacchini-Cottier and Launois, Reference Tacchini-Cottier, Launois, Myler and Fasel2008).

However, the paradigm Th1-protection/Th2-susceptibility is largely based on the cure/no cure responses to L. major infection in mice, whereas visceral disease in humans, dogs and other rodents does not show a clear Th1/Th2 dichotomy pattern (Strauss-Ayali et al. Reference Strauss-Ayali, Baneth and Jaffe2007). Finally, the paradigm Th1/protection has recently been debated, especially in view of results obtained in human visceral leishmaniasis (Mansueto et al. Reference Mansueto, Vitale, Di Lorenzo, Rini, Mansueto and Cillari2007) or in vaccination experiments, since many leishmanial antigens which stimulated a Th1 immune response did not show a protective action (Campos-Neto, Reference Campos-Neto2005; Khalil et al. Reference Khalil, Ayed, Musa, Ibrahim, Mukhtar, Zijlstra, Elhassan, Smith, Kieny, Ghalib, Zicker, Modabber and Elhassan2005).

The results presented herein suggest that L. infantum infection induces a mixed Th1/Th2 response in both asymptomatic and symptomatic dogs, with higher cytokine expression in dogs exhibiting manifest disease at 8 months follow-up than at 4 months follow-up.

This is in accordance with results of other investigations, showing a mixed cytokine response in canine leishmaniasis. In fact, in the spleen of dogs with natural L. infantum chagasi infection, both IL-10 and IFN-γ were associated with disease progression (Lage et al. Reference Lage, Oliveira, Busek, Guerra, Giunchetti, Corrêa-Oliveira and Reis2007), and in the spleen of experimentally infected dogs, both IL-4 and IFN-γ may have a role in allowing persistence of the parasite (Strauss-Ayali et al. Reference Strauss-Ayali, Baneth and Jaffe2007). Finally, a recent longitudinal study in experimentally infected dogs suggested an early expression of both Th1 (IFN-γ) and Th2 (IL-4, IL-13) cytokines in dogs that develop clinical leishmaniasis (Sanchez-Robert et al. Reference Sanchez-Robert, Altet, Alberola, Rodriguez-Cortés, Ojeda, López-Fuertes, Timon, Sanchez and Francino2008).

As regards IFN-γ, our results showing a higher expression of its levels at the second follow-up in dogs with overt disease are not in accordance with previous investigations in which IFN-γ production by LSA-stimulated PBMC was correlated with protection or asymptomatic infection (Strauss-Ayali et al. Reference Strauss-Ayali, Baneth, Shor, Okano and Jaffe2005; Chamizo et al. Reference Chamizo, Moreno and Alvar2005; Carrillo et al. Reference Carrillo, Ahmed, Goldsmith-Pestana, Nieto, Osorio, Travi, Moreno and McMahon-Pratt2007). In addition, in experimental L. infantum infection, a protective role for a Th1-mediated immune response was suggested by the finding of enhanced levels of IFN-γ in cultured PBMC (Pinelli et al. Reference Pinelli, Gonzalo, Boog, Rutten, Gebhard, del Real and Ruitenberg1995). In natural infection, in animals that remained asymptomatic a Th1 dominance mediated by IL2, IFN-γ and IL-18 was recorded (Manna et al. Reference Manna, Reale, Viola, Vitale, Manzillo, Michele, Caracappa and Gravino2006). Accordingly, dogs vaccinated with killed promastigotes produced IFN-γ (Panaro et al. Reference Panaro, Acquafredda, Lisi, Lofrumento, Mitolo, Sisto, Fasanella, Trotta, Bertani, Consenti and Brandonisio2001), and stimulation with the recombinant proteins (HSP-70, PFR-2 and KMP-11) induced an up-regulation of IFN-γ mRNA expression in dog PBMC (Carrillo et al. Reference Carrillo, Crusat, Nieto, Chicharro, Thomas Mdel, Martínez, Valladares, Cañavate, Requena, López, Alvar and Moreno2008). Among the vaccines revealing a high efficacy in the field (reviewed by Miró et al. Reference Miró, Cardoso, Pennisi, Oliva and Baneth2008), purified excreted-secreted antigens from L. infantum promastigotes with muramyl dipeptide correlate with a specific Th1-type cellular immune response and increased IFN-γ levels 8 months after vaccination (Lemesre et al. Reference Lemesre, Holzmuller, Gonçalves, Bourdoiseau, Hugnet, Cavaleyra and Papierok2007).

