Skip to main content
PLOS ONE logoLink to PLOS ONE
. 2013 Jul 4;8(7):e67463. doi: 10.1371/journal.pone.0067463

Trypanosoma cruzi Infection in Neotropical Wild Carnivores (Mammalia: Carnivora): At the Top of the T. cruzi Transmission Chain

Fabiana Lopes Rocha 1,2,3, André Luiz Rodrigues Roque 1, Juliane Saab de Lima 4, Carolina Carvalho Cheida 5, Frederico Gemesio Lemos 3,6, Fernanda Cavalcanti de Azevedo 3, Ricardo Corassa Arrais 3,7, Daniele Bilac 1, Heitor Miraglia Herrera 8, Guilherme Mourão 9, Ana Maria Jansen 1,*
Editor: Érika Martins Braga10
PMCID: PMC3701642  PMID: 23861767

Abstract

Little is known on the role played by Neotropical wild carnivores in the Trypanosoma cruzi transmission cycles. We investigated T. cruzi infection in wild carnivores from three sites in Brazil through parasitological and serological tests. The seven carnivore species examined were infected by T. cruzi, but high parasitemias detectable by hemoculture were found only in two Procyonidae species. Genotyping by Mini-exon gene, PCR-RFLP (1f8/Akw21I) and kDNA genomic targets revealed that the raccoon (Procyon cancrivorus) harbored TcI and the coatis (Nasua nasua) harbored TcI, TcII, TcIII-IV and Trypanosoma rangeli, in single and mixed infections, besides four T. cruzi isolates that displayed odd band patterns in the Mini-exon assay. These findings corroborate the coati can be a bioaccumulator of T. cruzi Discrete Typing Units (DTU) and may act as a transmission hub, a connection point joining sylvatic transmission cycles within terrestrial and arboreal mammals and vectors. Also, the odd band patterns observed in coatis’ isolates reinforce that T. cruzi diversity might be much higher than currently acknowledged. Additionally, we assembled our data with T. cruzi infection on Neotropical carnivores’ literature records to provide a comprehensive analysis of the infection patterns among distinct carnivore species, especially considering their ecological traits and phylogeny. Altogether, fifteen Neotropical carnivore species were found naturally infected by T. cruzi. Species diet was associated with T. cruzi infection rates, supporting the hypothesis that predator-prey links are important mechanisms for T. cruzi maintenance and dispersion in the wild. Distinct T. cruzi infection patterns across carnivore species and study sites were notable. Musteloidea species consistently exhibit high parasitemias in different studies which indicate their high infectivity potential. Mesocarnivores that feed on both invertebrates and mammals, including the coati, a host that can be bioaccumulator of T. cruzi DTU’s, seem to take place at the top of the T. cruzi transmission chain.

Introduction

The hemoflagellate protozoan Trypanosoma cruzi is a multihost parasite that infects mammalian species from eight orders and dozens of triatomine species, the insect vectors [1], [2]. This parasite is the etiological agent of Chagas disease, one of the most important parasitic infections in Latin America [1], [3]. From the distinct T. cruzi infection routes, nowadays the oral route has increasing importance due to the high number of oral infection outbreaks in the last decades in Brazil and other Latin American countries [4], [5]. This current epidemiological scenario challenges health authorities because previously employed control measures are not effective against this scenario. Moreover, it emphasizes the importance of looking at the sylvatic cycle to understand all components of this complex system and the environmental factors that underlie the emergence of human cases. Indeed, despite having been recognized by Carlos Chagas as an enzootic parasite already when he described this taxon more than one century ago [6], there are still many open questions regarding the T. cruzi ecology and transmission in sylvatic environments.

Trypanosoma cruzi exhibits huge biological, biochemical and genetic diversity. Presently, six major genotypes or Discrete Typing Units (DTU) are acknowledged within the taxon, T. cruzi I (TcI) to T. cruzi VI (TcVI), besides the newly coined TcBat genotype, as yet described as restricted to bats [7][9]. Recent studies also reported intraspecific variability within these genotypes, such as TcI isolates [10]. These DTU’s are recognized to be valid units to discriminate T. cruzi genotypes, albeit putative associations with vectors and hosts, and the extent of their range are still poorly known. TcI is the most widespread DTU with respect to its geographical distribution [8]. TcII, classically associated to human cases in domestic cycles [8], is also more and more observed infecting sylvatic mammals in several biomes throughout South America [11], [12]. The knowledge concerning TcIII-TcVI is more recent and as new evidence accumulates, we can observe more clearly that the already proposed associations of genotypes with particular hosts, vectors or ecotopes are still under debate and possibly reflect subsampling [11][13].

Trypanosoma cruzi is maintained in complex transmission nets that occur in overlapping or independent transmission cycles in distinct sylvatic ecotopes [13][15]. Although T. cruzi is potentially able to infect all mammalian species [16], according to the particularities of host, parasite genotype and their interactions, some species might maintain longer and/or higher parasitemias than others, which will probably reflect different potentials of these hosts to infect vectors and, thus, to serve as reservoirs in a particular intervals of time and space [17]. In this sense, the potential to infect vectors is directly related to the presence of trypomastigotes in the bloodstream of a given mammalian species, thus available to be taken up by the vector during its blood meal. The mammal infection by oral route occurs when the animal ingests infected bug’s feces, food contaminated with the parasite or by preying on infected bugs or mammals [18]. This latter (predator-prey route) can occur through the ingestion of bloodstream trypomastigotes and also by the amastigotes present in the prey tissues as they are capable of infecting host cells [19][21]. Another important feature to be accounted is the ecology of each mammalian host species, which might enhance (or not) contact among mammals and vectors that ultimately shape T. cruzi transmission dynamics.

Species from the mammalian order Carnivora display a remarkable ecological diversity, having occupied virtually every habitat, vegetational zone and ecological niche. Regardless of their special adaptations for predation, they are widely diverse in their feeding ecology (frugivorous, insectivorous and hypercarnivorous – up to 70% of meat) and likewise in traits such as body size, home range, sociality and activity [22]. Carnivorans were reported to be naturally infected by T. cruzi [23] and, considering the efficiency of the T. cruzi oral infection route [24], may occupy a unique position as bioaccumulators of parasites and, perhaps, distinct T. cruzi DTU’s. Nevertheless, little is known of their role in T. cruzi transmission cycles, probably because carnivores are difficult to study as they require specialized management and costly long-term studies. The investigation of T. cruzi infection in wild carnivores is essential because this mammalian order exhibits a combination of biological traits that expose themselves to several opportunities of infection by T. cruzi in nature: eclectic feeding behavior, long-lived, broad range areas, disperse long distance and the ability to explore both arboreal and terrestrial strata in different habitats. Free-ranging carnivorans, recognized to play a crucial role in regulating ecosystems [25], might also have an important effect in multi-host parasitic transmission webs, like that of T. cruzi, as they prey on species from several taxa.

The aim of this study was to determine the role of Neotropical wild carnivores in the T. cruzi transmission cycle. Here, we investigated T. cruzi infection in the carnivore community of three different sites in Brazil and evaluated the infection patterns in the light of the species ecological traits. We additionally appraised the T. cruzi infection records in South America carnivore species to provide a comprehensive analysis of their infection patterns and the possible correlations among distinct carnivore groups (especially considering their habitat, diet and phylogeny). The hypothesis that carnivores are bioaccumulators of T. cruzi parasites belonging to distinct DTU’s is also discussed.

Materials and Methods

Ethics Statement

This study was approved by the ethics committee of Oswaldo Cruz Foundation/FIOCRUZ (CEUA P-292-06). The capture and sample collection of wild carnivores had permission from the Instituto Chico Mendes de Conservação da Biodiversidade (ICMBio) (SISBIO license number 25078-2 for Pantanal, number 11124-2 for PNSC and number 14576-2 for Araguari/Cumari), in accordance to Brazilian regulations. All animal handling procedures followed the Guidelines of the American Society of Mammalogists [26]. Appropriate biosecurity techniques and individual protection equipment were used during all procedures of collection and handling of the biological samples.