However, in accordance with results presented here, there was a positive correlation between IFN-γ production and progress of infection in freshly stimulated PBMC (Poot et al. Reference Poot, Spreeuwenberg, Sanderson, Schijns, Mottram, Coombs and Vermeulen2006; Sanchez-Robert et al. Reference Sanchez-Robert, Altet, Alberola, Rodriguez-Cortés, Ojeda, López-Fuertes, Timon, Sanchez and Francino2008), bone marrow (Quinnell et al. Reference Quinnell, Courtenay, Shaw, Day, Garcez, Dye and Kaye2001) and spleen samples (Lage et al. Reference Lage, Oliveira, Busek, Guerra, Giunchetti, Corrêa-Oliveira and Reis2007; Strauss-Ayali et al. Reference Strauss-Ayali, Baneth and Jaffe2007). The higher expression of IFN-γ levels found in the present work in dogs with overt disease at the second follow-up may suggest that Leishmania-infected macrophages become non-responsive to the activating stimulus of IFN-γ (Olivier and Gregory, Reference Olivier, Gregory, Myler and Fasel2008). Nonetheless, IFN-γ may exert a dual, i.e protective or disease-promoting, role in CanL, as shown in Toxoplasma gondii infection (Pfaff et al. Reference Pfaff, Abou-Bacar, Letscher-Bru, Villard, Senegas, Mousli and Candolfi2007).

The correlation between disease progression and higher expressions of IL-4, IL-10 and TNF-α recorded herein suggests a counter-protective role for these cytokines in CanL. As regards IL-4 and IL-10, our results are in accordance with other publications showing correlation between IL-4 expression and parasite load in skin samples during CanL (Brachelente et al. Reference Brachelente, Müller, Doherr, Sattler and Welle2005). A decreased expression of IL-4 mRNA was also observed in freshly isolated PBMC of asymptomatic dogs compared to control dogs (Chamizo et al. Reference Chamizo, Moreno and Alvar2005). In addition, stimulation with the P-8 amastigote antigen or recombinant proteins (HSP-70, PFR-2 and KMP-11) induced low levels of IL-4 mRNA expression in dog PBMC, with no measurable induction of IL-10 (Carrillo et al. Reference Carrillo, Ahmed, Goldsmith-Pestana, Nieto, Osorio, Travi, Moreno and McMahon-Pratt2007, Reference Carrillo, Crusat, Nieto, Chicharro, Thomas Mdel, Martínez, Valladares, Cañavate, Requena, López, Alvar and Moreno2008). The inhibitory effect of IL-4 and IL-10 on signal transduction for the inducible enzyme iNOS2 (Bogdan et al. Reference Bogdan, Röllinghoff and Diefenbach2000), responsible for nitric oxide production by activated macrophages and involved in the long-term protection of dogs against natural L. infantum infection (Panaro et al. Reference Panaro, Brandonisio, de Caprariis, Cavallo, Cianciulli, Mitolo and Otranto2008; Zafra et al. Reference Zafra, Jaber, Pérez-Ecija, Barragán, Martínez-Moreno and Pérez2008), should be borne in mind.

IL-10 plays an important counter-protective role in the course of Leishmania infection also in humans and mice (Nylén and Sacks, Reference Nylén and Sacks2007; Anderson et al. Reference Anderson, Lira, Kamhawi, Belkaid, Wynn and Sacks2008). However, a possible low implication of IL-10 during CanL is suggested by other studies, in which the disease severity was not related with the expression of IL-10 by PBMC of experimentally infected dogs (Santos-Gomes et al. Reference Santos-Gomes, Rosa, Leandro, Cortes, Romão and Silveira2002) and the expression levels of IL-10 did not change during the infection in spleens of L. infantum-infected dogs (Strauss-Ayali et al. Reference Strauss-Ayali, Baneth and Jaffe2007). Similarly, Corrêa and colleagues (Reference Corrêa, Dossi, de Oliveira Vasconcelos, Munari and de Lima2007) showed higher levels of IL-10 than of IFN-γ in the spleen and liver of both symptomatic and asymptomatic dogs naturally infected by L. chagasi, with no clear correlation with the clinical status.