Study Areas

Field studies were carried out in three sites in tropical areas of Brazil (Fig. 1). The first site is a research station in the central region of the Pantanal, named Nhecolândia, in the Municipality of Corumbá, Mato Grosso do Sul State (18° 58.50′S 56° 37.40′ W). The Pantanal is a large Neotropical wetland recognized for its abundant and diverse wildlife. The research station is covered by a mosaic of forest patches, savannas, scrub savannas, seasonally flooded grasslands and several permanent or temporary lakes. This area is subjected to annual and multi-annual variations of flooding intensity, with an alternation of high-flood and severe drought years [27]. The second site is the Serra da Canastra National Park – SCNP (20° 15.32′S, 46° 27.75′ W) and surroundings, a conservation unit in the southwest of the Minas Gerais State. The area is a 200,000 hectare remnant of the Cerrado biome, covered with grasslands, interspersed with areas of rocky outcrops, scrub savanna and riparian vegetation. The climate is tropical, the dry season occurs from March to October and the wet season from November to February [28]. The third site comprise extensions within the Municipalities of Araguari, Minas Gerais State (18° 37.81′ S, 48° 10.54′ W) and Cumari, Goiás State (18° 22.02′ S, 48° 5.48′ W). Most of this area is occupied by cattle farms covered with exotic pasture vegetation (Brachiaria sp.), although there are still small patches of original Cerrado vegetation. The climate has two well-defined seasons, the wet season from September to March, and the dry season, from April to August [29]. The latter two areas are within the Cerrado biome, which is a vast area of tropical savanna, encompassing about 204 million hectares in the central part of the Brazilian territory [30].

Figure 1. Spatial distribution of free-ranging carnivore species examined for Trypanosoma cruzi infection in Brazil.

Figure 1

(A) Pantanal - Mato Grosso do Sul State (MS), (B) Serra da Canastra National Park (SCNP) and its surroundings - Minas Gerais State (MG), (C1) Araguari – Minas Gerais State (MG) and (C2) Cumari – Goiás State (GO). Geometric symbols represent carnivore species, according to the figure legend. In the upper left figure the black contour shows the study sites within respective States in Brazil.

Carnivore Capture and Sample Collection

Wild carnivores were captured: (i) from August 2009 to February 2012 in the Pantanal, except for the ring-tailed coatis, which capture ended in April 2010; (ii) from April 2004 to August 2008 in the SCNP region; and (iii) from April 2008 to July 2011 in the Araguari/Cumari region. For most carnivore species, we used box traps made with galvanized wire mesh baited with a mixture of bacon, eggs, sardine, fruits, boiled chicken and live chicken according to the target species and study sites. Specifically, pumas (Puma concolor) were captured with foot-snares not baited and set along trails previously monitored through camera-traps, while crab-eating raccoons (Procyon cancrivorus) were actively searched during night periods and captured using a handheld fishing net. We immobilized the animals with an intramuscular injection of a combination of zolazepan and tiletamine (Zoletil®) at dosages of 3–20 mg/kg according to the target species. Anesthetized animals were marked with ear-tags, PIT-tags (passive-integrated-transponder) and/or VHF or GPS radio collars for individual identification. We took blood samples by puncture of the cephalic vein stored in Vacutainer® tubes with EDTA for hemoculture (only in the Pantanal) and serological tests. Animals were released at the site of capture after total recovery from anesthesia. Total capture effort was 2,430 traps-nights in Pantanal, 4,153 traps-nights in SCNP and 1,340 traps-nights in Araguari/Cumari region.

Trypanosoma cruzi Survey

We examined a total of 208 free-ranging carnivores belonging to seven species. The T. cruzi infection survey was performed by serological assay and, in the case of the Pantanal, also by hemoculture (HC). This latter was performed as follows: 0.6 ml of blood from each animal was cultured in two tubes (0.3 ml each) containing Novy-Mc Neal-Nicole (NNN) medium with liver infusion tryptose (LIT) overlay. Tubes were examined every fifteen days up to five months. When positive, parasites were grown in LIT, cryopreserved and deposited in the Trypanosomatid collection from wild and domestic animals and vectors - COLTRYP (Oswaldo Cruz Foundation, Rio de Janeiro-RJ, Brazil).

For the detection of anti-T. cruzi IgG antibodies in sera, we performed the Indirect Immunofluorescent Antibody Test (IFAT) as described by Camargo [31]. The antigens were prepared using the reference strains F90 (TcI) and Y (TcII) from axenic culture and mixed in equal proportions. Wild canids and felids were tested using domestic dog and cat fluorescein conjugates (SIGMA®), respectively, whereas Procyonidae species were tested by IFAT using a goat anti-raccoon IgG fluorescein conjugate (KPL®). We adopted an IFAT cut-off value of 1/40 for all species, due to the possibility of cross-reaction with other trypanosomatid parasites. Each reaction included two positive and two negative control sera.

In order to detect possible dual infection or cross-reaction with Leishmania spp. sera were also tested by IFAT test using L. infantum (IOC/L579– MHOM/BR/1974/PP75) and L. braziliensis (IOC/L566– MHOM/BR/1975/M2903) promastigotes obtained from the Collection of Leishmania from Oswaldo Cruz Institute (CLIOC) mixed in equal proportion as antigens (cut-off: 1∶40). Wild canids were additionally tested for Leishmania infection using the Rapid Test for Diagnosis of Canine Visceral Leishmaniasis (TR DPP®, BioManguinhos, Rio de Janeiro, Brazil) and the Enzyme-Linked Immunoabsorbent Assay (ELISA, Biomanguinhos, Rio de Janeiro-RJ, Brazil). Cut-off value for ELISA was optical absorbance ≥0.200 mean ±3 SD. If positive for Leishmania infection in IFAT, DPP or ELISA, samples were considered positive to T. cruzi only when the IFAT titer for T. cruzi was 1/80 or higher.

For the seroprevalence calculation, each individual was counted once (positive/total number of sampled individuals). For the hemoculture prevalence, we incorporated all samples, including recaptured individuals.

Seropositive animals that had negative results in the parasitological test were considered to be infected with T. cruzi but with low parasitemia, thus probably less prone to be infective to the vectors. Parasitological tests, such as hemoculture, xenodiagnosis or fresh blood examination, are less sensitive and when positive reflect high parasite burden. Thus, positive hemocultures demonstrate their transmissibility potential, i.e., the potential of these hosts to infect vectors.

Trypanosoma cruzi Molecular Characterization

Epimastigote forms collected from positive hemocultures at the end of the log phase were washed, and incubated with proteinase K and SDS (sodium dodecyl sulfate). The genomic DNA of the lysed cells was extracted with standard phenol-chloroform protocols [32]. Characterization was carried out by multiplex PCR amplification of the non-transcribed spacer of the mini-exon gene (MMPCR) [33]. DTU's were identified according to amplicon size: 150 bp (TcIII/TcIV), 200 bp (TcI) and 250 bp (TcII/TcV/TcVI), besides T. rangeli – TR (100 bp) [34]. When MMPCR resulted in TcII/TcV/TcVI band pattern we performed a PCR amplification of the nuclear 1f8 gene followed by restriction fragment length polymorphism (RFLP) analysis of fragments digested by Alw21I enzyme [35] to discriminate TcII from hybrids (TcV and TcVI). We additionally performed kDNA PCR amplification [32], which distinguishes T. rangeli (a specific 760 bp band besides variable fragments of 300–450 bp) from T. cruzi (only one 330 bp band) in order to confirm T. cruzi in isolates that could not be characterized with the previous genomic targets. Each reaction included sterile distilled water instead of DNA as a negative control and positive control samples from T. cruzi strains representing the DTUs. PCR products were visualized under ultraviolet light after electrophoresis in 2% agarose gel with ethidium bromide staining.

Statistical Analysis

We used chi-square tests (α = 0.05) to investigate significant differences between seroprevalence rates for the different species and host sex in each study area.

In order to determine if T. cruzi infection rates in wild carnivores was associated with species diet, we retrieved data on the diet of the different species from the literature, taking into account the study site. The only exception was for the crab-eating raccoon, as there are no studies on its diet performed in the Pantanal. We first made scatter diagrams of the proportion of invertebrates in the species diet and the T. cruzi exposure rates to visualize the mathematical function that best represented the relationship between these variables. From the graphic analysis we estimated the linear regression model. Species with n <10 specimens per study site were excluded from this analysis. The T. cruzi exposure rates, hosts and diet assigned for each species, besides the references used are shown in supporting information (Table S1).

To test if infectiveness rates (the potential of the host to infect vectors as demonstrated by positive hemoculture, xenodiagnosis or fresh blood examination) between different taxa were phylogenetically autocorrelated we used the phylogenetic topology of Agnarsson et al. [36] to compute proximity matrices. For this, we calculated the infection rate (%) for each species as the total positive/total examined * 100. A complete list of data sets and source references is shown in supporting information (Table S2). We used Moran's autocorrelation index [37], Abouheif's test [38] with Abouheif's original matrix proximity calculus, Thioulouse et al. [39] implementation and patristic distances. Statistical significance of tests was done using 1,000 MonteCarlo permutations. We also tested for the phylogenetic effect of infectivity using ANOVA on phylogenetic eigenvector decomposition of the phylogenetic tree [40]. All computations were done under R 2.13 software and used packages ade4 [41], adephylo [42], ape3.0–5 and phylobase [43].