As regards TNF-α, its increased expression in LSA-stimulated PBMC recorded only in animals presenting clinical signs of CanL at the second follow-up after the diagnosis of infection, is not in accordance with previous studies showing its up-regulation in PBMC (Carrillo et al. Reference Carrillo, Ahmed, Goldsmith-Pestana, Nieto, Osorio, Travi, Moreno and McMahon-Pratt2007) and lymph nodes (Alves et al. Reference Alves, de Amorim, Moura, Ribeiro, Alves, Michalick, Kalapothakis, Bruna-Romero, Tafuri, Teixeira and Melo2008) of asymptomatically infected dogs. In this context, a better investigation of the genetic background of dogs predisposing to overt disease would be of particular interest (Baneth et al. Reference Baneth, Koutinas, Solano-Gallego, Bourdeau and Ferrer2008), since allelic associations between polymorphisms at the TNF locus within the major histocompatibility complex and susceptibility to the severe mucocutaneous form of leishmaniasis caused by L. braziliensis was demonstrated in humans (Blackwell, Reference Blackwell1999).

Overall, studies concerning the production of different cytokines in CanL are often difficult to compare because of their different experimental designs, i.e. in the course of natural or experimental infection, or in response to vaccination at different times during the infection and using different tissues (i.e. skin, spleen, liver, bone marrow, cultured or freshly isolated PBMC). The methods used for cytokine evaluation were also different, mainly involving dosage by ELISA or evaluation of mRNA expression by RT-PCR or real-time RT-PCR. Further investigation should be made of the PBMC fraction involved in the enhanced cytokine expression observed in the present study, possibly using dog CD markers and assessing canine regulatory T cell (TREG) populations.

Finally, results from serological tests have shown that 66·6% of animals showing clinical symptoms and 30·7% of asymptomatic dogs were positive at serology at the first and/or second follow-up, whereas the remaining dogs were negative. This confirms that the diagnostic and prognostic predictive value of serodiagnosis in dog leishmaniasis is scant (Otranto et al. Reference Otranto, Paradies, de Caprariis, Stanneck, Testini, Grimm, Deplazes and Capelli2009).

In conclusion, this study indicates that the cell-mediated immune response mechanisms underlying natural CanL in the Mediterranean area could be different from those in other animal models in which the classical paradigm of Th1/Th2 was associated with resistance or susceptibility. A better understanding of the complex profile of cytokine expression in CanL should contribute to the design of more efficient vaccines and therapies.

This work was partially funded by University of Bari (Fondi Ateneo 2007) and by Bayer Animal Health (Germany). The authors thank Ms M. Pragnell for her skillful technical assistance.