Results

Pantanal

The four examined carnivore species, the ocelot (Leopardus pardalis), the crab-eating fox (Cerdocyon thous), the ring-tailed coati (Nasua nasua) and the crab-eating raccoon (Procyon cancrivorus), were infected by T. cruzi as demonstrated by the high rates of positive IFAT tests, but high parasitemias, expressed by positive hemocultures, were found only in the two Procyonidae species (Table 1).

Table 1. Trypanosoma cruzi infection assessment of wild carnivores from three study sites in Brazil and ecological data.

Species (common name) SexF/M T. cruzi infection Ecological data
Serology(IFAT) Hemoculture Diet PM(%) PI(%) Activity Strata Habitattype Ecological datareferencesc
P/T (%)a F/Mb P/Ta (%) F/Mb
STUDY SITE: PANTANAL
Cerdocyon thous (crab-eating fox) 14/16 19/30 (63) 9/10 0/30 (0) C/F/I 32.8 33.4 C_N T Scrub/Savanna [52]
Leopardus pardalis (Ocelot) 2/0 2/2 (100) 2/0 0/2 (0) C 93.5 6.7 N T Forest [52]
Nasua nasua (ring-tailed coati) 26/40 21/44 (48) 10/11 19/66 (29) 6/13 C/F/I 14.3 46.6 D T/S Scrub/Forest [52]
Procyon cancrivorus (crab-eating raccoon) 6/7 9/12 (75) 4/5 2/13 (15) 1/1 C/F/I 3.8 41.7 N_C T Grassland/Forest [65]
STUDY SITE: SERRA DA CANASTRA NATIONAL PARK
Chrysocyon brachyurus (maned wolf) 24/19 11/43 (26) 7/4 C/F 24.4 4.3 C_N T Grassland [66], [67]
STUDY SITE: ARAGUARI/CUMARI
Cerdocyon thous 13/14 9/27 (33) 5/4 C/F/I 17.5 25.9 C_N T Scrub/Savanna [67], [28]
Chrysocyon brachyurus 2/2 0/4 (0) 0/0 C/F 24.4 4.3 C_N T Grassland [66], [67]
Lycalopex vetulus (hoary fox) 10/11 15/21 (71) 8/7 C/F/I 5.5 70.4 N T Grassland [67], [28]
Puma concolor (puma) 0/2 2/2 (100) 0/2 C 80 N T Scrub/Savanna [68], [69]

Footnotes:

IFAT - Indirect Immunofluorescent Antibody Test.

a

Positive/Total number of examined (% positive).

b

Positive female/male.

Species diet (C - carnivorous; F-frugivorous; I-insectivorous; PM proportion of mammals; PI proportion of invertebrates).

Activity (C crepuscular, N nocturnal, D diurnal), strata occurrence (T, terrestrial; S scansorial).

c

The ecological data was retrieved from the literature.

The two ocelots examined tested positive in the IFAT (titers 1∶80 and 1∶160) and the other three carnivore species were similarly exposed to T. cruzi infection (range 48–75%), as no significant differences was found in the seroprevalence rates among them (χ2 = 3.62, df = 2, p<0.16). The crab-eating fox seroprevalence was 63% and titers did not exceed 1∶80. The seroconversion observed among 7 out of 8 recaptured individuals, pointed to the existence of an active T. cruzi transmission cycle. For the two Procyonidae species, the seroprevalence were 48% and 75%, for the ring-tailed coati and crab-eating raccoon, respectively, with titers reaching up to 1∶320. Gender difference in seroprevalence was observed only in the ring-tailed coati, being higher in females (77%) than males (35%) (χ2 = 6.3; df = 1, p<0.01).

The prevalence of positive HC was nearly two times higher for ring-tailed coatis (29%) than for crab-eating raccoons (15%). Moreover, one ring-tailed coati was HC positive in the first capture and also in the second capture 14 months later.

We obtained 20 Trypanosoma sp. isolates morphologically similar to T. cruzi and T. rangeli through hemoculture, of these, three (two from ring-tailed coatis and one from crab-eating raccoon) could not be characterized due to contamination during field procedures. Genotyping from the 16 ring-tailed coati isolates revealed that twelve of them were TcI in single infections (n = 6, 37.5%) and mixed infections: TcI and TcII/TcV/TcVI (n = 2, 12.5%), TcI and TcIII/IV (n = 1, 6.3%) or TcI and Trypanosoma rangeli (n = 3, 18.8%). The single characterized isolate from the crab-eating raccoon was genotyped as TcI.

We were unable to define the T. cruzi genotype in four ring-tailed coati’s isolates (numbers 7, 9, 14, 15– Fig. 2). The MMPCR characterization on these isolates resulted on multiple bands pattern across repeated experiments, including an odd band about 320bp (isolates 7, 9 and 14). The 1f8/Alw21I assay confirmed only DTU TcI. The kDNA assay confirmed the four isolates were T. cruzi.

Figure 2. Trypanosoma cruzi genotyping of wild carnivore isolates from the Pantanal wetland, Brazil.

Figure 2

Representative agarose electrophoresis gels stained with ethidium bromide of the (A and B) Mini-exon multiplex PCR products, (C) 1f8 gene/Alw21I PCR-RFLP products and (D) kDNA PCR products. Lanes: M. Molecular weight markers (100bp DNA ladder), 1- Procyon cancrivorous isolate; 2–17– Nasua nasua isolates. Control samples: TcI, TcII, TcIII/TcIV, TcV/TcVI, TR - T. rangeli, TC – T. cruzi and C- Negative control.

Serra Da Canastra National Park (SCNP)

An active T. cruzi transmission cycle among carnivores was also observed in the maned wolf (Chrysocyon brachyurus) population from the SCNP region. Seroprevalence was 26% and among non-infected recaptured individuals (n = 10), 4 seroconverted after one-year follow-up and other 2 seroconverted after two years. In all cases, titers did not exceed 1∶80. No significant differences was found between genders (χ2 = 0.36; df = 1, p<0.54).

Araguari/Cumari

In this region none of the maned wolves (n = 4) displayed positive serological tests and we found a significative difference in the T. cruzi infection rates among the other three examined species (χ2 = 8.79, df = 2, p<0.01) (Table 1).

The two puma specimens tested positive in the IFAT (titers - 1∶40 and 1∶160). In the two canid species, the hoary fox’s (Lycalopex vetulus) seroprevalence rate (71%) was two times higher than that of the crab-eating fox’s (33%). Titers for both species reached up to 1∶320. Neither species had differences in seroprevalence amid gender (hoary fox: χ2 = 0.68; df = 1, p = 0.40; crab-eating fox: χ2 = 0.29; df = 1, p = 0.58).

Trypanosoma cruzi Infection Rates in Relation to Species Diet

T. cruzi infection rates in wild carnivores significantly increased with the proportion of invertebrates in the species diet (r2 = 0.623; df = 9; p<0.004; Fig. 3). In addition, the four felids examined, which include a high proportion of mammals in their diet, were all infected (Table 1).

Figure 3. Trypanosoma cruzi infection in Neotropical wild carnivores and the proportion of invertebrates in species’ diet.

Figure 3

Infection rate (total examined/total positive*100) was determined by IFAT - Indirect Immunofluorescent Antibody Test. Studies sites were Pantanal – Mato Grosso do Sul State, Araguari - Minas Gerais State/Cumari – Goiás State and Serra da Canastra National Park (SCNP) – Minas Gerais State, Brazil. The data set included samples collected on this study (filled symbols) and from the same studies sites previously published by our group. Species’ diets were retrieved from the literature (Table S1). The fitted linear regression (F(1,9): 14.9; r2 = 0.62, p = 0.004) is represented by the solid line (y = 0.73x+24). Dashed lines indicate the confidence intervals at 95%.

Neotropical Wild Carnivores as Trypanosoma cruzi Host

Data on Neotropical wild carnivore T. cruzi hosts combining our results and literature records were assembled in Table 2. Fifteen Neotropical carnivore species belonging to five families were described to be infected by T. cruzi by serological and/or parasitological methods in Argentine, Brazil, Chile and Colombia.

Table 2. Neotropical wild carnivores naturally infected by Trypanosoma cruzi from this study (in bold) and literature records.

Speciesa Serological Parasitological Lineage State/Country [references]
P/T (%)b P/T (%)b (DTU)c
FAMILY CANIDAE
Cerdocyon thous 9/27 (33) Goiás-Minas Gerais/BR
Cerdocyon thous 18/30 (60) 0/30 (0) Mato Grosso do Sul/BR
Cerdocyon thous 16/42 (38) 0/42 (0) Mato Grosso do Sul/BR [14]
Cerdocyon thous 4/8 (50) 0/3 (0) Minas Gerais/BR [15]
Cerdocyon thous 1/5 (20) São Paulo/BR [70]
Chrysocyon brachyurus 11/43 (26) Minas Gerais/BR
Chrysocyon brachyurus 8/39 (21) 0/30 (0) Minas Gerais/BR [15]
Lycalopex culpaeus 4/77 (5) CL [71]
Lycalopex culpaeus 1/15 (7) Freirina/CL [72]
Lycalopex culpaeus 1/2 (50) Jujuy/AR [73]
Lycalopex griseus 2/29 (7) Freirina/CL [72]
Lycalopex gymnocercus 1/1 Salta/AR [73]
Lycalopex vetulus 15/21 (71) Goiás-Minas Gerais/BR
Lycalopex vetulus 1/1 São Paulo/BR [59]
FAMILY FELIDAE
Leopardus pardalis 2/2 (100) 0/2 (0) Mato Grosso do Sul/BR
Leopardus pardalis 3/10 (30) 0/3 (0) Mato Grosso do Sul/BR [14]
Leopardus pardalis 1/1 1/1 TcI Minas Gerais/BR [15]
Puma concolor 2/2 (100) Goiás-Minas Gerais/BR
FAMILY MEPHITIDAE
Conepatus chinga 1/15 (6.6) TcIIIc1 Santiago del Estero/AR [74]
Conepatus chinga 1/91 (1.1) TcIIIc1 Santiago del Estero/AR [75]
Conepatus chinga 2/36 (5.5) Santiago del Estero/AR [76]
Conepatus chinga 2/49 (4.1) Santiago del Estero/AR [77]
FAMILY MUSTELIDAE
Eira barbara 1/5 (20) São Paulo/BR [78]
Eira barbara 1/2 (50) Mato Grosso/BR [79]
Eira barbara 2/4 (50) Pará/BR [80]
Eira barbara 1/4 (25) Pará/BR [81]
Eira barbara 1/1 Jujuy/AR [73]
Galictis cuja 1/1 Santiago del Estero/AR [76]
Galictis cuja 2/14 (14) São Paulo/BR [82]
Galictis vittata 1/1 São Paulo/BR [83]
Galictis vittata 1/1 TcII/TcV/TcVIc2and TcIII/IVc3 Rio de Janeiro/BR [84]
FAMILY PROCYONIDAE
Nasua nasua 21/44 (48) 19/66 (29) TcI, TcII, TcIII/TcIV Mato Grosso do Sul/BR
Nasua nasua 75/140 (54) 53/140 (38) TcI and TcII/TcV/TcVIc2 Mato Grosso do Sul/BR [45]
Nasua nasua 101/158 (64) 33/158 (21) TcI and TcII/TcV/TcVIc2and TcIII/TcIVc3 Mato Grosso do Sul/BR [44]
Nasua nasua 7/18 (39) TcIII/TcIVc3 Pará/BR [85] [86]
Nasua nasua 1/5 (20) São Paulo/BR [87]
Potus flavus 1/2 (50) TcI Bajo Colima/CO [34], [88]
Procyon cancrivorus 9/12 (75) 2/13 (15) TcI Mato Grosso do Sul/BR
Procyon cancrivorus 1/4 (25) São Paulo/BR [89]

Footnotes:

(−) Not available.

Serological test: IFAT - Indirect Immunofluorescent Antibody Test.

Parasitological tests: Hemoculture, xenodiagnosis or fresh blood examination.

a

We adopted Wilson & Reeder [90] for taxonomic reference; thus, host species names reported in this table not always correspond to the original paper.

b

Positive/Total number of examined (% positive).

Countries: AR – Argentine, BR – Brazil, CL – Chile, CO – Colombia.

c

Current nomenclatural consensus as Discrete Typing Units (DTU) following Zingales et al. [7]. Original classification and equivalence to currently grouping scheme. c1TCIIc = TcIII; c2 TcII (Mini-exon gene) = TcII/TcV/TcVI, c3 Z3 = TcIII/TcIV.

Distinct T. cruzi infection patterns among carnivore species were notable. Procyonids demonstrated to have a high potential to infect vectors, in particular the ring-tailed coati, given the persistently high parasitological prevalence rates (Table 2). Also, this species was recorded harboring the main T. cruzi lineages in single and mixed infection, corroborating its bioaccumulator potential. In spite of the few data available, mustelids might also display high potential to infect vectors and one species was recorded harboring mixed infections. Regarding the Mephitidae family, one single species, the skunk (Conepatus chinga) was found infected: parasitological tests consistently tested positive and this species harbored TcIII in single infections in Argentina. In canid species, high parasitemias were observed only in a few individuals of the Lycalopex genus and one crab-eating fox. The T. cruzi infection in felids is poorly reported: one ocelot was reported to have high parasitemia and the serological detection of T. cruzi infection in pumas suggests that they may also be involved in the T. cruzi network (Table 2).

The aforementioned differences in infection pattern among carnivore species were not phylogenetically autocorrelated, as none of the tests revealed a significant influence of carnivore phylogeny on T. cruzi infection detected by hemoculture/xenodiagnosis assays. For Moran's test I = 0.059, and the expected null value was −0.055 (p = 0.198). Abouheif's test with different proximity matrices were also not significant even though patristic distance retrieved marginally significant results (p = 0.077 – original; p = 0.099 – Thioulouse, p = 0.044 - patristic). The global ANOVA of infectiveness on phylogenetic structure was not significant (p = 0.277). However, tests on each of the 7 eigenvector showed that the first phylogenetic eigenvector, which contrasts the superfamily Musteloidea vs. families Canidae and Felidae was significant (p = 0.02689, Fig. S1). This indicates a difference in infectiveness rates between these groups (Fig. 4).

Figure 4. Trypanosoma cruzi infectiveness rates in Neotropical carnivore species at the tips of their phylogeny.

Figure 4

The size of circles denotes the infectiveness rates, which were determined as the total positive/total examined*100 in hemoculture or xenodiagnosis tests. Phylogenetic topology of Agnarsson et al. [36].

Discussion

Fourteen Neotropical carnivore species belonging to five families were already described to be infected by T. cruzi in Argentine, Brazil, Chile and Colombia. The fifteenth one, the puma was found infected in the present study. Distinct T. cruzi infection patterns across carnivore species and study sites were notable, as also observed among the seven species herein studied in three different areas of Brazil. Particularly interesting is the finding that carnivore species, mainly procyonids and mustelids, often exhibited high parasitemias and were able to harbor the main T. cruzi genotypes, both in single and mixed infections. We also evidenced that species diet could influence the T. cruzi infection rates.

In the Pantanal the T. cruzi cycle included all examined carnivore species, as previously reported in the same study site [14]. Notwithstanding, based on the positive hemoculture only the ring-tailed coatis and the crab-eating raccoons demonstrated a potential to infect vectors. This is in accordance with previous studies that report the role played by the ring-tailed coati as the main reservoir of T. cruzi in the Pantanal due to its high prevalence of infection, long-lasting parasitemia and infection with the main T. cruzi lineages [14], [44], [45]. Moreover, the coati has numerous paths for contact with T. cruzi, as it occupies both arboreal and terrestrial strata in several habitat types and can prey on infected insects and mammals [46]. Another coati’s ecological characteristic that facilitates infection by T. cruzi is its behavior of construction of arboreal nests for resting and reproduction, as we have found several of these nests infested with triatomine bugs in our recent field observations (J. Saab, unpublished data). Along with its potential to infect vectors and the capacity to maintain multiples lineages of the parasite [44], [45], this species may be considered a network hub, a common connection point joining transmission cycles maintained within terrestrial and arboreal mammals and vectors.

We observed a temporal change in the ratio of infection by the different T. cruzi lineages in the coati population of the Pantanal in comparison to former reports. Previously, single TcI and TcII/TcV/TcVI infections were reported to occur in similar ratios, whereas TcIII/TcIV (formerly Z3) and Trypanosoma rangeli (TR) occurred in minor proportion [44]. Herein, TcI has prevailed over TcII/TcV/TcVI whereas TcIII/TcIV, which was not reported in the past few years [45], was isolated again from the coati population. We also observed a gradual increase in the prevalence of T. rangeli (3%–[44]; 7%–[45]; 20% this study). It is well-known that the striking variation of the flooding intensity in the Pantanal, as well as other environmental changes, has a strong effect on the local community structure, modulating vectors, hosts and consequently their parasites density, distribution and interrelationships [27], [47]. In the same manner changes in the hosts’ environment are expected to impact the parasite subpopulation (in this case, T. cruzi DTU’s), but the outcome of this impact might be different according to each subpopulation dynamics. For instance, TcI infects a huge variety of mammal host species and its infection is described as resulting in high and long lasting parasitemias [8], [17], [48]. This is not the case of TcII and probably may also not be the case of TcIII/TcIV (formerly Z3), which infection results in short period parasitemias and are described to occur in more restricted transmission cycles [8], [17]. Therefore the distribution of TcI in a given environment is expected to be less impacted by environmental changes than TcII and TcIII/TcIV (formerly Z3). Likewise with any other living being populations, T. cruzi subpopulations might also expand and retract according to the resources available. Moreover, competitive exclusion and interactions between tripanosomatid species and/or T. cruzi subpopulations certainly take a role in modulating the ratios of infection. In any case, this highlight how complex and dynamic the T. cruzi transmission cycles can be, even regarding a single species in a small snippet of time and space.