References

REFERENCES

Alvar, J., Aparicio, P., Aseffa, A., Den Boer, M., Cañavate, C., Dedet, J. P., Gradoni, L., Ter Horst, R., López-Vélez, R. and Moreno, J. (2008). The relationship between leishmaniasis and AIDS: the second 10 years. Clinical Microbiology Reviews 21, 334359.Google Scholar
Alvar, J., Yactayo, S. and Bern, C. (2006) Leishmaniasis and poverty. Trends in Parasitology 22, 552557.CrossRefGoogle ScholarPubMed
Alves, C. F., de Amorim, I. F., Moura, E. P., Ribeiro, R. R., Alves, C. F., Michalick, M. S., Kalapothakis, E., Bruna-Romero, O., Tafuri, W. L., Teixeira, M. M. and Melo, M. N. (2008). Expression of IFN-gamma, TNF-alpha, IL-10 and TGF-beta in lymph nodes associates with parasite load and clinical form of disease in dogs naturally infected with Leishmania (Leishmania) chagasi. Veterinary Immunology and Immunopathology Nov 17 [Epub ahead of print].Google ScholarPubMed
Anderson, C. F., Lira, R., Kamhawi, S., Belkaid, Y., Wynn, T. A. and Sacks, D. (2008). IL-10 and TGF-beta control the establishment of persistent and transmissible infections produced by Leishmania tropica in C57BL/6 mice. The Journal of Immunology 180, 40904097.CrossRefGoogle ScholarPubMed
Baneth, G., Koutinas, A. F., Solano-Gallego, L., Bourdeau, P. and Ferrer, L. (2008). Canine leishmaniosis – new concepts and insights on an expanding zoonosis: part one. Trends in Parasitology 24, 324330.CrossRefGoogle Scholar
Barbiéri, C. L. (2006). Immunology of canine leishmaniasis. Parasite Immunology 28, 329337.CrossRefGoogle ScholarPubMed
Blackwell, J. M. (1999). Tumour necrosis factor alpha and mucocutaneous leishmaniasis. Parasitology Today 15, 7375.Google Scholar
Bogdan, C., Röllinghoff, M. and Diefenbach, A. (2000). Reactive oxygen and reactive nitrogen intermediates in innate and specific immunity. Current Opinion in Immunology 12, 6476.CrossRefGoogle ScholarPubMed
Brachelente, C., Müller, N., Doherr, M. G., Sattler, U. and Welle, M. (2005). Cutaneous leishmaniasis in naturally infected dogs is associated with a T helper-2-biased immune response. Veterinary Pathology 42, 166175.Google Scholar
Bradford, M. M. (1976). A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry 72, 248254.CrossRefGoogle ScholarPubMed
Brandonisio, O., Carelli, G., Ceci, L., Consenti, B., Fasanella, A. and Puccini, V. (1992). Canine leishmaniasis in the Gargano promontory (Apulia, South Italy). European Journal of Epidemiology 8, 273276.Google Scholar
Brandonisio, O., Panaro, M. A., Fumarola, I., Sisto, M., Leogrande, D., Acquafredda, A., Spinelli, R. and Mitolo, V. (2002). Macrophage chemotactic protein-1 and macrophage inflammatory protein-1 alpha induce nitric oxide release and enhance parasite killing in Leishmania infantum-infected human macrophages. Clinical and Experimental Medicine 2, 125129.Google Scholar
Campos-Neto, A. (2005). What about Th1/Th2 in cutaneous leishmaniasis vaccine discovery? Brazilian Journal of Medical and Biological Research 38, 979984.Google Scholar
Carrillo, E., Ahmed, S., Goldsmith-Pestana, K., Nieto, J., Osorio, Y., Travi, B., Moreno, J. and McMahon-Pratt, D. (2007). Immunogenicity of the P-8 amastigote antigen in the experimental model of canine visceral leishmaniasis. Vaccine 25, 15341543.CrossRefGoogle ScholarPubMed
Carrillo, E., Crusat, M., Nieto, J., Chicharro, C., Thomas Mdel, C., Martínez, E., Valladares, B., Cañavate, C., Requena, J. M., López, M. C., Alvar, J. and Moreno, J. (2008). Immunogenicity of HSP-70, KMP-11 and PFR-2 leishmanial antigens in the experimental model of canine visceral leishmaniasis. Vaccine 26, 19021911.Google Scholar
Carrillo, E. and Moreno, J. (2008). Cytokine profiles in canine visceral leishmaniasis. Veterinary Immunology and Immunopathology Oct 17 [Epub ahead of print].Google Scholar