We were not able to define the T. cruzi genotype in four out of 16 ring-tailed coati isolates, as they displayed multiple bands, besides and additional odd band pattern of 320bp in the MMPCR assay. The other two molecular targets employed confirmed only TcI and excluded T. rangeli, showing that the band pattern observed was not related to multiple infections. In this sense, we are probably facing T. cruzi isolates with odd band patterns in the MMPCR assay, a method routinely used worldwide and recently validated for a rapid typing of T. cruzi DTU groups [34]. Indeed, unusual profiles within different molecular targets, including the mini-exon gene, had already been observed in T. cruzi wild mammal isolates [49]. Rather than methodological constraints, these observations may point out that any time we might deal with undiscovered/unusual lineages which the most employed markers are not capable of characterizing, especially while working with isolates derived from wild hosts. These findings reinforce that the diversity of T. cruzi might be much higher than currently acknowledged, as evidenced, for example, by the recent description of the Tcbat [50].

As already observed [45], the ring-tailed coati was the only carnivore species examined in this study to display gender differences in the infection rate. Coatis have an unique social system among carnivore species; males and females have marked differences in their ecology, as females live in groups while most adult males are solitary (except during the breeding season) [51]. The rate of infection by T. cruzi in a specific host is driven by contact processes among vector-parasite-host; thus we might expect that these ecological dissimilarities lead to different infection ratios. In the case of ring-tailed coatis, females were observed to have differential habitat use during reproductive period [52] and to spend more time in nests, whereas males’ coatis are not involved in parental care [53]. This may put females at greater risk for exposure to T. cruzi, as these nests are a suitable ecotope for triatomines (J. Saab, unpublished data), indicating that habitat use and not gender is the deciding factor here.

The crab-eating raccoon was another Procyonidae species implicated in the maintenance and dispersion of T. cruzi in the Pantanal region. Different from the congener common raccoon Procyon lotor, widely studied and the most commonly reported T. cruzi host in North America (along with Didelphis virginiana) [54], the crab-eating raccoon is poorly studied. This raccoon species is nocturnal, omnivorous and highly associated with water. Shelter sites in Pantanal were frequently registered in clusters of terrestrial bromeliad (Bromelia balansae) (C. Cheida, unpublished data), a recognized habitat for the vector species Triatoma sordida and Pastrongylus megistus, both known to occur in the Mato Grosso do Sul State [55]. The high parasitemias observed in this study corroborate that the crab-eating raccoon, just as the other procyonids, has a potential to infect triatomines.

The crab-eating foxes and the ocelots from the Pantanal, although highly exposed, did not display high parasitemias. Regarding the crab-eating foxes, our hypothesis is that the pattern of T. cruzi infection in this species, and probably in other wild canid species, is similar to that found in domestic dogs, which is characterized by a short period of patent parasitemia during the acute phase, followed by a chronic phase with low recovery of positive hemocultures, even in reinfections [56]. Also, in spite of its plasticity in diet and habitat preferences [29], this species has much less capacity to explore microhabitats suitable for triatomines than the coatis with its great ability with its paws and snout [57]. Besides, differently from coatis, the crab-eating fox are restricted to the terrestrial environment. On the other hand, the ocelot has the most carnivorous diet among these three species and can explore both terrestrial and arboreal strata. In such hypercarnivorous, T. cruzi infection might reflect the rates of infection among their prey [15]. Indeed, ocelots from the Pantanal tested negative in hemoculture and the small mammals from the same region were reported to display low HC prevalence [58].

A T. cruzi transmission cycle involving another carnivore species, the maned wolf, was also observed in the Serra da Canastra National Park region. Our results on T. cruzi infection in maned wolves verified by serology are in accordance with a previous study conducted by us [15] and both reported seroconversion. Together, this eight-year follow-up attested that T. cruzi is enzootic among maned wolves from SCNP, and also that transmission is well-established and active in the area.

In Araguari/Cumari region, the two tested puma were infected by T. cruzi, possible due to the top chain position of this species, besides the classical contaminative route. Indeed, to the best of our knowledge, this is the first such report from a top predator. Infection rates in the hoary fox was two times higher than the infection rates in the crab-eating fox, and the other canid species examined, the maned wolf, tested negative. The present study represents the first sizable data on the hoary fox since a single specimen was previously described infected in the early 70′s [59]. Amongst those three canids, the hoary fox seems to be the most likely to be exposed to triatomine bugs due to their ecological characteristics. It is the only Neotropical canid with a predominantly insectivore diet and also the only of those three canids to use armadillo burrows regularly [29], [60], a recognized ecotope for some vectors in this area, such as the Panstrongylus species [55], [61].

The oral transmission has been constantly suggested as the principal mechanism of parasite dispersion among free-ranging mammals and recently, even humans [5], [62]. This route may be of particular importance for carnivore species, since many of them feed on both insects and mammals [63], thus providing several opportunities for infection throughout its life. The classic contaminative route may also be present in some of these infections, but it is probably less prone to be the most effective because some of these carnivores are very active at night, do not use permanent dens, and the contaminated feces still would have to pass the usually dense fur of these carnivorans. Herein, we demonstrated that the higher the proportion of invertebrates in species diet, the greater T. cruzi infection rate. Interestingly, the T. cruzi exposure rate in the three canid species, the hoary fox, the crab-eating fox and the maned wolf, scales in the proportion of the amount of invertebrates in their diet. The transmission by the ingestion of infected triatomines is highly efficient and was already demonstrated in the carnivores striped skunk (Mephitis mephitis) [64] and raccoon (Procyon lotor) [21]. Our results suggest that carnivore species with insectivorous diet would have more probability of contact with triatomine bugs while foraging. For top-chain species, the infection through the ingestion of infected prey might also be an important infection route [19].

Our assemblage on T. cruzi infection among Neotropical carnivore species corroborated epidemiological evidence that they are involved in the T. cruzi transmission networks, though with variable potential to amplify and disperse parasite populations according to the species ecological characteristics and regional peculiarities. The long-term maintenance of the T. cruzi transmission cycles will rely on vector feeding upon mammals displaying patent parasitemias. Herein, we found that species belonging to the superfamily Musteloidea were more likely to display high parasitemias and thus to infect vectors. One common component within this group is that, despite the adaptations to predation of vertebrates as other carnivore species, many species are omnivores [22]. Mesocarnivores feed on both invertebrates and mammals and thus seems to take a place at the top of the T. cruzi transmission chain. In fact, the frequent findings of mixed infection, as demonstrated by the coati, corroborate the bioaccumulator potential expected for mammals at the top of the parasite chains.

Supporting Information

Figure S1

Trypanosoma cruzi infectiveness rates (%) of each species at the tips of the phylogeny and values on the phylogenetic eigenvector 1 (P.E.V. 1) from Agnarsson et al. (2010). Infectiveness rates were determined as the total positive/total examined*100 in hemoculture or xenodiagnosis tests. Values are scales and normalized around 0 to have a comparable scale.

(PDF)

Table S1

Trypanosoma cruzi infection rates in Brazil and species’ diet.

(PDF)

(PDF)

Table S2

Trypanosoma cruzi infectiveness rates (%) of Neotropical wild carnivores from this study and literature records. Infectiveness rate (INF) for each species based on parasitological tests (hemoculture, xenodiagnosis or fresh blood examination) was calculated by total positive/total examined*100.

(PDF)

Acknowledgments

We would like to express our gratitude to Dr. Pedro Cordeiro-Estrela for his help with phylogenetic analysis and to Dr. Vera Bongertz for revising the English version. We also grateful to Magyda Dahrough, Caio F. da Motta, Mozart C. de Freitas Júnior, Frederico A. de Sousa, Daniel Rocha and Hugo C. M. Costa for all efforts and assistance during field work. We would also like to thank Valdirene Lima for the consistently helpful comments in genotyping analysis. Marcos Lima, Carlos Ruiz, Kerla Monteiro, Juliana Barros and André Pereira provided essential support and guidance during laboratory work. We thank Embrapa Pantanal for logistical and institutional support. We are in debt with the Maned Wolf Conservation Project team for kindly contributing maned wolf’s samples, especially to Flávio Rodrigues, Jean Pierre Santos, Joares May-Júnior, Rogério de Paula, Ronaldo Morato and Pró-canívoros Institute.

Funding Statement

This study was funded by ChagasEpiNet 223034. Fundação de Apoio ao Desenvolvimento do Ensino, Ciência e Tecnologia do Estado de Mato Grosso do Sul (FUNDECT) - 9777.256.476.13022008. National Research Center for the Conservation of Natural Predators – CENAP/ICMBio. Wildlife Conservation Society – OWOH 2008_001. Consórcio Capim Branco de Energia. CNPq Edital Universal 014/2008. PDJ-CNPq 150608/2013-6. Smithsonian Institution. Neotropical Grassland Conservancy. Idea Wild. U.S. Fish and Wildlife Service. A doctoral grant was provided by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) to FLR and CCC. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

  • 1. WHO (2002) Control of Chagas disease. World Health Organ Tech Rep Ser 905: 1–109. [PubMed] [Google Scholar]
  • 2. Noireau F, Diosque P, Jansen AM (2009) Trypanosoma cruzi: adaptation to its vectors and its hosts. Vet Res 40: 26. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 3. Hotez PJ, Bottazzi ME, Franco-Paredes C, Ault SK, Periago MR (2008) The neglected tropical diseases of Latin America and the Caribbean: a review of disease burden and distribution and a roadmap for control and elimination. PLoS Negl Trop Dis 2: e300. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4. Toso MA, Vial UF, Galanti N (2011) Oral transmission of Chagas' disease. Rev Med Chil 139: 258–266. [PubMed] [Google Scholar]
  • 5. Shikanai-Yasuda MA, Carvalho NB (2012) Oral transmission of Chagas disease. Clin Infect Dis 54: 845–852. [DOI] [PubMed] [Google Scholar]
  • 6. Chagas C (1909) Nova tripanozomiaze humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzi n. gen., n. sp., ajente etiolojico de nova entidade morbida do homem. Mem Inst Oswaldo Cruz 1: 159–218. [Google Scholar]
  • 7. Zingales B, Andrade SG, Briones MR, Campbell DA, Chiari E, et al. (2009) A new consensus for Trypanosoma cruzi intraspecific nomenclature: second revision meeting recommends TcI to TcVI. Mem Inst Oswaldo Cruz 104: 1051–1054. [DOI] [PubMed] [Google Scholar]
  • 8. Zingales B, Miles MA, Campbell DA, Tibayrenc M, Macedo AM, et al. (2012) The revised Trypanosoma cruzi subspecific nomenclature: rationale, epidemiological relevance and research applications. Infect Genet Evol 12: 240–253. [DOI] [PubMed] [Google Scholar]
  • 9. Marcili A, Lima L, Cavazzana M, Junqueira AC, Veludo HH, et al. (2009) A new genotype of Trypanosoma cruzi associated with bats evidenced by phylogenetic analyses using SSU rDNA, cytochrome b and Histone H2B genes and genotyping based on ITS1 rDNA. Parasitology 136: 641–655. [DOI] [PubMed] [Google Scholar]
  • 10. Ramirez JD, Duque MC, Montilla M, Cucunuba ZM, Guhl F (2012) Multilocus PCR-RFLP profiling in Trypanosoma cruzi I highlights an intraspecific genetic variation pattern. Infect Genet Evol 12: 1743–1750. [DOI] [PubMed] [Google Scholar]
  • 11. Rozas M, Botto-Mahan C, Coronado X, Ortiz S, Cattan PE, et al. (2007) Coexistence of Trypanosoma cruzi genotypes in wild and periodomestic mammals in Chile. American Journal of Tropical Medicine and Hygiene 77: 647–653. [PubMed] [Google Scholar]
  • 12. Araujo CA, Waniek PJ, Xavier SC, Jansen AM (2011) Genotype variation of Trypanosoma cruzi isolates from different Brazilian biomes. Exp Parasitol 127: 308–312. [DOI] [PubMed] [Google Scholar]
  • 13.Perez E, Monje M, Chang B, Buitrago R, Parrado R, et al. (2012) Predominance of hybrid discrete typing units of Trypanosoma cruzi in domestic Triatoma infestans from the Bolivian Gran Chaco region. Infect Genet Evol. Doi: 10.1016/j.meegid.2012.09.014. [DOI] [PubMed]
  • 14. Herrera HM, Rocha FL, Lisboa CV, Rademaker V, Mourao GM, et al. (2011) Food web connections and the transmission cycles of Trypanosoma cruzi and Trypanosoma evansi (Kinetoplastida, Trypanosomatidae) in the Pantanal Region, Brazil. Trans R Soc Trop Med Hyg 105: 380–387. [DOI] [PubMed] [Google Scholar]
  • 15. Rocha FL, Roque AL, Arrais RC, Santos JP, Lima VD, et al. (2013) Trypanosoma cruzi TcI and TcII transmission among wild carnivores, small mammals and dogs in a conservation unit and surrounding areas, Brazil. Parasitology 140: 160–170. [DOI] [PubMed] [Google Scholar]
  • 16. Tibayrenc M (2010) Modelling the Transmission of Trypanosoma cruzi: The Need for an Integrated Genetic Epidemiological and Population Genomics Approach. Modelling Parasite Transmission and Control 673: 200–211. [DOI] [PubMed] [Google Scholar]
  • 17. Roellig DM, McMillan K, Ellis AE, Vandeberg JL, Champagne DE, et al. (2010) Experimental infection of two South American reservoirs with four distinct strains of Trypanosoma cruzi . Parasitology 137: 959–966. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18.Jansen AM, Roque ALR (2010) Domestic and wild mammalian reservoir. In: Telleria J, Tibayrenc M, editors. American trypanosomiasis Chagas Disease - one hundred years of research. London: Elsevier. 249–276.
  • 19. Thomas ME, Rasweiler Iv JJ, D'Alessandro A (2007) Experimental transmission of the parasitic flagellates Trypanosoma cruzi and Trypanosoma rangeli between triatomine bugs or mice and captive neotropical bats. Mem Inst Oswaldo Cruz 102: 559–565. [DOI] [PubMed] [Google Scholar]
  • 20. Mortara RA, Andreoli WK, Fernandes MC, da Silva CV, Fernandes AB, et al. (2008) Host cell actin remodeling in response to Trypanosoma cruzi: trypomastigote versus amastigote entry. Subcell Biochem 47: 101–109. [DOI] [PubMed] [Google Scholar]
  • 21. Roellig DM, Ellis AE, Yabsley MJ (2009) Oral transmission of Trypanosoma cruzi with opposing evidence for the theory of carnivory. J Parasitol 95: 360–364. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 22.Nowak RM (2005) Walkeŕs carnivores of the world. USA: The John Hopkins University Press. 313 p.
  • 23. Barretto MP, Ribeiro RD (1979) Reservatórios silvestres do Trypanosoma (Schizotrypanum) cruzi Chagas, 1909. Rev Ins Adolfo Lutz 39: 25–36. [Google Scholar]
  • 24. Yoshida N, Tyler KM, Llewellyn MS (2011) Invasion mechanisms among emerging food-borne protozoan parasites. Trends Parasitol 27: 459–466. [DOI] [PubMed] [Google Scholar]
  • 25. Letnic M, Ritchie EG, Dickman CR (2012) Top predators as biodiversity regulators: the dingo Canis lupus dingo as a case study. Biological Reviews 87: 390–413. [DOI] [PubMed] [Google Scholar]
  • 26. Sikes RS, Gannon WL (2011) Guidelines of the American Society of Mammalogists for the use of wild mammals in research. Journal of Mammalogy 92: 235–253. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 27. Alho CJR, Silva JSV (2012) Effects of Severe Floods and Droughts on Wildlife of the Pantanal Wetland (Brazil) - A Review. Animals 2: 591–610. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 28.IBAMA. Instituto Brasileiro do Meio Ambiente e Recursos Naturais Renováveis (2005) Plano de manejo do Parque Nacional da Serra da Canastra: 1–94.
  • 29.Lemos FG, Facure KG, Azevedo FC (2011) A first approach to the comparative ecology of the hoary fox and the crab-eating fox in a fragmented human altered landscape in the Cerrado Biome at Central Brazil. In: Rosalino LM, Gheler-Costa C, editors. Middle-sized carnivores in agricultural landscapes. New York: Nova Sciences Publishers. 143–160.
  • 30. Sano EE, Rosa R, Brito JLS, Ferreira LG (2010) Land cover mapping of the tropical savanna region in Brazil. Environmental Monitoring and Assessment 166: 113–124. [DOI] [PubMed] [Google Scholar]