Corrêa, A. P., Dossi, A. C., de Oliveira Vasconcelos, R., Munari, D. P. and de Lima, V. M. (2007). Evaluation of transformation growth factor beta1, interleukin-10, and interferon-gamma in male symptomatic and asymptomatic dogs naturally infected by Leishmania (Leishmania) chagasi. Veterinary Parasitology 143, 267274.CrossRefGoogle ScholarPubMed
Chamizo, C., Moreno, J. and Alvar, J. (2005). Semi-quantitative analysis of cytokine expression in asymptomatic canine leishmaniasis. Veterinary Immunology and Immunopathology 103, 6775.CrossRefGoogle ScholarPubMed
Chappuis, F., Sundar, S., Hailu, A., Ghalib, H., Rijal, S., Peeling, R. W., Alvar, J. and Boelaert, M. (2007). Visceral leishmaniasis: what are the needs for diagnosis, treatment and control? Nature Reviews Microbiology 5, 873882.Google Scholar
Dantas-Torres, F. (2007). The role of dogs as reservoirs of Leishmania parasites, with emphasis on Leishmania (Leishmania) infantum and Leishmania (Viannia) braziliensis. Veterinary Parasitology 149, 139146.Google Scholar
Dujardin, J. C., Campino, L., Cañavate, C., Dedet, J. P., Gradoni, L., Soteriadou, K., Mazeris, A., Ozbel, Y. and Boelaert, M. (2008). Spread of vector-borne diseases and neglect of Leishmaniasis, Europe. Emerging Infectious Diseases 14, 10131018.Google Scholar
Gröne, A., Weckmann, M. T., Capen, C. C. and Rosol, T. J. (1996). Canine glyceraldehyde-3-phosphate dehydrogenase complementary DNA: polymerase chain reaction amplification, cloning, partial sequence analysis, and use as loading control in ribonuclease protection assays. American Journal of Veterinary Research 57, 254257.CrossRefGoogle ScholarPubMed
Khalil, E. A., Ayed, N. B., Musa, A. M., Ibrahim, M. E., Mukhtar, M. M., Zijlstra, E. E., Elhassan, I. M., Smith, P. G., Kieny, P. M., Ghalib, H. W., Zicker, F., Modabber, F. and Elhassan, A. M. (2005). Dichotomy of protective cellular immune responses to human visceral leishmaniasis. Clinical & Experimental Immunology 140, 349353.CrossRefGoogle ScholarPubMed
Lage, R. S., Oliveira, G. C., Busek, S. U., Guerra, L. L., Giunchetti, R. C., Corrêa-Oliveira, R. and Reis, A. B. (2007). Analysis of the cytokine profile in spleen cells from dogs naturally infected by Leishmania chagasi. Veterinary Immunology and Immunopathology 115, 135145.Google Scholar
Lemesre, J. L., Holzmuller, P., Gonçalves, R. B., Bourdoiseau, G., Hugnet, C., Cavaleyra, M. and Papierok, G. (2007). Long-lasting protection against canine visceral leishmaniasis using the LiESAp-MDP vaccine in endemic areas of France: double-blind randomised efficacy field trial. Vaccine 25, 42234234.Google Scholar
Louassini, M., Adroher, F. J., Foulquie, M. R. and Benitez, R. (1998). Investigations on the in vitro metacyclogenesis of a visceral and a cutaneous human strain of Leishmania infantum. Acta Tropica 70, 355368.CrossRefGoogle Scholar
Manna, L., Reale, S., Viola, E., Vitale, F., Manzillo, V. F., Michele, P. L., Caracappa, S. and Gravino, A. E. (2006). Leishmania DNA load and cytokine expression levels in asymptomatic naturally infected dogs. Veterinary Parasitology 142, 271280.Google Scholar
Mansueto, P., Vitale, G., Di Lorenzo, G., Rini, G. B., Mansueto, S. and Cillari, E. (2007). Immunopathology of leishmaniasis: an update. International Journal of Immunopathology and Pharmacology 20, 435445.Google Scholar
Maroli, M., Rossi, L., Baldelli, R., Capelli, G., Ferroglio, E., Genchi, C., Gramiccia, M., Mortarino, M., Pietrobelli, M. and Gradoni, L. (2008). The northward spread of leishmaniasis in Italy: evidence from retrospective and ongoing studies on the canine reservoir and phlebotomine vectors. Tropical Medicine & International Health 13, 256264.Google Scholar