  • 31. Camargo ME (1966) Fluorescent antibody test for the serodiagnosis of American trypanosomiasis. Technical modification employing preserved culture forms of Trypanosoma cruzi in a slide test. Rev Inst Med Trop Sao Paulo 8: 227–235. [PubMed] [Google Scholar]
  • 32. Vallejo GA, Guhl F, Chiari E, Macedo AM (1999) Species specific detection of Trypanosoma cruzi and Trypanosoma rangeli in vector and mammalian hosts by polymerase chain reaction amplification of kinetoplast minicircle DNA. Acta Trop 72: 203–212. [DOI] [PubMed] [Google Scholar]
  • 33. Fernandes O, Santos SS, Cupolillo E, Mendonca B, Derre R, et al. (2001) A mini-exon multiplex polymerase chain reaction to distinguish the major groups of Trypanosoma cruzi and T. rangeli in the Brazilian Amazon. Trans R Soc Trop Med Hyg 95: 97–99. [DOI] [PubMed] [Google Scholar]
  • 34. Aliaga C, Breniere SF, Barnabe C (2011) Further interest of miniexon multiplex PCR for a rapid typing of Trypanosoma cruzi DTU groups. Infect Genet Evol 11: 1155–1158. [DOI] [PubMed] [Google Scholar]
  • 35. Rozas M, De DS, Adaui V, Coronado X, Barnabe C, et al. (2007) Multilocus polymerase chain reaction restriction fragment–length polymorphism genotyping of Trypanosoma cruzi (Chagas disease): taxonomic and clinical applications. J Infect Dis 195: 1381–1388. [DOI] [PubMed] [Google Scholar]
  • 36. Agnarsson I, Kuntner M, May-Collado LJ (2010) Dogs, cats, and kin: a molecular species-level phylogeny of Carnivora. Mol Phylogenet Evol 54: 726–745. [DOI] [PubMed] [Google Scholar]
  • 37. Moran PAP (1948) The Interpretation of Statistical Maps. Journal of the Royal Statistical Society Series B-Statistical Methodology 10: 243–251. [Google Scholar]
  • 38. Abouheif E (1999) A method for testing the assumption of phylogenetic independence in comparative data. Evolutionary Ecology Research 1: 895–909. [Google Scholar]
  • 39. Thioulouse J, Chessel D, Champely S (1995) Multivariate analysis of spatial patterns: a unified approach to local and global structures. Environmental and Ecological Statistics 2: 1–14. [Google Scholar]
  • 40. Diniz JAF, De Sant'ana CER, Bini LM (1998) An eigenvector method for estimating phylogenetic inertia. Evolution 52: 1247–1262. [DOI] [PubMed] [Google Scholar]
  • 41. Dray S, Dufour AB (2007) The ade4 package: Implementing the duality diagram for ecologists. Journal of Statistical Software 22: 1–20. [Google Scholar]
  • 42. Jombart T, Dray S (2010) Adephylo: exploratory analyses for the phylogenetic comparative method. Bioinformatics 26: 1907–1909. [DOI] [PubMed] [Google Scholar]
  • 43. Paradis E, Claude J, Strimmer K (2004) APE: Analyses of Phylogenetics and Evolution in R language. Bioinformatics 20: 289–290. [DOI] [PubMed] [Google Scholar]
  • 44. Herrera HM, Lisboa CV, Pinho AP, Olifiers N, Bianchi RC, et al. (2008) The coati (Nasua nasua, Carnivora, Procyonidae) as a reservoir host for the main lineages of Trypanosoma cruzi in the Pantanal region, Brazil. Trans R Soc Trop Med Hyg 102: 1133–1139. [DOI] [PubMed] [Google Scholar]
  • 45. Alves FM, Olifiers N, Bianchi RC, Duarte AC, Cotias PM, et al. (2011) Modulating variables of Trypanosoma cruzi and Trypanosoma evansi transmission in free-ranging coati (Nasua nasua) from the Brazilian Pantanal region. Vector Borne Zoonotic Dis 11: 835–841. [DOI] [PubMed] [Google Scholar]
  • 46. Desbiez ALJ, Bodmer RE, Tomas WM (2010) Mammalian Densities in a Neotropical Wetland Subject to Extreme Climatic Events. Biotropica 42: 372–378. [Google Scholar]
  • 47. Patz JA, Graczyk TK, Geller N, Vittor AY (2000) Effects of environmental change on emerging parasitic diseases. Int J Parasitol 30: 1395–1405. [DOI] [PubMed] [Google Scholar]
  • 48. Roellig DM, Ellis AE, Yabsley MJ (2009) Genetically different isolates of Trypanosoma cruzi elicit different infection dynamics in raccoons (Procyon lotor) and Virginia opossums (Didelphis virginiana). Int J Parasitol 39: 1603–1610. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 49. Lewis MD, Ma J, Yeo M, Carrasco HJ, Llewellyn MS, et al. (2009) Genotyping of Trypanosoma cruzi: systematic selection of assays allowing rapid and accurate discrimination of all known lineages. Am J Trop Med Hyg 81: 1041–1049. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 50. Marcili A, Lima L, Cavazzana M, Junqueira AC, Veludo HH, et al. (2009) A new genotype of Trypanosoma cruzi associated with bats evidenced by phylogenetic analyses using SSU rDNA, cytochrome b and Histone H2B genes and genotyping based on ITS1 rDNA. Parasitology 136: 641–655. [DOI] [PubMed] [Google Scholar]
  • 51. Hirsch BT (2011) Long-term adult male sociality in ring-tailed coatis (Nasua nasua). Mammalia 75: 301–304. [DOI] [PubMed] [Google Scholar]
  • 52.Bianchi RC (2009) Ecologia de mesocarnívoros em uma área no Pantanal Central, Mato Grosso do Sul. [Thesis]. Corumbá: Federal University of Mato Grosso do Sul. 193 p.
  • 53. Hirsch BT, Maldonado JE (2011) Familiarity breeds progeny: sociality increases reproductive success in adult male ring-tailed coatis (Nasua nasua). Molecular Ecology 20: 409–419. [DOI] [PubMed] [Google Scholar]
  • 54. Brown EL, Roellig DM, Gompper ME, Monello RJ, Wenning KM, et al. (2010) Seroprevalence of Trypanosoma cruzi Among Eleven Potential Reservoir Species from Six States Across the Southern United States. Vector-Borne and Zoonotic Diseases 10: 757–763. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 55. Gaunt M, Miles M (2000) The ecotopes and evolution of triatomine bugs (triatominae) and their associated trypanosomes. Mem Inst Oswaldo Cruz 95: 557–565. [DOI] [PubMed] [Google Scholar]
  • 56. Machado EM, Fernandes AJ, Murta SM, Vitor RW, Camilo DJ, et al. (2001) A study of experimental reinfection by Trypanosoma cruzi in dogs. Am J Trop Med Hyg 65: 958–965. [DOI] [PubMed] [Google Scholar]
  • 57. Desbiez ALJ, Borges PAL (2010) Density, habitat selection and observations of South American Coati Nasua nasua in the central region of the Brazilian Pantanal wetland. Small Carnivore Conservation 42: 14–18. [Google Scholar]
  • 58. Rademaker V, Herrera HM, Raffel TR, D'Andrea PS, Freitas TP, et al. (2009) What is the role of small rodents in the transmission cycle of Trypanosoma cruzi and Trypanosoma evansi (Kinetoplastida Trypanosomatidae)? A study case in the Brazilian Pantanal. Acta Trop 111: 102–107. [DOI] [PubMed] [Google Scholar]
  • 59. Albuquerque RD, Barretto MP (1970) On wild reservoirs and vectors of Trypanosoma cruzi. XLIV. Natural infection of the field fox, Dusicyon (Lycalopex) vetulus (Lung, 1842) by T. cruzi . Rev Inst Med Trop Sao Paulo 12: 375–382. [PubMed] [Google Scholar]
  • 60. Courtenay O, Macdonald DW, Gillingham S, Almeida G, Dias R (2006) First observations on South America's largely insectivorous canid: the hoary fox (Pseudaloplex vetulus). Journal of Zoology 268: 45–54. [Google Scholar]
  • 61. Mendes PC, Lima SC, Paula MBC, Souza AA, Rodrigues EAS, et al. (2008) Chagas disease and the space distribution of captured triatomines in Uberlândia, Minas Gerais - Brazil. Hygeia 3: 176–204. [Google Scholar]
  • 62. Roque AL, Xavier SC, da Rocha MG, Duarte AC, D'Andrea PS, et al. (2008) Trypanosoma cruzi transmission cycle among wild and domestic mammals in three areas of orally transmitted Chagas disease outbreaks. Am J Trop Med Hyg 79: 742–749. [PubMed] [Google Scholar]
  • 63. Gittleman JL, Harvey PH (1982) Carnivore Home-Range Size, Metabolic Needs and Ecology. Behavioral Ecology and Sociobiology 10: 57–63. [Google Scholar]
  • 64. Davis DS, Russell LH, Adams LG, Yaeger RG, Robinson RM (1980) An experimental infection of Trypanosoma cruzi in striped skunks (Mephitis mephitis). J Wildl Dis 16: 403–406. [DOI] [PubMed] [Google Scholar]
  • 65. Martinelli MM, Volpi TA (2010) Diet of racoon Procyon cancrivorus (Carnivora, Procyonidae) in a mangrove and restinga area in Espirito Santo state, Brazil. Natureza on-line 8: 150–151. [Google Scholar]
  • 66. Queirolo D, Motta-Junior JC (2007) Prey availability and diet of maned wolf in Serra da Canastra National Park, southeastern Brazil. Acta Theriologica 52: 391–402. [Google Scholar]
  • 67. Jacomo ATDA, Silveira L, Diniz JAF (2004) Niche separation between the maned wolf (Chrysocyon brachyurus), the crab-eating fox (Dusicyon thous) and the hoary fox (Dusicyon vetulus) in central Brazil. Journal of Zoology 262: 99–106. [Google Scholar]
  • 68. Martins R, Quadros J, Mazzolli M (2008) Food habits and anthropic interference on the territorial marking activity of Puma concolor and Leopardus pardalis (Carnivora: Felidae) and other carnivores in the Juréia-Itatins Ecological Station, São Paulo, Brazil. Revista Brasileira de Zoologia 25: 427–435. [Google Scholar]
  • 69. Vynne C, Keim JL, Machado RB, Marinho J, Silveira L, et al. (2011) Resource selection and its implications for wide-ranging mammals of the brazilian Cerrado. Plos One 6: e28939. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 70. Albuquerque RD, Barretto MP (1968) Studies on wild reservoirs and vectors of "Trypanosoma cruzi." XXX: natural infection of the bush dog, "Cerdocyon thous azarae" (Wied, 1824) by "T. cruzi". Rev Bras Biol 28: 457–468. [PubMed] [Google Scholar]
  • 71. Neghme A, Schenone H (1962) Enfermedad de Chagas en Chile: viente años de investigación. Ann Congr Int Doença de Chagas 3: 1069–1105. [Google Scholar]
  • 72. Whiting C (1946) Contribuición al estudio de las reservas de parasitos de la enfermedad de Chagas en Chile. Primeiros hallazgos en Chile de mamiferos silvestres infestados por Trypanosoma cruzi . Rev Chil Hig Med Prev 8: 69–100. [Google Scholar]
  • 73. Mazza S (1940) Otros mamíferos infectados naturalmente por Schizotrypanum cruzi, o cruzi-similes en provincias de Jujuy y Salta. M.E.P.R.A. 45: 119–134. [Google Scholar]
  • 74. Cardinal MV, Lauricella MA, Ceballos LA, Lanati L, Marcet PL, et al. (2008) Molecular epidemiology of domestic and sylvatic Trypanosoma cruzi infection in rural northwestern Argentina. International Journal for Parasitology 38: 1533–1543. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 75. Ceballos LA, Cardinal MV, Vazquez-Prokopec GM, Lauricella MA, Orozco MM, et al. (2006) Long-term reduction of Trypanosoma cruzi infection in sylvatic mammals following deforestation and sustained vector surveillance in northwestern Argentina. Acta Trop 98: 286–296. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 76. Wisnivesky-Colli C, Schweigmann NJ, Alberti A, Pietrokovsky SM, Conti O, et al. (1992) Sylvatic American trypanosomiasis in Argentina. Trypanosoma cruzi infection in mammals from the Chaco forest in Santiago del Estero. Trans R Soc Trop Med Hyg 86: 38–41. [DOI] [PubMed] [Google Scholar]
  • 77. Pietrokovsky SM, Schweigmann NJ, Riarte A, Alberti A, Conti O, et al. (1991) The skunk Conepatus chinga as new host of Trypanosoma cruzi in Argentina. J Parasitol 77: 643–645. [PubMed] [Google Scholar]
  • 78. Barretto MP, Ribeiro RD (1972) Studies on wild reservoirs and vectors of Trypanosoma cruzi. LI. Natural infection of the mustelid, Eira barbara barbara (Lin., 1758) by T. cruzi . Rev Bras Biol 32: 413–418. [PubMed] [Google Scholar]
  • 79. Deane LM (1964) Animal reservoirs of Trypanosoma cruzi in Brazil. Rev Bras Malariol Doencas Trop 16: 27–48. [PubMed] [Google Scholar]
  • 80. Deane LM (1961) Tripanosomídeos de mamíferos da região amazônica. I – Alguns flagelados encontrados no sangue de mamíferos silvestres do Estado do Pará. Rev Inst Med Trop Sao Paulo 3: 15–28. [Google Scholar]
  • 81. Rodrigues BA, Mello GB (1942) Contribuição ao estudo da tripanosomíase americana. Memorias do Instituto Oswaldo Cruz 37: 77–94. [Google Scholar]
  • 82. Ferriolli FF, Barretto MP (1969) Studies on wild reservoirs and vectors of Trypanosoma cruzi. XXXV. Natural infection of the ferret Galictis cuja furax (Thomas, 1907) by T. cruzi . Rev Inst Med Trop Sao Paulo 11: 264–273. [PubMed] [Google Scholar]
  • 83. Barretto MP, Albuquerque RD (1971) Studies on reservoirs and wild vectors of Trypanosoma cruzi. XLVII. Natural infection of the mustelid, Galictis vittata braziliensis (Thunberg, 1820) by T. cruzi . Rev Inst Med Trop Sao Paulo 13: 346–351. [PubMed] [Google Scholar]
  • 84. Lisboa CV, Xavier SC, Herrera HM, Jansen AM (2009) The ecology of the Trypanosoma cruzi transmission cycle: Dispersion of zymodeme 3 (Z3) in wild hosts from Brazilian biomes. Vet Parasitol 165: 19–24. [DOI] [PubMed] [Google Scholar]
  • 85. Lainson R, Shaw JJ, Fraiha H, Miles MA, Draper CC (1979) Chagas's Disease in the Amazon Basin: 1. Trypanosoma cruzi infections in silvatic mammals, triatomine bugs and man in the State of Para, north Brazil. Trans R Soc Trop Med Hyg 73: 193–204. [DOI] [PubMed] [Google Scholar]
  • 86. Miles MA, Povoa MM, de Souza AA, Lainson R, Shaw JJ, et al. (1981) Chagas's disease in the Amazon Basin: I. The distribution of Trypanosoma cruzi zymodemes 1 and 3 in Para State, north Brazil. Trans R Soc Trop Med Hyg 75: 667–674. [DOI] [PubMed] [Google Scholar]
  • 87. Ferriolli FF, Barretto MP (1968) Studies on wild reservoirs and vectors of Trypanosoma cruzi. XXIX. Natural infection of Nasua nasua solitaria Schinz 1821 by T. cruzi . Rev Inst Med Trop Sao Paulo 10: 354–363. [PubMed] [Google Scholar]
  • 88. Travi BL, Jaramillo C, Montoya J, Segura I, Zea A, et al. (1994) Didelphis marsupialis, an important reservoir of Trypanosoma (Schizotrypanum) cruzi and Leishmania (Leishmania) chagasi in Colombia. American Journal of Tropical Medicine and Hygiene 50: 557–565. [DOI] [PubMed] [Google Scholar]
  • 89. Barretto MP, Ferriolli FF (1970) Wild reservoirs and vectors of Trypanosoma cruzi. XXXIX: Natural infection of Procyon cancrivorus nigripes Mivart, 1885, by T. cruzi . Rev Bras Biol 30: 431–438. [PubMed] [Google Scholar]
  • 90.Wilson DE, Reeder DM (editors) (2005) Mammal species of the world. A Taxonomic and geographic reference. Johns Hopkins University Press. 2142 p.

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Figure S1

Trypanosoma cruzi infectiveness rates (%) of each species at the tips of the phylogeny and values on the phylogenetic eigenvector 1 (P.E.V. 1) from Agnarsson et al. (2010). Infectiveness rates were determined as the total positive/total examined*100 in hemoculture or xenodiagnosis tests. Values are scales and normalized around 0 to have a comparable scale.

(PDF)

Table S1

Trypanosoma cruzi infection rates in Brazil and species’ diet.

(PDF)

(PDF)

Table S2

Trypanosoma cruzi infectiveness rates (%) of Neotropical wild carnivores from this study and literature records. Infectiveness rate (INF) for each species based on parasitological tests (hemoculture, xenodiagnosis or fresh blood examination) was calculated by total positive/total examined*100.

(PDF)


Articles from PLoS ONE are provided here courtesy of PLOS

RESOURCES