Michalsky, E. M., Rocha, M. F., da Rocha Lima, A. C., França-Silva, J. C., Pires, M. Q., Oliveira, F. S., Pacheco, R. S., dos Santos, S. L., Barata, R. A., Romanha, A. J., Fortes-Dias, C. L. and Dias, E. S. (2007). Infectivity of seropositive dogs, showing different clinical forms of leishmaniasis, to Lutzomyia longipalpis phlebotomine sand flies. Veterinary Parasitology 147, 6776.Google Scholar
Miró, G., Cardoso, L., Pennisi, M. G., Oliva, G. and Baneth, G. (2008). Canine leishmaniosis – new concepts and insights on an expanding zoonosis: part two. Trends in Parasitology 24, 371377.Google Scholar
Nylén, S. and Sacks, D. (2007). Interleukin-10 and the pathogenesis of human visceral leishmaniasis. Trends in Immunology 28, 378384.Google Scholar
Oliva, G., Scalone, A., Foglia Manzillo, V., Gramiccia, M., Pagano, A., Di Muccio, T. and Gradoni, L. (2006). Incidence and time course of Leishmania infantum infections examined by parasitological, serologic, and nested-PCR techniques in a cohort of naive dogs exposed to three consecutive transmission seasons. Journal of Clinical Microbiology 44, 13181322.Google Scholar
Olivier, M. and Gregory, D. J. (2008). Interactions between Leishmania and the host macrophage. In Leishmania: after The Genome (ed. Myler, P. J. and Fasel, N.), pp. 239262. Caister Academic Press, Linton, UK.Google Scholar
Otranto, D., Paradies, P., de Caprariis, D., Stanneck, D., Testini, G., Grimm, F., Deplazes, P. and Capelli, G. (2009). Toward diagnosing Leishmania infantum infection in asymptomatic dogs in endemic area. Clinical and Vaccine Immunololgy 16, 337343.Google Scholar
Otranto, D., Paradies, P., Lia, R. P., Latrofa, M. S., Testini, G., Cantacessi, C., Mencke, N., Galli, G., Capelli, G. and Stanneck, D. (2007). Efficacy of a combination of 10% imidacloprid/50% permethrin for the prevention of leishmaniasis in kennelled dogs in an endemic area. Veterinary Parasitology 144, 270278.CrossRefGoogle Scholar
Palatnik-de-Sousa, C. B. (2008). Vaccines for leishmaniasis in the fore coming 25 years. Vaccine 26, 17091724.Google Scholar
Panaro, M. A., Acquafredda, A., Lisi, S., Lofrumento, D. D., Mitolo, V., Sisto, M., Fasanella, A., Trotta, T., Bertani, F., Consenti, B. and Brandonisio, O. (2001). Nitric oxide production by macrophages of dogs vaccinated with killed Leishmania infantum promastigotes. Comparative Immunology, Microbiology & Infectious Diseases 24, 187195.Google Scholar
Panaro, M. A., Brandonisio, O., de Caprariis, D., Cavallo, P., Cianciulli, A., Mitolo, V. and Otranto, D. (2008). Canine leishmaniasis in Southern Italy: a role for nitric oxide released from activated macrophages in asymptomatic infection? Parasites & Vectors 1, 10. doi:10.1186/1756-3305-1-10.Google Scholar
Paradies, P., Capelli, G., Cafarchia, C., de Caprariis, D., Sasanelli, M. and Otranto, D. (2006). Incidences of canine leishmaniasis in an endemic area of southern Italy. Journal of Veterinary Medicine. B, Infectious Diseases and Veterinary Public Health 53, 295298.CrossRefGoogle Scholar
Pfaff, A. W., Abou-Bacar, A., Letscher-Bru, V., Villard, O., Senegas, A., Mousli, M. and Candolfi, E. (2007). Cellular and molecular physiopathology of congenital toxoplasmosis: the dual role of IFN-gamma. Parasitology 134, 18951902.Google Scholar
Pinelli, E., Gonzalo, R. M., Boog, C. J., Rutten, V. P., Gebhard, D., del Real, G. and Ruitenberg, E. J. (1995). Leishmania infantum-specific T cell lines derived from asymptomatic dogs that lyse infected macrophages in a major histocompatibility complex-restricted manner. European Journal of Immunology 25, 15941600.Google Scholar
Pinelli, E., Killick-Kendrick, R., Wagenaar, J., Bernadina, W., del Real, G. and Ruitenberg, J. (1994). Cellular and humoral immune responses in dogs experimentally and naturally infected with Leishmania infantum. Infection and Immunity 62, 229235.CrossRefGoogle ScholarPubMed
Poot, J., Spreeuwenberg, K., Sanderson, S. J., Schijns, V. E., Mottram, J. C., Coombs, G. H. and Vermeulen, A. N. (2006). Vaccination with a preparation based on recombinant cysteine peptidases and canine IL-12 does not protect dogs from infection with Leishmania infantum. Vaccine 24, 24602468.CrossRefGoogle Scholar
Quinnell, R. J., Courtenay, O., Shaw, M. A., Day, M. J., Garcez, L. M., Dye, C. and Kaye, P. M. (2001). Tissue cytokine responses in canine visceral leishmaniasis. Journal of Infectious Diseases 183, 14211424.Google Scholar
Sanchez-Robert, E., Altet, L., Alberola, J., Rodriguez-Cortés, A., Ojeda, A., López-Fuertes, L., Timon, M., Sanchez, A. and Francino, O. (2008). Longitudinal analysis of cytokine gene expression and parasite load in PBMC in Leishmania infantum experimentally infected dogs. Veterinary Immunology and Immunopathology 125, 168175.Google Scholar
Santos-Gomes, G. M., Rosa, R., Leandro, C., Cortes, S., Romão, P. and Silveira, H. (2002). Cytokine expression during the outcome of canine experimental infection by Leishmania infantum. Veterinary Immunology and Immunopathology 88, 2130.CrossRefGoogle ScholarPubMed
Schmelzer, C., Lorenz, G., Rimbach, G. and Döring, F. (2009). In vitro effects of the reduced form of coenzyme Q(10) on secretion levels of TNF-alpha and chemokines in response to LPS in the human monocytic cell line THP-1. Journal of Clinical Biochemistry and Nutrition 44, 6266.Google Scholar
Schönian, G., Mauricio, I., Gramiccia, M., Cañavate, C., Boelaert, M. and Dujardin, J. C. (2008). Leishmaniases in the Mediterranean in the era of molecular epidemiology. Trends in Parasitology 24, 135142.Google Scholar
Strauss-Ayali, D., Baneth, G. and Jaffe, C. L. (2007). Splenic immune responses during canine visceral leishmaniasis. Veterinary Research 38, 547564.Google Scholar
Strauss-Ayali, D., Baneth, G., Shor, S., Okano, F. and Jaffe, C. L. (2005). Interleukin-12 augments a Th1-type immune response manifested as lymphocyte proliferation and interferon gamma production in Leishmania infantum-infected dogs. International Journal for Parasitology 35, 6373.Google Scholar
Tacchini-Cottier, F. and Launois, P. (2008). Host responses to infections with Leishmania. In Leishmania: after The Genome (ed. Myler, P. J. and Fasel, N.), pp. 263279. Caister Academic Press, Linton, UK.Google Scholar
Wilson, M. E., Jeronimo, S. M. B. and Pearson, R. D. (2005). Immunopathogenesis of infection with the visceralizing Leishmania species. Microbial Pathogenesis 38, 147160.Google Scholar
Zafra, R., Jaber, J. R., Pérez-Ecija, R. A., Barragán, A., Martínez-Moreno, A. and Pérez, J. (2008). High iNOS expression in macrophages in canine leishmaniasis is associated with low intracellular parasite burden. Veterinary Immunology and Immunopathology 123, 353359.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. IL-4 (Panel A), IL-10 (Panel B), TNF-α (Panel C), IFN-γ (Panel D) mRNA expression in PBMC from 13 asymptomatic (black columns) and 9 symptomatic (white columns) dogs in samples taken at first and second follow-up (i.e. 4 and 8 months after the diagnosis of canine leishmaniasis). Results of densitometric analysis of RT-PCR bands are expressed as arbitrary units (means±S.D.). CTL, controls; PHA, phytohaemagglutinin; LSA, Leishmania soluble antigen. See text for statistically significant differences.

Figure 1

Fig. 2. Gel electrophoretic analysis of RT-PCR products derived from PBMC total mRNA of asymptomatic (left) and symptomatic (right) dogs. Lanes 1 and 4: unstimulated PBMC; lanes 2 and 5: PHA stimulated PBMC; lanes 3 and 6: LSA stimulated PBMC. The figure is representative of 22 experiments carried out on 13 asymptomatic and 9 symptomatic dogs.